Det står inte något alls om detta på tillverkarens (Solar Converters Inc.) hemsida. Inte heller i
manualen för den...
Section 2: Step Down Transformer
Input Voltage: 10.5 - 32 DC volts
Current: 0 - 10 amps nominal
Output Voltage: 5.5 - 16 DC volts = 1/2 input voltage
Current: 0 - 20 amps continuous
2.1 Common Connection
Using wire of sufficient amperage for the load connection (#12 AWG or better) connect the negative of the battery to the
BLACK #12 AWG flying lead and the negative connection of the load.
2.2 Load Power Connection
Using a wire of sufficient amperage for the load power (#12 AWG or better) connect the positive of the load to the WHITE
#12 AWG flying lead.
2.3 Input Power Connection
Using wire of sufficient amperage for the input connection (#12 AWG or better) connect the positive of the battery to the
RED #12 AWG flying lead.
Section 3: Step Up Transformer
Input Voltage: 10.5 - 16 DC volts
Current: 0 - 20 amps nominal
Output Voltage: 21 - 32 DC volts = twice input voltage
Current: 0 - 10 amps continuous
3.1 Common Connection
Using wire of sufficient amperage for the load connection (#12 AWG or better) connect the negative of the battery to the
BLACK #12 AWG flying lead and the negative connection of the load.
3.2 Load Power Connection
Using a wire of sufficient amperage for the load power (#12 AWG or better) connect the positive of the load to the RED
#12 AWG flying lead.
3.3 Input Power Connection
Using wire of sufficient amperage for the input connection (#12 AWG or better) connect the positive of the battery to the
WHITE #12 AWG flying lead.
Section 4: Step Up and Step Down Transformer or Battery Voltage Equalization
Input/Output Voltage High: 12 - 32 DC volts
Current: 0 - 10 amps nominal
This is the voltage off the top of your battery string nominally 24 V
Input/Output Voltage Low: 6 - 16 DC volts
Current: 0 - 20 amps continuous
This is the midpoint voltage off your battery string nominally 12 V
Unit uses its bi-directional capability to take power from the higher voltage battery and transfer the excess charge to the
lower voltage battery. The net effect is to bring the battery voltages to be exactly equal. As well, as load current is taken
off the battery, the stronger battery will support the weaker battery, making your battery power last longer.
4.1 Common Connection
Using wire of sufficient amperage for the load connection (#12 AWG or better) connect the negative of the battery string to
the BLACK #12 AWG flying lead. Nominally this is the negative connection of the 24 V battery.
4.2 Low Voltage Connection
Using a wire of sufficient amperage for the load power (#12 AWG or better) connect the midpoint of the battery set to the
WHITE #12 AWG flying lead. Nominally this is the 12 V point in your 24 V battery string.
4.3 High Voltage Connection
Using wire of sufficient amperage for the input connection (#12 AWG or better) connect the positive of the battery to the
RED #12 AWG. Nominally this is the 24 V positive connection of the 24 V battery.
Note: It may take a while for the unit to equalize the voltages of the batteries as a considerable amount of charge
movement between batteries may be required depending upon the state of charge and quality of the respective batteries.
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