Anybody installed a Micro-Air EasyStart device on their whole house AC unit? It cuts down and manages the initial inrush current that the compressor needs. With it installed you can run the AC system using a generator.
You'll need the new starting amps from the comp with the soft start and the starting amps for both the condenser and air handler fans.
May not be needed if the gen is large enough. My 6500W (a 7500 hooked to NG) starts my 3 ton fine. My HVAC systems are completely split upstairs/downstairs though, so your unit may be larger than a 3 ton.Anybody installed a Micro-Air EasyStart device on their whole house AC unit? It cuts down and manages the initial inrush current that the compressor needs. With it installed you can run the AC system using a generator.
That's more or less a hard start without the disconnect relay. They don't actually lower the current needed just the amount of time that current is needed for.Can't you just use a large capacitor?
That's more or less a hard start without the disconnect relay. They don't actually lower the current needed just the amount of time that current is needed for.
Same here, our 8kW standby generator starts the 3-ton unit okay. It’s not on the emergency circuit so I have to run a jumper between the panels if it’s summer and we have a power outage.May not be needed if the gen is large enough. My 6500W (a 7500 hooked to NG) starts my 3 ton fine. My HVAC systems are completely split upstairs/downstairs though, so your unit may be larger than a 3 ton.
So this is actually a bit more complex of a topic and I simplified a bit in my previous post. You can read a few posts at HVAC school here that explain it better than I but be sure to read all 4 posts. It also has pretty graphs. But the basics are this:Hummmm...maybe I don't understand electrical demand and power the way I thought I did...engineering school was a long time ago.
My understanding is that it would take a "surge power" to get a compressor going. That is a power calculation, not a current calculation. So, when taking a surge demand like that, obviously voltage drops, and puts an even higher demand on current to supply the needed power to get something going. Now, if I were to install a capacitor, my understanding is that the overall power demand to get the compressor going remains about the same, but it helps to distribute that power requirement over a longer period of time. If overall power requirements remains pretty much the same, but the input to the capacitor is double or even tripled, then my understanding is that the instantaneous current demand should be cut by half or more, reducing the demand on the generator.
Now, I am just a mechanical engineer that specializes in hydraulics, but that is how it would work for a pump supplying flow with an installed accumulator in line to a high demand application. Maybe my logic is flawed?
So this is actually a bit more complex of a topic and I simplified a bit in my previous post. You can read a few posts at HVAC school here that explain it better than I but be sure to read all 4 posts. It also has pretty graphs. But the basics are this:
Hard start: Large capacitor that decreases the amount of time the compressor is coming up to speed by increasing the instantaneous torque of the motor. This doesn't decrease the instantaneous power required but decreases the total power over time because the compressor motor will spend less time in its more inefficient startup phase. This means it doesn't require less power at any moment to startup but spends less time starting so it spends less power total. You still have the 7-15 times running current required to start the motor you can just deliver it quicker
Soft start: Basically the opposite. These carefully regulate the voltage into the compressor matching it to the load slowly bringing the motor up to speed. This leaves the motor in the "run" phase at all times completely side stepping the inrush current needed to start the motor.
So this is actually a bit more complex of a topic and I simplified a bit in my previous post. You can read a few posts at HVAC school here that explain it better than I but be sure to read all 4 posts. It also has pretty graphs. But the basics are this:
Hard start: Large capacitor that decreases the amount of time the compressor is coming up to speed by increasing the instantaneous torque of the motor. This doesn't decrease the instantaneous power required but decreases the total power over time because the compressor motor will spend less time in its more inefficient startup phase. This means it doesn't require less power at any moment to startup but spends less time starting so it spends less power total. You still have the 7-15 times running current required to start the motor you can just deliver it quicker
Soft start: Basically the opposite. These carefully regulate the voltage into the compressor matching it to the load slowly bringing the motor up to speed. This leaves the motor in the "run" phase at all times completely side stepping the inrush current needed to start the motor.
Yes I suppose it depends on how close to the limits the generator is. The generator will still see the full power requirements needed by the compressor to start it just won't be as long. A "large" capacitor for this use is about 300mfd not near enough to make it invisible to the generator.Again, maybe you can help me...the statement you quoted...
Hard start: Large capacitor that decreases the amount of time the compressor is coming up to speed by increasing the instantaneous torque of the motor. This doesn't decrease the instantaneous power required but decreases the total power over time because the compressor motor will spend less time in its more inefficient startup phase. This means it doesn't require less power at any moment to startup but spends less time starting so it spends less power total. You still have the 7-15 times running current required to start the motor you can just deliver it quicker
That is what I was trying to explain. The instantaneous power is not changed...and must be supplied, but if it can be supplied by a large capacitor, and "load leveled" then it is a much easier load to drive from the generator or grid perspective.
While I am not a EE, I did dabble in competitive car stereo, and home audio where instantaneous power requirements are huge, but can be made palatable to the system by using capacitors.
The power to start is the same...if you can use a buffer (capacitor) to ease the shock to the system, it can be more easily powered.
Never heard of soft starters before, but the above simply didn’t make sense to me. Limiting voltage makes absolutely no sense. The winding would not produce the necessary electromagnetic field for the motor to start. I read up on it quickly and most articles say similar things, so I don’t blame you for repeating what they say.So this is actually a bit more complex of a topic and I simplified a bit in my previous post. You can read a few posts at HVAC school here that explain it better than I but be sure to read all 4 posts. It also has pretty graphs. But the basics are this:
Hard start: Large capacitor that decreases the amount of time the compressor is coming up to speed by increasing the instantaneous torque of the motor. This doesn't decrease the instantaneous power required but decreases the total power over time because the compressor motor will spend less time in its more inefficient startup phase. This means it doesn't require less power at any moment to startup but spends less time starting so it spends less power total. You still have the 7-15 times running current required to start the motor you can just deliver it quicker
Soft start: Basically the opposite. These carefully regulate the voltage into the compressor matching it to the load slowly bringing the motor up to speed. This leaves the motor in the "run" phase at all times completely side stepping the inrush current needed to start the motor.
Yes the solid state ones do use Thyristors to ramp the voltage up gradually. They do this by controlling the firing angle of the thyristors. combine this with ohms law and you have an easy way to control current. They don't directly act on the current.Never heard of soft starters before, but the above simply didn’t make sense to me. Limiting voltage makes absolutely no sense. The winding would not produce the necessary electromagnetic field for the motor to start. I read up on it quickly and most articles say similar things, so I don’t blame you for repeating what they say.
However, after more digging these soft starters use current limiting rectifiers. Now that makes more sense. You limit the current and slowly increase it. Sort of like slowly opening a water tap, vs quickly.
A larger capacitor will take that initial brunt, so in the end the result will be similar IMO. Not and EE though, so I might be missing something.
Only if you are using a VFD in a soft start role. A basic soft start is based on thyristors and does not act on the frequency.voltage and frequency can be varied for soft starts.
A cap can simply be seen as a voltage stabilize/damper.