Tag - Irrigation System Backflow Testing Springfield MO

Irrigation and Drainage Services - Lawn Irrigation Springfield MO

Troubleshooting for Irrigation

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Troubleshooting for Irrigation

The best way to troubleshoot electrical system problems within an irrigation system is with a step-by-step approach. The method detailed below isolates and checks each of the irrigation components: the controller, zone control valves and the wiring that connects it all together.

Step 1: Check the Obvious

Before launching a thorough system diagnosis, don’t forget to check the obvious. Is the system water supply on? Are there isolation valves at the backflow preventer, pump station or in the mainline that are preventing water from flowing? Has the flow control on the valve been turned all of the way off? Reviewing these factors up front can save time and effort.

Step 2: Make Sure You Don’t Have a Programming Error

If the zone operates fine manually using the controller’s manual mode, but does not operate automatically, this usually indicates a programming error rather than an electrical problem. Review the controller’s programming guide and look for data entry mistakes.

Step 3: Know How to Use a Volt ohm Meter

An inexpensive volt ohm meter will be your most valuable tool and a required component for successful electrical trouble shooting. Volt ohm meters can be purchased in the electrical supplies section of a local hardware store, electronics shop (like Radio Shack) or your local irrigation equipment supplier. Modern digital meters are more reliable and provide an easy to read display that can give precise quantitative feedback of the system symptoms.

Step 4: Is the Controller Operational?

After these preliminary steps, you’re now ready to check the controller itself. A blank LCD display, or failure to respond to keyboard entries, could indicate a lack of power to the unit or other damage. Begin by using your volt ohm meter to take a voltage reading of the primary incoming power, to the controller. It should read somewhere between 110 to 125 volts. If it doesn’t, you’ve found your problem. But, it’s seldom that easy. In some cases, you’ll notice that the display of the controller is scrambled, missing LED segments or the entire unit is “frozen” preventing buttons or dials from entering data. This is a symptom of “micro processor lock up,” where the primary brain of the controller has become confused with bad data from electrical surges or other causes. This can often be cleared by re setting the device. Reset the controller by either disconnecting all electrical and battery power from the unit for several minutes, or by pressing a “reset” button which clears the memory of the processor and reboots the system.

Step 5: Check for a Tripped Breaker or Blown Fuse

If the controller passes these tests, next check the station output of the controller to the valves that control the area that is not being irrigated. Again using the volt ohm meter, you can check to see if the output terminals indicate the 24 volts needed to open a standard solenoid. If you do not get a reading here, you should check for a blown fuse or tripped circuit breaker within the controller. Also check the output of the transformer in the controller to make sure that it is outputting correct voltage. A blown fuse or tripped circuit breaker in most controllers indicates an overload condition in the field not a problem with the controller. If one of these conditions is present, you can certainly replace the fuse or reset the circuit breaker, however this will not solve the root cause of the problem with either the field wiring or valve solenoid.

If you are fortunate to have a top of the line controller, you may have the benefit of a more modern feature called “automatic short circuit detection” which is a specialized self diagnostic system within the controller itself. This handy feature allows the controller to identify a zone that has a fault in the field wire or valve and skip over the affected zone, eliminating a blown fuse. The best part of this feature is that the controller will digitally display a message that says: “Station 3 Error” to assist with locating the valve or field wire problem.

Step 6: Check Field Wiring

If the controller, transformer and station outputs all work properly, the next place to check is the field wiring. And this happens to be the most common place where unforeseen problems can occur.

Use the volt ohm meter and perform an “ohm test” on a specific zone circuit (common wire plus station wire), with the controller power turned off. At this point, you will want to be certain the volt ohm meter is set to the correct resistance setting so that the unit provides accurate and measurable feedback. Make sure to disconnect the wires you are testing from the controller terminal block so that your reading is specific to the wires in the field, and not mixed up with feedback through the circuits of the controller. The “ohm test” will send a pulse of current from the battery in the volt meter through the circuit. A normal reading is 20 to 60 ohms.

If the circuit has a “short,” meaning the current is taking a shortcut back to the controller, the reading may be as low as 1 to 10 ohms. If the circuit is completely broken, you will get an infinity reading, meaning there is no clear path for the electricity to flow back through the circuit and to the volt ohm meter.

A reading of a high number, but not infinity, would indicate that there is still an intact circuit, but there is a high amount of resistance in the circuit that is keeping current from flowing efficiently enough to activate a solenoid valve. This is a common symptom of a bad electrical connection, usually an underground splice that was not properly waterproofed.

Test each circuit from the controller and you will notice a pattern. The good circuits will have similar readings and the bad circuit will stand out from the others. This gives you confidence in the process and helps you work specifically to the final step of checking the valve solenoid.

Step 7: Check the Valve Solenoid

The final step in a systematic approach is to decide whether diagnosed problems in the field wiring are related to the wiring and splices, or to the specific solenoid on the valve. At this point, you will move to the actual location of the valve in the field and cut into the wires leading into the solenoid to take an ohm reading of the solenoid’s resistance. Typically, if the solenoid is bad, you will get a reading for a “short” or 1 to 10 ohms. (There is no need to test voltage at the valve since you have already “ohm tested” each circuit at the controller so you know which zones have problems.)

How To Sharpen Your Trouble Shooting Skills

Electrical trouble shooting an irrigation control system using this step by process takes time to learn, and requires a willingness to try multiple approaches before finding the solution to your problem. Many irrigation manufacturers and distributors offer training classes on electrical trouble shooting that will give you an opportunity to get hands on experience with this process.

A few hours in an irrigation trouble shooting course can provide valuable training for that hot summer day when you face stressed turf – and a system that will not operate!

 

 

 

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Watering Trees, Plants and Shrubs - Lawn Sprinkler Design Springfield MO

FAQ on Backflow

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Backflow Prevention – Frequently Asked Questions

What is backflow?

Backflow is the undesirable reversal of flow in a potable water distribution system through across-connection. A cross-connection is an actual or potential link connecting a source of pollu-tion or contamination with a potable water supply. Backflow may allow liquids, gases, nonpotablewater and other substances, from any source, to enter a public water system.

How does backflow occur?

Backflow may occur due to high pressure on the customer side, or low pressure in the watersystem. Backflow through a cross-connection can contaminate the potable water in a building,on a block, or throughout an entire water system.

What is backflow prevention?

Backflow prevention protects public water systems from contamination or damage throughcross-connections located in customer facilities. Backflow prevention is typically achieved byplacing a backflow prevention assembly between the customer and the public water system.This is called containment backflow prevention.

Does my water system require backflow prevention?

Missouri’s backflow prevention regulation (10 CSR 60-11.010) applies to all community watersystems. These are water systems that serve at least 15 connections or at least 25 people on ayear-round basis. Missouri has more than 1,400 community water systems. They serve morethan 4.9 million people, almost 90 percent of the state population.

Must my home or business have backflow prevention?

Many businesses must have back flow prevention. Common examples are manufacturing andprocessing plants, medical facilities, laboratories (including school chemistry and biology labs),and buildings that have boilers, fire sprinkler systems and irrigation systems.

Solely residential facilities are exempt from the rule unless a specific cross-connection is identified. For example, single-family residences with a lawn irrigation system require back flow prevention. Multi-family residences with a boiler or fire sprinkler system require back flow prevention.

Call your local water supplier to confirm whether or not back flow prevention is required at your home or business.

What kind of back flow prevention is required at my home or business?

Under the Missouri rule, three types of back flow prevention assemblies are permissible for containment: air gaps, reduced pressure principle assemblies and double check valve assemblies. The type of assembly you need depends on the type of hazard present.

Generally, where you have a back flow hazard that may threaten public health you must havean air gap or a reduced pressure principle assembly. Where there is a lesser hazard that may damage the water system or degrade the aesthetic quality of the water, a double check valve assembly is required.

Only approved back flow prevention assemblies may be used. If you can find the manufacturer and model number on your assembly you can check with your water supplier to find out if it is an approved assembly. Modifications to an assembly invalidate the approval. If your assembly looks like it has been changed, get in touch with your water supplier or a certified back flow prevention assembly tester to see if it is an approved assembly.

Water suppliers may have more strict or specific requirements than the state rule. Contact your local water supplier to make sure you have the appropriate back flow prevention assembly to meet local requirements.

Must I have my back flow prevention assembly inspected?

Yes. To ensure the device is functioning properly, a certified tester must test it at least annually.For new facilities, the assembly must be tested when installed. If the tester finds the assembly is not working, you must arrange to have it repaired and tested again. It is your responsibility to pay for the test and repairs. The tester is required to provide a copy of the test report to you and the water supplier. To obtain a list of certified testers in your area, call your water supplier or the Missouri Department of Natural Resources.

Does the back flow prevention assembly protect my entire facility?

No. The required back flow prevention assembly provides containment and it protects the public water system from hazards in your facility. Cross-connections in your own plumbing may allow contaminants to back flow from hazardous processes to drinking water taps in your building.

Back flow prevention applied within a facility to protect drinking water plumbing from process plumbing is called isolation. Isolation back flow prevention is not covered by departmental rules,but may be required by local plumbing codes. Check with your local code enforcement agencies to see what standards apply to your facility.

Additional Resource:

Cross-Connection Control Manual,

U.S. Environmental Protection Agency (EPA 816-R-03-002, February 2003);

For more information

Missouri Department of Natural Resources

Water Protection Program, Public Drinking Water Branch

P.O. Box 176

Jefferson City, MO 65102-0176

1-800-361-4827 or (573) 751-5331 office,

(573) 751-3110 fax

 

 

 

 

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Proper Techniques for Lawn Irrigation - Springfield MO

How to set an Irrigation Controller

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How to set an Irrigation Controller

    1. Date & Time – set up the date and time to match the current date and time
    2. Set Seasonal Adjustment to 100% – Turn your dial to Seasonal Adjust and press the up or down arrows as necessary
    3. Program (A, B, or C)
      1. Pick one program and clear out the rest if anything is set in them
      2. Only set up multiple if you have special circumstances and don’t want to have to re-set original program “start-times” and “run-times”
    4. Set start times for each program
        1. Each program runs all zones for their “run time”

      i. 1 zone may run for 7 minutes
      ii. A program with 10 zones running for 7 minutes will run for 70 minutes total
      1.Therefore, start times must be at least 70 minutes apart or system will malfunction and show some kind of error on the screen
      2.We should never need more than 1 start time on a normal yard
      i.BUT, on new plantings, (bed or bushes) we DO use 2-3 start times so we can water 2-3 times in one day
      ii. Spring and Fall typically need 2 waterings a day and Summer can sometimes require 3 waterings to keep new plants or grass healthy
      iii. Often when we set more than one start time, we would save those settings as a second program (program B)
      1.This allows us to leave the original program exactly as it was so it can be returned to after the establishment period of any new plants

    5. Set run times for each zone

1.At 3x per week:
i.18 minutes on rotor zones & mp-rotator zones
ii.7 minutes on spray zones
iii.25-50 minutes on drip zones
iv. Specific adjustments should be made based on plant type, wind flow, and sun/shade of the area each zone waters

  1. Set days to water1.M WF or Tu Th S for a 3-day a week schedule
    1. M W F or Tu Th S for a 3-day a week schedule
  2. Set seasonal % adjustment for the season
    1. Summer: 100%-120%
    2. Spring/Fall: 40%-80%
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Proper Techniques for Lawn Irrigation - Springfield MO

Proper Techniques for Lawn Irrigation Springfield MO

Proper Techniques for Lawn Irrigation

Proper lawn irrigation can be the difference between perfect looking plants and wilted or dying plants. Overwatering is the number one cause of death for new plants. Different irrigation techniques use varying amounts of water and deliver water to different places on or around the plant. Always look up the water requirements for specific plants. For many small plants, frequent smaller volumes of water are ideal. In contrast, larger plants and trees prefer larger volumes of water less frequently. For 1-2 weeks after planting, it is best to water daily at half of normal watering time (and twice daily during the summer heat). Between 3-8 weeks after planting, three times a week at regular watering schedule works best for lawn irrigation systems.

Timing

The best time to water lawns and other plants is during the cooler parts of the morning, especially during a warm summer. Watering in the morning gives the water a chance to soak into the soil before the sun’s heat causes it to evaporate. Avoid letting water splash on plant leaves if at all possible, particularly if watering after 8 A.M.

Drip Lawn Irrigation Technique

Drip irrigation, also called trickle irrigation, delivers water directly to the soil. This method has advantages over watering methods that spray water over the entire plant. The best drip irrigation systems have plastic pipes beneath the soil that carry water directly to plant roots without visible sprinklers or hoses. Drip irrigation uses less water than other types of irrigation because the water soaks into the soil before much of it has a chance to evaporate and is especially beneficial for hilly landscapes because its low-flow pressure will not cause runoff and erosion.

Sprinkler Irrigation

Sprinkler irrigation is convenient because it can cover large areas without requiring you to do any work. Sprinkler systems range from multiple sprinklers with automatic timers to a single sprinkler attached to a hose in the garden. Watering when wind is minimal reduces evaporation loss.
Knowing the correct lawn irrigation technique is crucial to maintaining healthy and beautiful plants. Contact Gabris landscaping to determine the best technique.

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