Isolation transformers - where do I start?


Trying to get into power isolation. This idea seems to have merit because there seems to be less irritating high frequency distortion late at night than in the daytime.
So where do I start?
1)1 big 2kVa isolation transformer? Plug everything into it?

2) PS Audio "ultimate outlet". Plug everything into it?Reduces common mode noise by 40dB.

3) Sola constant voltage transformer 60 VA for the CDP and preamp (which draw 30 va each- I play music very soft - 1/2 watt output on the power amp - so probably much less than that).
- "Highly regulated sine wave outputs with harmonic distortion less than 3%"
- "Output voltage regulated +/- 1% with input voltage fluctuations of +10%/-20%."

4) Power conditioning shielded C-V transformer 140VA for CDP and PRE:
- reduces common mode noise by -120 dB / Normal mode noise -60 dB / <2pf capacitance between input and output wiring.
- Output regulation +/-3% with inout fluctuations +10%/-20%.

5) Get 2kVA for system and also smaller 60 VA for CDP only.

Is a power conditioning transformer ($250 for .14 kVA)better than just an isolation model ($250 for 2 kVA). I realize small capacity so only for CDP or preamp.

Any suggestions would be appreciated.
cdc
Sean's advice is very good. I would recommend looking at EquiTech's wall mounted units. These are very large isolation transformers that take 220 in and then drop it down to 110 with two balanced poles (thus further rejecting the noise). I made one similar to these with a transformer I had gotten from a medical device company that was no longer used. It was about a 6.5 KVA unit (yes it was heavy). The only downside to the EquiTechs is that they are expensive, but I think they have really engineered a superior product (it's the brute force method--but works quite well). It's used by many recording studios, they're just not as well known in the home market.
Cdc, I was in a very similar situation this past winter. I looked at all the pieces recommended above and found the Hubbell to be one of the best out there. Rick at Virtual Dynamics has recently informed me that he is modifying Hubbell Iso Transformers with Cryogenic treatment, internal wiring tweaks and some other stuff you'd have to ask him about. My power needs have been met lately so I am not in the market for one of these... If you end up getting one please let me know what it does in your system.
would dedicated outlets take care of most of the "problems" that transformers fix? what is it exactly that they fix anyway? fluctuations in current? noise?
I would start by buying a couple of smaller isolation transformers from eBay ($15-$35). Play around with them. Open them up and clean all contact points w/ contact cleaner--you'll be surprised...

I have several isolation transformers and I really like my C core ones. Some are "Chicago Transformer Co." 3.5 amp isolation transformers and they have three output taps: 105, 115, 125V. I plug my DAC to the 125V tap and besides lowering the noise floor it increases slam and authority in the music. Very similar to when I use my 3,000W 220V ONEAC to plug my power amp. Sean is correct when he says C cores are superior. My big ONEAC is also C core.

However, don't turn down a great deal just because it's toroidal--right, Sean?
Dennis: Dedicated lines simply separate the power lines for your audio gear from all of the other wiring in the house. This in itself can reduce noise within the AC feeding your A/V system, but you are still susceptible to the noise that is coming in from the outside line feeding your AC mains. As such, an "optimum" installation would be one with dedicated lines and either a very high current power regenerator or extensive isolation via low impedance filtering / isolation. If you wanted to get "really crazy", especially if you had BIG high powered amps, would be to bypass all of the AC completely and feed your system off of a bank of batteries. If i had a simple, low powered system, that is probably what i would do. Since i am not in that boat though, i've had to go the first route.

An isolation transformer "uncouples" or "isolates" the A/V components from the outside lines. It is basically a 1 to 1 transformer. In other words, if you put 120 volts into it, you get 120 volts out of it. Due to the indirect coupling via the transformers windings though, you end up losing the mass majority of noise that may have been riding on the line. This is a good thing in every aspect. As stated above, "old school" iron core transformers are more efficient at "electrically isolating" the AC signal from the noise, but a toroidal design can also be quite effective. As Francisco stated, i would not pass up a good deal on a legit isolation transformer just because it was toroidal based. While it may not work quite as well as an equivalent E-I or C core "old school" transformer, it would none the less reduce the noise on the line very drastically. The drawbacks to the reduced efficiency ( in terms of reducing noise ) that the toriodals may suffer from can more than be made up for by compact size and measurably less weight than if one were to make comparisons with standard transformers.

The drawbacks to using isolation transformers is that they can introduce losses into the AC system and play games with the phase of the signal being fed to components. In both cases, this is typically a side effect of trying to use too small of a transformer for too big of a job. If the core of an isolation transformer is getting physically hot, you can bet that it is not big enough for what you are using it for and "bad" side effects will result. It is not abnormal for any device that is passing a reasonable to large quantity of power to undergo some type of temperature rise, but a transformer should NOT get physically hot to the touch. If it is, the transformer is simply not up to the task or being pushed too close to its' limits on a steady state basis.

As such, that is why i recommended using transformers that were rated for well above the amount of power that you intend to pull through them. This minimizes the potential for thermal losses / phase shifts while allowing the system to obtain all of the benefits of such a design. The use of higher current rated transformers also helps to keep the line impedance down, which is always a good thing. The "filters" used in many PLC's are of somewhat higher impedance and this can introduce problems of a different nature.

Hope this helps and explains a few things. There are variations to what i've mentioned, but this should cover the basics. Sean
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