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project:sprinklers [2024-03-26 Tue wk13 20:52] – baumkp | project:sprinklers [2024-08-24 Sat wk34 16:27] (current) – [References] baumkp | ||
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Basically at this stage the outstanding problem was the just failing valve solenoids. | Basically at this stage the outstanding problem was the just failing valve solenoids. | ||
- | I have been using the Open Sprinkler V2.0 since about 2014, this is a 24VAC controller. I reached out to the solenoid valve supplier and asked them if they had any similar such problems. | + | I have been using the Open Sprinkler V2.0 since about 2014, this is a 24VAC controller. I reached out to the solenoid valve supplier and asked them if they had any similar such problems. |
I reached out to Open Sprinkler about the matter, however they did not seem to understand and indicated that the controller was a 24 VAC type and DC was not an issue. | I reached out to Open Sprinkler about the matter, however they did not seem to understand and indicated that the controller was a 24 VAC type and DC was not an issue. | ||
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To fully resolve this issue I purchase a single channel digital oscilloscope and tested the voltage at the controller out and the node boxes closer to the solenoid valves. | To fully resolve this issue I purchase a single channel digital oscilloscope and tested the voltage at the controller out and the node boxes closer to the solenoid valves. | ||
- | I would consider normal supply voltage tolerance to be minimum +/-10% this aligns with the IEC standard for electrical power distribution. So a 24VAC system should be able to absolutely reliably operate between 21.6 to 26.4 VAC. As the solenoid operation voltage was typically between 25 - 26VAC this condition is meet. The stand-by voltage was not a concern for the solenoid operation and the controller | + | I would consider normal supply voltage tolerance to be minimum +/-10% this aligns with the IEC standard for electrical power distribution. So a 24VAC system should be able to absolutely reliably operate between 21.6 to 26.4 VAC. As the solenoid operation voltage was typically between 25 - 26VAC this condition is meet. The stand-by voltage was not a concern for the solenoid operation |
- | Next I measured the DC resistance of a new solenoid at 33.1 Ω. Based upon the specification printed on the Solenoid 24 VAC, 50/60 Hz, Holding 0.25 Amp and inrush 0.43 Amp maximum I calculated the solenoid impedance to be 96.0 Ω. This means the solenoid holding reactance calculates as 90.1 Ω. The solenoid apparent power is 6.0 VA and real power 2.07 W. With 25.2 VAC supply at the solenoid this becomes 0.264 A current, 6.68VA apparent power and 2.3 W real power. | + | Next I measured the DC resistance of a new solenoid at 33.1 Ω. Based upon the specification printed on the Solenoid 24 VAC, 50/60 Hz, Holding 0.25 Amp and inrush 0.43 Amp maximum I calculated the solenoid impedance to be 96.0 Ω. This means the solenoid holding reactance calculates as 90.1 Ω. The solenoid apparent power is 6.0 VA and real power 2.07 W. With 25.2 VAC supply at the solenoid this becomes 0.264 A current, 6.68VA apparent power and 2.3 W real power. |
A USA based brochure for the K-Rain Valve KR7101 gives the following specification for the valve: Voltage: 24VAC 60 cycles, 0.4 amps in rush, 0.2 amps holding. Pressure 20 psi minimum to 150 psi. This aligns well with the calculation showing 0.21 Amp at 24 VAC 60 Hz. | A USA based brochure for the K-Rain Valve KR7101 gives the following specification for the valve: Voltage: 24VAC 60 cycles, 0.4 amps in rush, 0.2 amps holding. Pressure 20 psi minimum to 150 psi. This aligns well with the calculation showing 0.21 Amp at 24 VAC 60 Hz. | ||
- | I measures the voltage across the resistor with the Oscilloscope at between 2.81 to 2.88 VAC RMS and resistor was measured with a multimeter as 12.1 Ω, so circuit current is 0.232 to 0.238Amp. | + | I measures the voltage across the resistor with the Oscilloscope at between 2.81 to 2.88 VAC RMS and resistor was measured with a multimeter as 12.1 Ω, so circuit current is 0.232 to 0.238Amp. |
I measure the voltage across the resistor when operating an old solenoid valve and it was 3.03 VAC RMS, with calculated current of 0.25 Amp. Interestingly the waveform across the resistor on the new solenoids looked distorted, more triangular, whereas the old solenoid valves waveform was much more sinusoidal. | I measure the voltage across the resistor when operating an old solenoid valve and it was 3.03 VAC RMS, with calculated current of 0.25 Amp. Interestingly the waveform across the resistor on the new solenoids looked distorted, more triangular, whereas the old solenoid valves waveform was much more sinusoidal. | ||
- | As of writing I have only been running the system with the 12 Ω resistor for about 2 weeks. I had to replace 4 solenoids in the previous 3 month period | + | As of writing I have only been running the system with the 12 Ω resistor for about 3 months. I had to replace 4 solenoids in the previous 3 month period. So it would seem the addition of the 12 Ω resistor has resolved |
- | About 6 months earlier the control wire to the pump contactor failed and I needed to get it replaced. | + | About 9 months earlier the control wire to the pump contactor failed and I needed to get it replaced. |
In summary: | In summary: | ||
- | - Old decrepit failing underground solenoid wiring replace with new sheathed quality multi-core wire with node boxes fitted and operation well for 4 months. The LEDs in the control nodes make system diagnostics much easier. | + | - Old decrepit failing underground solenoid wiring replace with new sheathed quality multi-core wire with node boxes fitted and operation well for 5 months. The LEDs in the control nodes make system diagnostics much easier. |
- | - New solenoid | + | - New solenoid |
- I suspect the new solenoid valves are actually optimised for 60Hz operation not 50Hz and this has been the root cause of the new valve solenoid problems I have been having. | - I suspect the new solenoid valves are actually optimised for 60Hz operation not 50Hz and this has been the root cause of the new valve solenoid problems I have been having. | ||
- | - A readily available 12 Ω, 1 W resistor at cost of less than $1.00 seems to be a simple solution to rectify the solenoid failure problem. | + | - A readily available 12 Ω, 1 W resistor at cost of less than $1.00 is a simple solution to rectify the solenoid failure problem. |
Some additional comments: | Some additional comments: | ||
- Multi faceted problem solving is significantly more difficult than single point failure analysis. | - Multi faceted problem solving is significantly more difficult than single point failure analysis. | ||
- Avoid the use of single sprinkler wiring in more complex larger sprinkler reticulation systems. | - Avoid the use of single sprinkler wiring in more complex larger sprinkler reticulation systems. | ||
- | - I do not like jar top style valves, just a personal preference though. | + | - I do not like jar top style irrigation solenoid control |
- | - An inductor instead of a resistor may be a more effective solution to reduce the solenoid current and overall real power consumption, | + | - An inductor instead of a resistor may be a more effective solution to reduce the solenoid current and overall real power consumption, |
+ | |||
+ | **Summary** | ||
+ | |||
+ | After 12 weeks of reliable operation with no further solenoid failure the use of a 12 Ω resistor to limit solenoid current and power draw has rectified the solenoid failure problem. | ||
====References==== | ====References==== | ||
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- | <- project: | + | <- project: |