Voltage Regulator Control
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Voltage Regulator Control Instructions Manual EE-55166 Revision 2 - December/2011 The informations contained in this document are subject to alterations without prior notice. © 2011 Toshiba Infraestrutura América do Sul Ltda. all rights reserved. Toshiba Infraestrutura América do Sul Ltda. may hold patents, trademarks, copyrights or other intellectual property rights related to the content of this document. The possession of this document by the customer does not imply the concession of any right in relation to such patents, trademarks, copyrights, or other intellectual property rights, except those expressly mentioned in the appropriate license agreement, in writing, signed by Toshiba Infraestrutura América do Sul Ltda. EE-55166 TB-R1000 / Instructions Manual A Security Information The objective of this manual is to provide general information about the functionality of the voltage regulator TB-R1000 control. It does not exempt the user from the responsibility of the application, installation, operations and maintenance of this equipment. DANGER: This equipment operates at hazardous levels of supply voltage, and it can cause death or serious injury to the user. WARNING: This equipment shall be operated by authorized and trained personnel only. —User profile: For the purposes of this manual, any authorized and trained person is aware of the electrical risks inherent to the operation of the equipment being discussed (Voltage Regulator). Furthermore, the user shall have the following qualifications: a) Be trained and authorized to energize, de-energize, operate, parameterize, ground, and to carry out the maintenance procedures in accordance with to the security standards established by the user and under its responsibility. b) Be trained to operate and use the personal safety equipment properly, such as rubber gloves, helmet, safety goggles or masks, safety clothing, etc., in accordance with to the security standards established. c) Be trained in rendering first aid. d) Be trained in relation to the operational principles of the TB-R1000 CONTROL, as well as of its parameterization —Terminal blocks “1” and “12” located inside the box of the TB-R1000 CONTROL refer to the secondary of the CT of measurement of the regulator's current. DANGER: Before disconnecting the plug connectors of 20 pins on the rear part of the upper control panel, close the jump between the terminal blocks “1” and “12” located inside the box, avoiding open CT secondary. — To put the voltage regulator in or out of service, follow the instructions contained in the label attached to the box of the TB-R1000 control (Figure 01). DANGER: Before proceeding with the operations put the voltage regulator in or out of service, make sure that the indicating light of neutral position, located on the lower control panel, is lit and there is an indication of TAP “0” on the front control panel and on the external position indicator. Do not proceed with the operations before confirming these items. TB-R1000 / Instructions Manual B Security Information Figure 01 TB-R1000 / Instructions Manual C Table of Contents 1.0 1.1 1.2 1.3 1.4 1.5 Introduction............................................................................................................. Standard of quality.................................................................................................... Overview................................................................................................................... Available Functions .................................................................................................. Specifications of the equipment............................................................................... Type tests.................................................................................................................. 1 1 1 1 2 2 2.0 2.1 2.1.1 2.1.2 2.1.3 2.1.4 2.1.5 2.1.6 2.1.7 2.1.8 2.1.9 2.1.10 2.1.11 2.1.12 2.1.13 2.2 2.2.1 2.2.2 2.2.3 2.2.4 2.2.5 2.2.6 2.2.7 2.2.8 2.2.9 2.2.10 Layout of the Front Panel, Operations and Controls............................................. Upper panel.............................................................................................................. Display...................................................................................................................... Indications of the LCD............................................................................................... Keypad..................................................................................................................... Reset key.................................................................................................................. Manual/ Automatic key............................................................................................. Local/Remote key..................................................................................................... Raise Tap key............................................................................................................ Lower Tap key........................................................................................................... Menu key.................................................................................................................. Conf key.................................................................................................................... Increment key........................................................................................................... Decrement key.......................................................................................................... Serial communication port 1..................................................................................... Lower panel.............................................................................................................. External supply terminals......................................................................................... Voltmeter terminals................................................................................................... Operation counter..................................................................................................... Neutral indicating light.............................................................................................. Power switch............................................................................................................. Auxiliary control........................................................................................................ ON/Off switch........................................................................................................... Raise/Lower switch................................................................................................... Control fuse.............................................................................................................. Motor fuse................................................................................................................. 3 3 3 4 5 5 5 5 5 5 5 5 5 5 5 6 6 6 6 6 6 6 6 6 7 7 3.0 3.1 3.2 Modes of operation................................................................................................. 8 Manual/Automatic.................................................................................................... 8 Local/Remote........................................................................................................... 8 4.0 4.1 4.1.1 4.1.2 4.1.3 4.1.4 4.1.5 4.1.6 4.1.7 4.2 4.3 Display units............................................................................................................ Types of units............................................................................................................ Parameters............................................................................................................... Demands.................................................................................................................. Instantaneous........................................................................................................... Function.................................................................................................................... Configuration............................................................................................................ Totalizers................................................................................................................... Registers................................................................................................................... Hourly post function.................................................................................................. Daylight saving time.................................................................................................. TB-R1000 / Instructions Manual D 9 9 9 9 9 9 9 9 9 9 10 Table of Contents 4.4 4.5 Menu functions......................................................................................................... function codes.......................................................................................................... 11 13 5.0 5.1 5.2 5.3 Functions................................................................................................................. Reference voltage..................................................................................................... Bandwidth................................................................................................................. Time delay ................................................................................................................ 34 34 34 34 5.4 5.5 5.5.1 5.5.2 5.5.3 5.5.4 5.5.5 5.5.6 5.6 5.7 5.8 5.9 5.10 5.11 5.12 5.13 Adjustment of the line voltage drop compensator....... ............................................ Mode of operation of the reverse flow...................................................................... Locked forward mode ............................................................................................. Locked reverse mode ............................................................................................. Reverse IDLE mode ................................................................................................ Bi-directional mode ................................................................................................. Neutral IDLE mode .................................................................................................. Co-generation mode ............................................................................................... Load bonus mode ................................................................................................... Voltage limiter mode ................................................................................................ Self test..................................................................................................................... Date and Time Presentation ..................................................................................... Number of resets made since the last start-up.......................................................... TAP Zero function..................................................................................................... Open door detector.................................................................................................. Keypad password.................................................................................................... 35 36 37 37 38 38 38 39 39 40 41 41 41 42 42 42 6.0 Protocol DNP 3.0..................................................................................................... 43 7.0 7.1 7.2 7.3 7.4 7.5 7.6 7.7 7.8 7.9 7.10 7.11 Communication and configuration software........................................................ Minimum hardware requirements............................................................................ Software installation................................................................................................. Software basic operation.......................................................................................... File menu................................................................................................................. Registration menu.................................................................................................... Factory menu........................................................................................................... Tools menu............................................................................................................... Macro menu............................................................................................................. Report menu............................................................................................................ Graph menu............................................................................................................ Help menu................................................................................................................. 51 51 51 53 54 54 60 66 77 78 79 82 8.0 8.1 8.2 8.3 8.4 8.5 Installations and connections............................................................................... Characteristics of the control box............................................................................. Layout of the control box.......................................................................................... Layout of the control box with resistance heating controlled by thermostat.............. Schematic wiring diagram ....................................................................................... Schematic wiring diagram with resistance heating controlled by thermostat.......... 83 83 84 85 86 87 9.0 9.1 9.2 9.3 Accessories............................................................................................................ Auxiliary printed circuit board TB-PA102 (Optional)................................................. Transformer to correct voltage external power control (Optional)............................ Resistance heating controlled by thermostat (Optional).......................................... 88 88 89 89 TB-R1000 / Instructions Manual E 1 - Introduction 1.0 Introduction measured at intervals previously adjusted in the panel. It is possible to obtain all the values adjusted and measured through a serial port, also allowing the remote operation of the control. It also has a Clock / Calendar to register the events. This clock uses a super back-up capacitor that keeps it working during a power failure for at least 500 hours. All the circuits are protected against transients through varistors and fuses. This manual contains the instructions for the installation, operation, and maintenance of the TB-R1000 control for Single-phase Voltage Regulators manufactured by Toshiba Infraestrutura América do Sul Ltda. and equipped with tap changers of the types CR3, CR5, CR7, and CR10. 1.1 Standard of quality Toshiba Infraestrutura América do Sul Ltda. is a 100% subsidiary of Toshiba Corporation and is certified according to the standards ISO9001 and ISO14001. DNP3 POWER SUPPLY CONTROL SIGNAL 1.2 Overview WATCH DOG The objective of the TB-R1000 control for single-phase voltage regulator is to maintain the voltage at the consumer within the parameters selected by monitoring the line and by activating the “ON LOAD TAP CHANGER”. As a result, it brings the following benefits: RTC RS 232 RS 485 OPTIC FIBER ETHERNET MODEM GSM DRIVER V DSP 60 MIPs DRIVER I LCD MOTOR DRIVER M 1.3 Available functions —Line drop compensator; —Voltage limiter; —Reverse flow detector; —Line parameters measurement; —Measurement of demand with register of events; —Serial port for communication with protocol DNP 3.0; —Clock / Calendar; —Indication of position with the respective maximum and minimum values and with register of events; —Tap zero function. —Voltage regulated at the consumer; —Provides quality in the power supply. The TB-R1000 control has been designed based on the architecture of a DSP within 60 MIPs, which has a 256 kBytes of FLASH MEMORY. The flash memory is responsible for retaining the adjustments and memories during a power failure, thus ensuring that the control will keep all its adjustments without alterations even during long periods of supply shortage. A 12-bit A/D converter is used to convert the voltage and the line current from analog to digital. This information is used for processing the control, which, if compared to the adjusted values, will result in a corrective action in the system. The values adjusted and measured and the position of the on load tap changer can be visualized in a LCD. The TB-R1000 control has a RAM memory that registers the instantaneous values Communication DNP 3.0 RS232 RS485 Ethernet Optic fiber Optional Modem GSM Inputs Current transformer Potential transformer Neutral position indication Operation counter Polarity reversal Position sensor TB-R1000 / Instructions Manual 1 Outputs Motor Analog operation counter Analog position indicator reset 1 - Introduction —IEC 60255-22-4/02 Electrical fast transient/burst immunity test —IEC 61000-4-11/00 Voltage dips, short interruptions and voltage variations immunity test. —IEC -CISPR 22 Conducted and radiated emissivity. —IEC 60068-2-1 Cold test. —IEC 60068-2-14 Thermal cycle. —IEC 60068-2-2 Dry heat. —IEC 60068-2-78 Dump heat. —IEC 60255-21-1 Vibration. 1.4 Specifications of the equipment —Dimensions: Case 85 x 227 x 235 mm. Control box 165 x 304 x 470 mm. Weight: Case 2 kg. Control box + Case = 10.5 kg. —Load (120V): 4VA. —Operating temperature range: -40 to +85°C. —Accuracy within the measurement range: 0.5%. — Measurement Range: 80-137 VAC,45-65 Hz. —Current input: Measurement range 00.400 A(ac) 45-65 Hz with error margin below 0.5% (0.001 A) of the rated current at full charge (0.200 A). —Values calculated: kVA, kW, and kVAr, with error margin below 1% in all conditions. —“Absolute limit” supply range: 40 to 260 VAC. —Current: The control can support the short-circuit current in the regulator without damages or loss of calibration. 1.5 Type Tests —IEC 60255-22-5/02 High energy surges immunity test. —IEC 60255-22-1/88 1Mhz burst immunity test. —IEC 61000-4-3/00 Radiated, radio frequency, electromagnetic field immunity test. —IEC 60255-22-6/01 Immunity to electromagnetic fields from radio interference. —IEC 61000-4-8/00 Power frequency magnetic field immunity test. —IEC 60255-5/00 Impulse voltage test. —IEC 60255-5/00 Dielectric test. —IEC60255-22-2/96 Immunity test. TB-R1000 / Instructions Manual 2 2 - Layout of the Front Panel, Operations and Controls 2.0 Layout of the Front Panel, Operations and Controls 2.1.1 LCD 2.1.9 2.1.11 2.1.4 2.1.3 2.1 Upper Panel (Case) Keypad MENU 2.1.5 2.1.7 5.11 2.1.6 CONF 2.1.3 Keypad 2.1.8 2.1.10 T B- R10 0 0 2.1.12 2.1.13 RS-232 Serial Port 1 (Connector DB9) 2.2.3 Motor Fuse 2.2.10 Neutral Indicating Light 2.2 Lower Panel 2.2.9 Analog Operations Counter 2.2.4 Control Fuse 000 000 2.2.5 Power Switch 2.2.2 Voltmeter Terminals The front panel of TB-R1000 is divided into two sections, an upper panel, and a lower panel. 2.2.7 2.2.8 2.2.1 Auxiliary Control External supply Terminals 2.2.6 codes using the keypad, the obtainment of information about: ! Mode of operation: Manual/Automatic. — Mode of control: Local / Remote. — Load Bonus: Maximum / Minimum. — Voltage out of band: Raise or lower or below the parameterized values. — Voltage limit control: upper / lower. — Operating quadrant: Inductive or capacitive characteristic. — Power flow: Direct / Reverse. 2.1 Upper panel The following items are available in the upper panel: ! Liquid crystal display ! Keypad ! RS-232 Serial port 1 (Connector DB 9) 2.1.1 Display - The control is equipped with a LCD with characters dedicated to the voltage regulators functions, which allows, at the same time and without the necessity of accessing The display is equipped with backlight for operations with low luminosity. TB-R1000 / Instructions Manual 3 2 - Layout of the Front Panel, Operations and Controls 2.1.2 Indications of the LCD DEM 0 MAX MENU MIN CONF Magnitude Description ! Defines the description of the value displayed. Manual Mode ! Indicates the mode of operation. Enabled through the key MANUAL/AUTO. 1st Quadrant 2nd Quadrant 3rd Quadrant 4th Quadrant Remote mode Maximum load bonus Minimum load bonus Code and sub-code ! Local/Remote: Indicates the type of control. Enabled through the key LOCAL/REMOTE. Code Sub-code Magnitude unit ! Indicates the LOAD BONUS function in the maximum and minimum TAP values. Lower voltage Hourly Post Maximum voltage limiting activated Minimum voltage limiting activated ! Indicates the code and sub-code of the unit presented in the display. ! Indicates the unit of measurement presented in the display. Value of magnitude Demand Raise voltage ! Indicates the quadrant operation, as well as the power flow. 1st Quadrant: Direct flow with inductive load. 2nd Quadrant: Reverse flow with capacitive load. 3rd Quadrant: Reverse flow with inductive load. 4th Quadrant: Direct flow with capacitive load. ! Indicates the necessity of increasing or decreasing the voltage according to the values parameterized. Maximum demand Minimum demand Function ! Indicates the current hourly post. TAP 0 activated Activated menu ! Indicates the operation of the voltage limit function in the maximum and minimum voltage values. Configuration TB-R1000 / Instructions Manual 4 ! Indicates the value of the unit presented in the display. ! Indicates the operation of the DEMAND function. ! Indicates the operation of the demand of voltage and current in the maximum and minimum values. ! Indicates the operation of the “TAP 0” function. ! Indicates that the static mode has been enabled. ! Indicates the alteration of a certain code. 2 - Layout of the Front Panel, Operations and Controls 2.1.3 Keypad MENU CONF 2.1.10 CONF CONF - Enables the parameters alteration using the keypad. When selected, CONF ). the indication CONF is displayed ( This key is enabled only with the display set in the static presentation mode. Through an easy-to-use keypad, it is possible to change the values adjusted, view the values measured, change the mode of operation, select the mode as manual or automatic, select the TB-R1000 in local or remote mode, and also activate the tap changer motor without the necessity of any kind of accessory. 2.1.11 Increment - This key is enabled only with the display set in the static presentation mode. It has dual function: ! Cycles the list of the display units in crescent order out of the “configuration mode” ( CONF disabled). ! Increments the parameter selected in CONF enabled). the “configuration mode”( 2.1.4 RESET - This key operates the eletromechanical drag hands on the regulator position indicator to the present TAP. This also reset the values in the codes 41 and 42. 2.1.5 Manual /Automatic - Indicates the control's mode of operation. See item 3.1 2.1.12 Decrement - This key is enabled only with the display set in the static presentation mode. It has dual function: ! Cycles the list of the display units in decreasing order out of the “configuration mode” ( CONF disabled). ! It diminishes the parameter selected in the “configuration mode” ( CONF enabled). 2.1.6 Local/Remote - Indicates the type of monitoring. See item 3.2. 2.1.7 Raise TAP manual mode. - Increase the TAP in the 2.1.8 Lower TAP manual mode. - Decrease the TAP in the 2.1.13 RS-232 Serial communication port 1 (Connector DB 9) The TB-R1000 serial port allows the data acquisition saved in the mass memory, parameterization, on-line viewing of the values measured, and operation of the control through the control communication software or through the communication protocol DNP3.0. Baud rate 1200 to 38400 bps with 8 bits without parity and 1 stop bit. DISPLAY navigation keys. 2.1.9 MENU MENU - Indicates the mode of exhibition of the display: Cyclic or static. !Cyclic Mode - The control presents up to 8 units in the display at interval of 4 seconds, parameterized through the TBR Control communication software. !Static Mode - It fixes the indication of the current unit displayed. In this mode, the MENU indication is displayed ( MENU ). TB-R1000 / Instructions Manual 5 2 - Layout of the Front Panel, Operations and Controls 2.2 lower panel They are available in the lower panel following items: External supply terminals ! Voltmeter terminals ! Operations counter ! Neutral indicating light ! Power switch ! Auxiliary control ! Control fuse, 0,5A ! Motor fuse ,4A ! External source fuse, 4A WARNING: Be sure that the voltage level and polarity of the external source ful fill the specifications before connect it to the TB-R1000 control terminals, the red terminal correspond to the line terminal (PHASE), the black terminal is hardwired directly to the control chassis and correspond to the GROUND terminal. Fails to comply with this procedure can cause injury to the user or damages to the equipment. NOTE 1. Minimum requirements for the external source: —Voltage (absolute limit): 105 up to 240 Vac 50Hz. —Power: 300 VA. 2.2.1 External supply terminals Allows the supply of the control in case of line drop voltage. In this condition, the power switch (2.2.5) shall be in the “External” position. 2.2.6 Auxiliary control WARNING: The TAP-Changer Control shall be used only in the absence of the upper panel (Case) of TB-R1000 control. 2.2.2 Voltmeter Terminals The lower panel of the TB-R1000 has terminals for measuring the secondary voltage supplied to the load. 2.2.3 Motor fuse, 4A Protects the tap changer motor. 2.2.7 “ On/Off” switch This switch determine the control for the tap-changer motor. In the “On” position only the tap-changer motor is powered, no power is delivered to control, the operator should raise or lower the tap-changer motor manually through the “RAISE / LOWER” switch. In the ”OFF” position only the control is powered, no power is delivered to the tapchanger motor. 2.2.4 Control fuse, 0,5A Protects the TB-R1000 from mis-wiring of a external pt. 2.2.5 Power switch This switch determines the power source for control and tap-changer motor. NORMAL position - The control and tapchanger motor are powered by the voltage regulator internal source. 2.2.8 “Raise/Lower” switch ² This switch allows the operator raise and lower the tap-changer motor manually. In the “RAISE” position the tap-changer may be raise by momentarily toggling the switch. In the “LOWER” position the tap-changer may be lowered by momentarily toggling the switch. EXTERNAL¹ position - The control and tap-changer motor are powered by an external source connected to the “EXTERNAL SOURCE” terminals. OFF position: the control and tap-changer are not powered. TB-R1000 / Instructions Manual 6 2 - Layout of the Front Panel, Operations and Controls NOTE 2. “RAISE/LOWER” switch has no priority over the “EXTERNAL / OFF / NORMAL” and ”ON / OFF” switches. The functionality described above is valid only with the “EXTERNAL / OFF / NORMAL” switch on “EXTERNAL” or ”NORMAL” position and the “ON / OFF” switch on ”ON” position. 2.2.9 Operation counter Indicates the number of operations carried out by the tap changer. 2.2.10 Neutral indicating light Indicates that the regulator is operating with TAP Zero. DANGER: This indication of neutral position as well as TAP 0 display indication (code 12, sub-code 00) shall be considered during maneuvering operations of regulator to put it into or out of operation in the transmission line.(System) TB-R1000 / Instructions Manual 7 3 - Modes of Operation of TAP's shall have the LOAD BONUS parameters defined in codes 70, 71 and 72. 3.0 Modes of operation 3.1 Manual / Automatic 3.2 Local / Remote — Automatic Mode: - The switch (2.2.5) of the lower panel shall be in the “Normal” position. - The key (2.1.5) of the upper panel shall be in the “Auto” position. In this condition the icon “ “ is not showed on the display. - The switch (2.2.7) of the Auxiliary Control in the lower panel shall be in the “Off” position. In this condition, when the voltage in the line moves to a level which represents on outof-band condition, the TB-R1000 will operate in the following manner: A) The indication of increasing ” “ or decreasing “ “ the voltage will be displayed. B) The temporization for activating the tap changer motor shall be initialized. C) During the temporization, if the level of voltage in the line returns to the values parameterized within the band, the indication of increasing or decreasing the voltage will be disabled and the temporization will be finished. D) If the voltage level remains out-of-band during the entire temporization, the control will activate the tap changer in order to reestablish the level of voltage within the parameterized values. The Local/Remote key selects the serial port that will be used for commanding and monitoring the equipment. Local = Allows communication RS-232 through serial 1 (front). Remote = Allows communication to automation through serial 2 (Auxiliary PCI). In this condition the icon “ “ is showed on the display. Note: When the equipment is operating in the remote mode, it is not possible to change the parameters of control through the front serial port, being only possible to read the units displayed. — Manual Mode: - The switch (2.2.5) of the lower panel shall be in the “Normal” position for the operation of the control supplied by the line voltage or in the “External” position for external supply through the terminals (2.2.1). - The key (2.1.5) of the upper panel shall be in the “Manual” position. In this condition the icon “ “ is showed on the display. - The switch (2.2.7) of the Auxiliary Control in the lower panel shall be in the “Off” position. In this condition, the control will not operate due to the variation of the voltage level in the line like the automatic mode, but through manual commands made by the user through the Raise and Lower keys of the upper panel. In the manual mode, the range of variation TB-R1000 / Instructions Manual 8 4 - Display Units 4.1.7 Register These are units of register of occurrence. 4.0 Display units 4.1 Types of units There are seven types of codes in the control. 4.2 Hourly post function The TB-R1000 has been designed to work with hourly post function, which is act of programming the units of set voltage, bandwidth, time delay, reactive and resistive compensation according to hourly-seasonal variations, i.e., these units change according to the day and time. The control has four (4) time categories that may be configured in various possible ways, being identified as A, B, C, and D, all displayed in the control. The units that can be reconfigured according to the time category described above are the following: - Set voltage - Bandwidth - Time delay - Reactive line drop compensation - Resistive line drop compensation - Time delay mode Each time category has two (2) units: 4.1.1 Parameter These are units responsible for determining the levels of adjustment necessary for the perfect operation of the control in the direct and reverse flows. 4.1.2 Demand These are units of measurement of integrated value in time as configured in code 84 (Demand time Interval). They present the following sub-codes: 00 Demand of the previous period. 01 M a x i m u m d e m a n d s i n c e t h e initialization. 02 Date of occurrence of the maximum demand. 03 Time of occurrence of the maximum demand. 04 M i n i m u m d e m a n d s i n c e t h e initialization. 05 Date of occurrence of the minimum demand. 06 Time of occurrence of the minimum demand. Initial time: indicates the beginning of the hourly post on the days on which it is valid. Day on which the time category is valid: indicates the days on which the time category is valid, according to the modalities of time category listed below: Hourly post modalities 0 = Disables the hourly post. 1 = Enables from the programmed hour. 2 = Enables from the programmed hour in the daylight saving time . 3 = Enables from the programmed hour except in the daylight saving time. 4 = Enables from the programmed hour from monday to Saturday. 5 = Enables from the programmed hour from monday to Friday. 6 = Enables from the programmed hour on saturdays, sundays, and holidays. 7 = Enables from the programmed hour on saturdays and sundays. 4.1.3 Instantaneous It presents instantaneous measurement values. 4.1.4 Function These are units related to the mode of work of the control. 4.1.5 Configuration These are units responsible for determining the parameters related to the control and its type of work. 4.1.6 Totalizer These are units that present cumulative values throughout time. TB-R1000 / Instructions Manual 9 4 - Display Units 8 = Enables from the programmed hour on sundays and holidays. 9 = Enables from the programmed hour on mondays. 10 = Enables from the programmed hour on thuesdays. 11 = Enables from the programmed hour on wednesdays. 12 = Enables from the programmed hour on thursdays. 13 = Enables from the programmed hour on fridays. 14 = Enables from the programmed hour on saturdays. 15 = Enables from the programmed hour on sundays. 16 = Enables from the programmed hour on holidays. precedence shall prevail over the time precedence, and the time precedence shall prevail over the post precedence. Category “A” will be selected whenever all other categories are disabled. Holiday When defining any post hourly as a holiday, it is necessary to enter with the date in the Holiday date. 4.3 Daylight saving time The routines of daylight saving time are adjusted through software DNP3 TBR Control software. To enable it, select the “Daylight saving time” and enter with the beginnig and end date. This routine subtracts one hour from the internal electronic clock when post hourly is detected. Note: When setting the time with the daylight saving time enabled, do not forget to enter one hour ahead, i.e., to set for 2:30 PM, you shall enter 3:30 PM. The Hourly post function has 3 precedence rules, which are: 1. Day precedence. 2. Post precedence. 3. Category precedence. The priority will consider that the day TB-R1000 / Instructions Manual 10 4 - Display Units 4.4 Menu functions Unit Flow direction Function Parameter Direct flow Reverse flow Measurement of Direct flow demand Code Set voltage Bandwidth Time delay Line compensation, resistance Line compensation, reactance Set voltage Bandwidth Time delay Line compensation, resistance Line compensation, reactance Load voltage demand Compensated voltage demand Function 005 051 052 053 054 055 020 021 Source voltage demand Load voltage demand Compensated voltage demand Load current demand Power factor for maximum and minimum KVA 032 033 Apparent power demand Active power demand 034 035 Reactive power demand Source voltage demand 036 037 Reverse flow operation mode Reverse current flow threshold Potentiometric disk existence Load bonus mode Upper position Lower position Voltage limiting mode Upper voltage Lower voltage Demand time Interval Self test Number of resets made since the last start-up Event log reset/Operation counter reset/Position indicator reset Keypad password 056 057 058 070 071 072 080 081 082 084 088 042 095 100 DNP 3.0 Local/Remote selection Enable unsolicited 101 102 Active power demand Reactive power demand Direct flow and Reverse flow 003 004 022 023 024 025 026 027 030 031 Load current demand Power factor for maximum and minimum KVA Apparent power demand Reverse flow 001 002 TB-R1000 / Instructions Manual 11 4 - Display Units 4.4 Menu functions Unit Flow direction Function Code Instantaneous measurement Direct flow and Reverse flow Instantaneous load voltage Instantaneous source voltage Instantaneous line drop compensated voltage Instantaneous load current Tap position indication Power factor and quadrant Instantaneous apparent power Instantaneous active power Instantaneous reactive power Line frequency 006 007 008 009 012 013 014 015 016 017 Configurations Direct flow and Reverse flow Totalizer Direct flow and Reverse flow Control identification Regulator configuration Time delay operation mode Nominal apparent power PT ratio CT ratio Operation counter Active energy Reactive energy 044 045 046 047 048 049 000 010 011 Register Direct flow and Reverse flow Maximum TAP Minimum TAP Date and time Date presentation 040 041 091 094 Communication Direct flow and Reverse flow Remote data port 096 TB-R1000 / Instructions Manual 12 4 - Display Units 4.5 Function codes Code Sub-code 00 Type of unit Selection of the unit Totalizer Operation counter -16 to 17 Unit of measurement Display 0P COU 00 00 NA Default Value NA Adjustment Ranges Using Keypad Low High 0 999999 XXXXX • Registry the number of commutations performed by the regulator since its initialization. It is incremented whenever occurs operation in the TAP change in the tap changer. • The sub-code 00 indicates the total of commutations made in the regulator. • The sub-codes from -16 to 16 indicate the total of commutations performed in each TAP, respectively. • The sub-code 17 indicates the total of commutations made in the neutral position (TAP ZERO). 01 00 to 03 Direct flow parameter Set voltage (Direct flow) SET V 01 00 Volt (V) 120 100 135 120.0 V • Range: 100 up to135 V. Step 0.1 V. • Indicates the voltage level to which the control will regulate in the regulator’s load side during the direct power flow. • The sub-codes 00, 01, 02, and 03 determine the parameterization to post hourly A, B, C, and D, respectively. See item 4.2. 02 00 to 03 Direct flow parameter Bandwidth (Direct flow) bANdW 02 00 Volt (V) 2.0 1.0 6.0 2.0 V • Range: 1 up to 6 V. Step 0.1 V. • Indicates the voltage range above and below the reference voltage in which the load side voltage in the direct flow can vary without TAP commutation in the regulator. Example: One bandwidth of 2.0 V adjusted to a set voltage of 120 V will result a range of 118.0 V to 122.0 V, where the TAP commutation in direct flow will not occur. • The sub-codes 00, 01, 02, and 03 determine the parameterization to post hourly A, B, C, and D, respectively. See item 4.2. 03 00 to 03 Direct flow parameter Time delay (Direct flow) T dEL 03 00 Seconds (S) 30 5 180 30 s • Range: 5 up to 180 s. Step 1 s. • Indicates the time delay (temporization) between the moment in which the voltage at the load side is out of the bandwidth until the beginning of the commutation, during the direct power flow. • See the function code 46, mode of operation of the control’s time delay. • The sub-codes 00, 01, 02, and 03 determine the parameterization to post hourly A, B, C, and D, respectively. See item 4.2. 04 00 to 03 Direct flow parameter Line compensation, UR resistance (Direct flow) 04 00 Volt (V) 0.0 -25 25 0.0 V • Range: -25 up to 25 V. Step 0.1 V. • Indicates the value of the voltage drop in the resistive component of the transmission line to unit resistive power factor when the load of the line requests rated current. It shall be adjusted in the cases where the load center is concentrated at the end of the line. • The sub-codes 00, 01, 02, and 03 determine the parameterization to post hourly A, B, C, and D, respectively. See item 4.2. 05 00 to 03 Direct flow parameter Line compensation, UX reactance (Direct flow) 05 00 Volt (V) 0.0 -25 25 0.0 V • Range: -25 up to 25 V. Step 0.1 V. • Indicates the value of the voltage drop in the reactive component of the transmission line to unit reactive power factor when the load of the line requests rated current. It shall be adjusted in the cases where the load center is concentrated at the end of the line. • The sub-codes 00, 01, 02, and 03 determine the parameterization to post hourly A, B, C, and D, respectively. See item 4.2. TB-R1000 / Instructions Manual 13 4 - Display Units 4.5 Function codes Code Sub-code 06 00 Type of unit Selection of the unit Display Unit of measurement Instantaneous measurement Instantaneous load voltage secondary LOAd V 06 00 XXX.X V Volt (V) Default Value NA Adjustment Ranges Using Keypad Low High NA NA • Indicates the RMS voltage in the PT’s secondary, load side, that is measured in the control’s input terminals. 06 01 Instantaneous measurement Instantaneous load voltage primary LOAd V 06 01 XX.XX KV Kilo Volt (KV) NA NA NA Volt (V) NA NA NA Kilo Volt (KV) NA NA NA Volt (V) NA NA NA • Indicates the RMS voltage in the PT’s primary (high voltage) in the load side. 07 00 Instantaneous measurement Instantaneous source voltage secondary SOUR V 07 00 XXX.X V • Indicates the instantaneous RMS voltage at the low voltage of the source side. 07 01 Instantaneous measurement Instantaneous source voltage primary SOUR V 07 01 XX.XX KV • Indicates the instantaneous RMS voltage at the high voltage of the source side. 08 00 Instantaneous measurement Instantaneous line drop compensated voltage COMP V 08 00 XXX.X V • Indicates the value of regulated voltage at the theoretical load center at the end of the line, considering its losses when the line drop compensator is activated through codes 04, 05, 54, and 55. • To disable the line drop compensation function, the codes 04, 05, 54, and 55 shall be parameterized at 0.0 V. 09 00 Instantaneous measurement Instantaneous load current secondary LOAd I 09 00 X.XXX A Ampere (A) NA NA NA Ampere (A) NA NA NA Kilo Watt hour (KWh) NA NA NA • It refers to the RMS current that circulates at the load side in the CT’s secondary. 09 01 Instantaneous measurement Instantaneous load current primary LOAd I 09 01 XX A • It refers to the RMS current that circulates at the load side in the CT’s primary. 10 Totalizer Active energy 00 to 01 dIACEN 10 00 X KWH • Sub-code 00 – Indicates the current value of measurement of active power in KWh in the direct flow. • Sub-code 01 – Indicates the current value of measurement of active power in KWh in the reverse flow. TB-R1000 / Instructions Manual 14 4 - Display Units 4.5 Function codes Code Type of unit Sub-code 11 Totalizer Display Unit of measurement Default Value dRENEI 11 00 X KVArh Kilo Var hour (KVArh) NA Selection of the unit Reactive energy 00 to 03 Adjustment Ranges Using Keypad Low High NA NA • Sub-code 00 – Indicates the current value of measurement of inductive Reactive Power in the direct flow in KVArh. • Sub-code 01 – Indicates the current value of measurement of capacitive Reactive Power in the reverse flow in KVArh. • Sub-code 02 – Indicates the current value of measurement of inductive Reactive Power in the reverse flow in KVArh. • Sub-code 03 – Indicates the current value of measurement of capacitive Reactive Power in the direct flow in KVArh. 12 00 Instantaneous measurement Tap position indication AT TAP 12 00 NA NA -16 16 NA NA NA NA XX • Indicates the tap changer’s current tap. • Sub-code 00 – Decimal indication. • Sub-code 01 – Fraction indication. • Sub-code 02 – Percentage indication. 13 00 to 01 Instantaneous measurement Power factor and quadrant PF 13 00 X.XX • Sub-code 00 – Indicates the difference of phase between the voltage and the current in the load side. Negative values mean reverse flow. • Sub-code 01 – Indicates the quadrant in which the regulator is operating. 1 – Direct flow, inductive load. 2 – Reverse flow, capacitive load. 3 – Reverse flow, inductive load. 4 – Direct flow, capacity load. It does not take into account the hysteresis defined in code 57 (reverse current flow threshold). 14 00 Instantaneous measurement Instantaneous apparent power AP POW 14 00 X KVA Kilo Volt Ampere (KVA) NA NA NA Kilo Watt (KW) NA NA NA Kilo VA reactive (KVAr) NA NA NA Hertz (Hz) NA NA NA • Indicates the instantaneous apparent power at the high voltage load side. NOTE: The letter X in KVA is a representative value of the measurement. 15 00 Instantaneous measurement Instantaneous active power AC POW 15 00 X KW • Indicates the instantaneous active power at the high voltage load side. NOTE: The letter X in KW is a representative value of the measurement. 16 00 Instantaneous measurement Instantaneous reactive power RE POW 16 00 X KVAR • Indicates the instantaneous reactive power at the high voltage load side. NOTE: The letter X in KVAr is a representative value of the measurement. 17 00 Instantaneous measurement Line frequency FREQ 17 00 XX.X HZ • Indicates the frequency value of the system measured by the control. • The control is able to operate in system with 45 to 65 Hz with accuracy in its measurements. TB-R1000 / Instructions Manual 15 4 - Display Units 4.5 Function codes Code Sub-code 20 00 Type of unit Selection of the unit Display Measurement of demand in direct flow Load voltage demand (Direct flow) LOAd V 20 00 XXX.X V Unit of measurement Volt (V) Default Value NA Adjustment Ranges Using Keypad Low High NA NA • Indicates the value of demand in the previous period of load side voltage in the direct flow. Its value is updated at the end of every period of integration parameterized in code 84. 20 Register 01 Maximum load voltage demand (Direct flow) LOAd V 20 01 XXX.X V Volt (V) NA NA NA • Indicates the value of maximum demand of load side voltage in the direct flow. Its value is updated when the demand of the previous period surpasses the current value. 20 Register 02 Date of the maximum load voltage demand (Direct flow) LOAd V 20 02 XX.XX.XXXX NA NA NA NA NA NA NA NA NA NA • Indicates the date in which occurred the maximum demand of load side voltage in direct flow. • The type for presenting the date is adjusted in code 94. 20 Register 03 Time of the maximum load voltage demand (Direct flow) LOAd V 20 03 XX:XX:XX H Hour • Indicates the time in which occurred the maximum demand of load side voltage in direct flow. 20 Register 04 Minimum load voltage demand (Direct flow) LOAd V 20 04 XXX.X V Volt (V) • Indicates the value of minimum demand of load side voltage in the direct flow. Its value is updated when the demand of the previous period is below the current value. 20 Register 05 Date of the minimum Load voltage demand (Direct flow) LOAd V 20 05 XX.XX.XXXX NA NA NA NA NA NA NA NA NA NA • Indicates the date in which occurred the minimum demand of load side voltage in direct flow. • The type for presenting the date is adjusted in code 94. 20 Register 06 Time of the minimum load voltage demand (Direct flow) LOAd V 20 06 XX:XX:XX H Hour • Indicates the time in which occurred the minimum demand of load side voltage in direct flow. 21 00 Measurement of demand in direct flow Compensated voltage COMP V demand (Direct flow) 21 00 XXX.X V Volt (V) • Indicates the value of demand in the previous period of compensated voltage in the direct flow. Its value is updated at the end of every period of integration parameterized in code 84. TB-R1000 / Instructions Manual 16 4 - Display Units 4.5 Function codes Code Sub-code 21 Type of unit Selection of the unit Register Maximum compensated voltage demand (Direct flow) 01 Display COMP V 21 01 XXX.X V Unit of measurement Volt (V) Default Value NA Adjustment Ranges Using Keypad Low High NA NA • Indicates the value of maximum demand of compensated voltage in the direct flow. Its value is updated when the demand of the previous period surpasses the current value. 21 Register 02 Date of the maximum compensated voltage demand (Direct flow) COMP V 21 02 XX.XX.XXXX NA NA NA NA NA NA NA NA NA NA • Indicates the date in which occurred the maximum demand of compensated voltage in direct flow. • The type for presenting the date is adjusted in code 94. 21 Register 03 Time of the maximum compensated voltage demand (Direct flow) COMP V 21 03 XX:XX:XX H Hour • Indicates the time in which occurred the maximum demand of compensated voltage in direct flow. 21 Register 04 Minimum compensated voltage demand (Direct flow) COMP V 21 04 XXX.X V Volt (V) • Indicates the value of minimum demand of compensated voltage in the direct flow. Its value is updated when the demand of the previous period is below the current value. 21 Register 05 Date of the minimum compensated voltage demand (Direct flow) COMP V 21 05 XX.XX.XXXX NA NA NA NA NA NA NA NA NA NA • Indicates the date in which occurred the minimum demand of compensated voltage in direct flow. • The type for presenting the date is adjusted in code 94. 21 Register 06 Time of the minimum compensated voltage demand (Direct flow) COMP V 21 06 XX:XX:XX H Hour • Indicates the time in which occurred the minimum demand of compensated voltage in direct flow. 22 00 Measurement of demand in direct flow Load current demand (Direct flow) LOAd I 22 00 X.XXX A Ampere (A) • Indicates the value of demand in the previous period of current in the direct fl ow. Its value is updated at the end of every period of integration parameterized in code 84. 22 01 Register Maximum load current demand (Direct flow) LOAd I 22 01 X.XXX A Ampere (A) NA NA NA • Indicates the value of maximum demand of cu rrent in the direct flow. Its value is updated when the demand of the previous period surpasses the current value. TB-R1000 / Instructions Manual 17 4 - Display Units 4.5 Function codes Code Sub-code 22 Adjustment Ranges Using Keypad Low High NA NA Type of unit Selection of the unit Display Unit of measurement Register Date of the maximum load current demand LOAd I 22 02 XX.XX.XXXX NA Default Value NA Hour NA NA NA Ampere (A) NA NA NA 02 • Indicates the date in which occurred the maximum demand of current in direct flow. • The type for presenting the date is adjusted in code 94. 22 Register 03 Time of the maximum load current demand LOAd I 22 03 XX:XX:XX H • Indicates the time in which occurred the maximum demand of current in direct flow. 22 Register 04 Minimum load current demand LOAd I 22 04 X.XXX A • Indicates the value of minimum demand of current in the direct flow. Its value is updated when the demand of the previous period is below the current value. 22 Register Date of the minimum load current demand 05 LOAd I 22 05 XX.XX.XXXX NA NA NA NA Hour NA NA NA NA NA NA NA NA NA NA NA NA NA • Indicates the date in which occurred the minimum demand of current in direct flow. • The type for presenting the date is adjusted in code 94. 22 Register 06 Time of the minimum load current demand LOAd I 22 06 XX:XX:XX H • Indicates the time in which occurred the minimum demand of current in direct flow. 23 Register 00 Power factor for maximum apparent power demand (Direct flow) PF APP 23 00 X.XX • Indicates the power factor for the maximum demand of apparent power in the direct flow. 23 Register 01 Power factor for minimum apparent power demand (Direct flow) PF APP 23 01 NA X.XX • Indicates the power factor for the minimum demand of apparent power in the direct flow. 24 00 Measurement of demand in direct flow Apparent power AP POW demand (Direct flow) 24 00 X kVolt Ampere (kVA) • Indicates the value of demand in the previous period of apparent power in the direct flow. Its value is updated at the end of every period of integration parameterized in code 84. 24 01 Register Maximum apparent power demand (Direct flow) AP POW 24 01 X kVolt Ampere (kVA) NA NA NA • Indicates the value of maximum demand of apparent power in the direct flow. Its value is updated when the demand of the previous period surpasses the current value. TB-R1000 / Instructions Manual 18 4 - Display Units 4.5 Function codes Code Type of unit Selection of the unit Display Sub-code 24 Unit of measurement Register Date of the maximum apparent power demand (Direct flow) AP POW 24 02 XX.XX.XXXX NA 02 Default Value NA Adjustment Ranges Using Keypad Low High NA NA • Indicates the date in which occurred the maximum demand of apparent power in direct flow. • The type for presenting the date is adjusted in code 94. 24 Register 03 Time of the maximum apparent power demand (Direct flow) AP POW 24 03 XX:XX:XX H Hour NA NA NA NA NA NA • Indicates the time in which occurred the maximum demand of apparent power in direct flow. 24 Register 04 Minimum apparent power demand (Direct flow) AP POW 24 04 X kVolt Ampere (kVA) • Indicates the value of minimum demand of apparent power in the direct flow. Its value is updated when the demand of the previous period is below the current value. 24 Register 05 Date of the minimum apparent power demand (Direct flow) AP POW 24 05 XX.XX.XXXX NA NA NA NA NA NA NA NA NA NA • Indicates the date in which occurred the minimum demand of apparent power in direct flow. • The type for presenting the date is adjusted in code 94. 24 Register 06 Time of the minimum apparent power demand (Direct flow) AP POW 24 06 XX:XX:XX H Hour • Indicates the time in which occurred the minimum demand of apparent power in direct flow. 25 00 Measurement of demand in direct flow Active power demand (Direct flow) AC POW 25 00 kWatt (kW) X KW • Indicates the value of demand in the previous period of active power in the direct flow. Its value is updated at the end of every period of integration parameterized in code 84. 25 Register 01 Maximum active power AC POW demand (Direct flow) 25 01 kWatt (kW) NA NA NA X KW • Indicates the value of maximum demand of active power in the direct flow. Its value is updated when the demand of the previous period surpasses the current value. 25 02 Register Date of the maximum active power demand (Direct flow) AC POW 25 02 XX.XX.XXXX NA • Indicates the date in which occurred the maximum demand of active power in direct flow. • The type for presenting the date is adjusted in code 94. TB-R1000 / Instructions Manual 19 NA NA NA 4 - Display Units 4.5 Function codes Code Type of unit Sub-code 25 Register 03 Selection of the unit Display Time of the AC POW maximum activel power 25 demand (Direct flow) 03 XX:XX:XX H Unit of measurement Default Value Hour NA Adjustment Ranges Using Keypad Low High NA NA • Indicates the time in which occurred the maximum demand of active power in direct flow. 25 Register 04 Minimum active power demand (Direct flow) AC POW 25 04 kWatt (kW) NA NA NA X KW • Indicates the value of minimum demand of active power in the direct flow. Its value is updated when the demand of the previous period is below the current value. 25 Register 05 Date of the minimum active power demand (Direct flow) AC POW 25 05 XX.XX.XXXX NA NA NA NA NA NA NA NA NA NA • Indicates the date in which occurred the minimum deman d of active power in direct flow. • The type for presenting the date is adjusted in code 94. 25 Register 06 Time of the minimum activepower demand (Direct flow) AC POW 25 06 XX:XX:XX H Hour • Indicates the time in which occurred the minimum demand of active power in direct flow. 26 00 Measurement of demand in direct flow Reactive power demand (Direct flow) RE POW 26 00 X KVAR kVolt -Amp Reactive (kVAr) • Indicates the value of demand in the previous period of reactive power in the direct flow. Its value is updated at the end of every period of integration parameterized in code 84. 26 Register 01 Maximum reactive power demand (Direct flow) RE POW 26 01 X KVAR kVolt -Amp Reactive (kVAr) NA NA NA • Indicates the value of maximum demand of reactive power in the direct flow. Its value is updated when the demand of the previous period surpasses the current value. 26 Register 02 Date of the maximum reactive power demand (Direct flow) RE POW 26 02 XX.XX.XXXX NA NA NA NA NA NA NA • Indicates the date in which occurred the maximum demand of reactive power in direct flow. • The type for presenting the date is adjusted in code 94. 26 03 Register Time of the maximum reactive power demand (Direct flow) RE POW 26 03 XX:XX:XX H Hour • Indicates the time in which occurred the maximum demand of reactive power in direct flow. TB-R1000 / Instructions Manual 20 4 - Display Units 4.5 Function codes Code Type of unit Selection of the unit Display Unit of measurement Default Value Sub-code 26 Register Minimum reactive power demand (Direct flow) RE POW 26 04 X KVAR kVolt -Amp Reactive (kVAr) NA 04 Adjustment Ranges Using Keypad Low High NA NA • Indicates the value of minimum demand of reactive power in the d irect flow. Its value is updated when the demand of the previous period is below the current value. 26 Register 05 Date of the minimum reactive power demand (Direct flow) RE POW 26 05 XX.XX.XXXX NA NA NA NA NA NA NA NA NA NA • Indicates the date in which occurred the minimum demand of reactive power in direct flow. • The type for presenting the date is adjusted in code 94. 26 Register 06 Time of the minimum reactive power demand (Direct flow) RE POW 25 06 XX:XX:XX H Hour • Indicates the time in which occurred the minimum demand of reactive power in direct flow. 27 00 Measurement of demand in direct flow Source voltage demand (Direct flow) SOUR V 27 00 XXX.X V Volt (V) • Indicates the value of demand in the previou s period of source side voltage in the direct flow. Its value is updated at the end of every period of integration parameterized in code 84. 27 Register 01 Maximum Source voltage demand (Direct flow) SOUR V 27 01 XXX.X V Volt (V) NA NA NA • Indicates the value of maximum demand of source side voltage in the direct flow. Its value is updated when the demand of the previous period surpasses the current value. 27 Register 02 Date of the maximum Source voltage demand (Direct flow) SOUR V 27 02 XX.XX.XXXX NA NA NA NA NA NA NA NA NA NA • Indicates the date in which occurred the maximum demand of source side voltage in direct flow. • The type for presenting the date is adjusted in code 94. 27 Register 03 Time of the maximum Source voltage demand (Direct flow) SOUR V 27 03 XX:XX:XX H Hour • Indicates the time in which occurred the maximum demand of source side voltage in direct flow. 27 04 Register Minimum Source voltage demand (Direct flow) SOUR V 27 04 XXX.X V Volt (V) • Indicates the value of minimum demand of source side voltage in the direct flow. Its value is updated when the demand of the previous period is below the current value. TB-R1000 / Instructions Manual 21 4 - Display Units 4.5 Function codes Code Sub-code 27 Type of unit Selection of the unit Display Unit of measurement Register Date of the minimum Source voltage demand (Direct flow) SOUR V 27 05 XX.XX.XXXX NA 05 Default Value NA Adjustment Ranges Using Keypad Low High NA NA • Indicates the date in which occurred the minimum demand of source side voltage in direct flow. • The type for presenting the date is adjusted in code 94. 27 Register 06 Time of the minimum Source voltage demand (Direct flow) SOUR V 27 06 XX:XX:XX H Hour NA NA NA NA NA NA • Indicates the time in which occurred the minimum demand of source side voltage in direct flow. 30 00 Measurement of demand in reverse flow Load voltage demand (Reverse) LOAdVR 30 00 XXX.X V Volt (V) • Indicates the value of demand in the previous period of load side voltage in the reverse flow. Its value is updated at the end of every period of integration parameterized in code 84. 30 Register 01 Maximum load voltage demand (Reverse) LOAdVR 30 01 XXX.X V Volt (V) NA NA NA • Indicates the value of maximum demand of load side voltage in the reverse flow. Its value is updated when the demand of the previous period surpasses the current value. 30 Register 02 Date of the maximum load voltage demand (Reverse) LOAdVR 30 02 XX.XX.XXXX NA NA NA NA NA NA NA NA NA NA • Indicates the date in which occurred the maximum demand of load side voltage in reverse flow. • The type for presenting the date is adjusted in code 94. 30 Register 03 Time of the maximum load voltage demand (Reverse) LOAdVR 30 03 XX:XX:XX H Hour • Indicates the time in which occurred the maximum demand of load side voltage in reverse flow. 30 Register 04 Minimum load voltage demand (Reverse) LOAdVR 30 04 XXX.X V Volt (V) • Indicates the value of minimum demand of load side voltage in the reverse flow. Its value is updated when the demand of the previous period is below the current value. 30 05 Register Date of the minimum load voltage demand (Reverse) LOAdVR 30 05 XX.XX.XXXX NA • Indicates the date in which occurred the minimum demand of load side voltage in reverse flow. • The type for presenting the date is adjusted in code 94. TB-R1000 / Instructions Manual 22 NA NA NA 4 - Display Units 4.5 Function codes Code Type of unit Selection of the unit Display Sub-code 30 Unit of measurement Register Time of the minimum load voltage demand (Reverse) LOAdVR 30 06 XX:XX:XX H Hour 06 Default Value NA Adjustment Ranges Using Keypad Low High NA NA • Indicates the time in which occurred the minimum demand of load side voltage in reverse flow. 31 00 Measurement of demand in reverse flow Compensated voltage demand (Reverse) COMPVR 31 00 XXX.X V Volt (V) NA NA NA • Indicates the value of demand in the previou s period of compensated voltage in the reverse flow. Its value is updated at the end of every period of integration parameterized in code 84. 31 Register 01 Maximum compensated voltage demand (Reverse) COMPVR 31 01 XXX.X V Volt (V) NA NA NA • Indicates the value of maximum demand of compensated voltage in the reverse flow. Its value is updated when the demand of the previous period surpasses the current value. 31 Register 02 Date of the maximum compensated voltage demand (Reverse) COMPVR 31 02 XX.XX.XXXX NA NA NA NA NA NA NA NA NA NA • Indicates the date in which occurred the maximum demand of compensated voltage in reverse flow. • The type for presenting the date is adjusted in code 94. 31 Register 03 Time of the maximum compensated voltage demand (Reverse) COMPVR 31 03 XX:XX:XX H Hour • Indicates the time in which occurred the maximum demand of compensated voltage in reverse flow. 31 Register 04 Minimum compensated voltage demand (Reverse) COMPVR 31 04 XXX.X V Volt (V) • Indicates the value of minimum demand of compensated voltage in the reverse flow. Its value is updated when the demand of the previous period is below the current value. 31 Register 05 Date of the minimum compensated voltage demand (Reverse) COMPVR 31 05 XX.XX.XXXX NA NA NA NA NA NA NA • Indicates the date in which occurred the minimum demand of compensated voltage in reverse flow. • The type for presenting the date is adjusted in code 94. 31 06 Register Time of the minimum compensated voltage demand (Reverse) COMPVR 31 06 XX:XX:XX H Hour • Indicates the time in which occurred the minimum demand of compensated voltage in reverse flow. TB-R1000 / Instructions Manual 23 4 - Display Units 4.5 Function codes Code Sub-code 32 00 Type of unit Selection of the unit Display Unit of measurement Measurement of demand in reverse flow Load current demand (Reverse) LOAdIR 32 00 X.XXX A Ampere (A) Default Value NA Adjustment Ranges Using Keypad Low High NA NA • Indicates the value of demand in the previous period of current in the reverse flow. Its value is updated at the end of every period of integration parameterized in code 84. 32 Register 01 Maximum load current demand (Reverse) LOAdIR 32 01 X.XXX A Ampere (A) NA NA NA • Indicates the value of maximum demand of current in the reverse flow. Its value is updated when the demand of the previous period surpasses the current value. 32 Register 02 Date of the maximum load current demand (Reverse) NA NA NA NA Hour NA NA NA Ampere (A) NA NA NA LOAdIR 32 02 XX.XX.XXXX • Indicates the date in which occurred the maximum demand of current in reverse flow. • The type for presenting the date is adjusted in code 94. 32 Register 03 Time of the maximum load current demand (Reverse) LOAdIR 32 03 XX:XX:XX H • Indicates the time in which occurred the maximum demand of current in reverse flow. 32 Register 04 Minimum load current demand (Reverse) LOAdIR 32 04 X.XXX A • Indicates the value of minimum demand of current in the reverse flow. Its value is updated when the demand of the previous period is below the current value. 32 Register 05 Date of the minimum load current demand (Reverse) LOAdIR 32 05 XX.XX.XXXX NA NA NA NA Hour NA NA NA NA NA NA NA • Indicates the date in which occurred the minimum demand of current in reverse flow. • The type for presenting the date is adjusted in code 94. 32 Register 06 Time of the minimum load current demand (Reverse) LOAdIR 32 06 XX:XX:XX H • Indicates the time in which occurred the minimum demand of current in reverse flow. 33 00 Register Power factor for maximum apparent power demand (Reverse) PFAPPR 33 00 X.XX • Indicates the power factor for the maximum demand of apparent power in the reverse flow. TB-R1000 / Instructions Manual 24 4 - Display Units 4.5 Function codes Code Type of unit Selection of the unit Sub-code 33 Register Power factor for minimum apparent power demand (Reverse) 01 Unit of measurement Display PFAPPR 33 01 NA Default Value NA Adjustment Ranges Using Keypad Low High NA NA X.XX • Indicates the power factor for the minimum demand of apparent power in the reverse flow. 34 00 Measurement of demand in reverse flow Apparent power demand (Reverse) APPOWR 34 00 X KVA kVolt -Ampere (kVA) NA NA NA • Indicates the value of demand in the previous period of apparent power in the reverse flow. Its value is updated at the end of every period of integration parameterized in code 84. 34 Register 01 Maximum apparent power demand (Reverse) APPOWR 34 01 X KVA kVolt Ampere (kVA) NA NA NA • Indicates the value of maximum demand of apparent power in the reverse flow. It s value is updated when the demand of the previous period surpasses the current value. 34 Register 02 Date of the maximum apparent power demand (Reverse) APPOWR 34 02 XX.XX.XXXX NA NA NA NA NA NA NA NA NA NA • Indicates the date in which occurred the maximum demand of apparent power in reverse flow. • The type for presenting the date is adjusted in code 94. 34 Register 03 Time of the maximum apparent power demand (Reverse) APPOWR 34 03 XX:XX:XX H Hour • Indicates the time in which occurred the maximum demand of apparent power in reverse flow. 34 Register 04 Minimum apparent power demand (Reverse) APPOWR 34 04 X KVA kVolt Ampere (kVA) • Indicates the value of minimum demand of active power in the rev erse flow. Its value is updated when the demand of the previous period is below the current value. 34 Register 05 Date of the minimum apparent power demand (Reverse) APPOWR 34 05 XX.XX.XXXX NA NA NA NA NA NA NA • Indicates the date in which occurred the minimum demand of apparent power in reverse flow. • The type for presenting the date is adjusted in code 94. 34 06 Register Time of the minimum apparent power demand (Reverse) APPOWR 34 06 XX:XX:XX H Hour • Indicates the time in which occurred the minimum demand of apparent power in reverse flow. TB-R1000 / Instructions Manual 25 4 - Display Units 4.5 Function codes Code Sub-code 35 00 Type of unit Selection of the unit Display Unit of measurement Measurement of demand in reverse flow Active power demand (Reverse) ACPOWR 35 00 X KW kWatt (kW) Default Value NA Adjustment Ranges Using Keypad Low High NA NA • Indicates the value of demand in the previous period of active power in the reverse flow. Its value is updated at the end of every peri od of integration parameterized in code 84. 35 Register 01 Maximum active power ACPOWR demand (Reverse) 35 01 kWatt (kW) NA NA NA X KW • Indicates the value of maximum demand of active power in the reverse flow. Its value is up dated when the demand of the previous period surpasses the current value. 35 Register 02 Date of the maximum active power demand (Reverse) ACPOWR 35 02 XX.XX.XXXX NA NA NA NA NA NA NA NA NA NA • Indicates the date in which occurred the maximum demand of active power in reverse flow. • The type for presenting the date is adjusted in code 94. 35 Register 03 Time of the maximum active power demand (Reverse) ACPOWR 35 03 XX:XX:XX H Hour • Indicates the time in which occurred the maximum demand of active power in reverse flow. 35 Register 04 Minimum active power demand (Reverse) ACPOWR 35 04 kWatt (kW) X KW • Indicates the value of minimum demand of apparent power in the reverse flow. Its value is updated wh en the demand of the previous period is below the current value. 35 Register 05 Date of the minimum active power demand (Reverse) ACPOWR 35 05 XX.XX.XXXX NA NA NA NA NA NA NA NA NA NA • Indicates the date in which occurred the minimum demand of active power in reverse flow. • The type for presenting the date is adjusted in code 94. 35 Register 06 Time of the ACPOWR minimum active power 35 demand (Reverse) 06 XX:XX:XX H Hour • Indicates the time in which occurred the minimum demand of active power in reverse flow. 36 00 Measurement of demand in reverse flow Reactive power demand (Reverse) REPOWR 36 00 X KVAR kVolt -Amp Reactive (kVAr) • Indicates the value of demand in the previous period of reactive power in the reverse flow. Its value is updated at the end of every period of integration parameterized in code 84. TB-R1000 / Instructions Manual 26 4 - Display Units 4.5 Function codes Code Sub-code 36 Type of unit Selection of the unit Display Unit of measurement Register Maximum Reactive power demand (Reverse) REPOWR 36 01 X KVAR kVolt -Amp Reactive (kW) 01 Default Value NA Adjustment Ranges Using Keypad Low High NA NA • Indicates the value of maximum demand of reactive power in the reverse flow. Its value is updated when the demand of the previous period surpasses the current value. 36 Register 02 Date of the maximum Reactive power demand (Reverse) REPOWR 36 02 XX.XX.XXXX NA NA NA NA NA NA NA NA NA NA • Indicates the date in which occurred the maximum demand of reactive power in reverse flow. • The type for presenting the date is adjusted in code 94. 36 Register 03 Time of the maximum Reactive power demand (Reverse) REPOWR 36 03 XX:XX:XX H Hour • Indicates the time in which occurred the maximum demand of reactive power in reverse flow. 36 Register 04 Minimum Reactive power demand (Reverse) REPOWR 36 04 X KVAR kVolt -Amp Reactive (kVAr) • Indicates the value of minimum demand of reactive power in the reverse flow. Its value is updated when the demand of the previous period is below the current value. 36 Register 05 Date of the minimum Reactive power demand (Reverse) REPOWR 36 05 XX.XX.XXXX NA NA NA NA NA NA NA NA NA NA • Indicates the date in which occurred the minimum demand of reactive power in reverse flow. • The type for presenting the date is adjusted in code 94. 36 Register 06 Time of the minimum Reactive power demand (Reverse) REPOWR 36 06 XX:XX:XX H Hour • Indicates the time in which occurred the minimum demand of reactive power in reverse flow. 37 00 Measurement of demand in reverse flow Source voltage demand (Reverse) SOU VR 37 00 XXX.X V Volt (V) • Indicates the value of demand in the previous period of source side voltage in the reverse flow. Its value is updated at the end of every period of integration parameterized in code 84. 37 01 Register Maximum source voltage demand (Reverse) SOU VR 37 01 XXX.X V Volt (V) NA NA NA • Indicates the value of maximum demand of source side voltage in the reverse flow. Its value is updated when the demand of the previous period surpasses the current value. TB-R1000 / Instructions Manual 27 4 - Display Units 4.5 Function codes Code Type of unit Selection of the unit Display Sub-code 37 Unit of measurement Register Date of the maximum source voltage demand (Reverse) SOU VR 37 02 XX.XX.XXXX NA 02 Default Value NA Adjustment Ranges Using Keypad Low High NA NA • Indicates the date in which occurred the maximum demand of source side voltage in reverse flow. • The type for presenting the date is adjusted in code 94. 37 Register 03 Time of the maximum source voltage demand (Reverse) SOU VR 37 03 XX:XX:XX H Hour NA NA NA NA NA NA • Indicates the time in which occurred the maximum demand of source side voltage in reverse flow. 37 Register 04 Minimum source voltage demand (Reverse) SOU VR 37 04 XXX.X V Volt (V) • Indicates the value of minimum demand of reactive power in the reverse flow. Its value is updated when the demand of the previous period is below the current value. 37 Register 05 Date of the minimum source voltage demand (Reverse) SOU VR 37 05 XX.XX.XXXX NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA • Indicates the date in which occurred the minimum demand of source side voltage in reverse flow. • The type for presenting the date is adjusted in code 94. 37 Register 06 Time of the minimum source voltage demand (Reverse) SOU VR 37 06 XX:XX:XX H Hour • Indicates the time in which occurred the minimum demand of source side voltage in reverse flow. 40 Register Maximum TAP 00 NA TAP 40 00 XX • Indicates the maximum TAP value occurred since the last reset in the TAP indication performed. • When performing a TAP reset indication, this value will indicate the TAP upon the reset. 40 Register Maximum TAP Date 01 TAP 40 01 XX.XX.XX • Indicates the date of occurrence of the maximum TAP. • When performing a TAP reset indication, this value will indicate the date upon the reset. 40 Register Maximum TAP Hour 02 TAP 40 02 XX:XX:XX H • Indicates the time of occurrence of the maximum TAP. • When performing a TAP reset indication, this value wi ll indicate the hour upon the reset. TB-R1000 / Instructions Manual 28 4 - Display Units 4.5 Function codes Code Type of unit Selection of the unit Sub-code 41 Register Minimum TAP 00 Unit of measurement Display NA TAP 41 00 Default Value NA Adjustment Ranges Using Keypad Low High NA NA XX • Indicates the Minimum TAP value occurred since the last reset in the indication of TAP performed. • When performing a TAP reset indication, this value will indicate the TAP upon the reset. 41 Register Minimum TAP Date 01 TAP 41 01 NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA 0 0 99999 NA 1 1 3 XX.XX.XX • Indicates the date of occurrence of the Minimum TAP. • When performing a TAP reset indication, this value will indicate the date upon the reset. 41 Register Minimum TAP Hour 02 TAP 41 02 XX:XX:XX H • Indicates the time of occurrence of the Minimum TAP. • When performing a TAP reset indication, this value will indicate the hour upon the reset. 42 Function 00 Number of resets made RSTTAP since the last start-up 42 00 X • This code indicates the number of resets made since the last start-up. . • The Reset TAP Indication and operation counter is accessed by pressing the “RESET key” for 5 seconds. 42 Register Last position indication reset Date 01 RSTTAP 42 01 XX.XX.XX NA • Indicates the Date of occurrence of the last Reset of Indication of TAP and digital operation counter. 42 Register Last position indication reset Hour 02 RSTTAP 42 02 XX.XX.XX H NA • Indicates the Hour of occurrence of the last Reset of Indication of TAP and digital operation counter. 44 Parameter Control identification 00 NUM 44 00 XXXXXX • Range: 0 up to 99.999.999. • Indicates the control’s serial number 45 Parameter Regulator configuration 00 CONFIG 45 00 X • Defines the Configuration for connecting the regulator. 1 – 4wye; 2 – DELTA LAGGING; 3 – DELTA leading TB-R1000 / Instructions Manual 29 4 - Display Units 4.5 Function codes Code Type of unit Selection of the unit Sub-code 46 Parameter time delay operation mode 00 to 03 Unit of measurement Display TIMdMO 46 00 NA Default Value 0 Adjustment Ranges Using Keypad Low High 0 1 X • Defines the Mode of operation of the time delay. 0 – Sequential; 1 – Reverse time. see item 5.3 • The sub-codes 00, 01, 02, and 03 determine the parameterization to post hourly A, B, C, and D, respectively. See item 4.2. 47 Parameter 00 Nominal apparent power NOMPOW 47 00 X KVA kVolt Ampere (kVA) 276 50 833 NOMVOL 47 01 X.XX KV kVolt (kV) 13.2 2.4 19.92 Ampere (A) 200 50 1332 NA 115 34 287 NA 1000 250 6660 Volt (V) 120 100 135 • Range: 50 up to 833 kVA. Step 1. • Defines the Regulator’s rated power. 47 Parameter Nominal voltage 01 • Defines the Regulator’s rated voltage. 47 Parameter Nominal current 02 NOMCUR 47 02 X A • Range: 50 up to 1332 A. Step 1. • Defines the Line rated current. 48 Parameter 00 Voltage transformation ratio PT RAT 48 00 XX • Range: 34 up to 287. Step 1. • Defines the voltage transformation Ratio. 49 Parameter 00 Current transformation ratio CT RAT 49 00 XX • Range: 250 up to 6660. Step 1. • Determines the current transformation Ratio. 51 00 to 03 Parameter in reverse flow Set voltage (Reverse) SETV R 51 00 120.0 V • Range: 100 up to 135 V. Step 0,1 V. • Defines the voltage level to which the control will regulate in the regulator’s source side during the Reverse power flow. • The sub-codes 00, 01, 02, and 03 determine the parameterization to post hourly A , B, C, and D, respectively. See item 4.2. 52 00 to 03 Parameter in reverse flow Bandwidth (Reverse) bANd R 52 00 Volt (V) 2.0 1.0 2.0 V • Range: 1.0 up to 6.0 V. Step 0,1 V. • Determines voltage range above and below the reference voltage in which the source side voltage in the Reverse flow may vary without TAP commutation in the regulator. Example: An bandwidth of 2.0 V adjusted to a set voltage of 120 V will result a range from 118.0 V to 122.0 V, where a TAP commutation shall not occur in the direct flow. • The sub-codes 00, 01, 02, and 03 determine the parameterization to post hourly A, B, C, and D, respectively. See item 4.2. TB-R1000 / Instructions Manual 30 6.0 4 - Display Units 4.5 Function codes Code Subcode 53 00 to 03 Type of unit Selection of the unit Parameter in reverse flow Time delay Display TdEL R 53 00 Unit of measurement Default Value Seconds (S) 30 Adjustment Ranges Using Keypad Low High 5 180 30 s • Range: 5 up to 180 s. Step 1s. • Indicates the time delay (temporization) between the moment in which the source side voltage will stay out of the bandwidth range, until it reaches the beginning of the commutation, during the Reverse power flow. • See function code 46, mode of operation of the control’s delay time. • The sub-codes 00, 01, 02, and 03 determine the parameterization to post h ourly A, B, C, and D, respectively. See item 4.2. 54 00 to 03 Parameter in reverse flow Line compensation, resistance UR R 54 00 Volt (V) 0.0 -25 25 0.0 V • Range: -25 up to 25 V. Step 0.1 V. • Indicates the value of the voltage drop in the resistive component of the transmission line to unit active power factor when the load of the line requests rated current. It shall be adjusted in the cases in which the load center is concentrated at the end of the line. • The sub-codes 00, 01, 02, and 03 determine the p arameterization to post hourly A, B, C, and D, respectively. See item 4.2. 55 00 to 03 Parameter in reverse flow Line compensation, reactance UX R 55 00 Volt (V) 0.0 -25 25 0.0 V • Range: -25 up to 25 V. Step 0.1 V. • Indicates the value of the voltage drop in the reactive component of the transmission line to unit reactive power factor when the load of the line requests rated current. It shall be adjusted in the cases in which the load center is concentrated at the end of the line. • The sub-codes 00, 01, 02, and 03 determine the parameterization to post hourly A, B, C, and D, respectively. See item 4.2. 56 Parameter 00 Reverse sensing mode REVS M 56 00 NA 3 0 5 XX • Defines the Mode of operation of the reverse flow. 0 = Locked forward mode; 1 = Locked reverse mode; 2 = Reverse IDLE mode; 3 = Bi-directional mode; 4 = Neutral IDLE mode; 5 = Co-generation mode 57 Parameter Reverse currente flow NA 2.5 0 5 REVTHR 57 threshold 00 00 X.X • Range: 1.0 up to 6.0 %. Step 0.1. • Defines the reverse current flow threshold at which the control switches operation either from forward to reverse, or reverse to forward. 58 Parameter 00 Potentiometric disk presence POTd P 58 00 NA 0 0 1 X • Defines the mode for measuring the positions for the control. 0 – With potentiometric disk; 1 – Without potentiometric disk, case in which the control shall be always initialized in the neutral position. 70 Parameter Load bonus mode 00 LOAdbM 70 00 NA X • Defines the position Limiter Mode. 0 – Disabled; 1 – Upper limit only; 2 – Upper and lower limit TB-R1000 / Instructions Manual 31 0 0 2 4 - Display Units 4.5 Function codes Code Type of unit Selection of the unit Subcode 71 Parameter Upper Position 00 Adjustment Ranges Using Keypad Low High Unit of measurement Default Value NA 16 8 16 NA -16 -16 -8 NA 0 0 2 NA 135 120 135 LOWVOL 82 00 X.X V NA 105 105 120 dEMINT 84 00 NA 15 1 60 NA NA NA NA Display UPPPOS 71 00 X • Defines the upper TAP Limit among TAP’s 8, 10, 12, 14, and 16. 72 Parameter Lower Position 00 LOWPOS 72 00 X • Defines the lower TAP Limit among TAP’s -8, -10, -12, -14, and -16. 80 Parameter Voltage Limiting Mode 00 VLIMMO 80 00 X • Defines the Voltage Limiter Mode. 0 – Disabled; 1 – Upper limit only; 2- Upper and lower limit. 81 Parameter Upper Voltage Limit 00 UPPVOL 81 00 X.X V • Range: 120 up to 135 V. Step 0.1 V. • Defines the upper Voltage Limit. 82 Parameter Lower Voltage Limit 00 • Range: 105 up to 120 V. Step 0.1 V. • Defines the lower Voltage Limit. 84 Parameter 00 Demand Time Interval X • Defines the demand time interval in minutes, among the values 1, 2, 3, 4, 5, 6, 10, 12, 15, 20, 30, 60. 88 Function Self test -188 SELF T 88 -188 X • Executes the Self Test function. See item 5.8. 91 Register Current date dATE 91 00 XX.XX.XX NA NA NA NA Current time HOUR 91 00 XX:XX:XX NA NA NA NA 00 • Indicates the current date. 91 Register 01 • Indicates the current time. TB-R1000 / Instructions Manual 32 4 - Display Units 4.5 Function codes Code Subcode 94 Type of unit Selection of the unit Parameter Date presentation 00 Unit of measurement Display NA dATPRE 94 00 Default Value Adjustment Ranges Using Keypad Low High 0 0 1 NA NA NA X • Defines the type for presenting the date in the display. 0 – DD.MM.YYYY; 1 – MM.DD.YYYY 95 Function 00 Event Log Reset RESET Operation counter reset 95 Position indicator reset 00 NA XX When performing a reset, the registers of the operation counter of code 00 and its sub-code will be set to zero and the registers of maximum and minimum TAP, both for external indicator and for TB-R1000, with their respective information of date and time, will be adjusted to the current values. The registries of event log with the respective values of Demand will be zeroed. Indicates the number of resets made since the last startup. 96 Communication Remote Port 1 0 3 9600 1200 38400 0 1 0 1 • Enable the Local / Remote selection on control via DNP 3.0 digital communication protocol. 0 – Enabled , 1 - Disabled. 102 NA 0 0 Enable unsolicited HAbUNS Function 1 00 REMPOR 96 00 NA XX • Defines the remote communication port. 0 – Ethernet; 1 – RS-232; 2 – Opit Fiber; 3 – RS-485. 96 Communication Baud Rate 01 bAUD R 96 01 NA XX • Defines the baud rate communication of the remote port. Values: 1200, 2400, 4800, 9600, 19200, or 38400. 100 Function Keypad password 00 PASSWOR 100 00 NA 0 XX • Define the keypad security password to be applied before changes can be made to parameters. See item 5.13 101 Access selection via NA 0 LOCREM Function 00 00 DNP 3.0 protocol. Local/Remote event responses 101 00 X 102 00 X • The control will send unsolicited event responses to this master address. 0 – Enabled , 1 - Disabled. TB-R1000 / Instructions Manual 33 5 - Functions 5.0 Functions 5.2 Bandwidth (bANdW) (Code 02) The adjustment of the bandwidth determines the accuracy range from the Set Voltage (SET V), in which the regulator considers that there is not the necessity of commutation, thus establishing the maximum variation of the voltage in the load. Example: — SET V = 120V — BANDW= 3V or (2.5%) Range = 120 +/-3V or (2.5%) Maximum band = 123V Minimum band = 117V 5.1 Set voltage (SET V) (Code 01) This function has as purpose to adjust the line voltage according to the necessity of the system, so that the line remains as most stabilized as possible, regardless of the load applied to the regulator. The single-phase regulators with 32 steps has on a PT installed at the load side, which supplies a sample of the line voltage. In general, the voltage value of the PT's secondary is 120V, and when the regulator has rated voltage applied to the PT's primary, the voltage sensor of the TB-R1000 has the purpose of comparing the voltage supplied by the PT with the reference voltage adjusted. Therefore, supposing that the adjusted voltage is at 120V, in case of alteration to more 5V, for instance, the sensor of TB-R1000 will immediately detect the difference between the reference voltage adjusted (SET V = 120V) and the voltage in the secondary, which is the same of the load side, equal to (load V = 125V), and the TB-R1000 will command the tap changer to adjust the load side voltage until it has 120V in the PT's secondary and therefore, load side rated voltage. Thus, supposing that the adjusted voltage is at 120V, in case of alteration to less 5V, for instance, the sensor of TB-R1000 will immediately detect the difference between the reference voltage adjusted (SET V= 120V) and the voltage in the secondary, which is the same of the load side, equal to (load V = 115V) and the TB-R1000 will command the tap changer to adjust the load side voltage until it has 120V in the PT's secondary and therefore, load side rated voltage. The commutation will be performed whenever the voltage goes out-of-band, which will occur as follows: Maximum band Minimum band Beginning of the process for commutation This means that there is no commutation in the range from (117 to 123)V. The TB-R1000 does not emit to the tap changer any command of increase or decrease. 5.3 Time delay (T dEL) (Code 03) Selection of the time to begin the correction in the transmission line. The objective of the time delay is to avoid unnecessary commutations due to quick voltage variations. Without the temporization, an excessive number of commutations would occur, causing an accelerated mechanical wearing of the tap changer. Thus, the correction of voltage will only occur to voltage variations whose intensities are beyond the values adjusted by the set voltage and bandwidth, and for a period longer than that determined in the time delay. TB-R1000 / Instructions Manual 34 5 - Functions Another important feature is the coordination between two or more voltage regulators connected in cascade; the one nearer to the source shall respond in shorter time to the voltage variations to avoid excessive number of operations to the other regulators. There are two modalities of temporization for the actuation of the control, both selected through “code 46” L/I (linear time/reverse time); — Linear time: The time for actuation is similar to the time selected in the adjustment. — Reverse time: The time for actuation is inversely proportional to the variation of the input voltage. This time is calculated according to the following formula: T DEL = Note: To use the temporization in the REVERSE mode, it is important to take into account: The temporization in the REVERSE mode causes the increase of the number of commutations since it reduces the time for actuation in a great deal, thus reducing the tap changer life. 5.4 Adjustment of the line voltage drop compensator (UR and UX) (code 04 and 05 Forward) (code 54 and 55 Reverse) This is a component that simulates the impedance of the line from the bank of regulators to the theoretical load center(The location at which the voltage is regulated). The basic circuit of the compensator simulates the voltage drops existing in the line, making its compensation through the regulator. The PT's secondary, that supplies the sample of the load side voltage, is placed in line with a circuit whose resistance and inductance is the image of the resistance and inductance of the line. When the regulator is submitted to load, a current proportional to the load circulates in the CT, and accordingly a voltage drop happens at RC and XC proportionally to the line drop voltage. When the regulator is submitted to load, a current proportional to the load circulates in the CT. The control separates the resistive and reactive components of this current and calculates the resistive voltage drop in the line “Vr”, according to the adjustment in “Ur”, and the reactive voltage drop in line “Vx”, according to the adjustment in “Ux”. In this case, the voltage “measured” by the control is the voltage of the PT's secondary plus or less (according to the polarity adjusted in “Ur” and “Ux”) the drop caused by the compensator “Vr” and “Vx”. Soon the control will place the regulator to reestablish the balance between the voltage that it “measure” and the regulator's output voltage. Thus, this output voltage, which is the supply voltage of the control, may be higher or shorter than the voltage considered for the system, but due to the line voltage drop, the load voltage will remain constant. BANDW x TIME |MEAV - SET V| Where: TDEL= time delay BANDW = bandwidth MEAV= voltage measured TIME= temporization adjusted SETV= Set voltage Example: —SET V = 120V —BANDW = 3V ou 2,5% —TIME = 30 seg Suppose that MEAV = 125V TDEL =3V / |125 120| x 30 TDEL= 18 segundos Note: Whenever the reverse temporization function is used and where there is a difference of 5V between the reference voltage (VREF) and the supply voltage (load side), the reverse commutation time will be ¼ of the linear commutation time. Voltage Maximum band Minimum band Time Beginning of the time count Beginning of the commutation Graph of the temporization range TB-R1000 / Instructions Manual 35 5 - Functions LOAD Relay Regulator To allow the appropriate, safe operation under these conditions, the control has a “Power Reverse Flow Detector”. This detector is capable of automatically detecting the flow reversal through current “IL”, making the following alterations to the functionality of the operator, aiming the adequateness of its operation: —Reversal in the direction of the tap changer motor; —Reversal of the polarity of the line drop compensator. The control will perform the regulation as follows: Through voltage “VL” and current “IL” measured at the “LOAD” side, and the position in which the tap changer is found, the control calculates the voltage “Vf” and current “If” at the “SOURCE” side. The control will operate similarly to the direct flow, however using “Vf” and “If” and adjustment parameters “SET V”, “BANDW”, “T”, “Ur”, and “Ux”, all specific for the reverse flow. If the flow is once again reverted to the direct flow, the control will automatically make the alterations necessary within the circuit, in order to make it suitable to its normal functioning. However, it is important to remember not to apply this accessory whenever there is the possibility of functioning of the sources in parallel, as shown below. In this case, the voltage regulator is not recommended to be used as an accessory for interconnecting the systems, since when the power flow is not defined, it is likely to occur instability in the regulator's control system. Line drop compensator Regardless of the connection of the regulator bank, whether 4wye, open delta, or closed delta, the calculation of Rc and Xc shall be made as follows: - Using fundamental voltage equations, we easily conclude that the line voltage drop related to the control circuit occurs due to: I X I R 2) XC= C L RC= C L RTP RTP Where: RL = Line resistance, in ohms; XL= Line reactance, in ohms; RC = Compensator resistance, in Volts; XC = Compensator reactance, in Volts; IC = CT's primary rated current (A). 1) NOTE: For the Toshiba regulators, the CT's primary current is identical to the regulator's rated current. The PT's ratio is the following: RTP =Regulator's rated voltage 120 5.5 Mode of operation of the reverse flow (Code 56) The voltage regulators are generally installed in circuits with unidirectional power flow (source-load). However, as a few circuits are “INTERCONNECTED” type, it is likely to occur the reversal of the load flow, i.e., the regulator receive the voltage in the “LOAD” side. When this phenomenon happens, the regulator will behave inappropriately, with the possibility of causing over-voltage or subvoltage in the circuit connected to the regulator's source terminal. Power Flow G G Generator Consumers Generator Consumers Power flow in the interconnection circuit The control offers six different operation modes that are characteristic to detect the reverse flow of power. TB-R1000 / Instructions Manual 36 5 - Functions These characteristics are selected by the user by inserting a specific code in function code 56. The six modes and their corresponding codes are the following: 5.5.1 Locked forward mode (00) This operation mode will not be applied where is possible to have a reverse power. 0 = Locked forward mode 1 = Locked reverse mode 2 = Reverse IDLE mode 3 = Bi-directional mode 4 = Neutral IDLE mode 5 = Co-generation mode MEASUREMENT: Always operating in direct flow. OPERATION: Always operating in direct flow. This allows the operations to lower the current to zero, provided that there is not a direct threshold involved. Whenever the regulator enters a reverse flow and the CT's secondary current exceeds the value adjusted in the flow threshold of reverse current (code 57), in the example below at 2.5% or 0.005A, the control will assume the reverse flow, thus inhibiting the commutation. When the current flows back to the level above since the threshold, the normal operation in direct mode will begin (See Figure below). This section will explain each mode of operation individually. Since the control keeps the values of measurement of reverse flow separated from the values with direct flow, the measurement may be also explained in each mode. When determining the direction of the power flow, the control monitors only the active component of the current and then determines the current direction and the amplitude in such direction. Whenever the conditions indicate that there was a reversal of flow, the following parameters assume new values and the control's operation is affected as follows: Direct mode activated Reverse Direct Tap changer Blocked —Output voltage - Monitoring of what was the previous input of the transformer. DF 2,5% 0 2,5% Current level Operation in direct flow —Input Voltage - Monitoring of what was the previous output of the transformer. 5.5.2 Locked reverse mode (01) —Load current - In the direct flow, the current is directly used as it is measured. In the reverse flow, the current is affected by the difference of ratio between the input and the output of the regulator, pursuant to the following equation: This mode of operation shall not be applied where it is possible to have a direct power. MEASUREMENT: Always operating in the reverse flow, regardless of the power flow direction. Reverse =(load current)x(secondary input voltage) current (secondary output voltage) OPERATION: Always operating in the reverse direction using the adjustments of the control with reverse flow in function codes 51, 52, 53, 54, and 55. This allows the operation to lower the current until it reaches zero, provided that there is no reverse threshold involved. Where secondary input voltage and secondary output voltage are in the reverse flow. The apparent, active, and reactive power are calculated based on the new reverse values measured. TB-R1000 / Instructions Manual 37 5 - Functions When the regulator is operating in direct flow and the CT's secondary current exceeds the value adjusted in the direct threshold of direct current (code 57), in the example below of 2.5% or 0.005A, the control will assume the direct flow, thus inhibiting the commutation. Whenever the current flows returning to the level above this direct threshold, the normal operation of the reverse flow begins (See the Figure below). 5.5.4 Bi-directional mode (03) The use of this operation mode is recommended for all installations where the reverse power flow can occur, except where the reverse power flow is a co-generation or an independent power producer. MEASUREMENT: A threshold level of 2.5% (0.005A) of the current, with load in the TC's secondary (0.005A) is used in the adjustment of direction of the power flow. The measurement will occur in the direct flow until the current exceeds 2.5% of threshold in the reverse direction. The control keeps on measuring in the reverse flow until the current exceeds 2.5% of threshold in the direct flow and then the parameter of scale reverts it back to the normal. Reverse Mode Activated Reverse Direct Tap changer Blocked RF 2,5% 0 2,5% Current level Operation in reverse flow 5.5.3 Reverse IDLE mode (02) The use of this operation mode may occur where there is reverse flow, but when the source voltage is not regulate. MEASUREMENT: The threshold value of 2.5% (0.005A) of the current with load in the CT's secondary (0.005A) is used to adjust the direction of the power flow. The measurement will be direct until the current exceeds the threshold of 2.5% in the reverse direction. The control keeps on measuring in the reversal until the current exceeds the threshold of 2.5% in the direct flow, and then the parameter reverts back to the normal. OPERATION: The operation threshold function of the control is programmable in function code 57 above the range of 1 to 5% of the CT's rated current. When the regulator enter in direct flow and the secondary's current exceeds the value adjusted in the flow threshold of reverse current (code 57), in the example below at 2.5% or 0.005A, the control will assume the direct flow, enabling the commutation. Whenever the current flows back to the lower level of this threshold, the operation in normal flow will be inhibited. The commutation is disabled in the reverse flow. OPERATION: The control operates in the direct flow whenever the current is above the direct threshold adjusted (function code 57). The control operates in the reverse direction, using the adjustments in reverse power flow in function codes 51, 52, 53, 54, and 55 whenever the current is above the reverse threshold adjusted (function code 57). Bi-directional mode Reverse RF Tap changer Blocked DF 2,5% 0 2,5% Currente Level Operates in direct and reverse flow 5.5.5 Neutral IDLE mode (04) This mode of operation is applied upon the detection of the reverse flow, when the control commutate the regulator to TAP ZERO. The tap changer is blocked at CURRENT TAP in the band of 2.5%. Reverse Mode Inhibited Reverse Direct Tap changer Tap changer Blocked Blocked Direct MEASUREMENT: A threshold level of 2.5% (0.005A) of the current, with load in the CT's secondary (0.005A) is used in the adjustment of the power flow direction. DF 2,5% 0 2,5% Current level Not operative in reverse flow TB-R1000 / Instructions Manual 38 5 - Functions The measurement will occur in the direct flow until the current exceeds 2.5% of threshold in the reverse flow. The control keeps on measuring in the reverse flow until the current exceeds 2.5% of threshold in the direct flow and then the parameter of scale goes back to the normal. not to monitor the input voltage when the reverse power flow is detected, then altering the adjustment of line drop compensation to take into account this change in the power flow. OPERATION: The control operates in the direct flow whenever the current is above the direct threshold adjusted (function code 57). Whenever the current exceeds the reverse threshold adjusted (function code 57), the control will make the commutation to the neutral position. The neutral position, TAP ZERO. When the current is between the two thresholds, the control becomes inactive in the last position of the tap changer maintained before the direct threshold obtained. While commutated to the neutral position, if the current drops below the reverse threshold, the control will keep on commutating until the neutral position is reached. The temporization circuit (time delay) is set to zero in any variation below the direct threshold. Blocked TAP Zero Co-generation side Costumer's substation Co-generation regulation points Co-generation mode Reverse Direct DF RF 2,5% 0 2,5% Current level Mode of operation in co-generation 5.6 Load bonus mode (code 70) Direct Tap Charger Blocked Regulators bank Difference of compensation in the line drop Reverse Mode Blocked in TAP Zero Reverse Transmission line Substation The voltage regulator allows the increase of the current (load increase) with the reduction of the regulation range, the maximum normalized regulation range is 10%, but the control has an adjustments able to limit this range, allowing the regulator to block the tap changer in the desired position. The load bonus mode is selected in this code. The representative values (0, 1, and 2) in this code are: FD 2,5% 0 2,5% Current level The tap changer is blocked in TAP Zero when in the reverse flow 5.5.6 Co-generation mode (05) The growth in the number of applications of voltage regulators involving co-generation has increased significantly by the custumers in the past years. Normally, the operation desired of the regulator installed in the supplier and involving co-generation is to regulate the voltage in the custumer's substation during the moments in which the power flow is in the direction of the custumer area, and to regulate the regulator voltage (in the same side of output) during the power flow to the network. This is achieved simply by making the control 0 =Off line (Default); 1 = Upper limit activated only: (code 71), which defines the Limit TAP of upper Position when the “Position Limiter” Mode is enabled. TB-R1000 / Instructions Manual 39 5 - Functions supplier; — Load decreased by the first custumer with load increased in the source at the same time. It blocks the tap changer in the “raise” direction, at positions: +10% = TAP + 16 +8.75% = TAP + 14 +7.50% = TAP + 12 +6.25% = TAP + 10 +5% = TAP + 8 Z(r, x) of the line 2 = Enables the upper and lower limit: (code 72), which defines the Limit TAP of lower Position when the “Position Limiter” Mode is enabled. It blocks the tap changer in the “lower” direction, at positions: +/- 10% = TAP +/- 16 +/- 8,75% = TAP +/- 14 +/- 7,50% = TAP +/- 12 +/- 6,25% = TAP +/- 10 +/- 5% = TAP +/- 8 If only the block desired is the lowest one, the code shall be adjusted at 2 to enable this limit, and the value adjusted in code 71 to upper block may be adjusted to any extreme value (position +16) for the actuation of the upper block occur only when the tap changer reaches the maximum TAP (+16). Customer 1 Customer 2 Actuation of the voltage limiter at the costumer The voltage regulators are generally installed in circuits with loads distributed along the line. In the case of use of Line Voltage Drop Compensator, the customer immediately after the voltage regulator (customer 1) are submitted to inappropriate voltages. The use of a voltage limiter is recommended to protect these loads. The limiter will limit the voltage at the regulator's output within a pre-established value, in order not to harm the nearby custumers. The maximum and minimum limits deemed appropriate for the output voltage can be programmed in the control through function codes 81 (UPPVOL) and 82 (LOWVOL), respectively. The adjustment is made by accessing function code 80 (VLIMMO) and entering the appropriate code for the desired operation: 5.7 Voltage limiter mode (code 80) The voltage limiter function is used to establish the maximum and minimum limits in the regulator's output voltage. When the function is enabled, the control allows the regulator to operate in any of the directions, i.e., reverse or direct, and has priority over all other functions of operation. The voltage limiter is only disabled by the operator of the local TB-R1000 or through the communication software DNP3 interconnected to the TB-R1000 . The purpose of the voltage limiter is to protect the costumer from high or low abnormal voltage resulting from: —Abrupt changes and over-voltage in the transmission line; —Abnormal source load; —Inaccurate adjustments of the regulator's control (set voltage, bandwidth, and line drop compensation); —Load increased by the first custumer where there is a capacitive power factor in the 0 = Off line(OFF); 1 = upper limit only: It defines the upper voltage Limit when the “Voltage Limiter” mode is enabled. 2 = upper and lower limits: It defines the lower voltage Limit when the “Voltage Limiter” mode is enabled. If only the lower limit is desired, function code 80 shall be adjusted at 2 to enable this limit and the value programmed in function code 81 to the upper limit can be adjusted to a given extreme value (such as 135) to avoid the actuation of the upper limit. The control has the following reply sensitivity: If the control's supply voltage, which is the CT's secondary, exceeds the value of the lower TB-R1000 / Instructions Manual 40 5 - Functions or upper limit adjusted, the control will immediately send a signal to the tap changer make the increase or decrease, if necessary without counting the time. The control has a band of 2V between the voltage limiter adjusted and the control's supply voltage, PT's secondary. The limiter will act with two volts below the adjusted value, both for the upper and lower limits. Ex.: If 130V is adjusted in the voltage limiter, the controller anticipates and limits the voltage to 128V (see figure below), thus providing a security margin to the transmission line and avoiding unnecessary commutations and increasing the useful life of the tap changer. Auto-Test Chart Value shown in the display Immediate commutation w/o temporization Commutation inhibit band 130 128,5 } 115,5 114 * Immediate commutation w/o temporization } 0 Normal operation 1 Error of potentiometric disk 2 Frequency out of range 3 Error of frequency and potentiometric disk 4 Error of parameterization 5 Error of potentiometric disk and parameterization 6 Error of frequency and parameterization 7 Error of potentiometric disk, frequency, and parameterization 8 Tap changer failure 5.9 Date and Time Presentation (code 91) 1,5V This function indicates the current time and date. Visualization: press the MENU key, verify the actuation of the arrow in the upper right corner of the display and navigate until function 91 is shown in the display at the date in sub-code 00 and the time in sub-code 01. Parameterization: In code 91, in an eventual alteration of date and/or time, after having accessed the MENU, press the key CONF to access the alterations as deemed necessary. Another arrow will be shown, below the menu's arrow, indicating that the function is able to receive the new values. To alter the values in the sequence, i.e., year, month, and date or minutes and hours (seconds are not adjustable), it is necessary to have the CONF arrow enabled and after having adjusted the year or minute, press the CONF key for 2 seconds to access the next parameter, then add the values through the keys plus (+) and minus (-) in the front panel to all values mentioned above. 120 Vca Commutation inhibit band Description of the indication 1,5V Dead band voltage limits 5.8 Self test (code 88) When entering this code, the control automatically executes an self test routine of the main circuits. The TB-R1000 display shows a given value that ranges from 0 to 8, having as error the following nomenclatures: 1 Error of potentiometric disk. 2 Error of frequency out of range. 3 Error of frequency and potentiometric disk. 4 Error of parameterization. 5 Error of potentiometric disk and parameterization. 6 Error of frequency and parameterization. 7 Error of potentiometric disk, frequency, and parameterization. 8 Tap changer failure 5.10 Number of resets made since the last start-up (code 42) The indication “0” means normal operation. It indicates the number of times in which the mechanical position indicator reset has TB-R1000 / Instructions Manual 41 5 - Functions been enabled. All the indications of maximum and minimum TAP are reset to the current value when this code is accessed. shown. The TAP zero function shall not be disabled remotely. The operation is only concluded when the neutral indicating is lighting , indicating TAP zero. Visualization: press the MENU key, navigate until function 42 is shown in the display. It is possible to visualize the number of resets in sub-code 00 and the date and time of the last reset performed, in sub-codes 01 and 02, respectively. 5.12 Open door detector The TB-R1000 control has a function that allows the remote monitoring of open door. If the door of the TB-R1000 control is open, the control, by means of a reedswitch, once this function has no code, will send a signal to the microcontroller that on its turn sends the information remotely through the communication software DNP3. This function is essential in the security of a field operator, since it allows the remote monitoring if there is anyone operating the regulator and fails to send any command until the cover closes, thus ensuring the physical integrity of the field operator. Enablement: There are two ways to enable the external indicator reset. One is through the direct access of the RESET key in the front panel, where the operator shall press the key for 5 seconds until he/she can visualize the reset count and its actuation in the external indicator. The second way occurs through the communication software TBR Control, which allows the remote enablement of the reset in the “REMOTE CONTROL” field, by clicking once on “RESET POSITION INDICATOR”. 5.13 KEYPAD Password This function implement on the control a security code required to change each parameter in " Conf" mode. For a parameter alteration will be requested a value of password to be adjusted in code 100-00 (PASSWO) qualifying the alteration of parameters. When having access code 10000 an initial value 0(zero) will be displayed, use the keyboard keys "+" (2.1.11) and “-" (2.1.12) to adjust the correct password. When pressing KEYPAD key "CONF" with the correct password the control will enable the parameter alteration. 5.11 TAP Zero function This function has as purpose to bring the regulator to the zero position, regardless of the position in which it is found, facilitating a possible removal of the regulator from the operation. Enablement: The TAP zero function is enabled when both raise and lower key of the front panel are simultaneously pressed for 5 seconds, but the function manual and/or remote shall not be enabled. To confirm that the TAP zero function is enabled, an arrow is shown in the upper right corner of the display. The TAP zero function shall not be enabled remotely. Login definition: This function permits the user set the security code required to change each parameter in "Conf" mode. After access code 100-00 (LOGIN), adjust the value of current password and press "CONF", the display will shown code -54 -54 (LOGIN) and the current password. Through the keyboard keys "+" (2.1.11) and “-" (2.1.12) set the new value and press "CONF" again to confirm. Disablement: The procedure to disable this function is the same, it only takes pressing the raise(2.1.7) and lower(2.1.8) keys for 5 seconds, with the manual and/or remote functions disabled, and verify that the arrow of indication of TAP zero function is no longer TB-R1000 / Instructions Manual 42 6 - Protocol DNP 3.0 —The event log cannot be accessed by qualifiers 0 or 6, and the maximum size of each reply is 2048 bytes. 6.0 Protocol DNP 3.0 To execute a few specific commands, it is necessary to follow the sequences described below: TELE-PRESENCE —Read registers 244, 245, and 246 of object 30 to read the unit, sub-unit and unit value in the display. 1.2) . Read the registers of Object 01 to know what are the display segments accessed in the moment. Repeat the reading at every second. —The manual controls can be executed with object 12. EVENT LOG —Read register 210 of object 30 to lock the memory pointer and to know the current size of the memory. —Read the event log registers from 100 to (1000+10*current size). —Each interval of mass memory has its own date and time, since there is the possibility of occurrence of events such as power failure or daylight saving time, which would cause a variation at the interval between two readings. —The event log time has 3 bits that signal the dayliht saving time, an alteration of register that interfere the mass Memory and power failure. MODIFICATION OF REGISTER 41 —After having executed all the modifications desired, a COLD RESTART shall be performed. Password —It is not necessary to log when the password is zero. —When modifying the password “REG 137 obj. “41”, it will be necessary to log every time you wish to execute a write-in command. —To log, you must insert the correct password in reg 138 obj 41. —To logout, you need to restart, insert the wrong password in reg 138, wait for 10 minutes without communication, or press the local/remote key. FFT — To calculate the FFT of current and voltage, execute the Obj12 reg 3 close. — Wait the bit 27 of obj1 to change from 1 to zero. — Read the registers 179 to 212 of obj 30. Table of registers of object1 Object 1- Binary input – Var 1 and 2 BIT 7 6 5 4 3 2 1 0 15 14 13 12 11 10 9 8 23 22 21 20 19 18 17 16 31 30 29 28 27 26 25 24 Command Control via remote channel Voltage limiter on Inactive clock Block by Vmin Block by Vmax Flow Signaling decrease voltage Signaling increase voltage External indicator reset Mode of operation Tap changer decreasing Tap changer increasing Failure in the tap changer Failure in the potentiometric disk Load Bonus Enabled Reactive Failure in the measurement Internal failure Auxiliary board inexistent or failure No firmware Failure in the parameterization Outside TAP 0 Minimum TAP block Maximum TAP block TAP unknown Switching position routine Remote port login Local port login RESERVED Mass memory full Open door Daylight saving time STATUS YES = 1 YES = 1 YES = 1 YES = 1 YES = 1 0 = direct 1 = reverse YES = 1 YES = 1 YES = 1 0 = manual 1 = automatic YES = 1 YES = 1 YES = 1 YES = 1 YES = 1 0 = Q+ 1 = QYES = 1 YES = 1 YES = 1 YES = 1 YES = 1 YES = 1 YES = 1 YES = 1 YES = 1 YES = 1 YES = 1 YES = 1 Note 0 = Obj 12 not remotely executable – bit 5 of IIN RTC not configured or not responding – bit 4 of IIN bit 7 of IIN Message sent by the boot loader Incoherent or corrupted parameterization Control is inoperative in this state – bit 7 of IIN Logged in the remote port Logged in the local port When in 1 is calculating a FFT YES = 1 YES = 1 YES = 1 TB-R1000 / Instructions Manual 43 6 - Protocol DNP 3.0 Table of registers of object 12 Table of registers of object 12 Index 0 0 1 1 2 2 3 3 4 4 5 5 6 6 Function Increase TAP Decrease TAP Command CLOSE TRIP CLOSE TRIP CLOSE TRIP CLOSE TRIP CLOSE TRIP CLOSE TRIP CLOSE TRIP Note Counter informs the number of TAPs To Stop use “NUL” MANUAL AUTOMATIC Reset position indicator Execute FFT LOCAL REMOTE RESERVED --Resets the mass memory Table of registers of object 30 Obj 30 Var 1 and 3 32 bits analog input (dynamic variables) Index Code Sub/Command 0 (code 00 sub 00) 1 (code 00 sub -1) 2 (code 00 sub -2) 3 (code 00 sub -3) 4 (code 00 sub -4) 5 (code 00 sub -5) 6 (code 00 sub -6) 7 (code 00 sub -7) 8 (code 00 sub -8) 9 (code 00 sub -9) 10 (code 00 sub -10) 11 (code 00 sub -11) 12 (code 00 sub -12) 13 (code 00 sub -13) 14 (code 00 sub -14) 15 (code 00 sub -15) 16 (code 00 sub -16) 17 (code 00 sub 01) 18 (code 00 sub 02) 19 (code 00 sub 03) 20 (code 00 sub 04) 21 (code 00 sub 05) 22 (code 00 sub 06) 23 (code 00 sub 07) 24 (code 00 sub 08) 25 (code 00 sub 09) 26 (code 00 sub 10) 27 (code 00 sub 11) 28 (code 00 sub 12) 29 (code 00 sub 13) 30 (code 00 sub 14) 31 (code 00 sub 15) 32 (code 00 sub 16) 33 (code 00 sub 17) 34 (code 06 sub 00) 35 (code 06 sub 01) 36 (code 07 sub 00) 37 (code 07 sub 01) 38 (code 08 sub 00) 39 (code 09 sub 00) 40 (code 09 sub 01) 41 (code 10 sub 00) 42 (code 10 sub 01) 43 (code 11 sub 00) 44 (code 11 sub 01) 45 (code 11 sub 02) Escale 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 10 100 10 100 10 1 1 1 1 1 1 1 Unit operations operations operations operations operations operations operations operations operations operations operations operations operations operations operations operations operations operations operations operations operations operations operations operations operations operations operations operations operations operations operations operations operations operations V KV V KV V mA A kWh kWh kVArh kVArh kVArh Note Operation counter totalizer Number of times that TAP -16 has been enabled Number of times that TAP -15 has been enabled Number of times that TAP -14 has been enabled Number of times that TAP -13 has been enabled Number of times that TAP -12 has been enabled Number of times that TAP -11 has been enabled Number of times that TAP -10 has been enabled Number of times that TAP -9 has been enabled Number of times that TAP -8 has been enabled Number of times that TAP -7 has been enabled Number of times that TAP -6 has been enabled Number of times that TAP -5 has been enabled Number of times that TAP -4 has been enabled Number of times that TAP -3 has been enabled Number of times that TAP -2 has been enabled Number of times that TAP -1 has been enabled Number of times that TAP 1 has been enabled Number of times that TAP 2 has been enabled Number of times that TAP 3 has been enabled Number of times that TAP 4 has been enabled Number of times that TAP 5 has been enabled Number of times that TAP 6 has been enabled Number of times that TAP 7 has been enabled Number of times that TAP 8 has been enabled Number of times that TAP 9 has been enabled Number of times that TAP 10 has been enabled Number of times that TAP 11 has been enabled Number of times that TAP 12 has been enabled Number of times that TAP 13 has been enabled Number of times that TAP 14 has been enabled Number of times that TAP 15 has been enabled Number of times that TAP 16 has been enabled Number of times that TAP 000 has been enabled Load side voltage at low voltage Load side voltage at high voltage Source side voltage at low voltage Source side voltage at high voltage Load side compensated voltage at low voltage Load side current at low voltage Load side current at high voltage Direct flow active power Reverse flow active power Capacitive Reactive Power in direct flow Inductive Reactive Power in direct flow Capacitive Reactive Energy in reverse flow TB-R1000 / Instructions Manual 44 6 - Protocol DNP 3.0 Table of registers of object 30 Obj 30 Var 1 and 3 32 bits analog input (dynamic variables) Index Code Sub/Command Escale Unit 46 (code 11 sub 03) 1 kVArh 47 (code 12 sub 00) 1 TAP 48 (code 13 sub 00) 100 49 (code 13 sub 00) 1 50 (code 14 sub 00) 1 kVA 51 (code 15 sub 00) 1 kW 52 (code 16 sub 00) 1 kVAr 53 (code 17 sub 00) 10 Hz 54 (code 20 sub 00) 10 V 55 (code 20 sub 01) 10 V 56 (code 20 sub 02) 1 DD.MM.YYYY 57 (code 20 sub 03) 1 hh.mm.ss 58 (code 20 sub 04) 10 V 59 (code 20 sub 05) 1 DD.MM.YYYY 60 (code 20 sub 06) 1 hh.mm.ss 61 (code 21 sub 00) 10 V 62 (code 21 sub 01) 10 V 63 (code 21 sub 02) 1 DD.MM.YYYY 64 (code 21 sub 03) 1 hh.mm.ss 65 (code 21 sub 04) 10 V 66 (code 21 sub 05) 1 DD.MM.YYYY 67 (code 21 sub 06) 1 hh.mm.ss 68 (code 22 sub 00) 1 mA 69 (code 22 sub 01) 1 mA 70 (code 22 sub 02) 1 DD.MM.YYYY 71 (code 22 sub 03) 1 hh.mm.ss 72 (code 22 sub 04) 1 mA 73 (code 22 sub 05) 1 DD.MM.YYYY 74 (code 22 sub 06) 1 hh.mm.ss 75 (code 23 sub 00) 100 76 (code 23 sub 01) 100 77 (code 24 sub 00) 1 kVA 78 (code 24 sub 01) 1 kVA 79 (code 24 sub 02) 1 DD.MM.YYYY 80 (code 24 sub 03) 1 hh.mm.ss 81 (code 24 sub 04) 1 kVA 82 (code 24 sub 05) 1 DD.MM.YYYY 83 (code 24 sub 06) 1 hh.mm.ss 84 (code 25 sub 00) 1 kW 85 (code 25 sub 01) 1 kW 86 (code 25 sub 02) 1 DD.MM.YYYY 87 (code 25 sub 03) 1 hh.mm.ss 88 (code 25 sub 04) 1 kW 89 (code 25 sub 05) 1 DD.MM.YYYY 90 (code 25 sub 06) 1 hh.mm.ss 91 (code 26 sub 00) 1 kVAr 92 (code 26 sub 01) 1 kVAr 93 (code 26 sub 02) 1 DD.MM.YYYY 94 (code 26 sub 03) 1 hh.mm.ss 95 (code 26 sub 04) 1 kVAr 96 (code 26 sub 05) 1 DD.MM.YYYY 97 (code 26 sub 06) 1 hh.mm.ss 98 (code 27 sub 00) 10 V 99 (code 27 sub 01) 10 V 100 (code 27 sub 02) 1 DD.MM.YYYY 102 (code 27 sub 03) 1 hh.mm.ss 102 (code 27 sub 04) 10 V 103 (code 27 sub 05) 1 DD.MM.YYYY 104 (code 27 sub 06) 1 hh.mm.ss 105 (code 30 sub 00) 10 V 106 (code 30 sub 01) 10 V 107 (code 30 sub 02) 1 DD.MM.YYYY 108 (code 30 sub 03) 1 hh.mm.ss 109 (code 30 sub 04) 10 V 110 (code 30 sub 05) 1 DD.MM.YYYY 111 (code 30 sub 06) 1 hh.mm.ss 112 (code 31 sub 00) 10 V 113 (code 31 sub 01) 10 V 114 (code 31 sub 02) 1 DD.MM.YYYY 115 (code 31 sub 03) 1 hh.mm.ss 116 (code 31 sub 04) 10 V 117 (code 31 sub 05) 1 DD.MM.YYYY 118 (code 31 sub 06) 1 hh.mm.ss 119 (code 32 sub 00) 1 mA Note Inductive Reactive Power in reverse flow Current TAP Power factor Quadrant Apparent power Active power Reactive power Network frequency Load side voltage demand at low voltage Maximum load side voltage demand at low voltage Date of the maximum load side voltage demand at low voltage Time of the maximum load side voltage demand at low voltage Minimum load side voltage demand at low voltage Date of the minimum load side voltage demand at low voltage Time of minimum load side voltage demand at low voltage Load side compensated voltage demand at low voltage Maximum load side compensated voltage demand at low voltage Date of the maximum load side compensated voltage demand at low voltage Time of maximum load side compensated voltage demand at low voltage Minimum load side compensated voltage demand at low voltage Date of the minimum load side compensated voltage demand at low voltage Time of minimum load side compensated voltage demand at low voltage Load side current demand at low voltage Maximum load side current demand at low voltage Date of the maximum load side current demand at low voltage Time of the maximum load side current demand at low voltage Minimum load side current demand at low voltage Date of the minimum load side current demand at low voltage Time of the minimum load side current demand at low voltage FP for maximum demand S FP for Minimum demand S S demand at load Maximum S demand at load Date of the maximum S demand at load Time of the maximum S demand at load Minimum S demand at load Date of the minimum S demand at load Time of the minimum S demand at load P demand at load Maximum P demand Date of the maximum P demand at load Time of the maximum P demand at load Minimum P demand at load Date of the minimum P demand at load Time of the minimum P demand at load Q demand at load Maximum Q demand at load Date of the maximum Q demand at load Time of the maximum Q demand at load Minimum Q demand at load Date of the minimum Q demand at load Time of the minimum Q demand at load Load side voltage demand Maximum load side voltage demand Date of the maximum load side voltage Demand Time of the maximum load side voltage Demand Load side minimum voltage Demand Date of the load side minimum voltage Demand Time of the load side minimum voltage Demand Load side voltage demand at low voltage - reverse flow Maximum load side voltage demand at low voltage - reverse flow Date of he maximum load side voltage demand at low voltage - reverse flow Time of the maximum load side voltage demand at low voltage - reverse flow Minimum load side voltage demand at low voltage - reverse flow Date of the minimum load side voltage demand at low voltage - reverse flow Time of the minimum load side voltage demand at low voltage - reverse flow Load side compensated voltage demand at low voltage - reverse flow Maximum load side compensated voltage demand at low voltage - reverse flow Date of the maximum load side compensated demand at low voltage - reverse flow Time of the maximum load side compensated demand at low voltage - reverse flow Minimum load side compensated voltage demand at low voltage - reverse flow Date of the minimum load side compensated voltage demand at low voltage - reverse flow Time of the minimum load side compensated voltage demand at low voltage - reverse flow Load side current demand at low voltage - reverse flow TB-R1000 / Instructions Manual 45 6 - Protocol DNP 3.0 Table of registers of object 30 Obj 30 Var 1 and 3 32 bits analog input (dynamic variables) Index Code Sub/Command 120 (code 32 sub 01) 121 (code 32 sub 02) 122 (code 32 sub 03) 123 (code 32 sub 04) 124 (code 32 sub 05) 125 (code 32 sub 06) 126 (code 33 sub 00) 127 (code 33 sub 01) 128 (code 34 sub 00) 129 (code 34 sub 01) 130 (code 34 sub 02) 131 (code 34 sub 03) 132 (code 34 sub 04) 133 (code 34 sub 05) 134 (code 34 sub 06) 135 (code 35 sub 00) 136 (code 35 sub 01) 137 (code 35 sub 02) 138 (code 35 sub 03) 139 (code 35 sub 04) 140 (code 35 sub 05) 141 (code 35 sub 06) 142 (code 36 sub 00) 143 (code 36 sub 01) 144 (code 36 sub 02) 145 (code 36 sub 03) 146 (code 36 sub 04) 147 (code 36 sub 05) 148 (code 36 sub 06) 149 (code 37 sub 00) 150 (code 37 sub 01) 151 (code 37 sub 02) 152 (code 37 sub 03) 153 (code 37 sub 04) 154 (code 37 sub 05) 155 (code 37 sub 06) 156 (code 40 sub 00) 157 (code 40 sub 01) 158 (code 40 sub 02) 159 (code 41 sub 00) 160 (code 41 sub 01) 161 (code 41 sub 02) 162 (code 42 sub 00) 163 (code 42 sub 01) 164 (code 42 sub 02) 165 166 167 168 169 170 171 172 173 174 175 176 177 178 179 180 181 182 183 184 185 186 187 188 189 190 191 192 193 Escale 1 1 1 1 1 1 100 100 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 10 10 1 1 10 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 Unit mA DD.MM.YYYY hh.mm.ss mA DD.MM.YYYY hh.mm.ss kVA kVA DD.MM.YYYY hh.mm.ss kVA DD.MM.YYYY hh.mm.ss kW kW DD.MM.YYYY hh.mm.ss kW DD.MM.YYYY hh.mm.ss kVAr kVAr DD.MM.YYYY hh.mm.ss kVAr DD.MM.YYYY hh.mm.ss V V DD.MM.YYYY hh.mm.ss V DD.MM.YYYY hh.mm.ss operations DD.MM.YYYY hh.mm.ss operations DD.MM.YYYY hh.mm.ss operations DD.MM.YYYY hh.mm.ss DD.MM.YYYY hh.mm.ss DD.MM.YYYY hh.mm.ss % % % % % % % % % % % % % % % % % % % % % Note Maximum load side current demand at low voltage - reverse flow Date of the maximum load side current demand at low voltage - reverse flow Time of the maximum load side current demand at low voltage - reverse flow Minimum load side current demand at low voltage - reverse flow Date of the minimum load side current demand at low voltage - reverse flow Time of the minimum load side current demand at low voltage - reverse flow FP for maximum S demand - reverse flow FP for minimum S demand - reverse flow S demand at load - reverse flow Maximum S demand at load - reverse flow Date of the maximum S demand at load - reverse flow Time of the maximum S demand at load - reverse flow Minimum S demand at load - reverse flow Date of the minimum S demand at load - reverse flow Time of the minimum S demand at load - reverse flow P demand at load - reverse flow Maximum P demand at load - reverse flow Date of the maximum P demand at load - reverse flow Time of the maximum P demand at load - reverse flow Minimum P demand at load - reverse flow Date of the minimum P demand at load - reverse flow Time of the minimum P demand at load - reverse flow Q demand at load - reverse flow Maximum Q demand at load - reverse flow Date of the maximum Q demand at load - reverse flow Time of the maximum Q demand at load - reverse flow Minimum Q demand at load - reverse flow Date of the minimum Q demand at load - reverse flow Time of the minimum Q demand at load - reverse flow Load side voltage demand Maximum load side voltage demand Date of the maximum load side voltage Demand Time of the maximum load side voltage Demand Minimum load side voltage demand Date of the minimum load side voltage Demand Time of the minimum load side voltage Demand Register of the highest TAP commutated Date of the register of the highest TAP commutated Time of the register of the highest TAP commutated Register of the lowest TAP commutated Date of the register of the lowest TAP commutated Time of the register of the lowest TAP commutated Presents the number of TAP resets already performed Date of the last TAP reset Time of the last TAP reset Control model Hardware version (Negative values are from the manufacturer) Micro-controller Firmware Version (Negative values are from the manufacturer) Firmware load date Firmware load time Micro-controller bootloader version (Negative values are from the manufacturer) Bootloader load date Bootloader load time Voltage TDH Fundamental 2 harmonic 3 harmonic 4 harmonic 5 harmonic 6 harmonic 7 harmonic 8 harmonic 9 harmonic 10 harmonic 11 harmonic 12 harmonic 13 harmonic 14 harmonic 15 harmonic 16 harmonic Current TDH Fundamental 2 harmonic 3 harmonic TB-R1000 / Instructions Manual 46 6 - Protocol DNP 3.0 Table of registers of object 30 Obj 30 Var 1 and 3 32 bits analog input (dynamic variables) Index Code Sub/Command Escale Unit 194 1 % 195 1 % 196 1 % 197 1 % 198 1 % 199 1 % 200 1 % 201 1 % 202 1 % 203 1 % 204 1 % 205 1 % 206 1 % 207 1 % 208 1 DD.MM.YYYY 209 1 hh.mm.ss 210 1 Registers 211 1 Registers 212 1 operations 213 1 operations 214 1 operations 215 1 operations 216 1 operations 217 1 operations 218 1 operations 219 1 operations 220 1 operations 221 1 operations 222 1 223 1 224 1 225 1 226 1 227 1 228 1 229 1 230 1 231 1 232 1 233 1 234 1 235 1 236 1 237 1 238 1 239 1 240 1 241 1 242 1 DD.MM.YYYY 243 1 hh.mm.ss 244 245 246 247 248 249 250 251 252 253 254 255 256 1000 1001 1002 1003 1004 1005 1006 1007 1008 1009 1010 Note 4 harmonic 5 harmonic 6 harmonic 7 harmonic 8 harmonic 9 harmonic 10 harmonic 11 harmonic 12 harmonic 13 harmonic 14 harmonic 15 harmonic 16 harmonic Battery load Date of the Last mass memory register Time of the Last mass memory register Mass memory current size Maximum mass memory size Register for the TAP commuted by the control in the last time Register for the TAP commuted by the control before the last time Register for the TAP commuted by the control 3 times ago Register for the TAP commuted by the control 4 times ago Register for the TAP commuted by the control 5 times ago Register for the TAP commuted by the control 6 times ago Register for the TAP commuted by the control 7 times ago Register for the TAP commuted by the control 8 times ago Register for the TAP commuted by the control 9 times ago Register for the TAP commuted by the control 10 times ago Last register modified Penultimate register modified Register modified 3 times ago Register modified 4 times ago Register modified 5 times ago Register modified 6 times ago Register modified 7 times ago Register modified 8 times ago Register modified 9 times ago Register modified 10 times ago Register modified 11 times ago Register modified 12 times ago Register modified 13 times ago Register modified 14 times ago Register modified 15 times ago Register modified 16 times ago Register modified 17 times ago Register modified 18 times ago Register modified 19 times ago Register modified 20 times ago Register of date of the last modification Register the time of the last modification Current display unit Current display sub-unit Value shown in the display Current hourly post 0->A; 1->B; 2->C; 3->D Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Time of the last register (6 bits hour + 7 bits minute + 1 DLST + 1 bit modification + 1 bit alpha) Date of the last register (7 bits year + 4 bits month + 5 bits day) Last mass memory register - Unit 1 Last mass memory register - Unit 2 Last mass memory register - Unit 3 Last mass memory register - Unit 4 Last mass memory register - Unit 5 Last mass memory register - Unit 6 Last mass memory register - Unit 7 Last mass memory register - Unit 8 Time of the penultimate register (6 bits hour + 7 bits minute + 1 bit DLST + 1 bit modification + 1 bit alpha) TB-R1000 / Instructions Manual 47 6 - Protocol DNP 3.0 Table of registers of object 30 Obj 30 Var 1 and 3 32 bits analog input (dynamic variables) Index Code Sub/Command 1011 1012 1013 1014 1015 1016 --65400 Escale Unit Note Penultimate mass memory register (7 bits year + 4 bits month + 5 bits day) Penultimate mass memory register - Unit 1 Penultimate mass memory register - Unit 2 Penultimate mass memory register - Unit 3 Penultimate mass memory register - Unit 4 Penultimate mass memory register - Unit 5 --End of mass memory Table of registers of object 40, 41 Obj 40 (reading) and 41 (write-in) (configuration) Index Code Sub/Command 0 (code 01 sub 00) 1 (code 01 sub 01) 2 (code 01 sub 02) 3 (code 01 sub 03) 4 (code 02 sub 00) 5 (code 02 sub 01) 6 (code 02 sub 02) 7 (code 02 sub 03) 8 (code 03 sub 00) 9 (code 03 sub 01) 10 (code 03 sub 02) 11 (code 03 sub 03) 12 (code 04 sub 00) 13 (code 04 sub 01) 14 (code 04 sub 02) 15 (code 04 sub 03) 16 (code 05 sub 00) 17 (code 05 sub 01) 18 (code 05 sub 02) 19 (code 05 sub 03) 20 (code 44 sub 00) 21 (code 45 sub 00) 22 (code 46 sub 00) 23 (code 46 sub 01) 24 (code 46 sub 02) 25 (code 46 sub 03) 26 (code 47 sub 00) 27 (code 47 sub 01) 28 (code 47 sub 02) 29 (code 48 sub 00) 30 (code 49 sub 00) 31 (code 51 sub 00) 32 (code 51 sub 01) 33 (code 51 sub 02) 34 (code 51 sub 03) 35 (code 52 sub 00) 36 (code 52 sub 01) 37 (code 52 sub 02) 38 (code 52 sub 03) 39 (code 53 sub 00) 40 (code 53 sub 01) 41 (code 53 sub 02) 42 (code 53 sub 03) 43 (code 54 sub 00) 44 (code 54 sub 01) 45 (code 54 sub 02) 46 (code 54 sub 03) 47 (code 55 sub 00) 48 (code 55 sub 01) 49 (code 55 sub 02) 50 (code 55 sub 03) 51 (code 56 sub 00) 52 (code 57 sub 00) 53 (code 58 sub 00) 54 (code 70 sub 00) 55 (code 71 sub 00) 56 (code 72 sub 00) 57 (code 80 sub 00) 58 (code 81 sub 00) 59 (code 82 sub 00) 60 (code 84 sub 00) Escale 10 10 10 10 10 10 10 10 1 1 1 1 10 10 10 10 10 10 10 10 1 1 1 1 1 1 1 100 1 1 1 10 10 10 10 10 10 10 10 1 1 1 1 10 10 10 10 10 10 10 10 1 10 1 1 1 1 1 10 10 1 Unit V V V V V V V V minute minute minute minute V V V V V V V V kVA kV A V V V V V V V V minute minute minute minute V V V V V V V V % V V minute Note Reference voltage, post A, direct flow Reference voltage, post B, direct flow Reference voltage, post C, direct flow Reference voltage, post D, direct flow Insensitivity, post A, direct flow Insensitivity, post B, direct flow Insensitivity, post C, direct flow Insensitivity, post D, direct flow Delay time, post A, direct flow Delay time, post B, direct flow Delay time, post C, direct flow Delay time, post D, direct flow Resistive compensation, post A, direct flow Resistive compensation, post B, direct flow Resistive compensation, post C, direct flow Resistive compensation, post D, direct flow Reactive compensation, post A, direct flow Reactive compensation, post B, direct flow Reactive compensation, post C, direct flow Reactive compensation, post D, direct flow Control Serial Number Regulator connection configuration: 0=Invalid; 1=0 2=-30 3=+30 degrees Mode of operation of the delay time, post A 0=Sequential 1=Reversal Mode of operation of the delay time, post B 0=Sequential 1=Reversal Mode of operation of the delay time, post C 0=Sequential 1=Reversal Mode of operation of the delay time, post D 0=Sequential 1=Reversal Regulator's rated apparent power Regulator's rated voltage Regulator's rated current PT ratio CT ratio Reference voltage, post A, reverse flow Reference voltage, post B, reverse flow Reference voltage, post C, reverse flow Reference voltage, post D, reverse flow Insensitivity, post A, reverse flow Insensitivity, post B, reverse flow Insensitivity, post C, reverse flow Insensitivity, post D, reverse flow Delay time, post A, reverse flow Delay time, post B, reverse flow Delay time, post C, reverse flow Delay time, post D, reverse flow Line drop resistive compensation, post A, reverse flow Line drop resistive compensation, post B, reverse flow Line drop resistive compensation, post C, reverse flow Line drop resistive compensation, post D, reverse flow Line drop reactive compensation, post A, reverse flow Line drop reactive compensation, post B, reverse flow Line drop reactive compensation, post C, reverse flow Line drop reactive compensation, post D, reverse flow Mode of operation of the reverse flow - see the manual Reverse flow current threshold Presence of potentiometric disk 0 = Without 1 = Default disk Load bonus mode - see the manual Maximum TAP limit Minimum TAP limit Selects the voltage limiter mode - see the manual Maximum voltage limit Minimum voltage limit Demand interval TB-R1000 / Instructions Manual 48 6 - Protocol DNP 3.0 Table of registers of object 40, 41 Obj 40 (reading) and 41 (write-in) (configuration) Index 61 62 63 64 65 66 67 68 69 70 71 72 73 74 75 76 77 78 79 80 81 82 83 84 85 86 87 88 89 90 91 92 93 94 95 96 97 98 99 100 101 102 103 104 105 106 107 108 109 110 111 112 113 114 115 116 117 118 119 120 121 122 123 124 125 126 127 128 129 130 131 132 133 134 Code Sub/Command (code 88 sub -188) (code 91 sub 00) (code 91 sub 01) (code 94 sub 00) (code 95 sub 00) (code 96 sub 00) (code 96 sub 01) (code 100 sub 00) (code 101 sub 00) (code 102 sub 00) Escale 1 1 1 1 1 1 1 1 1 1 Unit DD.MM.YYYY hh.mm.ss bps - 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 hh.mm.ss hh.mm.ss hh.mm.ss hh.mm.ss DD.MM.YYYY DD.MM.YYYY DD.MM.YYYY DD.MM.YYYY DD.MM.YYYY DD.MM.YYYY DD.MM.YYYY DD.MM.YYYY Note Auto-test Bit1 =Disk, bit2 = frequency out of range, bit3= parameterization error Current date Current time Date and Time format - see the manual Number of resets executed in the external indicator Remote port 0 = Ethernet, 1= R232, 2=Optic fiber, 3= RS485 Remote serial speed Keypad password DNP 3.0 Local/Remote selection Enable unsolicited Event class selection Time sincronization Reserved Reserved Auxiliary board model Unit's DNP address Unit's TCP/IP address Communication software TCP/IP address Unit's TCP/IP mask Unit's TCP/IP port Communication software TCP/IP port Unit's TCP/IP gateway Communication software telephone number Communication software telephone prefix Mass storage unit 1 Mass storage sub-unit 1 Mass storage unit 2 Mass storage sub-unit 2 Mass memory unit 3 Mass memory sub-unit 3 Mass memory unit 4 Mass memory sub-unit 4 Mass memory unit 5 Mass memory sub-unit 5 Mass memory unit 6 Mass memory sub-unit 6 Mass memory unit 7 Mass memory sub-unit 7 Mass memory unit 8 Mass memory sub-unit 8 Network default frequency 0=undefined 1=50Hz 2=60Hz 3=error Display unit 1 Display sub-unit 1 Display unit 2 Display sub-unit 2 Display unit 3 Display sub-unit 3 Display unit 4 Display sub-unit 4 Display unit 5 Display sub-unit 5 Display unit 6 Display sub-unit 6 Display unit 7 Display sub-unit 7 Display unit 8 Display sub-unit 8 Category "A" initial time Days in which post "A" is valid - see the manual Category "B" initial time Days in which post "B" is valid - see the manual Category "C" initial time Days in which post "C" is valid - see the manual Category "D" initial time Days in which post "D" is valid - see the manual Daylight saving time assessment 0 = disabled Daylight saving time beginning date Daylight saving time end date Holiday date Holiday date Holiday date Holiday date Holiday date Holiday date TB-R1000 / Instructions Manual 49 6 - Protocol DNP 3.0 Table of registers of object 40, 41 Obj 40 (reading) and 41 (write-in) (configuration) Index Code Sub/Command 135 136 137 138 139 140 141 142 143 144 145 146 147 148 149 150 151 Escale 1 1 1 1 1 1 1 1 8 1 Unit DD.MM.YYYY DD.MM.YYYY hh.mm.ss s s bps Note Holiday date Holiday date Password - Programming - password 0 means no password Password - Login to logout, send wrong password or restart the control Number of power failures Total time of failures Time that the unit takes to consider a failure, in seconds Number of repetitions of frame without confirmation bit 31 = Mult frag, 30 simple frag Interval between frame repetitions Local serial speed Configuration of auxiliary contacts 0= "1: Reset, 2:NeutralP., 3:Op.Conf." Mobile chip PIN Reserved Reserved Reserved Reserved TB-R1000 / Instructions Manual 50 7 - Communication Software 7.0 Communication and Configuration Software TOSHIBA TBR-CONTROL This help contains information for Configuration and monitoring the TB-R1000 Control via a personal computer using the installed TOSHIBA TBR-CONTROL communications and parameterization software. Protocol DNP 3.0 was developed using software tools to facilitate the operator interface, however, we suggest that the user reads this help carefully to correctly use the software. 7.1 Minimum Hardware Requirements The TOSHIBA TBR-CONTROL software must be installed on a personal computer with the following minimum resources: —Microsoft Windows 95 —CD Drive —RS-232 Standard serial communication port —Mouse —RS-232 Serial communication cable 7.2 Software Installation To install TOSHIBA TBR-CONTROL software, the user must follow the steps below: — I n s e r t t h e TO S H I B A T B R CONTROL software installation CD into the CD drive. — Access the installation file: E:\TBR Control.msi (In the drive where the CD was inserted). — Click on the button to continue and select the installation location. TB-R1000 / Instructions Manual 51 7 - Communication Software — Then, the installation confirmation screen will display. — Click on the icon to continue the TBR Control installation. — Wait while TBR Control is being installed until the full installation final screen is displayed. TB-R1000 / Instructions Manual 52 7 - Communication Software — Click on Close, the installation was successfully completed. 7.3 Software Basic Operation 1 A channel according to the cable connected to TB-R1000. 2 A regulator according to the DNP address of TB-R1000. 3 To make the connection or dial a telephone number. After this, the software will be connected and ready to send and receive parameters for TBR1000. Schedule parameters, check box 4. TB-R1000 / Instructions Manual 53 7 - Communication Software 7.4 File Menu —Exit – Quit the application 7.5 Setup Menu — General – Configures the internal software parameters. — Channel - Adds/Changes/Deletes Communication channels. — Regulators - Adds/Changes/Deletes Regulators. — Analog Input Selection - Selects data to be displayed on the Input Values screen. — Analog Output Selection - Selects data to be displayed on the Output Values screen. TB-R1000 / Instructions Manual 54 7 - Communication Software — Access Files Folder - Not implemented yet. — Excel Files Folder - Not implemented yet. — Text Files Folder - Not implemented yet. — Setup Files Folder - Not implemented yet. — Saved Files Format - Not implemented yet. — Default Language - Selects the software standard language. — Log Screen Cleanning - Not implemented yet. — Attempts Connection - Not implemented yet. — Attempts Communication - Not implemented yet. — Timeout - Time in seconds without an answer from TBR-1000 to display a timeout message. TB-R1000 / Instructions Manual 55 7 - Communication Software — Description - Communication port. Ex.: com1, com2, com3, etc. — Speed - Enter the door communication speed. Ex.: 1200, 2400, 4800, 9600, 19200, 38400. — Pulse Dial - Select between Pulse and Tone dialing. Values: True, False. — Remote Port - Select a value from the list. For PCs, always use RS-232. — Phone Number - Enter the telephone number to dial. Use only when a modem is connected. TB-R1000 / Instructions Manual 56 7 - Communication Software — Description - Enter a description up to 50 characters. — Serial Number - Enter the regulator’s serial number. — DNP Address - Enter the same DNP number of the regulator, or 65532 (FFFC) for autoanswer. (The unit’s DNP address in Analogic Output). TB-R1000 / Instructions Manual 57 7 - Communication Software — Analog Input. Note: Unchecking these parameters does not reduce the DNP mesh size. TB-R1000 / Instructions Manual 58 7 - Communication Software — Analog Output. Note: Unchecking these parameters does not reduce the DNP mesh size. TB-R1000 / Instructions Manual 59 7 - Communication Software 7.6 Factory Menu — Remote Port - Adds/Changes/Deletes remote ports. — Message - Adds/Changes/Deletes software messages. — Language - Adds/Changes/Deletes languages. — Internal Name - Adds/Changes/Deletes internal message names. — Command - Adds/Changes/Deletes DNP 3.0 parameters — Exchange - Adds/Changes/Deletes DNP 3.0 parameters — Function - Adds/Changes/Deletes DNP 3.0 parameters — Object - Adds/Changes/Deletes DNP 3.0 parameters — Variation - Adds/Changes/Deletes DNP 3.0 parameter TB-R1000 / Instructions Manual 60 7 - Communication Software This form is used to translate any message into any language. —Description - Enter the message description. —Language - Select a value from the list. —Internal Name - Select a value from the list. TB-R1000 / Instructions Manual 61 7 - Communication Software TB-R1000 / Instructions Manual 62 7 - Communication Software — Description - Select a value from the list. — Detailed - Select a value from the list. — Code - Enter a Code for this command. — SubCode - Enter a SubCode for this command. — Minimum - Enter a minimum value for this command. — Maximum - Enter a maximum value for this command. — Step - Enter a Step for this command. — Exchange - Select a value from the list. — Sequence - Enter the sequential order of the DNP3 mesh for this command. — Bit - Enter the bit when the binary type is used. — Write Mask - Enter the mask used to save the value. Not implemented yet. — Read Mask - Enter the mask used to display the value. — Type - Select a value from the list. — Multiplier - Enter a value to multiply the read value. — Unit - Enter the unit of the read value. TB-R1000 / Instructions Manual 63 7 - Communication Software — Description - Enter a description up to 50 characters. — Function - Select a value from the list. — Object / Variation - Select a value from the list for each side. TB-R1000 / Instructions Manual 64 7 - Communication Software TB-R1000 / Instructions Manual 65 7 - Communication Software 7.7 Tools Menu — Schedule - Adds/Changes/Deletes Schedule data. — Remote - Accesses the remote monitoring screen. — Analog Input - Reads Analogic Input data. — Analog Output - Reads and saves Analogic Output data. —Direct Relay - Executes direct relay operations. —Mass Memory - Reads mass storage data. —Item Selection - Selects the values to be sent via analogic input. —Binary Input Change Selection - Selects the binary input change values (Unsolicited) — Harmonics - Displays the harmonics chart (FFT). — Chart Tap - Displays taps from -16 to +16 in a chart. TB-R1000 / Instructions Manual 66 7 - Communication Software This function is used to run a macro in certain time intervals and save the results to the database. — Description - Enter a description up to 50 characters. — Detailed Description - Enter a description up to 50 characters. — Communication Failure - Not implemented yet. — Status - Enabled = The schedule is active. Stopped = The schedule is on hold. Disabled = The schedule is inactive. —Macro - Select a value from the list. — Next Execution - Select a date from the calendar. — Hour Window - If enabled, select an interval to run the macro. — Frequency - If enabled, select an interval according to: TB-R1000 / Instructions Manual 67 7 - Communication Software This example runs the macro every 6 seconds This example runs the macro on the first Wednesday of January every year. —FILTER - Enable and enter the start and end values. It can be launched from the Toolbar button in the main form TB-R1000 / Instructions Manual 68 7 - Communication Software This form displays the analogical input values for TB-R1000, except for the values filtered by the Analogic Input Selection and Item Selection. The CSV Button saves the entire table to a text file. It can be launched from the Toolbar button in the main form. TB-R1000 / Instructions Manual 69 7 - Communication Software This form displays and allows changing the TB-R1000 Analogic Output values, except for the values filtered by the Output Value Selection. The CSV Button saves all data to a text file. The Read CSV Button reads all data from a text file. It can be launched from the Toolbar button in the main form. TB-R1000 / Instructions Manual 70 7 - Communication Software TB-R1000 / Instructions Manual 71 7 - Communication Software It sends a DNP3 Trip/Close DNP3 command to TB-R1000 according to a previously recorded macro when clicking the Send button. It can be launched from the Toolbar button in the main form. TB-R1000 / Instructions Manual 72 7 - Communication Software Reads and stores the internal TB-R1000 mass memory. Eight items are simultaneously monitored, which can be adjusted at the Unit tab in Analogic Output. You must enter the codes and subcodes for the desired Unit. Click on the Save Button to save the entire table to the database for use in graphs or reports; afterwards, the following question is shown: “It is advisable to clear the mass memory after this procedure. Confirm?” If you want to clear the mass memory without running those tasks, use the form Remote Control, click on the Send button for the “Reset Mem Massa” macro. It can be launched from the Toolbar button in the main form. TB-R1000 / Instructions Manual 73 7 - Communication Software Check or uncheck the parameters to be transmitted via the serial, reducing the DNP3 package size for the Analogic Input Buttons: Read - Reads TB-R1000 data. Send - Sends data to TB-R1000 CSV Save - Saves all data to a text file. CSV Read - Reads all data from a text file. Close - Returns to the main form. It can be launched from the Toolbar button in the main form. Note: Unlike the Input Value Selection, uncheking these parameters will reduce the size of the DNP3 package. TB-R1000 / Instructions Manual 74 7 - Communication Software Selects the events to be recorded in the binary input change response. TB-R1000 / Instructions Manual 75 7 - Communication Software This form calculates and displays in graph format the harmonic distortion for both Voltage and Current. It can be launched from the Toolbar button in the main form. This form displays the total number of operations in each tap in bar graph format. It can be launched from the Toolbar button in the main form. TB-R1000 / Instructions Manual 76 7 - Communication Software 7.8 Macro Menu —Macros… - Adds/Changes/Deletes Macros —Name - Enter a description up to 50 characters. —Detailed Description - Enter a description up to 50 characters. —Source - Not implemented yet. —Factory - Not implemented yet. —Destination - Not implemented yet. —Parameters File - Not implemented yet. —Command - Select a value from the list. TB-R1000 / Instructions Manual 77 7 - Communication Software 7.9 Report Menu —Reports… - Adds/Changes/Deletes Reports —Name - Enter a description up to 50 characters. —Detailed Description - Enter a description up to 50 characters. —Date - If enabled, select an interval to generate the graph. —Time - If enabled, select an interval to generate the graph. —Y Axis - Select a txt file from the list. —Failure Points To Zero - If checked, displays as zero all the failed points. TB-R1000 / Instructions Manual 78 7 - Communication Software 7.10 Graph Menu —Graphs… - Add/Alter/Delete Graphs —Name - Enter a description and a detailed description up to 50 characters. —Date - If enabled, select an interval to generate the graph. —Time - If enabled, select an interval to generate the graph. —Y Axis - Select a txt file from the list. —Failure Points To Zero - Check this option to generate the graph with the failure indication, according to: TB-R1000 / Instructions Manual 79 7 - Communication Software The Figure below presents 30 readings made at one-minute interval, and with a failure indication at 2:42 p.m.: TB-R1000 / Instructions Manual 80 7 - Communication Software Graph generated without failure indication: and graph generated with failure indication: Click on the Ok button to save the data above and use the same parameters in the future. TB-R1000 / Instructions Manual 81 7 - Communication Software 7.11 Help Menu —Contents - Displays this Help. —About - Displays information about this software and the system. TB-R1000 / Instructions Manual 82 8 - Installations and Connections 8.0 Installations and connections 8.1 Characteristics of the control box 1) Degree of protection level: IP 65. 2) Weight: 10.5 kg. 304 Dimensions in mm A Ø1 50 2 Ø1 B 2 C Ø7 Grounding E M12 Grounding 342 396 470 D F 19 G 12 185 190 A- Attachment support B- Latch with hole for padlock C- Gasket D- Flip-over cover E- Wiring passage F- Base for grounding to the regulator's tank G- Hinge H- Automation passage cover (20mm diameter) TB-R1000 / Instructions Manual 83 H 8 - Installations and Connections 8.2 Layout of the control box 1 2 "A" 3 17 4 5 MENU 6 CONF T B - R10 0 0 7 16 8 15 TOSHIBA T&D DO BRASIL LTDA 9 14 000 000 Cut "A-A" 10 11 12 13 1- External box 2- Magnet activator of the open door detector 3- Auxiliary board protection box Optional accessory TB-PA102 (Item 9.1) 4- Auxiliary printed circuit board Optional accessory (Item 9.2) 5- PT for external source 240 V 6- Control's upper panel (Case) 7- Wiring passage 8- Terminal blocks 9- Motor starting capacitor 10- Automation passage cover (20mm diameter) 11- Analog operation counter 12- Control's lower panel (Panel “B”) 13- Neutral indicating light 14- Motor fuse (4A) 15- Control fuse (0.5A) 16- Serial connector protection cover 17- Panel “A” TB-R1000 TB-R1000 / Instructions Manual 84 "A" 8 - Installations and Connections 8.3 Layout of the control box with resistance heating controlled by thermostat 1 2 "A" 3 18 4 5 MENU 6 CONF T B - R10 0 0 7 17 8 16 TOSHIBA T&D DO BRASIL LTDA 9 15 000 000 10 Corte "A-A" 11 12 1- External box 2- Magnet activator of the open door detector 3- Auxiliary board protection box Optional accessory 4- Auxiliary printed circuit board Optional accessory (Item 9.3) 5- Thermostat 6- Control's upper panel (Case) 7- Wiring passage 8- Terminal blocks 9- Motor starting capacitor 10- Resistance heating Optional accessory (Item 9.3) 11- Automation passage cover (20mm diameter) 12- Analog operation counter 13- Control's lower panel (Panel “B”) 14- Neutral indicating light 15- Motor fuse (4A) 16- Control fuse (0.5A) 17- Serial connector protection cover 18- Panel “A” TB-R1000 TB-R1000 / Instructions Manual 85 13 14 TB-PA102 (Item 9.1) "A" 8 - Installations and Connections 8.4 Schematic wiring diagram — Auxiliary contact “1” = Reset of the external position indicator. — The auxiliary contact, “2” can be selected pursuant to the customer's project Q1,Q2: Loads 127 Vac, 500ma Voltage Regulator OC: Operation counter Q1 Q2 1 2 OC 3 4 VSA 7 8 9 10 11 1 NP: Neutral position CSA PI NP PI: Polarity inverter 6 5 PD 12 1 PD: Potentiometric divider, 18 x 10 Ohms - 1% VSA: Voltage source adjustable from 80 to 165 Vac Rated frequency Only for under load tap-changers with potentiometric divider CSA: Current source adjustable from 0 to 0.4A Rated frequency and power factor -1 to 1 TB-R1000 Control Terminal blocks Auxiliary contact “2” X Auxiliary contact “1” 3 3 240V Neutral Supply / Measurement Phase motor Raise voltage contact Lower voltage contact 3 1 3 2 120V Fase (Maximum 4 VA) Auxiliary contact “2” Raise limit switch X Potentiometric divider supply Potentiometric divider reading Common potentiometric divider Analog operation counter Analog operation counter 8 Operation counter sensor 7 7 6 Lower limit switch Neutral position sensor Polarity inverter Potentiometric divider Position reading Potentiometric divider Control's supply Motor's supply Auxiliary contact “1” 5 4 4 Open the jumper between 32 and 33 on the terminal blocks for controls with this power transformer Neutral position sensor Neutral C.T. C.T. Polarity inverter 3 Control's supply plug connector 5 1 12 2 Operation counter sensor Neutral Current input Raise voltage Lower voltage 1 1 0 PT for external source 240 V (Optional) Open the jumpers 24, 25, 26 and 27 on the terminal blocks for controls with external position indicators 9 10 11 23 24 25 26 27 28 29 30 31 32 33 34 2 2 6 3 2 4 Capacitor 86 1 8 1 7 EXTERNAL SOURCE 1 FUSES MOTOR CONTROL 4A 0,5A LOWER 1 3 3 1 2 M TB-R1000 / Instructions Manual 1 9 2 5 2 M 3 M OFF 2 2 3 M 1 1 1 1 3 C 2 C VOLTMETER NORMAL 1 RAISE ON 2 7 2 2 NEUTRAL POSITION 3 2 1 5 1 4 1 9 OFF 1 7 2 2 EXTERNAL 2 0 5 1 1 OPERATIONS COUNTER 1 7 1 0 Panel "B" 2 9 1 8 2 8 1 4 1 5 2 3 9 10 11 23 24 25 26 27 28 29 30 31 32 33 34 9 8 8 7 6 6 1 5 1 2 4 3 C 3 2 C 12 2 1 1 1 8 1 2 0 Ground 8 - Installations and Connections 8.5 Schematic wiring diagram with resistance heating controlled by thermostat — Auxiliary contact “1” = Reset of the external position indicator. — The auxiliary contact, “2” can be selected pursuant to the customer's project Q1,Q2: Loads 127 Vac, 500ma Voltage Regulator OC: Operation counter 7 8 9 10 11 1 PI: Polarity inverter 6 12 1 PD: Potentiometric divider, 18 x 10 Ohms - 1% VSA: Voltage source adjustable from 80 to 165 Vac Rated frequency Only for under load tap-changers with potentiometric divider CSA: Current source adjustable from 0 to 0.4A Rated frequency and power factor -1 to 1 TB-R1000 Control Fase (Maximum 4 VA) Auxiliary contact “2” Open the jumpers 24, 25, 26 and 27 on the terminal blocks for controls with external position indicators Raise limit switch Lower limit switch Neutral position sensor Polarity inverter Potentiometric divider Position reading Potentiometric divider Control's supply Motor's supply Auxiliary contact “1” Operation counter sensor Neutral Current input Raise voltage Lower voltage Terminal blocks Thermostat Fuse Terminal Block Glass body fuse, 4A, 250Vac, Ø5 x 20mm 1 1 1 12 2 3 4 5 6 7 8 9 10 11 23 24 25 26 27 28 29 30 31 Control's supply plug connector Ground 1 1 1 12 2 3 4 5 6 7 8 9 10 11 23 24 25 26 27 28 29 30 31 25 W - 750 ohms Resistance heating Capacitor Panel "B" OPERATIONS COUNTER FUSES EXTERNAL NEUTRAL POSITION ON RAISE CONTROL 0,5A OFF EXTERNAL SOURCE VOLTMETER NORMAL MOTOR 4A OFF TB-R1000 / Instructions Manual 87 LOWER Auxiliary contact “2” 5 Auxiliary contact “1” 4 NP: Neutral position CSA Potentiometric divider supply Potentiometric divider reading Common potentiometric divider Analog operation counter Analog operation counter 3 VSA Operation counter sensor 2 PD PI NP Neutral position sensor Neutral C.T. C.T. Polarity inverter 1 OC Neutral Supply / Measurement Phase motor Raise voltage contact Lower voltage contact Q1 Q2 9.0 - Accessories 9.0 Accessories Communication with optic fiber 9.1 Auxiliary printed circuit board TB-PA102 (Optional) It uses multimode optic fiber cables 62.6 / 125, “ST” type connector, to communicate with TB-R1000 control. To connect with a remote transmission unit (RTU) where the distance between the control and the RTU generally is long, the auxiliary board containing the optic fiber circuit is recommended for the insulation of surges. Communication with RS-232 In this communication output, it's required a serial cable DB-9 232 connected with the control and the communication software “TBR Control” to make the communication. TB-R1000 Control The auxiliary printed circuit board TB-PA102 allows remote monitoring through the communications via RS-232, RS-485, and optic fiber that communicates with speed of up to 34,800 bps, and additionally to the remote monitoring, the auxiliary board provides an automation passage through a dry-contact relay that can be parameterized pursuant to the technical specification. DB-9 (Male) 12 3 4 5 6 7 8 9 Serial cable DB-9 (Female) RS-485 Automation PC RS-232 Optic fiber Auxiliary board TB-R1000 / Instructions Manual 88 12 3 4 5 6 7 8 9 9.0 - Accessories 9.2 Transformer to correct voltage external power control (Optional) Internal mounting plate control box Fuse Terminal Block Applicable only where the phase voltage for external power is greater than 127 Vac. Note: The voltage value should be reported by the client. Thermostat Glass body fuse, 4A, 250Vac, Ø5 x 20mm 1 1 1 1 12 30 1 1 1 12 30 R 1 R Transformer Resistance heating (25 W / 750 ohms) 9.3 Resistance heating controlled by thermostat (Optional) This accessory is intended to prevent condensation of water inside the control box where the temperature should not fall below a specified minimum value. Thermostat Operating Range: Between 0 and 60 ° C. Characteristics of resistance: 25 watts, 750 ohms, 0.18 amps. TB-R1000 / Instructions Manual 89 Rodovia Fernão Dias (BR 381), 3045 - Contagem - Minas Gerais - Brazil Export Sales: +55 31 3329 6660, Customer Assistance: +55 31 3329 6565 / +55 31 3329 6564 e-mail: exportsales@toshiba.com.br, falecom@toshiba.com.br
