Battery Selection

Select Auxiliary Battery Type (if any)

Select “Deep Cycle” batteries to receive optimum performance from your Inverter/Charger. Do not use ordinary car or starting batteries or batteries rated in Cold CrankingAmps (CCA). If the batteries you connect to the Inverter/Charger are not true Deep Cycle batteries, their operational lifetimes may be significantly shortened. If you are using the same battery bank to power the Inverter/Charger as well as DC loads, your battery bank will need to be appropriately sized (larger loads will require a battery bank with a larger amp-hour capacity) or the operational lifetimes of the batteries may be significantly shortened.

Batteries of either Wet-Cell (vented) or Gel-Cell /Absorbed Glass Mat (sealed) construction are ideal. 6-volt “golf cart”, Marine Deep-Cycle or 8D Deep-Cycle batteries are also acceptable. You must set the Inverter/Charger’s Battery Type DIP Switch (see Configuration section on page 6 for more information) to match the type of batteries you connect or your batteries may be degraded or damaged over an extended period of time. In many cases, the vehicle battery may be the only one installed. Auxiliary batteries must be identical to the vehicle batteries if they are connected to each other.

Match Battery Amp-Hour Capacity to Your Application

Select a battery or system of batteries that will provide your Inverter/Charger with proper DC voltage and an adequate amp-hour capacity to power your application. Even though Tripp Lite Inverter/Chargers are highly-efficient at DC-to-AC inversion, their rated output capacities are limited by the total amp-hour capacity of connected batteries and the support of your vehicle’s alternator if the engine is kept running.

• STEP 1: Determine Total Wattage Required

Add the wattage ratings of all equipment you will connect to your Inverter/Charger. Wattage ratings are usually listed in equipment manuals or on nameplates. If your equipment is rated in amps, multiply that numbertimesAC utility voltage to determine watts. (Example: a ¼ in. drill requires 2½ amps. 2½ amps × 120 volts = 300 watts .)

Note: Your Inverter/Charger will operate at higher efficiencies at about 75% - 80% of nameplate rating.

• STEP 2: Determine DC Battery Amps Required

Divide the total wattage required (from step 1, above) by the battery voltage (12) to determine the DC amps required.

STEP 3: Estimate Battery Amp-Hours Required (for operation unsupported by the alternator)

Multiply the DC amps required (from step 2, above) by the number of hours you estimate you will operate your equipment exclusively from battery power before you have to recharge your batteries with utility- or generator-supplied AC power. Compensate for inefficiency by multiplying this number by 1.2. This will give you a rough estimate of how many amp-hours of battery power (from one or several batteries) you should connect to your Inverter/Charger.

NOTE! Battery amp-hour ratings are usually given for a 20-hour discharge rate. Actual amp-hour capacities are less when batteries are discharged at faster rates. For example, batteries discharged in 55 minutes provide only 50% of their listed amp-hour ratings, while batteries discharged in 9 minutes provide as little as 30% of their amp-hour ratings.

Example

Tools

¼" Drill

Orbital Sander

Cordless Tool Charger

300W

+

220W

+

20W

=

540W

 

 

Appliances

 

 

Blender

 

Color TV

 

Laptop Computer

 

 

300W

+

140W

+

100W

=

540W

540 watts ÷ 12V = 45 DC Amps

45 DC Amps × 5 Hrs. Runtime

× 1.2 Inefficiency Rating = 270 Amp-Hours

STEP 4: Estimate Battery Recharge Required, Given Your Application You must allow your batteries to recharge long enough to replace the charge lost during inverter operation or else you will eventually run down your batteries. To estimate the minimum amount of time you need to recharge your batteries given your application, divide your required battery amp-hours (from step 3, above) by your Inverter/Charger’s rated charging amps (see Specifications section).

NOTE! For Tripp Lite Inverter/Chargers providing 1000 watts or less of continuous AC power, a full-size battery will normally allow sufficient power for many applications before recharging is necessary. For mobile applications, if a single battery is continuously fed by an alternator at high idle or faster, then recharging from utility or generator power may not be necessary. For Tripp Lite Inverter/Chargers over 1000 watts used in mobile applications, Tripp Lite recommends you use at least two batteries, if possible fed by a heavy-duty alternator anytime the vehicle is running. Tripp Lite Inverter/Chargers will provide adequate power for ordinary usage within limited times without the assistance of utility or generator power. However, when operating extremely heavy electrical loads at their peak in the absence of utility power, you may wish to “assist your batteries” by running an auxiliary generator or vehicle engine, and doing so at faster than normal idling.

270 Amp-Hours ÷ 55 Amps

Inverter/Charger Rating = 5 Hours Recharge

8R

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Tripp Lite 93-2182, 200310080 owner manual Battery Selection, Select Auxiliary Battery Type if any

200310080, 93-2182 specifications

Tripp Lite, a renowned leader in power protection and connectivity solutions, designs high-quality products tailored to meet the demands of businesses and individuals alike. Among their extensive catalog is the Tripp Lite 93-2182,200310080 model, a powerhouse of technological innovation and pragmatic design.

The Tripp Lite 93-2182 is a versatile power distribution unit (PDU) that is engineered to provide efficient and reliable power to multiple devices. With a rack-mountable design, it is ideal for data centers, server rooms, and any setup where space is at a premium. Its sleek form factor allows it to blend seamlessly into existing infrastructure while maximizing power delivery and minimizing clutter.

One of the standout features of this PDU is its combination of multiple output options, including various NEMA outlets to accommodate a wide range of devices. This makes it an excellent solution for environments with diverse equipment requirements. Users can connect servers, networking equipment, and other critical devices without the need for additional power strips, promoting a cleaner workspace and reduced risk of tripping hazards.

In terms of technology, the Tripp Lite 93-2182 is equipped with surge protection capabilities that shield connected equipment from voltage spikes. This protection is crucial in safeguarding sensitive electronics from potential damage. Additionally, the PDU features built-in circuit breakers which provide over-current protection, ensuring the safe operation of connected devices.

Another significant characteristic of this model is its robust monitoring capabilities. Some versions come with options to monitor power consumption, which can help users make informed decisions regarding load balancing and energy efficiency. Furthermore, comprehensive management features allow for efficient remote monitoring, enhancing control over power distribution across the network.

The durability of the Tripp Lite 93-2182 is also noteworthy. Constructed with high-quality materials, it is designed to withstand the rigors of a dynamic data environment. The attention to detail in its design ensures that it operates under various conditions while maintaining optimal performance.

In summary, the Tripp Lite 93-2182,200310080 represents a culmination of advanced engineering and practical design. With its versatile output options, surge protection features, and robust monitoring capabilities, it is a reliable choice for anyone looking to optimize their power distribution needs, particularly in tight spaces where efficiency is paramount.