Summary
Type: | | Sealed Lead Acid VRLA |
Capacity Range: | | 7 to 100 AH |
Nominal Voltage: | | 12 VDC |
Plates Material: | | Alloy of lead, calcium, tin |
Terminals Material: | | Silver plated copper |
Case Material: | | Compact ABS plastic |
Features
Gas recombination with electrolyte
Good performance in wide temp. range
Maintenance-free
Excellent recharge recovery
Low internal discharge rate
Stable quality with high reliability
GP series sealed batteries of Interberg company of Spain with the most advanced technology and high density of lead, calcium and cut alloy for use in general applications such as UPS, renewable energy systems, telecommunication equipment, etc. with the latest technology designed by automatic machines and produced. The use of calcium alloy in the manufacture of quality plates and separators has resulted in good charging and discharging efficiencies with high currents and excellent performance over a wide temperature range in these batteries. The use of epoxy sealant completely prevents electrolyte leakage and makes the battery maintenance-free.
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Battery capacity is the product of the discharge current and the time it takes for the battery voltage to reach the specified minimum. This diagram shows the decrease in battery voltage over time under different discharge currents. For example, it shows that after about 12 minutes, if a battery with 2 times the capacity (2C) of discharge and current is drawn from it, its voltage drops from 12 volts to less than 10 volts. This diagram, with the help of discharge current tables, determines how long it takes for the voltage to reach the final limit of the table for a particular discharge current.
Battery capacity is a function of ambient temperature and battery discharge rate. Low temperatures reduce battery capacity and high temperatures can damage it. This diagram shows that the capacity of the battery under different charging currents varies from three times the capacity to 0.05 times its capacity at different temperatures, and shows that the temperature must be raised to charge the battery; But if the temperature exceeds 25 degrees Celsius, it will no longer have much effect and we will have saturation in the graph; So to balance the stored capacity and output and maintain battery life, it is best to charge / discharge the battery at 25 degrees Celsius.
This diagram shows the life of Interberg GP series batteries based on their discharge over the years of use in different temperature conditions. Examination of this diagram shows, for example, that if the temperature rises to 32 degrees Celsius (7 degrees above the ideal temperature), the battery life will be reduced by about half.
This diagram shows that if the battery is subjected to certain conditions and with different discharge depths (DOD) [this means charging and being used to a certain level, for example 50%], the number of cycles that have been charged and discharged, in The amount of final capacity it can maintain is affected.
If the batteries are discharged with a higher DOD (per cycle), the capacity of the battery to store energy in cycles of about six hundredths of a second will decrease rapidly. (That is, for a load after 600 hrs, the battery capacity is reduced to 50% instead of 100%.) This diagram shows that if only up to 30% of the battery capacity is used per discharge under the above conditions, its life is up to about 1400 cycles. Will go up; Of course, this also has another meaning, which is that if we use a battery with a higher nominal capacity for a shorter time and use a small capacity, its annual life and the number of times it will be charged and discharged will increase.
Applications
All kinds of electrical equipment such UPS, telecommunication equipment, renewable energy systems, measuring equipment and instruments, signaling equipment, mapping equipment and, etc.