Contact Us Home

Family Farm Series Publications:
Vegetable Crop Production

Tips on Irrigating Vegetables

Quick Links:

TABLES

(The authors are H.W. Otto, UC Cooperative Extension, Orange County, and Jewell Meyer UC Cooperative Extension, Riverside. Contents adapted in part from "Solid Set Sprinklers for Starting Vegetables" and "Furrow Irrigation," both UC publications.

Irrigation costs are going up. With irrigation taking a larger share of growing costs, you'll want to find better ways to irrigate. This publication contains pointers that will help you irrigate more efficiently.

Back to Index

Pre-Irrigation

The first irrigation for most vegetables is a deep pre-irrigation--except where rains have already wet the soil as deep as most roots will go. Pre-irrigation leaches salts and can save water by trimming the number of irrigations needed later.

How deep should you pre-irrigate? Wet the soil a little deeper than your crop's rooting depth. Approximate rooting depth for vegetables is shown in Table 1.

Knowing your crop's rooting depth can also help you decide how long to run the water in later irrigations. Using Table 2, you can tell roughly how much water you'll need to pre-irrigate a dry soil to a desired depth.

Back to Index

Table 1. Approximate rooting depth of vegetables(l)

Crop Depth
Asparagus, pumpkin, winter squash, seeded tomato, seeded watermelon, lima beans, sweet potato over 4 feet
Bush and pole beans, cantaloupe, carrot, cucumber, eggplant beets, peas, pepper, summer squash 3 to 4 feet
Broccoli, cabbage, cauliflower, corn, lettuce, radish, garlic, onion, celery, potato 1-1/2 to 2 feet

Back to Index

Table 2. Inches water to pre-irrigate a dry soil to different depths (approx.) (2)

Soil Type(3) Inches water per foot soil depth Inches water to reach 6' deep
Clay 1.4 - 1.8 8.6-10.8
Silty clay 1.6 - 1.9 9.6 - 11.4
Sandy clay 1.6 - 1.9 9.6 - 11.4
Silty clay loam 2.2 - 2.3 13.0 - 13.7
Clay loam 2.0 - 2.2 12.2 - 13.0
Sandy clay loam 2.0 - 2.2 12.2 - 13.0
Silt-loam 1. 8 - 2.0 10.8 - 12.2
Loam 1.7 - 1.9 10.1-11.4
Very fine sandy loam 1.7 - 1.9 10.1 - 11.4
Fine sandy loam 1.2 - 1.4 7.2 - 8.6
Sandy loam 1.1 - 1.3 6.5 - 7.9
Loamy very fine sand 1.1 - 1.3 6.5 -7.9
Loamy fine sand 1.0 - 1.2 5.8 - 7.2
Loamy sand 0.7 - 1.0 4.3 - 5.8
Very fine sand 0.7 - 1.0 4.3 - 5.8
Fine sand 0.7 - 1.0 4.3 - 5.8
Sand 0.7 - 1.0 4.3 - 5.8
Coarse sand and gravel 0.4 - 0.7 2.2 - 4.3

Notes:
(1)The figures are averages for mature plants. Root depth varies, depending on soil profile, crop variety, whether you direct seeded or transplanted, etc.
(2) Based on available water holding capacity; plants have dried soil to permanent wilting point, 15 ATM.
(3) Assumes the soil is uniform throughout irrigation depth.

Back to Index

Table 3. Estimating soil moisture by feel.

 
How Soil Feels or Looks
Soil Moisture Level COARSE (sand) LIGHT (Loamy sand, sandy loam) MEDIUM (fine sandy loam, silt loam) HEAVY (clay loam, clay)
No available soil moisture. Plants wilt. Irrigation required. (1st range) Dry, loose, single grained, flows through fingers. No stain or smear on fingers. Dry, loose, clods easily crushed and will flow through fingers. No stain or smear on fingers. Crumbly, dry, powdery, will barely maintain shape. Clods, breaks down easily. May leave slight smear or stain when worked with hands or fingers. Hard, firm baked, cracked. Usually too stiff or tough to work or ribbon (1) by squeezing between thumb or forefinger. May leave slight smear or stain.
Moisture is available, but level is low. Irrigation needed. (2nd range) Appears dry; will not retain shape when squeezed in hand. Appears dry; may tend to make a cast when squeezed in hand, but seldom will hold together. May form a weak ball (2) under pressure but will still be crumbly. Color is pale with no obvious moisture. Pliable, forms a ball; will ribbon but usually breaks or is crumbly. May leave slight stain or smear.
Moisture is avail able. Level is high. Irrigation not yet needed. (3rd range) Color is darkened with obvious moisture. Soil may stick together in very weak cast or ball Color is darkened with obvious moisture. Soil forms weak ball or cast under pressure. Slight finger stain, but no ribbon when squeezed between thumb and fore finger. Color is darkened from obvious moisture. Forms a ball. Works easily, clods are soft with mellow feel. Will stain finger have slick feel when squeezed. Color is darkened with obvious moisture. Forms good ball. Ribbons easily, has slick feel. Leaves stain on fingers.
Soil moisture level following an irrigation. (4th range) Appears and feels moist. Color is darkened. May form weak cast or wet outline or slight wet outline or slight smear on hand. Appears and feels moist. Color is darkened. Forms cast or ball. Will not ribbon, but will show smear or stain and leave wet outline on hand. Appears and feels moist. Color is darkened. Has a smooth, mellow feel. Forms ball and will ribbon when squeezed. Stains and Smears. Leaves wet outline on hand. Color is darkened. Appears moist; may feel sticky. Ribbons out easily, smears and stains hand, leaves wet outline. Forms good ball.

(1) Ribbon is formed by squeezing and working soil between thumb and forefinger.
(2) Cast or ball is formed by squeezing soil in hand.

Back to Index

When to Irrigate

After pre-irrigation, later irrigations depend on soil, weather, and the crop.
1. Coarse or sandy soil needs water more often than loam, silt, and most clay.
2. Soil dries out faster when the weather warms up.
3. Wind speeds up soil drying.
4. Sunny weather dries soil faster than cloudy weather.
5. When plants are large, they use more water.

Since water needs change through the seasons, irrigating by calendar is not recommended.

Back to Index

Your Soil as an Irrigation Guide

One way to decide whether to irrigate is to use a shovel or auger and feel the soil where most of your crop's roots are. Table 3 shows you how to tell the soil's moisture by feel. This is a general guide only, but the method has been used for years by many farmers. Of course, you must also consider root depth, recent weather, and when the field was last irrigated.

Back to Index

Which Irrigation System is Best?

Sprinkler, furrow, and drip irrigation systems each have advantages and disadvantages as shown in Table 4 below:

Back to Index

Table 4. Which irrigation system is best?

System Advantages Disadvantages
Sprinkler Provides good soil moisture and aeration High initial cost
  Leaches excess salts Encourages weed growth between rows
  Reduces crusting, making High energy requirement
  seedling emergence easier May encourage some diseases
  Relatively uniform water Wet soil may interfere with timing of pesticide sprays application
  Can be used on unleveled land  
Furrow Most commonly used Less even water distribution
  Lowest initial cost Crusting problems
    Can concentrate salts near plants
    Requires land leveling
Drip Usually requires less water Less commonly used on vegetables
  Can cut irrigation labor cost (except strawberries, pole tomatoes)
  Allows picking and spraying while irrigating High capital cost
  May stretch limited water supply Resetting system each year costly
  Can be used on sloped land Requires some technical expertise

Back to Index

Sprinklers

Sprinklers for starting vegetables

The investment for sprinklers is high, yet a growing number of farmers use them to bring up a stand of vegetables because of the advantages listed in Table 4. They are not used for beans or corn unless they are planted shallow--about one inch deep.

How often to sprinkle vegetables

Growers usually get best results by sprinkling daily until the crop comes up. Brief (one hour) daily irrigations help soften the crust and keep salts moving downward. Of course, seedlings must not be kept waterlogged or they will die from damping off. Once the stand is established, you can move sprinklers to the next field.

How fast should sprinklers apply water?

Your sprinkler system should not apply water faster than it soaks into the soil. Putting water on faster than the soil's intake rate results in puddling, the main cause of soil crusting. Sprinkler systems that apply 0.1 to 0.15 inches per hour have proven successful on a wide range of California soils.

But on some soils--those with strong clay or silt characteristics--even that much water is too much. To prevent crusting on such soils, only about 0.06 inches per hour is applied. These low sprinkling rates don't mean you'll spend too much time sprinkling a field. That's because a system can irrigate a field in the same time at low application rates as high application rates, but you'll have to buy more lateral lines.

Weed control

It is especially important to have good weed control when using sprinklers since sprinkling also germinates a high percentage of weed seeds.

Choosing your sprinkler system

1. Select sprinklers that wet a circle at least 60 to 65 feet in diameter (conventional pressure systems, 50 to 65 pounds per square inch--psi).

2. Have a nozzle size that won't put water on faster than your soils can take it. The 5/64 to 3/32 inch size works well for most soils. On heaviest (fine textured) soils, the 5/64 inch size can prevent crusting better than the 3/32 inch size, though the smaller nozzle's pattern is affected more by wind.

3. Use 50 to 65 psi at the nozzles for uniform sprinkling and to prevent crusts. New low pressure systems at about 30 to 40 psi may have smaller droplets and cause less crusting.

4. Spacing between sprinklers along the pipe depends on wind. Sprinkler spacing should not be over 65 percent of rated diameter of spray with no wind, 60 percent of the diameter for winds up to five miles per hour, and 50 percent for winds up to 10 miles per hour. Between laterals, a spacing of 40 to 45 feet is often suggested for conventional, high pressure systems. New low pressure systems need closer spacings, usually 40' x 40'.


Choosing a sprinkler system will be easier if you use Tables 5-9. For example, if you want to avoid crusting by applying water at 0.1 inch per hour on quartermile long fields (1,320 feet), Table 3 shows that 5/64 inch nozzles at 50 psi on 30 X 40 foot spacings will give you 0.1 inch per hour.

This setup puts on 1.25 gpm (gallons per minute). See Table 5. With 1,320 foot rows and 30 foot long pipe, you'll need 44 sprinklers/row, 1320 = 44
30
Table 6 shows that three-inch pipe is more than large enough to put on the 1.25 gpm, but a two-inch line isn't big enough (maximum is 34 sprinklers at 1.25 gpm).

If you put the main line through the center of the field, a two-inch line would handle up to 34 sprinklers running each way (68 total) and that's more than enough for the 44 sprinklers needed in this example. (See Table 7.)

Back to Index

Table 5. Application rates for various nozzle sizes, pressures, and spacings.

       
Application rate at spacings (inch/hour)
Nozzle Size Pressure (psi)(1) Discharge(2) (gpm)(3) Diameter(4) of spray (feet) 20' x 40' 30' x 40' 30'x45' 40' x 40'
1/16 35 0.69 59-61 .080 .055    
1/16 40 0.74 60-62 .086 .059    
1/16 45 0.76 60-72 .091 .061    
1/16 50 0.80 61-73 .093 .064    
1/16 55 0.85 62-74 .102 .068    
1/16 60 0.88 63-75 .106 .071    
5/ 64 35 1.08 63-65 .126 .086 .077 .066
5/64 40 1.15 64-66 .134 .092 .082 .069
5/64 45 1.19 59-73 .143 .095 .085 .072
5/64 50 1.25 62-72 .150 .100 .089 .075
5/64 55 1.30 64-74 .156 .104 .094 .079
5/64 60 1.36 67-76 .164 .110 .097 .082
3/32 35 1.55 68-70   .124 .110 .093
3/32 40 1.66 69-71   .132 .118 .099
3/32 45 1.72 68-76   .137 .123 .103
3/32 50 1.80 69-77   .145 .128 .108
3/32 55 1.88 70-78   .151 .134 .113
3/32 60 1.98 71-79   .159 .141 .119
7/ 64 35 2.11 71-73   .1 69 .150 .127
7/64 40 2.25 73-75   .180 .160 .135
7/64 45 2.32 71-78   .185 .165 .139
7/64 50 2.44 72-80   .196 .174 .141
7/64 55 2.56 74-81   .205 .182 .154
7/64 60 2.69 76-82   .216 .192 .161
1/8 35 2.77 76-78   .221 .197 .167
1/8 40 2.96 77-79   .236 .211 .178
1/8 45 3.04 76-82   .243 .217 .182
1/8 50 3.22 78-82   .257 .230 .193
1/8 55 3.39 79-83   .271 .242 .204
1/8 60 3.55 80-84   .284 .253 .213
(1) PSI--pounds per inch.
(2) Showing a three-digit number here is only to indicate the progression as nozzle size and pressure increase. Sprinkler equipment seldom performs so precisely.
(3) GPM--gallons per minute.
(4) Shows range of diameters of spray for different makes and models of sprinklers.

Back to Index

Table 6. Guide for selecting size of aluminum pipe for sprinkler lateral line.

> >
 
Maximum number of sprinklers to use on single lateral line
 
30-foot sprinkler spacing
Pipe size
40-foot sprinkler spacing
Pipe size
Sprinkler Discharge (gpm) 2 inch 3 inch 4 inch 2 inch 3 inch 4 inch
.75 47 95 200 43 85 180
1.00 40 80 150 36 72 125
1.25 34 69 118 31 62 104
1.50 30 62 100 28 56 94
1.75 27 56 92 25 50 83
2.00 25 51 84 23 46 76
2.25 23 47 78 21 43 71
2.50 21 44 73 19 40 66
2.75 20 42 68 18 38 62
3.00 19 40 65 17 36 58
3.25 18 38 62 16 34 56
3.50 17 36 59 15 32 53
3.75 16 34 56 14 31 51
4.00 16 33 54 14 30 48

Can you irrigate the whole field at one time?

Table 8 tells you how many acres you can irrigate at one time using the precipitation rate you're aiming for. This table also shows how much water you'll need to order from the district if you're not pumping from a well. Be sure to order enough water so the pump doesn't run dry.

Pick the right pump

Tables 5 and 8 can help you figure the size of pump you'll need if you are designing a system. Power sources for pumps have a horsepower--hp--rating to match the pump. But many sprinkler systems used for seed germination have separate pumps designed to be driven from the power-take-off--P.T.O.--of a farm tractor. The tractor used to drive the pump must be able to provide the needed hp at the P.T.O. Table 9 shows the hp needed to drive a pump operating at 75 percent efficiency for different waterflow and pressure requirements.

Back to Index

Table 7. Guide to main line pipe sizes(1)

 
Waterflow (gpm)
Distance
(feet) 		200 400 600 800 1000 1200 1400 1600 1800
 
Pipe diameter (inches)
200 3 4 5 5 6 6 6 7 7
400 4 5 5 6 6 7 7 8 8
600 4 5 6 7 7 7 8 8 8
800 4 5 6 7 7 8 8 8 10
1000 5 6 6 7 8 8 8 10 10
1200 5 6 7 7 8 8 10 10 10
(1) Using aluminum pipe (C=120) with pressure losses ranging from @D to 15 psi, average about 10.

Back to Index

Table 8. Flow of water required to operate solid set sprinkler systems.

 
Acres irrigated per set
 
4
8
12
16
20
Precipitation Rate (inch/hour) gpm cfs(l) gpm cfs gpm cfs gpm cfs gpm cfs
.06 108 .5 217 .5 326 1.0 435 1.0 543 1.5
.08 145 .5 290 1.0 435 1.0 580 1.5 725 2.0
.10 181 .5 362 1.0 543 1.5 724 2.0 905 2.5
.12 217 .5 435 1.0 652 1.5 870 2.0 1086 2.5
.15 271 1.0 543 1.5 815 2.0 1086 2.5 1360 3.5
.20 362 1.0 724 2.0 1086 2.5 1448 2.5 1810 4.5

Back to Index

Table 9. Continuous power output required at tractor P.T.O. to pump water.

   
Flow (gpm) - hp required (3)
Pressure(2) (psi) Head(2) (feet) 100 200 300 400 500 600 700 300 1000
50 116 3.9 7.8 11.7 16 20 23 27 31 39
55 128 4.3 8.7 13 17 22 26 30 35 43
60 140 4.7 9.5 14 19 24 28 33 38 47
65 151 5.1 10 15 20 25 30 36 41 51
70 162 5.5 11 16 22 27 33 38 44 55
75 173 5.8 12 17 23 29 35 41 47 58
80 185 6.2 12 19 25 31 37 44 50 62

(1) CFS--The flow of water to the next larger 1/2 cfs that must be ordered from the water district, assuming the district accepts orders only in increments of 1/2 cfs. Actually 1/2 cfs equals 225 gpm.
(2) Including nozzle pressure, friction loss, and elevation lift.
(3) Pump assumed to operate at 75 percent efficiency.

Nozzle wear: How far gone are your sprinkler nozzles?

With heavy nozzle wear, your pump can be using about 10 to 20 percent more energy to keep up the water pressure. That translates into bigger fuel bills and more water put on than you need.

One easy way to check for worn sprinkler nozzles is to stick the shank of a drill bit the same size as a nozzle rating with the system running. If the nozzle is worn, water will spray out as follows:

Slight wear sprays 5 to 8 feet
Moderate wear sprays 10 to 15 feet with slight streams
Heavy wear sprays 10 to 15 feet with strong streams

Screen out debris

Unless your water comes from a well, it is likely to carry debris that can clog the small sprinkler nozzles. To catch the debris, use a screen with openings slightly smaller than the sprinkler size. The screen can be a commercial cone screen used on the pressure side of the pump. Or, use a home built screen box and put the suction hose into it. Either type needs cleaning from time to time.

Preparing the seedbed for sprinkler irrigation

When sprinkling, it's more important to have a well prepared seedbed--with small clods--than with furrow irrigation. (Large clods won't "melt" with sprinkler irrigation.

Placement of sprinkler pipe

If you put the pipe down to irrigate the whole field at the same time (solid set) you'll have two basic ways to lay out pipe. With the second method, less pressure is lost at the far ends, so irrigation is more uniform.

First Method
Second Method

Laying Down the Irrigation Pipes

Spreading pipe in furrows with trailer Spreading pipe across beds with trailer

 

When spacing is, for instance 30 x 40 feet, wind doesn't disturb water distribution as much if the closer spacing runs at right angles to the prevailing winds. (This is assuming you are using the usual rectangular sprinkler spacings.) To do this, pipes can be laid across beds if needed to make sprinkling more uniform to the wind.

Back to Index

Furrow Irrigation

Wide furrows vs. narrow furrows

Each furrow width has pros and cons. Broad, wide furrows are especially good for soils that don't take in water well. Wide furrows, especially when roughened or furrowed out, slow the speed of the stream and allow more time for water to soak in. Wide furrows are useful for land with slightly too much slope. Unfortunately, wide furrows may also result in wetter beds and more rots or other crop diseases if used on fields that don't need them.

How much should furrows slope?

The more uniform the slope from one end of the irrigation run to the other, the more uniform the water distribution. The preferred slope for most row crops is less than one percent.

Furrow stream size

In general, the greater the slope along the furrow, the smaller the furrow stream should be. See Table 10. The best approach to controlling furrow size is to first irrigate quickly to wet your field the length of the furrows; then reduce the flow to barely wet
furrows with little or no runoff.

Back to Index

Table 10. Maximum furrow stream size.

Percent slope Gallons per min. per furrow
2.0 5.0
1.0 10.0
0.5 20.0
0.3 30.0
0.2 50.0

How long to irrigate

The number of hours to furrow irrigate a field is about four times the time it takes to wet the furrows. So, if it takes two hours to reach the end of your furrows, with reduced flow the total irrigation time should be about eight hours. To prevent waterlogging of soils, the reverse "rule of thumb" is true. Water must reach the end of the furrows in one fourth the total expected irrigation time. See Table 11.

Back to Index

Table 11. Maximum allowable time for water to go from one end of field to other.

Soil Texture Hours
Loamy sands 2-3
Sandy loams 3-4
Fine sandy loams 4-5
Silt loams 5-6
Silty clay loams 6-7
(If water takes more time than shown with the maximum furrow size, shorten the length of the run.)

Back to Index

Table 12. Maximum recommended furrow lengths(l)

Water intake rate Probable soil texture Maximum furrow length(2)
High (1 to 3 inches per hour) Sandy, clay, sandy clay loam 660
Medium (1/2 to I inch per hour) Loam, silt loam 1,320
Medium low (1/2 to 1/4 inch) Clay, clay loam, silty clay loam 2,640
Low (1/4 or less inch per hour) Clay 2,640

(1) Does not apply to fields with slopes over 0.5 percent.
(2) Irrigation runs should not exceed 600 feet on sandy soils and about 1,300 feet on clayey soils.

After irrigating: did the water go where you wanted it to?

For routine checks on soil moisture penetration, you can use a shovel, soil probe, and tensiometers about one third in from each end of the field. To get a better idea of whether irrigation water is soaking to where you want it, occasionally dig a trench across your furrows and inspect the wetting pattern of the water. Not only will you see your soil profile, you'll also have a clearer picture of how well roots are getting the water they need. Your soil will probably look much like one of the soil profiles in the following section.

How water soaks into most kinds of soils.

Profile Description Furrow wetting Pattern Remarks
Deep sand or peat, water soaks in very fast. Not enough lateral movement of moisture to make furrow irrigation feasible.
Deep sandy clay or loam, water soaks in fast. Final water intake rate 1/2'' to 3' per hour Suitable for furrow irrigation but may require special techniques where the final water intake rate is more than 1'' per hr.
Deep clay or loam. Takes water in at 1/4" to 1" per hr. Ideal for furrow irrigation.
Slowly permeable soil on top; (e.g. clay). Water runs quickly through sub- soil (coarse sand, etc.) More water may be stored in this soil than might be expected. Abrupt soil change slows downward water movement and increases storage of water for plants.
  Unsuitable for irrigating row crops. Artificial drainage may be a solution.

Loam or clay top soil could contain salts. Permanent water table within 61 to 8' of surface. Poor drainage.

  Exceedingly hazardous to furrow irrigate. Slight rise in water table may cause concentration of harmful salts at ground
surface. Less than 31 to 41 of top soil is loam or clay soil that could contain salts. Permanent water table is a few inches below in poorly drained sand or gravel.
Exceedingly tight, deep soil.Water intake rate is 1/1011 to 1/4" per hour. Not enough water penetration for good irrigation. Possible exception is when continuously flooded for rice growing.
Tight, deep soil. Cracks allow enough water in to meet crop needs. Cracks make possible deep wetting of the soil.
Deep soil with underground sand or gravel streaks. All or parts of the row may not get enough water. Deep subsoiling may remedy the trouble.
Top soil could contain salts Soil underneath is tight and doesn't drain. Nonirrigable (except for rice) unless subsurface drainage can be provided.
Same as previous picture except slope gives drainage. Often suitable for furrow irrigation.

Back to Index

Drip Irrigation

Drip tubing or tape is the main low pressure trickle system used on vegetables. It is available at most farm supply stores. The tubing is usually buried two to six inches deep in the beds. Drip tubing (tape) almost universally emits 0.6 gallons per minute for each 100 feet of tubing. Some new low flow tubing is available at .35 gal/min/foot. In cool weather, the equivalent of one hour per day of irrigation with normal hi-flow tubing will supply enough water for most vegetables. Most growers irrigate two or three times a week in cool weather for two to four hours each time. In warm weather with maturing crops, you will need twice as much watering time. That translates into four to eight hours at each irrigation, two to three times a week. This schedule is for single row crops with one tube below or beside each row. If you put one tube below and beside two crop rows, your water requirements will be about doubled.

Back to Index

Irrigating Hardpans, Claypans, and Compacted Soils

If you have shallow soil above a hardpan or claypan, and it's too thick to be penetrated by a ripper or slip plow, you have to irrigate cautiously. If you irrigate deeper than the restricting layer, roots drown out from Phytophthora or other root rot. If you irrigate too late, plants suffer because they can't get enough water from shallow soil.

You can try to correct the problem with tillage. Otherwise, you will have to farm the field as if the crop's root system is only as deep as the impervious layer. This means irrigating more often and shallower than with deeper soils.

A similar approach is called for if your fields have been compacted. For example, if you worked the soil while it was too wet, check for a shallow root system due to compaction. If the root system is shallow (for whatever reason), you will need to consider the "more often but less deep" approach to irrigation.

Another method some growers use when roots are shallow is irrigating every other row. Then they irrigate the furrow that was left dry several days later. This cuts losses if Phytophthora or drown out is a problem.

Back to Index

Saving on the Water Bill

Some years not enough water is available at an affordable price. If you don't have enough irrigation water to go around, here are some useful ways to save water:

1. Pre-irrigate in early spring to fill the soil profile throughout the expected root depth.

2. Fertile fields are most efficient in using water. Rather than trying to stretch water over too many acres, farm only the fertile fields.

3. Control weeds. They use up water.

4. Shorten irrigation runs to avoid excessive runoff.

5. Every other row irrigation coupled with narrow or split beds can cut down both water use and in-the-row salt buildup.

6. Use tensiometers and soil augers to help decide when to irrigate. Don't irrigate by the calendar if the soil doesn't need water.

7. During cool weather, delay irrigation.

8. Laser beam grading and planing may be needed to assure uniform application of water.

9. Large amounts of water are wasted on pumping costs for well water. This is because electric pumps are not always kept repaired. While electric pumps are not cheap to repair, pumping costs of letting them go cost more. It is recommended that pumps be repaired when 200 kwh are required to lift one acre-foot 100 feet.

10. A tail water reuse system may be needed. A reuse system pumps tail water back to the head end, or to another field. Efficiencies of 87 to 92 percent have been achieved with surface irrigation using gated pipe and reuse systems.

Back to Index

Appendix: List of Equivalents

The following equivalents may be used for converting from one unit to another and for computing volumes from flow units:

Volume units

One acre-inch = 3,630 cubic feet, 27,154 gallons, 1/12 acre-foot.

One cubic foot = 1,728 cubic inches, 7,481 (approx. 7.5) gallons, weighs approx. 62.4 pounds(62.5 for ordinary calculations).

One acre-foot = 43,560 cubic feet, 325,851 gallons, 12 acre-inches.

One gallon = 231 cubic inches, 0.13368 cubic foot, weighs approx. 8.33 pounds.

Rate of flow units

One cubic foot per second = 448.83 (approx. 450 gallons per minute),
50 So. Calif. miner's inches,
40 Calif. statutory miner's inches,
1 acre-inch in 1 hour 30 seconds (approx. 1 hour), or
0.992 (approx. 1) acre-inch per hour,
I acre-foot in 12 hours 6 minutes (approx. 12 hours), or
1.984 (approx. 2) acre-feet per day (24 hours).

One gallon per minute = 0.00223 (approx. 1/450) cubic foot per second,
0.1114 (approx. 1/9) So. Calif. miner's inch,
0.0891 (approx. 1/11) Calif. statutory miner's inch,
1 acre-inch in 452.6 (approx. 450) hours, or 0.00221 acre- inch per hour,
1 acre-foot in 226.3 days, or 0.00442 acre-foot per day 1 inch depth of water over 9'0'.3, square feet in 1 hour.

Millions gallons per day = 1.547 cubic feet per second,
694.4 gallons per minute,
77.36 So. Calif. miner's inches,
61.89 Calif. statutory miner's inches.

One So. Calif. miner's inch = 0.02 (1/50) cubic foot per second,
8.89 (approx. 9) gallons per minute,
0.80 (4/5) Calif. statutory miner's inch,
1 acre-inch in 50 hours and 25 minutes, or 0.0198 (approx. 1/50) acre-inch per hour ,
1 acre-foot in 605 hours (approx. 25 days) or 0.0397 (approx. 1/25) acre-foot per day.

One Calif. statutory miner's inch = 0.025 (1/40) cubic foot per second,
11.22 (approx. 11-1/4) gallons per minute,
1.25 So. Calif. miner's inches,
1 acre-inch in 40 hours 20 minutes, or 0.0248 (approx. 1/40) acre- inch per hour,
1 acre-foot in 484 hours (approx. 20 days), or 0.0496 (approx. 1/20) acre-foot per day.

Conversion table for units of flow.

  Cubic feet per second Gallons per minute Million gallons per day So.Cal. miner's inch Calif. statutory miner's inch Acreinches per 24 hours Acrefeet per 24 hours
Cubic feet per second 1.0 448.8 0.646 5 0.0 40.0 23.80 1.984
Gallons per minute 0.00222 1.0 0.00144 0.1114 0.0891 0.053 0.00442
Million gallons per day 1.547 694.4 1.0 77.36 61.89 36.84 3.07
So. Cal. miner's inches 0.020 8.98 0.0129 1.0 0.80 0.476 0.0397
Cal. stat. miner's inches 0.025 11.22 0.0162 1.25 1.0 0.595 0.0496
Acre-inches per 24 hrs. 0.042 18.86 0.0271 2.10 1.68 1.0 0.0833
Acre-feet per 24 hrs. 0.504 226.3 0.3259 25.21 20.17 12.0 1.0

The following approx. formulas may be conveniently used to compute the depth of water applied to a field:

((cu. ft. per sec). x (hours))/(acres) = acre-inches per acre, or average depth in inches

((gal. per min.) x (hours)/(450 x acres) = acre-inches per acre, or average depth in inches

((So. Cal. miner's inches) x (hours))/(50 x acres) = acre-inches per acre, or average depth in inches

((Cal. stat. miner's inches) x (hours))/(40 x acres) = acre-inches per acre, or average depth in inches

Area equivalents.

1 hectare =

2.471 acres
  10,000 square miles
  107,640 square miles
1 acre = 0.405 hectare
  4,046.8 square meters
  4,840 square yards
  43,560 square feet
  160 square rods
1 square mile = 259.2 hectares
  640 acres
  329 rods

Linear equivalents.
1 meter = 39.37 inches, 1.094 yards
1 inch = 2.54 centimeters
1 yard = 36 inches, 3 feet, 914 meters
1 rod = 5.029 meters, 16.5 feet, 5.50 yards
1 mile = 5,280 feet, 329 rods

Back to Vegetable Crop Production