Post on 05-Mar-2021
transcript
Vineyard Irrigation Proficiency Series – Part 3
Chemigation for Vineyard Drip Irrigation Systems
January 29, 2021
Agenda
• Principles of Chemigation• Laws and Regulations• Types of Injectors• Drip Clogging and Water Quality Concerns• Fertilizers, Chlorine and Acid injection• Calibration of Equipment
• Demonstration of Injector Calibration (video)
Chemigation
The process of injecting an approved chemical into irrigation water and applying it through
the irrigation system to a crop or field.
Chemigation
General term that includes:• Fertigation• Insectigation• Fungigation•Nematigation
Advantages of Chemigation
• Uniformity of application• Precise application• Economics• Timeliness• Reduced soil compaction and crop damage• Operator safety
Disadvantages of Chemigation
• High management• Additional equipment• Must calculate injection rates and volumes• Injection equipment must be calibrated
Chemigation – Laws and RegulationsGeneral Classes• Controlled Substances
(pesticides and herbicides)
• Fertilizers and Nutrients
• Drip Maintenance/Clogging Control Chemicals (chlorine, acid)
Controlled Substances
Typically Pesticides and Herbicides
• Highly regulated by the EPA and States
• Regulations cover labeling, mixing/injection, and equipment
• Regulations designed to protect the environment, human health and water supplies
Other Chemicals….
Fertilizers and NutrientsDrip Maintenance/Clogging Control Chemicals
• Regulated by the Texas Commission on Environmental Quality
• Requires backflow prevention devices for public water supply and groundwater protection
The US EPA’s Label Improvement Program (LIP)
• Established in the 1980’s (fully implemented in 1988)
• States were required to implement regulations at least as stringent as proposed by the EPA
The US EPA’s Label Improvement Program (LIP)
• Labels must state whether product is approved to be applied through the irrigation system
• Application instructions are provided
• Requires use of specific safety equipment and devices designed to prevent accidental spills
Reading Chemical Labels
Example #1
Summary of Chemigation Equipment Requirements
1. Irrigation Pipeline
• Check valve between well and injection points*• Vacuum relief valve between check valve and well• Low pressure cut off• Low pressure drain*
*Alternative safety equipment may be substituted approved by EPA, March 1989.
2. Injection Hose
• Anti‐back flow injection valve – 10 psi• Normally closed solenoid valve between injection pump and chemical tank*
• A metering type injection pump*
*Alternative safety equipment may be substituted approved by EPA, March 1989.
3. Power Interlock
• Interlock injection pump and water pump power• Interlock normally closed solenoid valve and injection pump power
Other Chemicals
• Fertilizers and Nutrients• Drip Maintenance/Clogging Control Chemicals
• TCEQ regulations are designed to protect water supply
• Basic requirement is a check valve (backflow prevention valve) when connected to a water well or public water supply
Requirements for water wells…
All irrigation distribution systems … into which any type of chemical … or other foreign substances will be injected into the water pumped from wells shall be equipped with an in‐line, automatic quick‐closing check valve capable of preventing pollution of the ground water.
Other Required Devices
Installed between the pump discharge and the check valve• Vacuum‐relief device• Automatic low pressure drain• Inspection port
Chemigation Injectors and Pumps
The most common types:• Mechanical
• Piston (positive displacement) pumps• Diaphragm pumps
• Venturi meters• Other
• Water Driven
Piston/Positive Displacement Pumps• Uses a “piston” to inject chemical into the irrigation water
• Rate is determined by the• length of the stroke• number of strokes per minutes
• Chemicals come into contact with piston, so materials should be matched
Piston/Positive Displacement PumpsInjection rate remains constant and does not change if the irrigation pipeline pressure varies
• Injection rates cannot be adjusted while operating • Commonly used to inject fertilizer (large rate injection)
Piston/Positive Displacement Pumps
Diaphragm Pumps
• A membrane separates chemical from the drive mechanism (piston)
• Easy to adjust flow rate while operating • Commonly used for low‐rate injection (pesticides, etc.) or continuous injections (chlorine or acid to lower pH)
• Easy to calibrate and maintain
Diaphragm Pump
Diaphragm Pump Operation
Venturi Meters
• Simple device with no moving parts• The meter uses a reduced diameter throat tube (or a tube with a needle valve or orifice plate)
• Velocity changes in tube create vacuum to pull chemical into stream
Venturi Meters
Venturi Meters
•Most low‐end venturi injectors are not adjustable and have a constant proportion injection rate such as 1:50 (one gallon injected for every 50 gallons flowing through meter)
• Suction‐Injection rates are calibrated by adjusting the inlet and outlet pressure by controlling the flow through the venturi
Venturi Meter Selection/Calibration
• Also called Proportional Injectors• A water driven “engine” moves a piston within a cylinder at a proportional rate to the flow
• Available in fixed ratio and adjustable models• Commonly used only for chlorine or fertilizer
Water Driven Injectors
Water Driven Injectors
Injecting Fertilizers
Fertilizers
• Frequently injected into drip irrigation systems• dry and liquid formulations are available• liquid formulations are more expensive but are very convenient
• can be injected directly (without mixing with water) with a variable rate injector.
Fertilizers
• Fertilizers containing phosphorus and sulfur may react with calcium and/or magnesium in irrigation water
• forming precipitates that could clog emitters
• Micronutrients can also cause precipitates• Consult with supplier before use or test prior to injection
Fertilizers
• Solubility of dry formulas varies depending on type and water quality
• Incomplete dissolving may result in clogging of emitters and lines
• Solubility in Pure waterammonium nitrate 9.8 lb/galcalcium nitrate 8.5 lb/galpotassium chloride 2.3 lb/galpotassium nitrate 1.1 lb/gal
Fertilizers ‐ Summary
• Test solubility first• Beware of formulas containing phosphorus/sulfur in waters with calcium/magnesium
• Use soluble chelated forms of micronutirents• Liquid fertilizers are more expensive, but easier to deal with
Fertilizers
• Following the 1‐2‐1 method when injecting fertilizers
• first 25% of the irrigation set, inject no fertilizer –allowing the pipelines to fill
• inject during the middle half of the irrigation • no injection during the final quarter of the irrigation to allow the pipelines to be flushed and to move the fertilizer in the soil away from the emitter
Useful Conversion Factors
1 ppm = 1 mg/l1 ppm = 1 mg/kg1 % = 10,000 ppm1 % = 1.33 oz (by weight) per gal of water0.1% = 1000 ppm
Clogging Control
Clogging Control
• Biological ‐ Chlorine• Aglae• Bacteria
• Minerals ‐ Acids• Iron• Calcium/Lime• Salts• Etc.
Chlorine
• Inject chlorine to control biological clogging of lines and emitters
• Water high in iron or sulfur may foster bacterial activity, particularly in combination with fine suspended solids (< 100 microns)
Chlorine
• Injected to control biological clogging of lines and emitters
• Household bleach is often used in small systems (5.25% Chlorine)
• Use formulas with higher concentrations if iron bacteria and/or organic matter are problems
• Container label will specify concentration
Chlorine
Chlorine
• Chlorine concentration at the end of the drip line should be:
‐ 1 to 2 ppm for occasional treatment‐ 0.5 to 1 ppm for continuous treatment
• Begin with injection of low concentrations (5 ppmto 10 ppm) for one hour
Acid Injection
• Acid is injected to control mineral clogging of emitters
• Water likely to cause problems:• High water pH (>7.5) • “moderate” to “hard water”
• >60 ppm Ca• >500 mg/l TDS (total dissolved solids)
Acid Injection
• Inject acid to lower pH to about 6.5 for mild clogging problems
• For more severe clogging, lower the pH to 4• Expose emitters to this concentration for ½ to 1 hour
Acid Injection
• 98% sulfuric acid is commonly used in drip irrigation
• Other common acids:• Nitric Acid• Phosphoric Acid• Hydrochloric Acid (Swimming Pool Acid)
• Citric acid or vinegar can be used in organic farming
Acid Injection
• Laboratories can do a titration analysis which will determine the amount of acid needed to lower the water to a certain pH
• Texas A&M Soil, Water and Forage Testing Lab
• The injection rate (gal per hour) of acid is calculated by
IR= injection rate, gal per hrA = gal of acid needed to lower pH (per ac‐ft of water)Q = Flow rate of irrigation system (gpm)
Water Quality
• Highly Recommended water sources be tested prior to any chemigation to avoid negative reactions
• TAMU Soil Testing Lab has specific analysis for water used in drip irrigation
• More info at http://SoilTesting.tamu.edu
Water Quality Testinghttp://soiltesting.tamu.edu
Calibration of Equipment
• Small differences in injection rates make large differences in total amount of chemical applied
• Results in insufficient or excessive application
• Calibration involves injecting water and checking the actual volume of water injected
Calibration of Equipment
Useful conversionsvolume1 gal = 3,785 ml1 oz = 29.57 ml
flow1 ml/min = 0.016 gal/hr63.09 ml/min = 1 gal/hr1 oz/min = 0.469 gal/hr
Calibration of Equipment
For fixed ratio injectors, check the injection ratio
100:1 means that one gal of solution will be injected for each 100 gal of water flowing through the unit
Calibration of Equipment
For adjustable injectors:• Calculate the desired injection rate (gal/hr, ml/min) • Then calibrate/adjust injector accordingly
Calculations ‐ Example 1
Calculate the total solution needed and the injection rate for equipment setting/calibration
Step 1: total gallons of chemicals neededmultiply the total acres by the chemical solution to be applied (gal/ac)
Step 2: calculate injection rate in gal/hrdivide by the length of the chemigation event
Step 3: Convert gal/hr to milliliters per minute (ml/min)63.09 ml/min = 1 gal/hr
Step 4: set/check injector rate by injecting water for 1 minute
Calculations ‐ Example 1
20 acres to be chemigated with ‐ 60 gal of solution per acre ‐ in one hour
Step 1: total gallons of chemicals needed20 ac x 60 gal/ac = 1200 gallons of solution
Step 2: calculate injection rate in gal/hr(1200 gal) divided by (1 hour) = 1200 gal/hr
Step 3: Convert gal/hr to milliliters per minute (ml/min)1200 gal/hr ÷ 63.09 = 19 ml/minute
Step 4: set/check injector rate by injecting water for 1 minute
Calculations ‐ Example 2
Calculate injection rate based on concentration (ppm) of solution to be injected
.
IR = injection rate (gal/hr)F = flow rate of irrigation system (gpm)C = concentration of chemical wanted (ppm)P = Percentage of chemical in solution (%)
Calculations ‐ Example 2I want to inject chlorine at a concentration of 5 ppm for one hour. My irrigation system has a flow rate of 100 gpm, and I’m using household bleach (5.25% chlorine)
𝐼𝑅 .
𝐼𝑅 0.006 100 𝑔𝑝𝑚 5 𝑝𝑝𝑚
5.25%
IR = 0.571 gal/hr of bleach
IR = injection rate (gal/hr)F = flow rate of irrigation system (gpm)C = concentration of chemical wanted (ppm)P = Percentage of chemical in solution
Calculations ‐ Example 3
Determining amount of solution for fixed ratio injectors
For example 2, my venturi injector has a 100:1 ration
(injecting chlorine at a concentration of 5 ppm for one hour, a flow rate of 100 gpm, and using household bleach)
IR = 0.571 gal/hr of bleach
Step 1: Calculate total flow of irrigation system in one hour100 gpm x 60 min/hr = 6000 gallons per hour
Step 2: Calculate total gallons of solution to be injected (divide Step 1 by ratio)
6000 gph ÷ 100 = 60 gallons of solution
Step 3: Mix the 0.571 gallons of bleach with 60 gallons of water in the injection tank
Chemigation Operation & Calibration Video Demonstration
Contact Information
• Dr Guy Fipps, PEProfessor & Extension Ag Engineerg‐fipps@tamu.edu
• Charles SwansonExtension Program Specialist IIclswanson@tamu.edu979‐845‐5614