CP-061HT Peltier-Thermoelectric
Cold Plate Cooler
•
•
•
•
Heat-sink air flows along length of fins (in one end, out opposite end).
•
Provides effective direct-contact cooling which is ideal for precision temperature
control.
•
Threaded holes are located in the cold plate for easy attachment of a temperature
sensor, interface plates, and other cooled plates.
•
High-temperature version of the CP-061 enables a maximum allowable plate
temperature at 100 °C.
•
CE marked, RoHS compliant.
Low fan noise (39 dBA) is beneficial in laboratory instrumentation.
No additional modifications needed for bench-top use.
Ideal for small to medium heat loads, such as laser diodes, thermal stabilization of
electronic components, or medical and laboratory instruments.
TE
®
TECHNOLOGY, INC.
1590 Keane Drive
Traverse City, MI 49696-8257
www.tetech.com
TEL: 231-929-3966
FAX: 231-929-4163
email: cool@tetech.com
Expert Engineering, Precision Manufacturing: Quality Thermal Solutions Delivered
NOTE: All specifications are subject to change without notice.
© 2010 TE Technology, Inc.
CP-061HT 29-JUL-2015 Page 1 of 4
CP-061HT
Specifications
TE Power (typical)1:
24 VDC at 4.5 A
TE Power (maximum)2:
24 VDC at 5.4 A
Hot-side Fan Power:
24 VDC at 0.23 A
Please review the product manual:
Thermoelectric Cooling Assembly
(TCA) Instruction Manual, FAQ’s and
related technical information, and
ordering information posted on our
web site before purchasing or using
this product.
NEMA Rating:
NA
Weight (kg):
2.3
Performance is based on unrestricted air
flow to fan and from air-flow outlets. Do
not operate if the cold-plate temperature
exceeds 100 °C or the heat-sink
temperature exceeds 100 °C. Do not
operate fan at air temperatures below -10
°C or above +70 °C.
1Current,
at steady-state, is rated at +25 °C ambient, +25 °C cold plate, maximum heat removal. At -21 °C cold plate, the typical steady-state current is 4.6 A.
2Current,
at steady-state operation under-worst case conditions, is rated at -10 °C ambient, +100 °C cold plate, maximum heat removal.
4X M5 x 0.8 THREADING TAPPED 9.7 DEEP
4X M4 x 0.7 THREADING TAPPED 9.7 DEEP
NOTES:
88.9
41.9
1.
All dimensions in millimeters.
2.
Cold side shown in blue; hot
side shown in red.
3.
A 3D PDF, .igs, and .sldprt
solid models are also
available from the website.
Contact TE Technology for 3D
solid models in STEP or SAT
format.
19
7.9
88.9
19
139.7
43.6
6.4
153.9
25.4 DEEP HOLE with
M3 x 0.5 THREADING TAPPED 9.7 DEEP
for SENSOR MOUNTING
104.6
12.7
127
63.5
12.3
12.7
80
21.7
AMBIENT-SIDE
AIR FLOW OUTLET
AMBIENT-SIDE
AIR FLOW INLET
92.2

Download manual
www.tetech.com
RoHS Compliant
Directive 2011/65/EU
TE
®
TECHNOLOGY, INC.
1590 Keane Drive
Traverse City, MI 49696-8257
www.tetech.com
TEL: 231-929-3966
FAX: 231-929-4163
email: cool@tetech.com
Expert Engineering, Precision Manufacturing: Quality Thermal Solutions Delivered
NOTE: All specifications are subject to change without notice.
© 2010 TE Technology, Inc.
CP-061HT 29-JUL-2015 Page 2 of 4
Bottom View of CP-061HT
Cooler can be mounted using the four M5 x 0.8 PEM nuts located as shown in the base of the shroud.
6.3
4X M5 x 0.8 THREADED PEM NUT
2X 79.4
2X 12.7
2X 128.6
2X 12.7
RoHS Compliant
Directive 2011/65/EU
TE
®
TECHNOLOGY, INC.
1590 Keane Drive
Traverse City, MI 49696-8257
www.tetech.com
TEL: 231-929-3966
FAX: 231-929-4163
email: cool@tetech.com
Expert Engineering, Precision Manufacturing: Quality Thermal Solutions Delivered
NOTE: All specifications are subject to change without notice.
© 2010 TE Technology, Inc.
CP-061HT 29-JUL-2015 Page 3 of 4
CP-061HT Cooling Performance Graph
(removing heat from cold plate)
100
90
Cold Plate Temperature (°C)
80
70
60
50
40
30
20
10
50 °C ambient
0
35 °C ambient
-10
25 °C ambient
-20
-30
0
10
20
30
40
50
60
70
80
90
100
110
120
130
140
150
160
Heat Removed from Cold Plate (watts)
How to use the Performance Graph:
1. Select Performance Line.
2. Select Cold Plate Temperature.
3. Determine Cooling Capacity.
The diagonal lines shown represent
cooling performance at the indicated
ambient air temperature. If the cooler
is to operate at a different ambient,
then you must sketch in a new
performance line. This can be drawn
parallel to one of the existing lines,
using the distance between the
existing lines as a scale to properly
locate the new line.
Draw a horizontal line on the graph
from the vertical axis
corresponding to the desired coldplate temperature until it intersects
with the performance line
corresponding to the ambient
temperature at which the cooler is
to operate.
The maximum amount of heat
that the cooler can remove from
the cold plate is determined by
drawing a vertical line from the
intersection point (determined in
the previous step) down to the
horizontal axis of the graph. If the
heat load dissipating into the cold plate
exceeds the cooling capacity, then the
cooler will not be able to maintain the
desired cold plate temperature.
Example: You need to maintain the cold plate at 15 °C while in a 25 °C ambient. The cooler can remove a
maximum of approximately 45 W of heat from the cold plate. If the heat load (heat source connected to the cold
plate plus the heat gain through insulation, solar, vapor condensation, etc.) exceeds this, you would need more
coolers and/or a larger cooler.
TE
®
TECHNOLOGY, INC.
1590 Keane Drive
Traverse City, MI 49696-8257
www.tetech.com
TEL: 231-929-3966
FAX: 231-929-4163
email: cool@tetech.com
Expert Engineering, Precision Manufacturing: Quality Thermal Solutions Delivered
NOTE: All specifications are subject to change without notice.
© 2010 TE Technology, Inc.
CP-061HT 29-JUL-2015 Page 4 of 4