4 transfer time, 5 battery temperature sensor operation, Operation 3.4 transfer time – Magnum Energy ME-G Series User Manual

Page 33

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2015 Sensata Technologies

Operation

3.4 Transfer

Time

While in Standby mode, the AC input is continually monitored. Whenever AC power falls below

the VAC dropout voltage (80 VAC, default setting), the inverter automatically transfers back to

Inverter mode with minimum interruption to your appliances—as long as the inverter is turned

on. The transfer from Standby mode to Inverter mode occurs in approximately 16 milliseconds.

While the ME-G Series is not designed as a computer UPS system, this transfer time is usually

fast enough to hold them up. However, the VAC dropout setting has an effect on the ability of the

loads to transfer without resetting. The lower this setting, the longer the effective transfer will be

and therefore, the higher the probability for the output loads to reset. This occurs because the

incoming AC voltage is allowed to fall to a level that is so low that when the transfer does occur,

the voltage on the inverter’s output has already fallen low enough to reset the loads.
The disadvantage of a higher VAC Dropout setting is that smaller generators (or large generators

with an unstable output) may nuisance transfer. This commonly happens when powering loads that

are larger than the generator can handle—causing the generator’s output voltage to constantly

fall below the inverter’s input VAC dropout threshold.

Info: When switching from Inverter mode to Standby mode, the inverter waits

approximately 15 seconds to ensure the AC source is stable before transferring.

3.5 Battery Temperature Sensor Operation

The plug-in Battery Temperature Sensor (BTS) is used to determine the battery’s temperature.

This information allows the multi-stage battery charger to automatically adjust the battery charge

voltages for optimum charging performance and longer battery life.
If the temperature around an installed BTS is below 77°F (25°C), the absorb and fl oat charge

voltages increase. If the temperature around the BTS is higher than 77°F (25°C), the absorb

and fl oat charge voltages decrease. See Figure 3-4

to determine how much the charge voltage

changes (increases or decreases) depending on the temperature reading of the BTS. For example,

the nominal absorb charge voltage for a fl ooded battery at 77°F (25°C) on a 12-volt model is

14.6 VDC. If the battery temperature is 95°F (35°C), the absorb charge voltage would decrease

to 14.3 VDC (14.6 VDC – 0.3 change).
If the temperature sensor is NOT installed, the charge voltages will not be automatically adjusted

because of temperature, but will be maintained at a temperature of 77°F (25°C). The life of the

batteries may be reduced if they are subjected to large temperature changes when the BTS is

not installed.

Info: When the BTS is connected, the battery charger uses a value of 5mV/°C/Cell from

0-50°C to change the charge voltage based on temperature.

Figure 3-4, BTS Temperature to Charge Voltage Change

-0.75

-0.6

-0.45

-0.3

-0.15

0

0.15

0.3

0.45

0.6

0.75

0

5

10

15

20

25

30

35

40

45

50

Temperature reading from BTS

Temperature Compensation using BTS

0C

32F

5C

41F

10C

50F

45C

113F

30C

86F

40C

104F

35C

95F

25C

77F

20C

68F

15C

59F

50C

122F

Change to battery charging voltage

no BTS

connected

12VDC units

+0.75V

+0.6V

+0.45V

+0.3V

+0.15V

No Change

-0.15V

-0.3V

-0.45V

-0.6V

-0.75V