Jim,
Actually I haven't been able to hook up any of my gear. We moved into a new house and after 18 months of remodeling, we're just now to the point when I can begin to put "my space" together.
My wife will certainly appreciate your subpanel suggestions, especially the resale benefit. She doesn't understand any of this and I think a transformer might scare her--even more than all the non-integrated components. And that wouldn't do anything for the music.
I'm not going to pretend to understand everything about the transformer hookup. I find all this difficult without diagrams. I am going to look for some and review them along with your explanation. My primary reason for starting this thread is that there are so many kinds of transformers, that I didn't really know what I should be shopping for. I figured if I understood how it all needed to be hooked up, then I would be able to shop halfway intelligently.
I can relate to your guy with the high electric bill, but I'm not sure I figured the cost correctly. I did some reading today and I came across a formula for excitation current in the primary winding, which would depend on the inductance of the transformer. I=E/(2x3.14xL) The current in the primary winding would then increase only in response to a load placed on the secondary winding. So it wouldn't be pulling current full bore anytime it was hooked up. Without a draw on the secondary, only an excitation current would be drawn on the primary. Does this sound correct? What would be a more realistic cost estimate for allowing a transformer to hum away?
I've got just a few more questions regarding breaker sizes. My understanding is that if I'm needing 20 amps on a circuit, then I will need a 20 amp breaker at the subpanel, because a 15 amp breaker would trip. And a circuit protected by a 20 amp breaker would require #12AWG or larger, because 20 amps would overheat anything smaller. Is this correct?
If I have 80 amps worth of breakers on the subpanel, would I need to have at least an 80 amp breaker protecting the feeder on the main panel? And then the feeder size would be based on whatever wire can handle 80 amps? Can I have an even larger breaker on the main panel as long as I increase the size of my feeder appropriately?
If I were to have an isolation transformer with a new main panel, what would determine the size of the new main breaker? If the rating of the isolation transformer wasn't large, realisticly wouldn't the limiting factor for the amps on the new main panel be the breaker protecting the isolation transformer?
Thanks again.
Chris
Actually I haven't been able to hook up any of my gear. We moved into a new house and after 18 months of remodeling, we're just now to the point when I can begin to put "my space" together.
My wife will certainly appreciate your subpanel suggestions, especially the resale benefit. She doesn't understand any of this and I think a transformer might scare her--even more than all the non-integrated components. And that wouldn't do anything for the music.
I'm not going to pretend to understand everything about the transformer hookup. I find all this difficult without diagrams. I am going to look for some and review them along with your explanation. My primary reason for starting this thread is that there are so many kinds of transformers, that I didn't really know what I should be shopping for. I figured if I understood how it all needed to be hooked up, then I would be able to shop halfway intelligently.
I can relate to your guy with the high electric bill, but I'm not sure I figured the cost correctly. I did some reading today and I came across a formula for excitation current in the primary winding, which would depend on the inductance of the transformer. I=E/(2x3.14xL) The current in the primary winding would then increase only in response to a load placed on the secondary winding. So it wouldn't be pulling current full bore anytime it was hooked up. Without a draw on the secondary, only an excitation current would be drawn on the primary. Does this sound correct? What would be a more realistic cost estimate for allowing a transformer to hum away?
I've got just a few more questions regarding breaker sizes. My understanding is that if I'm needing 20 amps on a circuit, then I will need a 20 amp breaker at the subpanel, because a 15 amp breaker would trip. And a circuit protected by a 20 amp breaker would require #12AWG or larger, because 20 amps would overheat anything smaller. Is this correct?
If I have 80 amps worth of breakers on the subpanel, would I need to have at least an 80 amp breaker protecting the feeder on the main panel? And then the feeder size would be based on whatever wire can handle 80 amps? Can I have an even larger breaker on the main panel as long as I increase the size of my feeder appropriately?
If I were to have an isolation transformer with a new main panel, what would determine the size of the new main breaker? If the rating of the isolation transformer wasn't large, realisticly wouldn't the limiting factor for the amps on the new main panel be the breaker protecting the isolation transformer?
Thanks again.
Chris