It could have good load regulation and not very good line regulation. A low output impedance will result in good load regulation even if line regulation is less than stellar.I think I read that the Hypex SMPS isn't regulated per se, the output follows the input. But it may indeed have a lower output impedance.
So this hypex SMPS is not to be used with a class AB topology?In what sense? If an amp fails, it fails. Most time by some sense of overload or in the long run by wear out of electrolytic capacitors. The Hypex SMPS are designed for their own Class-D amps, not for general use.
It supplied amps and voltage so yes, it should be good for class AB stuff. It won't load down/sag like a designed for the task power supply but it will do in a jiffy.So this hypex SMPS is not to be used with a class AB topology?
If the switch mode supply delivers the same DC voltages as the conventional supply does, it should make no difference. Only possible problem could arise with the SMPS is that it is likely to be regulated, and won't sag much under load, whereas the 50/60Hz-xfmr-diode-'lytic one will sag, limiting the power dissipation in the output stage when severely overloaded. So long as that overload/dissipation issue is properly addressed, then both types of supply should work well. Power amplifier output stages don't benefit much from regulation, while small sign stages do.So this hypex SMPS is not to be used with a class AB topology?
So this hypex SMPS is not to be used with a class AB topology?
The switching devices in a typical SMPS have much less loss (lower on resistance, less voltage drop, heat, etc.) than rectifier diodes, a factor in achieving higher efficiency.It may not be comparable but nonetheless if you change out the transformer, bridge and filter caps for an SMPS, I am not convinced that the amplifier will use less power. I am actually sure it won't because as you mentioned it is regulated meaning that under extreme loads where the original supply will sag, the SMPS will supply more power by not letting the rails sag as much. There is a switched inductor in the SMPS, but since it only has one set of windings and low number of turns, it will be less lossy than the standard rectifier transformer.
I would not expect much in the way of savings at idle. Like amplifiers themselves, efficiency becomes more important at higher power levels.To really benefit this scenario, as I researched it in the last few days, you would have a+/- supply for the output transistors to prevent them for over-stressing, and add an additional boost supply for the VAS section. That would save some power and it does, because I build an amplifier like that. With Mosfet outputs, you need a boost of about 10-12V because of the large Vgs needed to drive them. By reducing the supply to the Mosfets you expose them to less stress and dissipation. There are quite a few Class AB amplifiers like that. The idle current, which I think the OP did not mention is 350mA at 84V x 2. So roughly 120 W idle for two channels. Lower the output transistor voltage by 10V on each rail and you get a saving of 14W. Not really a lot.
I do not know, but what does Hypex offer for their high-power amplifiers? Buckeye Amps went with a custom SMPS for his design.For my use, I was looking at this because of the additional Aux voltages, but is not enough power unless I buy one for each channel
SMPS800RE | Connex Electronic
connexelectronic.com
This would be a worthwhile modification for me if I could get a 2000W SMPS
Thanks, I did not catch that you needed additional rails. If this is to mod a vintage amp I would not bother replacing the power supply with an SMPS, would look at other circuit elements.Yeah I agree with everything you said, but the Hypex power supply you mentioned does not have 2 additional voltage rails.
I can get a 2kW supply from the other vendor also without the additional rails. Not going to pursue a mod like that.
Capacitor lifetime varies wildly IME. Temperature is a big killer of electrolytics. Re-capping is popular but not needed as much as people think IME/IMO. Caps can often be reconditioned, and replacing caps with much larger values can cause other problems like blown fuses, diodes, and transformers if inrush current is not controlled.I think people who rejuvenate vintage equipment, will usually only replace the caps. Frankly I am surprised that my caps lasted 40 years with only a small increase in leakage current and ESR. My concern is that if one wanted to recap their old audio amps, this seems to be the time do do it, as I see that many manufacturers are obsoleting those big caps. I bought special TDK caps with 57Amp ripple current capability. I was mostly impressed with their chart that showed that at 45C instead of 105C and 20% ripple current, the estimated life expectancy was 250,000 hours. These are the components NASA puts in their space probes, lol. With all the disposable equipment being made nowadays, you may not find components rated for more a few years life, before they are destined for the landfill.
See third picture. Shows the effect of temperature and ripple current. It is very predictable as EPCOS/TDK has made many lifetime tests. They even have confidence on their 250,000 hour (28+ years) life test. Out of all the capacitors on Mouser website this one was amazing.Capacitor lifetime varies wildly IME. Temperature is a big killer of electrolytics.
I must confess I did not go back to the start of the thread; I usually look at "New Posts" which all too often has me jumping into the middle of something I do not belong. Like now.There are other sources to consider when seeing that hum is out of spec.. Attached is a schematic of one channel of this amp. It has the rails for the voltage gain stages isolated with additional capacitors. OP did not mention if he looked to see if these were open. I have seen many capacitors not nearly 40 years old that were just an open circuit. In my case when I get more time I will replace them.
Small capacitors are often used to keep supply impedance low over a wider bandwidth. Capacitor self-resonance is pretty low for big electrolytics, and circuit PSRR falls with frequency, so extra smaller caps with higher self-resonant frequency help. Choosing poorly can also cause issues if noise hits at resonant peaks if the filtering is not done properly (just throwing caps at it is not always a good idea). This is something I have actually spent a lot of time on, and have taught fellow engineers who have not as much practical experience. The problem is actually worse with SMPS due to the high speed and need for low ESR but need to avoid resonances.You can see the elegance of this circuit, doing its job with just FIVE! transistors in the gain stages. (Taken right out of the Toshiba data book from 1985 - I have a copy. Kind of dates me). It may not have really high PSRR, this is why the exxtra filtering on the supply rail. The description states that to save money, use a smaller transformer with sagging rails and set the rail voltage under load to be able to produce speced output power. Somewhat the antithesis of using a SMPS.
Square-wave testing seems to have gone by the wayside, at least for most published tests. I suspect (hope) it is still done internally. For the past 2-3 decades higher-bandwidth power devices and refined circuit topologies have made all but the very worst designs quite stable with capacitive (etc.) loads.The other interesting test published in their service manual is the ability to handle capacitive loads. This is an ideal amplifier to drive electrostatic loadspeakers with. I have not seen many, if any amplifier tests done in recent timeframe that even test with square wave, let alone with a capacitor in parallel. The ringing shows the ability of the feedback network to keep the output somewhat under control.
Yah, that's impressive! Most of the capacitor manufactures offer lifetime test results as well as enhanced SPICE and/or S-parameter models of their capacitors. C-D, Murata, Panasonic, TDK, etc. are among the ones I researched trying to design broadband (DC to ~10 GHz) supply decoupling networks, but of course the final selection also had to consider size and especially cost. When I first started my last job, they had a decoupling issue, so naturally I suggested a great cap I had used for advanced mil-spec R&D designs. The purchasing guys had heart attacks when they found out the cost, and I had to come up with a cost-effective design that had more parts but was much cheaper.See third picture. Shows the effect of temperature and ripple current. It is very predictable as EPCOS/TDK has made many lifetime tests. They even have confidence on their 250,000 hour (28+ years) life test. Out of all the capacitors on Mouser website this one was amazing.
The replacement power supply caps cost $69 each. To me that is not a heart attack price, because larger filter capacitors were always expensive, even going back to the 1970s, but others may.The purchasing guys had heart attacks when they found out the cost, and I had to come up with a cost-effective design that had more parts but was much cheaper.