Taco needs to create an animation of how the 570 series zone valve works.

@Steamhead 's solution is the better one — isolation relays. There is no problem if the two completely separate 24 VAC circuits are, in fact, completely separate except at the #2 terminal of the valve (or valves — but I'll not get into that!). Where trouble can arise is if there are two connections possible between them, or where someone tries to use the boiler transformer to power a thermostat or something of that sort. Then you can fry transformers instantly. But not if it's wired correctly.

The isolation relay trick will work nicely in any case, and prevents errors from becoming problems!

One other gotcah I just thought of — the thermostat circuit has to be powered with a 24 VAC transformer with enough power to operate the valve motor. You can't just hook up two wires to the valve and two to the thermostat and expect anything to happen.

Well, @EdTheHeaterMan , that's basically the mirror image of what I posted. I've seen it done both ways in the field. You can fry your transformers either way. This is why I always use isolation relays.

@Jamie Hall , in general a 40VA transformer can power three 570s.

having been in tech support at Taco 25 years ago, this was one of the most asked question.

After reading this tread, there’s been several explanations of why #2 common terminal works. As long as the valve 2, & 3 terminal interface with TT terminals, dry contacts, there’s no issue.

If you continue to have questions contact Taco tech support at 401-942-8000 for further assistance.

many systems have one end of the secondary of the xfmr tied to ground. if both xfmrs have one end tied to ground then there is another wire connecting the 2 ckts together besides the 2 terminal on the zone valve so you could get anything from a valve or boiler that doesn't shut off to burned out transformers if you don't account for that extra wire when drawing your current paths.

The answer in on the 3d page of this Taco brochure.

I used to struggle with this myself.

it's just cleaner and simpler to have a 4 wire valve with 2 valve wires and 2 end switch wire

The brochure explains

it perfectly

It operates differently than other thermal actuators or zone valves. I believe the stroke switch opens to drop power to the wax motor or it would over-stroke. Possibly the wax or oil inside over-heats? It pulses power about every 17 seconds.

When powered it pulls .9- 1.1a . Va= volts X amps .9a X 24V = 21.6. So 3 on a 24 transformer is a bit over.

If you cut open the side of one you see where the terminals wire to, and it makes more sense.

Also watch the stroke and end switch working. A clamp on amp meter shows how the power constantly cycles to the wax motor. Yellow wires to heat motor, black to end switch.

The 250Ma thermal actuator, helmet heads, ZVs or manifold actuators have an inrush and settle down to a constant 125Ma draw.

Spring return ZVs the syncrous motor stal;s when fully open and becomes a 5W heater. So a hot motor does not indicate a failed motor.

Some motorized ZV only use power to open and close.

@JohnNY said "But T-T on a boiler are not dry contacts. They are energized in the burner circuit. Of course, Steamhead's addition of a relay, RIBU1C/S I'd imagine, would provide dry contacts. So, I guess that's the best way to install the 570 series. Thanks for weighing in, Joe, and everyone else.

@JohnNY I don't believe that T T on a boiler are dry contacts and @Joe Mattiello didn't say they were. He indicated that dry contacts connected to #2 and #3 on the 570 were "dry contacts" that are used to operate the T T on the boiler.
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Actually you can't fry a transformer "either way" as long as you are consistent with the way YOU wire the zone valve. Where you end up frying a zone valve is when YOU are inconsistent in wiring zone valves on the same system. I have explained it in detail here:

Somewhere in this comment it states that as long as you use the same wiring design throughout the system (either C to #2 or R to #2), you will be fine.

The problem occurs when someone uses the opposite design from yours, and then you come along to "fix" the problem and wire the system your way, while all of the other zone valves are wired the my way. That is when you can fry the transformer.

The reason is that your way is right in your mind, and you may fail to recognize that the other method (which is also right in my mind) was used throughout the rest of the system.

If one valve has R from the transformer connected to terminal #2 and another valve has C from the transformer connected to terminal #2, eventually all of the #2 terminals will be tied together as part of the end-switch circuit used to operate the T-T terminals on the boiler.

When power is applied to the transformer, the R and C circuits become connected together through the #2 terminal wiring, creating a direct short circuit across the transformer. The result is a burned-out transformer.

The key is consistency, and in my little brain R-to-R, W-to-#1 and #2-to-C makes the most sense when you look at the big picture.

@Steamhead , please don't take offense to my use of "your way" and "my way" as implying that one method is better or worse than the other. I was simply using those terms as an easy way to distinguish between the people who wire the valves one way and those who wire them the other way.

My point is that either method can work perfectly well, provided the same method is used consistently throughout the entire system. I chose the terms "your way" and "my way" only to make the explanation easier for others who may read this discussion in the future.

Here is the diagram that fails from my January 15, 2024 post that shows the flaw when you are not consistent. across the top are three different ways to wire a 570 that will work just fine when done consistently on a system:

See how three correct methods when used on the same system will fry the transformer? R to # 2 and C to #2 on the same system will eventually cause R and C to be connected without a load between them so the smoke is let out.

Zone relay boxes make it simple to wire most any ZV, and with a fuse protected transformer for errant mis wiring.

Readimng the directions helps regardless of which method you use.

Yes, I agree. The relay just provides another layer of isolation. Also adds more stuff to fail and more wiring to confuse folks even more. However maybe ultimately easier to repair without screwing it up and smoking transformers. The multi Zone relay boxes may be the best compromise, other than the extra cost.

I have not found the animation video yet, but what is funny is the YouTube folks are confusing the switch functions. The tab actuator is the End Switch, The conical part is for the Wax Motor duty cycle.

Not to me!

I consider cutaways an excellent training tool. Most hands on people like to know what is happening inside. We get a lot of ah ha moments.

Cut one open for training your own team if nothing else.

Caleffi produces dozens of cut away cases every year for reps and wholesalers. The trade schools snap them up also.

I clamp my PortaBand, with a coarse blade for soft metal, in the vice to slice open these valves. Spray paint, clear coat them.

You need to use a good relay known for its reliability. I like these:

https://www.supplyhouse.com/Resideo-R8222B1067-24V-General-Purpose-Relay-with-SPDT-Switching

If your transformer mounts on a 1900 box, you can replace it with a transformer/relay (a.k.a. fan center) unit, which uses the same relay. This makes the wiring a lot neater. Your terminal 3 outputs go to G on the transformer/relay, and the Normally Open relay contacts connect to TT on the boiler. You'll have to route the wires from the N.O. contacts out of the box through a bushing and connect to the thermostat wire from the boiler outside the box, since thermostat wire is not rated for the higher voltages found inside the box:

https://www.supplyhouse.com/Resideo-R8239A1052-40-VA-Fan-Center-w-SPDT-Switching-Action-Includes-R8222B

I like those zone valve panels too, but there isn't always room for one.

@Alan (California Radiant) Forbes I have not had the opportunity to cut one open to watch it function. However the way the switch placement looks to me, the tab will move off of the micro-switch's actuator first as the wax motor warms up. As the wax motor shaft moves further out and the wider part of the conical part of the motor shaft pushes enough against the actuator of the leaf switch the current through the heating element is shut off. As the heating element cools the motor shaft will eventually start to retract causing the leaf switch to close again adding heat to the wax motor.

The shaft of the wax motor moves slowly. I do not believe in normal operation the minor cycling (oscillation) of the motor shaft will cause cycling of the End Switch.

I agree with @Steamhead using a relay does make them foolproof and you don't have to worry so much about the wiring being mixed up.

I prefer the rib relays because the pilot light tells you what is going on.

Besides with two transformers intermingled you or I may know what is going on but many people do not.

2 wires to power the valve and two wires for the end switch make more sense to me.

@JohnNY You said, "When connected to 1 and 2, the reading across them tests at 7.8 volts and the valve doesn't open.".

How many volts do you read on a good valve?

ZV, RIB, transformer, box to mount it on, around 200 bucks. Wiring, labor X 6 zones= ?

I think for simplicity, labor hour and parts, a relay box makes a lot of sense.

The TACO 6-zone panel (ZVC-406-5) has an 80VA transformer, so it has enough juice for 6 zone valves.

That's because terminal 2 is typically connected to R on the transformer. With the thermostat contacts open, the lead between terminal 1 and the thermostat will show 24v to ground (or to C on the transformer) since there is no path to C through the thermostat. But when the thermostat closes, the lead between 1 and the thermostat will show zero, because the load (the heat motor) now absorbs the voltage out from 1.

We sometimes find the same in old knob-and-tube wiring. There was no polarity in the early days, so sometimes a light switch ended up in the neutral wire instead of the hot. It controlled the light just fine, but it meant the socket was still hot even when the light was off, which could electrocute someone changing a bulb. If we measured voltage to ground (which could be a cold water pipe) on such a circuit, we'd find 120v on one switch terminal when the light was off, but zero on both terminals when the light was on, for the same reason. And don't get me started on those "Carter circuit" 3- and 4-way switches that alternated between the hot and neutral……….