Winter 2008 $10 REPLACE i Libya Archaeology Dual Battery Comparison Flashlights Hole-in-the-Rock, Utah Overland Journal Winter 2008 41 Gentlemen’s Dual By Chris Marzonie Photography as noted An introduction to dual battery systems, and a review of seven products to keep the fridge cold, and you from being stranded Overland Journal Winter 2008 It’s that sinking feeling— you know the one. You’ve rolled up the camp and packed everything into the vehicle; you jump into the driver’s seat, turn the key and . . . click. Overland travelers are equipping their vehicles with more and more aftermarket products that rely on electrical power—everything from two-meter radios to GPS units, fridges to laptops, winches to driving lights. The power required by these devices can be substantial, and adds to that needed by the factory equipment: computerized engine management, OEM stereo systems, OEM lighting, perhaps power locks and windows—and one of the most important: the starter. You are ultimately putting a lot of trust in electrical components that operate in unison to keep you moving when you want to move, and comfortable when you’re parked. Primarily, you’re relying on the battery, the starter, and the alternator (or generator in older vehicles), although most newer vehicles also have a computer control module that can wreak havoc if it malfunctions. In this article, we’re focusing on one of these components: the battery. The original factory battery was designed for operating the original factory equipment. Aside from the vital task of turning the starter motor, the design intent includes circuitry assumed to operate with the engine turned off, such as hazard flashers, convenience lights, instrument lights, audible indicators, the horn, and maybe a bit of stereo operation. Beyond that, the battery relies on the alternator—via a running engine—to provide power for continuous, high-draw devices. It also relies on the alternator to recharge any power lost from the battery when starting the car or running equipment with the engine off. When you ask a battery to do much more than this, you begin to stretch the limits of the original design intent, reducing reliability and shortening its life. A dual battery system solves these problems. By correctly installing a second battery, you are doubling the odds of having power when you need it, and reducing the chance of total failure by half. Another option is to replace the sole battery in the vehicle with an upgraded version that has more robust construction and higher capacity, along with a tolerance for repeated discharges. This may be appropriate based on your intended use and budget, but generally speaking the added reliability and redundancy of a dual-battery system is hard to beat. In the most basic sense, you are always carrying a spare battery with you, which can mean the difference between a brief interruption of a solo trip and being stranded. Electrical loads The first consideration is how much power you’ll need. You should complete this exercise before you buy that microwave oven, the portable blender, or the extra strand of party lights. Load calculations can be grouped into three categories: Power while moving, power while stationary, and power for winching. Power while moving includes things such as auxiliary lighting, stereos, navigation equipment, fridges, etc., that are in use while the engine is running. Accessories such as high-wattage auxiliary lighting and high-power stereos will draw a substantial amount of the power available from the charging system, and that effects how long it will take to recharge the batteries while moving. You can use this information to roughly determine how long you may need to drive the vehicle to recharge the second battery, and likewise to determine if your factory alternator is up to the task of supplying sufficient power for all of your equipment, while still charging the batteries in a timely fashion. Next, you’ll want to determine how much power you will use while stationary, with the engine off. (See the sidebar for a sample calculation.) Typically this will include any electrical items you’ll be using while camped. Some of the most common are fridges, lighting, communications radios, stereo systems, and rechargers for small batteries in laptops, phones, and cameras. Err on the conservative side with your numbers, so you’ll have a buffer. This will compensate for things such as unusually hot days (longer fridge run times and less-efficient power transfer) unusually heavy gadgetry sessions, aged batteries, or those late night soirees when you and your buddies stay up to watch the moon set. Remember to account for additional loads when using AC power inverters. Some of us won’t be able to outfit batteries big enough to keep up with all of our vices, especially while boondocking for more than a day or two, so at that point it may be wise to look into solar and/or wind charging systems. Finally, let’s examine the relationship between winching and batteries. Winches demand an enormous amount of current. Using a second battery to power the winch helps preserve the start- 42 Overland Journal Winter 2008 ing battery (or reserve battery depending on your system) and extend winch operating time. If you consistently find yourself doing long and/or frequent winch pulls (such as in mud and snow country), you would do well to invest in a high-output alternator along with the largest deep-cycle battery (or batteries) you can afford and have room for, to satisfy the power-hungry winch. Find out what your winch’s maximum draw is, then use the load calculation, substituting the winch for the 12V accessory. (Additionally, you’ll need to consider Peukert’s Law, which means the faster you discharge the battery, the less capacity it has. An online Peukert calculator is available at csgnetwork.com/batterylifecalc.html.) Factor in additional loss due to heat, inefficiency, and less-than-ideal battery conditions, and you’ll get an idea of how long you can run your winch from your auxiliary battery. In most cases, occasional winch use to recover yourself or another vehicle, or move a fallen tree from the road, will be handled just fine with a single battery in good condition. If frequent or long pulls are expected, then you may want more reserve power. This can be achieved by either adding a third battery, or combining the primary and secondary battery in a dual system. You may also want to consider supplying the winch from the main battery so it can take direct advantage of the alternator’s output regardless of the isolator’s switch position. If you plan to combine batteries, you’ll need a combiner switch that is capable of handling the large, continuous current loads the winch demands. Slee Off Road documents a fine example of such a system on their website, and offers installations for this configuration. It employs a heavy-duty manual battery switch with a bypass feature that locks the dual-battery isolator out of the circuit, thereby protecting it from the large currents. This allows the operator to disable the isolator solenoid from the circuit, and then use either battery or both batteries for winching operations, or to self-jump-start the vehicle. Blue Sea Systems also has a product of this type, called the “Add a Battery.” (Note that the system shown on Slee’s website may require an Automatic Charging Relay (ACR) for newer vehicles.) See the resouce listing at the end of this article. Choosing the batteries The second step in selecting system components is to choose the battery or batteries. Many people keep the original starting battery, especially if it’s in good condition. But if you tend to discharge it on a regular basis (especially if you set up the secondary battery strictly as a reserve), you should consider installing an AGM deep-cycle battery with high cranking amps, which can handle both heavy starting loads and repeated discharge. When adding a secondary battery, a simple rule of thumb is to install the largest capacity battery you can afford, both in terms of price and available space. Quality is another consideration; an impressive amp-hour rating will do no good if a cheap battery fails early on. Don’t neglect the mount—a generic battery tray held to an inner fender with self-tapping screws just won’t do. The mount must be engineered to hold the battery securely in place in the event of a collision or rollover. The subject of batteries and varying types of deep-cycle designs is enough for an article of its own, so I’ll keep this to a brief summary of what’s available to the automotive and RV market. With the exception of hybrid cars, virtually all automotive batteries are lead-acid. Lead-acid is just one of many different battery chemistry methods, and has traditionally been used for automobiles because of the properties associated with it. Capable of safely producing large amounts of current, lead-acid batteries are relatively predictable in their operation, reasonably durable, and economical. The basic principal of a lead-acid battery is to combine lead plates or grids along with electrolyte, otherwise known as battery acid (sulfuric acid and water), to create chemical energy that can be converted to electrical energy and vice versa. There are three types of lead-acid battery: flooded-cell (wet cell), gel, and AGM (absorbed glass mat). Flooded cell batteries are the oldest design and use a liquid (wet) battery acid. They usually tolerate overcharging and undercharging better than AGM or gel batteries, although they have some limitations for charge current, as the acid can boil and off-gas if too much current is applied. They require periodic maintenance, including cleaning, since they vent hydrogen gas and acid Load Calculation Electrical loads are measured by amp-hours (AH). One amp-hour equals a load of one amp for a period of one hour. Batteries are commonly specified based on a 20-hour rate, whereby they are discharged down to 10.5 volts over a 20-hour period, and the resulting amp-hours supplied are measured. However, that’s unrealistic for our calculations, because typical batteries should not be discharged lower than 50 percent of their capacity, or they will suffer premature wear. In a 12-volt system, 12.7 volts is considered a 100 percent state of charge, while 12.06 volts is considered 50 percent. (To calculate amps, divide watts by volts; e.g., a 60-watt, 12-volt light draws 5 amps. Multiply that figure by time used to get amp-hours) Here is a sample calculation of a typical vehicle’s electrical requirements. Fridge: 40 AH (5 amps, cycling on 50 percent of the time, x 16 hours—turned off for 8 hours overnight) Laptop (running): 6 AH (6 amps x 1 hour) Laptop (charging): 6 AH (3 amps x 2 hours) 2-Meter Radio: 1.4 AH (0.7 amps x 2 hours) Lights: 3.75 AH (three 5W lights (.417 amps) x 3 hours) Total AH required in a 24-hour period = 57.15 For this example, a typical 105 amp-hour deep-cycle battery would almost be sufficient for a 24-hour period, provided the 50 percent state-of-charge regimen was followed. Note: Idling your engine, even at high RPM, is a poor method of recharging your battery while camped. Assuming a 50 percent discharge, it can take several hours of idling to bring the battery back up to nearly fully charged. The amount of pollution created and fuel wasted is not worth it. Either bring an extra battery, or use a solar/wind charging system (to be covered in a future article) or a small, efficient, portable generator. Overland Journal Winter 2008 43 mist, which leads to corrosive build-up on exterior parts. Most have accessible cell ports with caps to allow distilled water to be added to replenish the electrolyte mixture. On a cost per cycle basis, they are the least expensive by a large margin, and can last a long time if properly maintained. Disadvantages are the more intensive maintenance, susceptibility to vibration damage, and intolerance for non-use (the lifespan is shortened if left to sit without being used or charged). Gel batteries suspend the acid in a firm silica gel, eliminating the need to replenish the water in the cells. The advantage to the gel electrolyte is that the battery can be mounted in any position, and there is no acid to splash or spill. Gel cells can be left idle for long periods of time, and hold a charge much better than a flooded cell. The gel cannot circulate among the cells as in a wet cell battery, so the plates must be kept somewhat thin to accept a charge in a reasonable amount of time. The biggest disadvantages of gel batteries are their finicky charging requirements and expensive price tags. They must be charged at a slow rate, per the manufacturer’s specifications, in order to last. Overcharging can create damaging pockets in the gel that reduce performance and can cause premature failure. AGM (absorbed glass mat) batteries are often improperly referred to as gel batteries, and are sometimes labeled as “dry cell.” Although similar in concept to a gel battery, instead of gel, an electrolyte paste is absorbed into fine fiberglass mats to about 95 percent saturation (often referred to as “starved electrolyte”), which is sandwiched between the plates. The famous “spiral cell” design, with cylindrical cells packaged in cases resembling a six-pack, is one example of AGM construction, but the standard box-shaped cases are common as well. The box case allows more cell volume in roughly the same overall dimensions as a spiral-cell counterpart, and therefore typically boasts higher reserve power. AGM batteries are considered by many to be the best choice for 4WD and overland applications. The nature of their construction makes them highly durable and vibration-resistant, with low internal resistance. They can sit for long periods of time with little self-discharge. Charging capacity is limited by heat, not necessarily current, so you can dump a large amount of amperage into them for a much faster recharge than gel batteries. Their biggest disadvantage is price, often twice as much as flooded-cell batteries. Types of dual-battery systems How do you like your eggs? Poached, hard-boiled, or scrambled? Ok, over-medium it is. There are different styles of battery isolation systems to choose from, and debates abound about which one is best. The four common types of isolators include manual switches, diodes, solenoids, and MOSFETs (metal-oxide-semiconductor field-effect transistor). The term “isolator” refers to the device’s ability to isolate the second battery from the main battery when a charging current is not present. This allows you to run your accessories from one battery while preserving the other for starting duty. In addition to isolation, some devices have the capability to combine the two batteries to increase the available power output. This can be useful for winching or self jump-starting. 44 • The manual switch is the simplest isolator. It employs heavy-duty contacts, selected by a rotary knob, which allow the operator to combine, isolate, or individually charge the batteries. While simple, rugged, and inexpensive, this method requires user involvement. So if you are a person like me, who once left an expensive camera lens sitting on an ARB bumper, from which it fell to be run over by a 35-inch mud-terrain tire, you might want to opt for an automatic system, lest you leave both batteries connected and wonder why your fridge is doing so well. It’s been running for how many days without flattening the battery? Man, we could stay out here forever! (And you might get your wish.) • A diode isolator is essentially a switch made of semiconductor material that only allows current to flow in one direction. It’s like a one-way valve for electricity. A diode isolator is commonly configured as a trio of metals studs, set into a chunk of extruded aluminum cast with cooling fins, also known as a “heat sink.” The cooling fins are necessary because as current passes through the diodes, they heat up. This heat means there is some loss of voltage. The chief downside to a diode isolator is that higher current results in more heat and a higher voltage loss Overland Journal Winter 2008 (up to a full volt in some models). The lost voltage on the outlet side of the isolator may not be seen by the vehicle’s voltage regulator, resulting in a less than fully charged battery. Diode isolators are very common and generally affordable, as well as easy to connect to the vehicle’s charging system. Units rated for larger amperage can be quite bulky, and therefore require adequate space for installation. • A solenoid isolator (also called a relay) consists of heavy-duty mechanical contacts similar to those used on starters and winches. When the charging voltage drops below a preset level, the device switches to isolate the batteries. When charging resumes and the voltage rises to a preset level, the device connects both batteries to the charging current. This type of isolator is often economical, simply constructed, and easy to install. Solenoids are capable of handling high currents, and many can momentarily combine battery current to allow self jump-starting of the vehicle. The disadvantage is that the contacts can theoretically become pitted and oxidized over time, eventually leading to increased resistance, voltage loss, and possibly failure. They don’t discriminate when it comes to direction of current, so once connected, a severely discharged battery may be subject to a huge inrush of current from a fully charged (starting) battery. Solenoid isolators often come with companion “smart” controllers that allow remote (in-cab) operation, overrides, and even custom voltage settings. • Recently, the MOSFET isolator has become popular. A MOSFET is a solid-state device able to switch power quietly, without moving parts, with minimal voltage loss and virtually no heat. MOSFETs are also compact for a given capacity, so require less space for installation. MOSFETs were originally used in smaller electronic devices and with lower currents than seen in vehicle applications, but developments in technology have made them viable for high-current applications such as dual-battery systems. Depending on the construction, MOSFETs can potentially be sensitive to voltage spikes and power surges unless they are specifically rated for continuous duty under such high loads. A word on inverters: If you install an inverter to run typical 120V appliances and accessories, choose one that will waste as little power as possible. This includes selecting a size appropriate for your intended use. You don’t need a 2,000-watt inverter to run a 100-watt laptop. Inverters waste power in the conversion process, in addition to requiring power just to operate. Large inverters can be very inefficient at inverting small loads. Many list a peak efficiency of 90 percent, which means 10 percent of the power used is wasted, and that’s a best-case scenario. Run a small load through a 2,000 watt inverter and the efficiency could drop precipitously, wasting much of the power consumed from your battery. That means a loss of precious amp-hours, and less time that can remain stationary without supplemental charging. Configuration options Having reviewed the different types of systems, let’s discuss ways to wire them. For basic dualbattery duty, there are two prevalent schools of thought: One is to use the primary (starting) battery to run all of the accessory loads, leaving the auxiliary battery unmolested and fully charged as a reserve supply. The second approach is the opposite—run all the accessories from the auxiliary battery, and reserve the primary battery for starting the engine and powering stock equipment. Many argue that leaving the secondary battery isolated and unused unless needed for jumpstarting the vehicle is a waste of a perfectly good battery. Batteries need to be cycled periodically (that is, discharged and recharged) to keep them alive and healthy. However, with the advent of AGM batteries and their ultra-long shelf lives, combined with occasional jump-starts and periodic manual cycling by the owner, there’s not much reason to doubt a long and reliable use period for such a system. On the other hand there are those, like myself, who prefer to keep a standard-size, highcranking battery for starting the vehicle and running the OEM circuits, and install a monster deep-cycle model with a high amp-hour rating to run all the accessories. This keeps both batteries cycled with regular use, but still isolates the primary battery from the secondary battery while the engine is off. And for those with manual switches, well, you can slice it anyway you like. Just don’t forget to turn the knob. Whichever way you choose, be sure to use wire that’s up to the job. Somewhat unintuitively, 12VDC systems require heavier-gauge wire than 120VAC systems like those in your house. Use a wire chart to determine the correct gauge for the length of run you need. 45 Overland Journal Winter 2008 Product Profiles Hellroaring Technologies Model: BIC-95150B By Brian DeArmon Remote toggle switch (center) for manually combining the batteries (Photo: Brian DeArmon) The Hellroaring BIC-95150B installed on the firewall of Brian’s Jeep TJ (Photo: Brian DeArmon) 46 By Jonathan Hanson The complete National Luna kit (Photo: Jonathan Hanson) Overland Journal Winter 2008 $175 (isolator) $47 (switch) The Hellroaring isolator is a small, fully potted (encased in resin and sealed from dirt and moisture), solid-state device (combined diode/FET) with an integrated heat sink, and can be configured in several ways, allowing you to set up the electrical system as you desire. The most common 4WD application is the basic auxiliary battery isolation, but it can also be configured for starting battery isolation. The BIC-95150B comes with an exhaustive 10 pages of instructions, which makes things seem more complicated than they really are. Refer to the included wiring diagrams while reading the instructions and it becomes clear that installation is a breeze. In its basic configuration, power is supplied to the isolator from the alternator (usually tapped in at the positive terminal of the OEM battery). Power is then supplied from the isolator to the auxiliary battery’s positive terminal. The auxiliary battery is grounded to either the chassis or the OEM battery, and finally the isolator itself is grounded via a fused connection (provided by Hellroaring). It’s that simple. To spice things up a bit, two options exist. First is a remote switch that allows both batteries to be combined in parallel, allowing for heavier loads to be placed on the system without excessive voltage drop. The second is a remote LED indicator for the remote switch. Both of these options are single wire inputs. The Hellroaring isolators are able to handle up to 90 amps, so unusually heavy or long electrical loads, such as starting your engine from the auxiliary battery when the main battery is flat, should not be attempted without an external relay with the proper load rating. When I installed the isolator on my 2003 Jeep TJ, I opted for the basic auxiliary battery isolation. This allowed me to build a secondary electrical system that essentially removed all connections between the OEM system and any of my aftermarket electrical equipment. The only connections between the two systems are at the batteries. The hot side of the two batteries is connected with 8-gauge wire, via the isolator, and the ground posts are connected with a 1/0 battery cable. All of the aftermarket accessory circuits are fed off of the auxiliary battery. This leaves the OEM electrical system completely unmolested, and should I forget to turn off the 2-meter radio or fridge before setting off on a multi-day backpacking trip, the OEM battery will still be fully charged when I return. Being a solid-state device, there is very little to go wrong. My BIC-95150B has performed flawlessly over the past year, even when mounted under the hood where temperatures are high. I have managed to run the deep-cycle auxiliary battery down to 5 volts, essentially rendering all of my aftermarket electrical/electronic gear useless. One turn of the key, the engine started off of the main battery, and all excess output from the alternator is directed to the auxiliary battery, bringing everything back to life, all without a 30-mile hike to the nearest town to summon help. hellroaring.com, 406-553-3801 National Luna Intelligent Split Charging Kit $375 After experiencing premature failure in two inexpensive diode battery isolators on our Toyota truck (I’m a slow learner), I was determined to find a more reliable system for my 1973 FJ40. Research and a conversation with Paul May at Equipt Expedition Outfitters led me to the National Luna Intelligent Split Charging Kit. The most telling feature of the National Luna kit is the instructions, which comprise exactly one page. This is an astonishingly simple system to install—the major portion of my time was spent running wires and creating a safe container for the auxiliary battery; installation and hookup of the control unit and display was the work of perhaps an hour. And the system changes nothing in the vehicle’s existing wiring—if necessary you can revert to your stock battery setup by removing two wires. The next obvious feature of the system is the comprehensive and top-quality kit in which it comes, which includes everything from 20 feet each of fine-strand, 16mm red and black battery cable, to two sets of battery terminals, plus crimp fittings, fuse holders, and zip ties. The only things I added were split loom protection and shrink tubing. Normally I’m leery of the term “kit,” but this one is truly all there. Product Profiles The NL system employs an 85-amp (continuous duty) solenoid as its routing switch. While perhaps not as ultimately efficient as a MOSFET-type switch (solenoid contacts can oxidize and slightly reduce current flow over time), it’s reliable and needs no cooling fins (as diode switches require), since inherent power wastage is scant. The brain of the NL system is encased in a small package above the solenoid. It is timed so that only the main battery receives charge for the first five minutes after starting, to allow it time to recover and reduce immediate load on the alternator. Then the solenoid switches charging current to both batteries. An in-cab display uses dual LED columns, colored red to yellow to green, to indicate the state of charge in each battery. It’s easy to see at a glance while camped if your system is in need of charging. So far I’ve been perfectly satisfied with the National Luna system. I like having easy visual access to the status of the batteries, and it’s equally important to me that I could quickly disconnect the unit in the unlikely event of trouble in the field. The kit is simple enough, and the instructions clear enough, that even an amateur mechanic could easily accomplish a professional installation. equipt1.com, 866-703-1026 The National Luna solenoid on the passenger-side firewall of the JF40 (Photo: Jonathan Hanson) Painless Performance Products 250-Amp Dual Battery Current Control System #40102 $131 In an attempt to be prepared for those times when Murphy’s Law becomes reality, and to provide power for future accessories such as a refrigerator, I chose a simple and inexpensive manual system manufactured by Painless Performance Products for my 2003 Tundra. I researched several articles about dual-battery systems, but Painless’s kit was available locally at a popular retailer. The kit comprises a 250-amp solenoid, an SPDT center-off waterproof switch, indicator lights, a length of 4-conductor wire similar to trailer wiring cable, and needed connectors and other hardware. The instructions suggest that one should run everything off the primary battery, keeping the auxiliary charged and ready for emergency backup. That philosophy made sense to me, so I followed it in all of my accessory wiring. Both the instructions and installation were very straightforward for anyone with basic electrical circuit knowledge. The operator chooses manually from three possible switch positions. The center position disengages the auxiliary battery from the charging circuit entirely, essentially replicating the factory configuration. The “green” position engages the solenoid to charge or use power from the auxiliary battery while the ignition key is in the accessory or run positions. The “red” position engages the solenoid at all times, combining the batteries as if they were one. Operating the system normally, the batteries are isolated with the switch in the center. To charge the auxiliary battery, select the green position. To enable a cable-free jump-start for a weak primary battery, or provide extra power to high-demand accessories such as a winch, select the red position. I decided to relocate both batteries and the solenoid to the space behind the rear axle, to save space in the engine compartment for an air compressor. This required a long run of positive 2/0 gauge cable. Because I felt there was a risk of water intrusion into the solenoid at the relocated position, I used RTV silicone to seal all the seams in the solenoid. One of the shortcomings of the Painless kit was the implication that it had everything one needs, when in fact it lacks any heavy-gauge cable or connectors for the secondary battery. If the application calls for long lengths of cable (mine did), it can be a very expensive add-on (mine was). Likely as a cost-reducing decision, the Painless system also excludes components to measure the voltage available from the individual batteries without extra wiring or third-party voltmeters. There is also no voltage-sensing relay to automatically charge both batteries and isolate the secondary battery if the primary vehicle charging system voltage drops below a minimum threshold. After a year of use, I am pleased with the product, but I wish I had more data on battery status—and I must admit it would be nice to have the auxiliary battery charged automatically instead of having to remember to do so manually. painlessperformance.com, 817-244-6212 By Gary Greer 47 Painless Performance #40102 installed under Gary’s Toyota Tundra (Photo: Chris Marzonie) Remote switch with indicator lights for switching among isolation, charging, and combining of batteries (Photo: Chris Marzonie) Overland Journal Winter 2008 Product Profiles By Dan Streight Power Gate SR-200 installed on the firewall of Dan’s Toyota Land Cruiser (Photo: Dan Streight) (Photo: Perfect Switch LLC) 48 By Pierre Michaud Perfect Switch Power-Gate - Model SR-200 Single Rectifier Switch $268 Like most overland rigs, the engine bay on my 1999 Toyota Land Cruiser is packed with just about everything except an abundance of space. Yet I still needed to install a dual battery system in my engine bay. Even though Toyota engineers left the perfect location for the second battery, figuring out where the typical solenoid-style isolator would fit was giving me, well, fits. Fortunately I had been reading about a new entry in the battery isolator world. This new isolator design was a departure from all other systems on the market, and had no moving parts. Nada, zero, none: Just pure electronic circuitry. I’ll be the first to admit: I know very little about electronics. I’m okay with simple circuits in AC or DC, but you’ll quickly lose me when you start talking about field-effect transistors and the like. It turns out a MOSFET is a good thing. Perfect Switch, a company that invented and manufacturers the Power-Gate battery isolator, has created a rectifier/isolator that uses MOSFET technology. Aside from the benefit of not using any moving parts, the Power-Gate MOSFET isolator is also very small in size. This technology keeps waste current to a minimum, thereby eliminating the need for a typical heat sink that adds bulk to conventional diode isolators. The installation was easy and straightforward, as Power-Gate provides excellent full-color instructional diagrams. Just find a spot for a small metal and epoxy package about the size of a deck of cards. On my Land Cruiser that was on the upper portion of the driver’s side firewall. I used the Power-Gate as a template and center-punched where the holes would be drilled. Four self-tapping screws are all that’s required to secure the unit along with the supplied plastic spacers to allow air circulation between the Power-Gate and the mounting surface. My Power-Gate has, for the last several years, done its job quietly, reliably, and without taking up much engine bay space. What more can you ask of your isolator? Editor’s note: Although the single-rectifier isolator will keep the starting battery isolated, it will allow the main battery to draw from the auxiliary (the auxiliary battery is not isolated). Perfect Switch says they will soon release a dual-rectifier model that will isolate both batteries. perfectswitch.com, 858-720-1339 Sure Power Battery Separator/Interconnect Model 1314-200 (and 1315-200) $125 The Sure Power system appealed to me due to its affordability, simplicity, and availability through a large network of suppliers. The solenoid-switched, 200-amp unit automatically combines the auxiliary and main batteries once the charging system reaches 13.2 volts, and will disconnect the batteries should the voltage drop below 12.8. A time-delay feature is built in to prevent unnecessary switching due to voltage fluctuations. The user can manually connect the main and auxiliary battery should the need arise. I’ve found this feature useful during hard winching sessions when you need additional battery capacity. I originally purchased the model 1314-200 and mounted it on the firewall of my 2003 Toyota Tacoma. I had some concerns regarding the effects of high temperature, but the specifications indicated the unit was suitable for operating conditions ranging from minus 40º C (minus 40º F) to 85º C (185º F). This location was close to the main and auxiliary batteries, minimizing the length of wire required for the connections. Per the manufacturer’s recommendations, I used 4-gauge wire with copper lugs and shrink tubing. This mounting location provided a hidden benefit; I could clearly hear when the solenoid would connect or separate the batteries. I mounted the manual intervention switch on the console surrounding the shifter boot for easy access. I chose not to use the manual intervention/ auxiliary start indicating light, because the switch I used had a red indicating light built in. The overall installation was simple, thanks to the excellent instructions. However, no wiring supplies are included. After a week of operation the unit failed. I could no longer hear it operating, and determined that it was no longer connecting the two batteries automatically. It would do so using the manual Overland Journal Winter 2008 Product Profiles override function, but would automatically disconnect once the vehicle was turned off, defeating the whole concept of an automatic system. After a call to the retailer and some troubleshooting, we determined that the unit was defective. They were quick to supply a replacement unit, shipped at no cost. It was a model 1315-200 (which monitors either battery level to initiate charging, rather than only the main battery as with the 1314), in this case, due to availability. The replacement unit has been in service since then with no issues to report, although I am aware of three other units that have failed in a similar fashion. One other minor gripe I have with this setup is the lack of a battery monitor, easily solved by installing a voltmeter. Overall I’ve been very satisfied with the performance of the Model 1315200. It has kept the main and auxiliary batteries charged, and even provided a self-jump start on one occasion. Truth be told, if I had to do it all over again, I’d still go the Sure Power route. surepower.com, 800-845-6269 Xantrex - Pathmaker 100-amp Model 84-2051-02 $215 Xantrex is well-known in the marine, RV, and solar industries for mobile power products. I’ve been using their Pathmaker 100-amp isolator/combiner system for about six years with excellent results, and no failures to date. The system comprises a solenoid-type switch, a control module with status indicators, a selector switch with momentary position, and dial controls for customized user settings. Different amperage ratings and battery bank configurations are available (up to three batteries and 500 amps). There is an optional remote switch with indicator available. Installation is straightforward using the comprehensive owner’s manual. You’ll need to procure the necessary cables and connectors to suit your installation. I found a suitable mounting location for the solenoid on the firewall of my 1998 Tacoma. One cable from the solenoid connects to the positive terminal of the starting battery, one to the positive terminal of the auxiliary battery, and one to ground. That’s it, pretty simple. I added some complexity by remotely mounting the control module in the cab, which required removing the module from the solenoid mounting plate, extending the wiring from the solenoid through the firewall to the module, and fabricating a simple box in which to mount the device. The control module senses both cut-in and cut-out voltages for connecting and disconnecting the batteries, and incorporates voltage overload protection. All of these voltages are user selectable using the dial controls. Normal operation has the toggle switch in the center position. A green light indicates that the batteries are connected (at or above connect-voltage). A yellow light indicates that they are isolated (at or below disconnect voltage). A red light indicates a high voltage disconnect. When I charge the auxiliary battery at home with a charger, I use the toggle switch to manually disconnect the batteries (my charger will not operate when two batteries are present). I can use the momentary switch function to combine the batteries for emergency starting (self-jump starting), an option I have gratefully used on a couple of occasions. The combination automatically resets to auto position after five minutes, or with another push of the switch. Overall I have been very satisfied with the convenience and reliable operation of the Xantrex system. However, there are some characteristics supposedly associated with the design that I’m curious to learn more about. Apparently when the batteries are connected via a solenoid, there is nothing to prevent the two from naturally equalizing with one another. In other words, if I severely deplete my auxiliary battery and the solenoid connects it to the charging system once the connect voltage is sensed, the available current from the nearly fully charged primary battery will rush into the secondary battery until they have equal voltages. This intense transfer of power is potentially hard on both the solenoid contacts and the batteries—but I have no quantifiable results to prove the extent of such effects. Regardless, the system has worked as advertised for a long time, and continues to provide me with a safe starting battery or self-jump capability when I’m on solo adventures out in the hinterlands, and that is something I really appreciate. xantrex. com/web/id/104/p/1/pt/4/product.asp Sure Power Model 1314-200 installed on the firewall of Pierre’s Toyota Tacoma (Photo: Pierre Michaud) Switch (close-up view) (Photo: Pierre Michaud) By Chris Marzonie 49 Xantrex Pathmaker solenoid with battery cables attached (Photo: Chris Marzonie) Xantrex Pathmaker control panel (Photo: Chris Marzonie) Overland Journal Winter 2008 Product Profiles By Matthew Carter (special thanks to Robert Gorrell) Xantrex Pathmaker control panel (Photo: Chris Marzonie) Xantrex Pathmaker solenoid with battery cables attached (Photo: Chris Marzonie) 50 Wrangler NW Power – Dual Battery Kit 100-115/100-120 $347 (kit), $187 (Isolator) One of the first projects I undertook on my 2003 Toyota Tacoma was to install dual batteries. I wanted one battery reserved for starting purposes, and another that would be dedicated to aftermarket accessories and back-up starting. The research began. I couldn’t find an all-inclusive kit available for the early Tacomas, so I decided to fabricate my own. After making room under the hood and building my tray and tie-down, I loaded it with a red-top Optima for starting and a yellow-top Optima for deep-cycle duty. Now it was time for an isolator. The companies I learned about during my research included National Luna, Sure Power, Hellroaring, and Wrangler NW (a.k.a. AmFor Electronics). After speaking to each of these companies and talking to owners of each system, I decided on the Wrangler NW product. My choice was based on system simplicity, owner opinion, price, word-of-mouth reliability, and customer service. I called AmFor Electronics and spoke to Stan, who spent at least an hour on the phone with me answering questions. After telling him that I had mounted my batteries side by side, he suggested that I send him a picture. After reviewing the photo, he recommended their Jeep TJ kit minus the tray. I added the optional in-cab battery manager kit, a pre-wired, three-position switch that provides both dual-on and dual-off positions and an emergency-connect position. Total price was $300. The parts showed up in a matter of days. The quality of the materials was top-notch. All wires were labeled and pre-terminated with the proper connections and shrink-tube. Since my installation was custom, it took a little imagination on my part, but overall was easy. For performance and a clean look, I added marine-style connectors to the factory cables. These were the only extra parts I purchased. Since the installation, the solenoid isolator and in-cab manager switch have worked flawlessly. The system has held up to 10,000 miles of heat, cold, dust, and vibration without a hiccup. I currently have an auxiliary fuse block connected to the yellow-top, and I’m running a couple of low-amp accessories and my winch with it. The Red-Top is my primary starting battery and powers all factory accessories. I love this system and would recommend it to anybody. wranglernw.com, 800-962-2616 Conclusions This was a different kind of review, since we couldn’t measure the comparative efficiencies of these units, installed in vehicles thousands of miles apart, with different batteries, alternators, and lengths of wiring run, all of which could produce spurious differences in readings even if we assembled everyone in one place. So we couldn’t determine an editor’s choice by strictly empirical means. Instead, we documented the known strengths and weaknesses of each type of isolator, then investigated the products in terms of quality, ease of installation (and ease of de-installation should a problem arise in the field), comprehensiveness if a kit is offered, price, and customer service. The three principals on the staff—myself, Scott Brady, and Jonathan Hanson—have each had first-hand experience with different systems, so we pooled our individual conclusions, which turned out to be unanimous. We suggest avoiding diode-type isolators, which, while lacking moving parts, waste current and can fail from excessive heat buildup. Combination diode/FET systems offer better efficiency, but if you are considering one, check the manufacturer’s rated voltage loss, especially when the battery is discharged. Our preference is either a solenoid or a MOSFET. The MOSFET’s advantage is solid-state construction, but product choices are limited, and until dual-rectifier units are available, a discharged primary battery Overland Journal Winter 2008 can draw down a secondary battery in a MOSFET system. Many solenoid-based systems have been in continuous use for years, so they have the advantage of a longer proven history. Despite the mechanical contacts, they are durable and long-lasting performers. Our Editors’ (plural) Choice went to the National Luna. As a kit, it is exhaustively complete, child’s play to install, and will accommodate almost any application and second battery location. If you’d rather put together your own system, the NL Intelligent Solenoid and monitor are available separately. Our only wish is that a higher amperage capability were available. We gave the Value Award to the Xantrex Pathmaker, another solenoid-modulated unit. The Pathmaker offers a number of features not found on even the National Luna, such as adjustable voltage cut-in and higher amperage capabilities. The only questionable aspect of this choice is that the Pathmaker has been discontinued by Xantrex. The company claims to have a two-year supply, and warranty coverage is still there. The best source is now not Xantrex, but a Google search for one of many online vendors. Of course, a viable alternative to any of these is a durable, reliable manual system—just don’t leave your camera lens sitting on the bumper while you pop into the cab to switch batteries. Dual Battery Comparison Hellroaring Technologies Model: BIC-95150B National Luna Intelligent Split Charging Kit Painless Performance Products - 250 Amp Dual Battery Current Control System #40102 Perfect Switch Power-Gate Model SR-200 Single Rectifier Switch Sure Power Battery Separator/Interconnect Model 1315-200 Wrangler NW Power - Dual Battery Kit 100-115/100-120 346.72 kit 187.25 isolator Xantrex - Pathmaker 100-amp Model 84-205102 Price $175 (Isolator) $47 (Remote) $375 kit $140 isolator $131 $268 $125 $300 $215 Type Diode/FET (Solid-State) Solenoid (Mechanical) Solenoid (Mechanical) MOSFET (Solid-State) Solenoid (Mechanical) Solenoid (Mechanical) Solenoid (Mechanical) Weight 0.6 lbs/0.27 Kg 9.48 lbs/4.3kg (kit weight) 1.6 lbs./0.7 kg 1.16 lbs./0.53 kg 1.9 lbs./0.86 kg Approx. 1.5 lbs./0.68 kg (kit weight) 1.3 lbs./0.59kg Dimensions 4.8" x 3" x 2" 12.19 x 7.62 x 5.08 cm 4.5" x 5" x 2.25" 11.43 x 12.7 x 5.72 cm 4" x 3.25" 10.16 x 8.26 cm 3.5" x 7" x 0.875" 8.89 x 17.78 x 2.22 cm 3.28" x 4.06" x 4.02" 8.33 x 10.31 x 10.21 cm 3.69" x 3.3" x 2.8" 9.37 x 8.38 x 7.11 cm 6.3" x 7.4" x 3.6" 16 x 18.8 x 9.14 cm Operating temperature -40C to 65C -40F to 149F -40C to 12C -40 to 257 F -40C to 88C -40F - 190F -20C to 85C -4 to 185F -40C to 60C -40 to 140 F -40C to 65C -40 to 149 F -28.9C to 48.9C -20 to 120F Status lights included Yes Yes Yes Yes No Yes Yes Manual switch/ Self-jump No (avail. w/BIC95300B) Yes Yes No Yes Yes Yes Wiring and connections included No Yes Partial No No Yes No Voltage indicator included No Yes No No No No No User-adjustable set-points No No No No No No Yes Audible alarm No Yes (can be turned off) No No No No No DC current capacity 95A continuous, 150A/20 secs, 250A/50ms 85A continuous, 400A peak 240A continuous, 300A peak Up to 500A continuous, 800A/15ms peak 200A continuous, 600A peak 200A continuous, 600A peak 100A continuous, 400A peak Voltage range 7.5-20VDC 10-15VDC Not available 10-32VDC 9-16VDC Not available 7-33VDC Country of origin U.S.A. South Africa U.S.A. U.S.A. U.S.A. Mexico U.S.A. Warranty One-year Three-year One-year One-year One-Year One-year One-year Website hellroaring.com equipt1.com, sierraexpeditions.com painlessperformance.com perfectswitch. com surepower.com wranglernw.com xantrex.com Resources Slee Off-road, sleeoffroad.com/technical/tz_dual_batteries.htm, 888-494-7533 Blue Sea, bluesea.com, 360-738-8230 Discover Batteries, discover-energy.com, available from lubricationspecialist.com, 888-306-4255 Overland Journal Winter 2008 51 Review Team Brian DeArmon 52 Pierre Michaud Dan Streight Pierre Michaud is a system specialist and project manager at a CANDU6 nuclear power station in New Brunswick, Canada (at least, until recently— we hear a move to Australia is in the immediate offing). So he’s used to dealing with electrical currents of slightly higher amperage levels than those discussed in this review. With a job like that, we imagine relaxation time is vital for his blood pressure. Until very recently, Pierre relaxed with the help of his 1999 Toyota Tacoma, which took him fishing, hunting, mountain biking, and hiking. But apparently he’s now on the hunt for a new Toyota somewhere in Oz. From an early age, a desire to explore the outdoor world was instilled in Dan and his siblings by their parents. Whether fishing, hunting, mountain biking, backpacking, hiking, back-country ski touring, camping, or, now, overlanding in his 100-Series Land Cruiser, Dan has outdoors in his DNA. The past dozen or so years Dan has been exploring a playground right where he lives and works: Nevada. It’s said that 85 percent of Nevada is public land, with some 1,000,000 miles of roads to explore. That ought to keep Dan busy for at least a couple more years. Overland Journal Winter 2008 Riding on four wheels or two, the soles of his boots, or the saddle of a horse, Brian DeArmon has spent most of his life exploring the wonders of nature. This obsession has taken him from the Rocky Mountains, to the Gold Coast of Australia, the beaches of the Seychelles Islands, the frozen landscapes of Alaska, and a few places in between. Settled now in the Sonoran Desert, Brian is enjoying a lull in the fast pace of life before the next adventure begins. Gary Greer Gary Greer lives in Houston, Texas, with his wife and two teenage children. His entrepreneurial career in the energy industry affords him time to spend in the Sam Houston Area Council, and as an active Boy Scout leader. Scouting has fueled his passion for service, leadership development, conservation, and the outdoors. While he enjoys four-wheeling in his 2003 Tundra, he especially enjoys the rare opportunity to overland with his kids. Because Texas has little public access land, this involves extensive highway travel to overland trailheads, severely limiting trip frequency. Matthew Carter Matt Carter is a paramedic with Pridemark Paramedic Services in Denver, Colorado. He has been working on vehicles since the age of 16, taught by his buddies Rob Gorrell, Kyle Voigt, and Chris Hill. His latest project vehicle is a 2003 Toyota Tacoma, currently being modified for overland travel in the West. When not working on his truck, Matt enjoys using it to go snowboarding, mountain biking, and camping.