I dont know how it works in france but here in germany i would expect X 2/2 to just be a label for that contact so you can reference it in a larger diagram. I doubt there is any electrical meaning to it.
Ask Electronics
For questions about component-level electronic circuits, tools and equipment.
Rules
1: Be nice.
2: Be on-topic (eg: Electronic, not electrical).
3: No commercial stuff, buying, selling or valuations.
4: Be safe.
Thanks for the feedback. I see that that’s indeed the case.
My first thought: connector two, pin two?
Looking at the attached videos, these are usually connected up with wide rows of quick plug thingies that you can just push cables into. So yeah X indicating its a connector, 2 being the number of the mumber of the connector row and the last number being the pin. Thats how i have seen it done many times.
Just from the wording, ignoring the numbers, this looks like the control connection (red +5v,black ground and the last one signal).
From your description is guess this connects to the boiler on a dedicated port which provides the DC and reads the signal. 5v is quite common for sensors so that doesn't seem off.
That is probably inspired by EN IEC 81346-2 where "X" indicates a connector of some kind and the numbers following the X identify the connector and the relative position on the connector (for connectors with multiple contacts).
These flow sensors are usually hall effect sensors, with two or four magnets attached to a rotor with a little water wheel. When water flows, the magnets turn and create something like a PWM signal at the output (actually it's high level when magnet is there and low level when magnet is not there or vice versa). Measuring the pin with a slow multimeter, this would indeed give you approximately half the supply voltage when water is flowing, depending on a few other factors. So- readings sound sensible to me. To note that if the rotor stops with a magnet close to the hall effect sensor, you will read 5V (or VCC) at the output, but always VCC/2 when flowing.
Most of these sensors employ an open collector output stage, but that doesn't need to bother you with the readings you're getting, I think.
Read your post again, and your readings are of course not in line with what I laid out. Are you measuring the sensor in-system?
If you are, the sensor might indeed be faulty. If you aren't, you probably need a pullup resistor on the output pin.
Yeah, if by /in system/ you mean connected to the board. I didn’t mess with anything other than to stick my probes onto the wires. The boiler is not switching on to heat water and it acts just as if it is not detecting that water is running. So a broken flow sensor was one of the theories. And since the readings seem quite off from what’s expected I guess buying a new sensor is the right move.
Once I get it removed I’ll see if it looks like I can rebuild it but I don’t expect that to go well. I may not have to waste it though. Considering the at rest voltage is double the running water voltage, it’s still detecting water running. It’s just not giving the voltage the board expects. So one idea is maybe I can repurpose this to turn on a shower light when the shower water is running.
If I had an electronics background I would probably try to do a makeshift gadget that converts 0.66 V to 2V and 1.33 V to 0 V. Then I wouldn’t need a new sensor (which could cost €100.. i’ve not checked locally yet but online prices are looking terrible).
With better tools, it would be easier to troubleshoot more precisely. An oscilloscope would help you understand what's going on, for example.
From what you describe, I'm actually starting to suspect the other end (the controller?) to be the problem.
One idea you could try before buying anything is to disconnect the sensor, supply it with 5V and ground (double check with data sheet!) and see what's happening on the output when there is flow. If you don't measure anything, as I would expect since the pin alternates between a floating state and ground, you then add a 10k or 50k ohms pullup resistor between 5v and output and measure again, and should get the levels you expected to see in the first place.
Don't know if you're comfortable doing this, but maybe you can find somebody to help you out?
It shows 5V on the diagram but I don’t think that’s precise. I measured the red wire at 4.68v which is around what the guy in the video got in his test. Since the board is part of the circuit I suppose I cannot rule out the board as a problem. Testing the sensor in isolation will be rough going because it’s a proprietary joint. So I would have to get a tight rubber hose and fit that onto a garden hose. For powering it I have a switchable ac adapter with a 4.5 V setting. Or I can maybe get 5V off a USB charger or ATX PSU from a PC. My multimeter does not have a frequency function but I can see from the video that it would be useful for this so I might look for 2nd hand multimeter at the next street market, though that will set me back a week (OTOH might be worth it if it helps diagnose this in a way that helps avoid buying the wrong part).
Whatever is broken here, it was something that gradually failed. For several months it was a gamble when turning on the hot tap whether the boiler would detect it and give hot water. It was like a 50/50 game of chance for a while then getting hot water became progressively less likely until it flatlined.
5V or 4.68V input isn't meaningful. The sensor has some input range and 4.68V most definitely falls into that. Could be a design choice that has no real implications.
On the other hand, if the device normally supplies 5V, just yours doesn't, then that's further evidence you have a faulty controller.
My money is on faulty controller at this point, but I think you'll need to find someone with electronics chops if you want to avoid just buying parts until it works again.
For what it's worth, I didn't mean take the sensor out of the wall, but just electrically unplug it from the controller to see what it does on its own when you turn on the water.
A frequency counter won't really help you here, I think. You already know to expect ~VCC/2 when water is running, and either VCC or 0V if it isn't. The speed of the square wave isn't very relevant.
For what it’s worth, I didn’t mean take the sensor out of the wall, but just electrically unplug it from the controller to see what it does on its own when you turn on the water.
Yeah I figured that but the terminals on the sensor are hard to reach so I was figuring I would need to remove it. But then it occurred to me that I could leave the thing in place and do the isolated test by unplugging the X2 connector from the motherboard and easily access the pins through that connector. So that’s what I did. Results:
- at rest, the signal wire is 4.75 V
- water running, the signal wire is 2.3 V
So in isolation the sensor worked correctly. Then I plugged it back into the motherboard and retested to confirm again the bad voltages. But in fact the readings were correct. It’s unclear why it works now. I wonder if the unplugging and replugging of the x2 connector improved a connection that deteriorated somehow.
Thanks for saving me €36! However incidental. If I had not done the test in isolation, I probably would not have messed with the X2 connector. I would have normally just replaced the sensor as an experiment.
(edit) I can hear a ticking sound coming from the motherboard. I’m not sure how long it’s been doing that. It’s quite faint unless I put my ear close to the board. Maybe it’s normal.
Good job troubleshooting.
It shows 5V on the diagram but I don’t think that’s precise. I measured the red wire at 4.68v which is around what the guy in the video got in his test. Since the board is part of the circuit I suppose I cannot rule out the board as a problem. Testing the sensor in isolation will be rough going because it’s a proprietary joint. So I would have to get a tight rubber hose and fit that onto a garden hose. For powering it I have a switchable ac adapter with a 4.5 V setting. Or I can maybe get 5V off a USB charger or ATX PSU from a PC. My multimeter does not have a frequency function but I can see from the video that it would be useful for this so I might look for 2nd hand multimeter at the next street market, though that will set me back a week (OTOH might be worth it if it helps diagnose this in a way that helps avoid buying the wrong part).
Oh and be careful if you do end up trying it.
There's no safety risk in what I described, but reversing the power supply might very well fry the device.