Calculating watts from generator to batteries

Re: Calculating watts from generator to batteries

Beth,

So I don't create more confusion... Exactly what batteries (brand/model, or Voltage and 20 Hour Amp*Hour rating). How many batteries per string (4x 6 volt batteries, or 12x 2 volt batteries per string, etc.). There is quite a range in capacity and output voltage for Trojan batteries (if Trojan). I want to get your bank capacity correct (it will change the calculations quite a bit if I guess wrong).

For the Honda, what model number? I assume you are using the 120 VAC outlet (what is the current rating at 120 VAC)? Or is it the 240 VAC outlet (the SW4024 is probably a 120 volt input unit?).

For charging the battery bank, you are using the SW4024?

-Bill

Re: Calculating watts from generator to batteries

So, your battery bank AH rating is 3x 400 AH = 1,200 AH at 24 volts.

The SW4024 appears to have a good power factor (assume 1.0). Assume 80% efficient charger at maximum charging current of 120 amps. And 30 amps 120 VAC maximum AC charging current.

I am confused about the popping a circuit breaker when the SW4024 was set to 30 amps. Which circuit breaker was it popping (inverter or another breaker elsewhere in your system)? Was it the Generator 240 VAC breaker or a 120 VAC breaker on the output of the step-down transformer? And what was its current rating? Was it opening right away, or after a period of time? Any pattern?

This would indicate that the SW has a "poor" Power Factor:

• 20 amps max programed / 30 max RMS draw by SW = 0.66 (very rough estimate)

Although--It is not impossible that there is a bad circuit breaker or some other issue (such as over heated CB panel) that is causing them to open at too low of current rating.

In general, it would seem that the maximum charging current for your setup would be:

• 4,500 Watts * 0.80 inverter efficiency * 0.95 transformer eff * 1/29 volts battery charging = 117 Amps (120 amps max rating for SW)

However, because you have derated the system to 20 amps of 120 VAC:

• 120 VAC * 20 amps * * 0.80 inverter efficiency * 1/29 volts battery charging = 66 Amps

Anyway--The ratio of charging current to battery bank capacity:

• 66 amps / 1,200 AH = 0.055 or 5.5%

It is not high (you can go to 10-15% of Bank AH rating) without any problems.

You are running your genset at:

• 20 amps / 37.5 amps maximum (at 120 VAC) = 0.53 or 53% of rated load

Which is perfectly OK--It would be nice to get your genset to operate at closer to 80% rated load (30 amps)--but you have the breaker issue.

From reading the SW manual--their AC input current readings are a bit miss-leading... Trace chose to read only the "Real" in-phase current. So if there is a "Bad Power Factor" somewhere (inductive load leading to PF~0.6 instead of >0.9), their meter will not show that.

To (easily) measure the "True" (believe it or not, you can call these the vector sum of the "Real" and "Imaginary" components of the current--If you remember your real and imaginary numbers from math oh so many years ago) AC and DC currents in your system--A clamp on AC / DC rated amp meter (~$100 for a "cheap" one) may be needed.

But--if your system operate OK as is--The only reason to try and get more current (Power) from the genset would be to reduce run-time and noise (by running the genset at 80% load instead of 55% loading and getting more charging current for faster charging).

I looked through the SW Menu system in the manual--I did not see one that displayed the Battery Current... Is there a menu where you can monitor the battery DC current? And what is its value when charging (and what is the AC input current).

Lastly, the SW will automatically manage the AC input current from the genset so that it does not draw more than the present setting... You an add AC loads to your SW system and it will first cut back on the amount of charging current to the battery bank... And second, if the loads go very high (larger than 20 Amps AC of your present max AC2 input current setting), it will actually take power from the battery bank and "assist" the generator in supplying the AC loads too.

-Bill

Re: Calculating watts from generator to batteries

Here is a fairly good discussion of AC power and Power Factor and non-linear AC wave forms...

Regarding electrical "Phase" between voltage and current...

Think about attaching a rope to a car to pull it up hill... If you stand right in front of the car and pull on the rope--100% of your pull goes into moving the car forward.

If you stand 45 degrees off to the side, only the Cosine of 45 degrees (0.7) of your force goes into pulling the car forward... The rest goes into pulling the car to the side... If you still want to pull 100 lbs forward, you need to pull ~140 lbs on the rope to pull 100lbs forward.

Voltage sine wave form and the current wave form--The current can either follow the voltage wave form or it can be "delayed" (for inductors) and the wire needs to carry more current for the equivalent amount of power...

Another thing that can happen is that the current only flows at the very peak of the voltage--This is sort of like standing in front of the car and pulling 200 lbs for 1 second and 0 lbs for 1 second... The average is still a 100 lb pull--but you need a rope rated for 200 lbs or it will break.

The Amp meter in the Inverter system only measures the current that pulls the car forward--This particular meter does not measure the total current being carried by the wire.

(Sorry, this is a very sort explanation of a long subject--please feel free to ask if you have more questions).

It is not difficult to use a Clamp on amp meter... But to make good use of it, you need to understand the basics of electricity to use it correctly.

I am going to use the old water analogies--It is not exact, but may help you understand....

Say you have a small water system with two storage tanks on the top of a hill... and the pipes run down to your home. Normally, the two pipes carry equal gallons of water to each tank--and the water flow is equal to the two tanks. However, one of the pipes/tank valves gets blocked... Now, from at the home, you are drawing water and replacing water in the tanks just like normal... But you now have 1/2 the storage capacity and you need to figure out what is wrong.

You use a Flow Meter (aka clamp on DC amp meter) around each pipe (wire) and check the flow (amps) going through each pipe. One will be carrying all of the water and the other will not be carrying any--So now you can find out what is going one.

On the other hand, say that one tank has a hole in it... The tank with the hole is now taking much more water than the other tank--so you are pumping water into the tanks, but find that your storage goes flat in a few hours (as the one tank drains water from itself an the other connected water tank)--The flow meter (clamp on amp meter) can again show how the flows are different between what should have been two identical water tanks... You can then use other tools to isolate the problem.

For testing your generator--You need to make a short extension cord (that you can plug between the generator and the inverter) with the three power wires (hot A, hot B, and neutral wires) split out from the cable (leave the insulation on the wires themselves). You can now clamp on the AC clamp meter and measure the total current through each of the wires. If the A/B (240 hot wires) are carrying 10 amps and your 20 amp breaker is popping--then probably you have a bad circuit breaker. (remember that 10 amps at 240 VAC is the same amount of power as 20 amps at 120 VAC).

The reason you have to "split" out the insulated wires is that for electrical current flow there is the power going out one wire and coming back on the second. If you put a current clamp around both wires--the net current flow is zero amps. You need to clamp on just one wire at a time to measure the current in that one wire.

Here is an OK video on using a clamp meter.

If your AC current is too high, then you can look at the Inverter/Charger/Battery bank for problems.

If you have somebody nearby who has some electrical experience, they can spend an hour with you and train you have to check out your system with a current meter.

It is a very handy tool (just like a DMM is)--but it is not quite as easy to understand as a volt meter is.

Also, note that I am saying get an AC and DC capable current clamp meter. You have both AC power and a DC battery bank.

The AC clamp meter are just fine and even quite a bit less expensive--But they cannot measure DC amps (they will just read zero amps if you try it).

-Bill