Water pressure Archive - Irrigation Blog for Do-it-yourselfer

Calculate the water pressure drop in the pipeline

Johann Kodnar — Wed, 05 Jan 2022 21:27:19 +0000

Knowing the existing water pressure at the point where the irrigation system draws water (see Planning, Chapter 1) is a good start, but only half the battle. Because this pressure does not reach the sprinklers in full. On the way to the sprinklers, the water in the pipeline has to overcome resistance that slows it down and thus reduces the water pressure. You will then find approximate values that can be used for this purpose and, alternatively, an option to calculate the loss in detail yourself.

To understand what happens to water pressure in an irrigation pipeline, imagine the following 4 levels:

Water is let out of the fully open outdoor faucet without trapping it
Water is drained from the fully opened outdoor faucet into a wide stovepipe (4 inches)
Water is drained from the fully opened outdoor faucet into a 3/4 inch irrigation pipe
Water is let out of the fully opened outside tap through a funnel into a straw

In the first scenario, the water does not encounter any resistance. This corresponds to the water pressure that is measured at the water extraction point. It is the same in the second scenario, in which the water flows into a very wide pipe. The water has more than enough space to flow unhindered, the water pressure loss is also practically zero here. In the third scenario, the diameter of the 3/4 inch pipe is no longer sufficient to allow unhindered flow. The friction results in a (slight) deceleration of the water flow and the water pressure decreases. This applies even more to the fourth extreme scenario, in which the water is passed through a straw and a large part of the existing water pressure is lost in the process. At the end of the straw there is only a small trickle with minimal water pressure.

How strong the water pressure loss is depends on the pipe diameter and two parameters in particular:

The length of the pipe
The amount of water that flows through the pipe

The following applies:

The longer the pipe, the greater the loss
The greater the amount of water, the more noticeable a restricting pipe circumference, i.e. the greater the pressure loss

Approximate calculation

You will then find approximate values with which you can work as part of your irrigation planning. These are calculated for the common 3/4 inch pipeline, which is mostly used in the private sector. This typically has a wall thickness of about 0.08 inches and an inside diameter of about 0.82 inches through which the water flows.

Sketch of a 3/4 inch irrigation pipe

The water pressure loss is given for a certain amount of water per hour. That is the amount of water that runs through the pipeline per hour. This amount of water is smaller than the amount of water that is available to you at your water connection (see bucket test for calculating this value). If you use the values of the bucket test, you are completely on the safe side and still have a small buffer.

For the various water volumes from 320 to 950 gallons per hour, the pressure drop is indicated for a pipe length of 30, 60, 90, 120 or 150 feet. Since this loss increases constantly with increasing pipe length, you can easily determine values for longer pipe lengths yourself by updating the table values. The pipe length is the length of the underground pipeline between the water extraction point and the most distant sprinkler. And always for each sector. If you divide the pipeline into several sectors, then the pressure loss has to be calculated separately for each sector and thus the pipe length of the corresponding sector is relevant.

The pressure loss in a 3/4 inch pipe is therefore roughly:

Amount of water	30 feet pipeline	60 feet pipeline	90 feet pipeline	120 feet pipeline	150 feet pipeline
320 gallons/hour	0.87 psi loss	1.74 psi loss	2.61 psi loss	3.48 psi loss	4.35 psi loss
370 gallons/hour	1.01 psi loss	2.03 psi loss	3.04 psi loss	4.06 psi loss	5.07 psi loss
470 gallons/hour	1.74 psi loss	3.48 psi loss	5.22 psi loss	6.96 psi loss	8.7 psi loss
630 gallons/hour	2.75 psi loss	5.51 psi loss	8.26 psi loss	11.02 psi loss	13.77 psi loss
740 gallons/hour	3.62 psi loss	7.25 psi loss	10.87 psi loss	14.50 psi loss	18.12 psi loss
950 gallons/hour	5.80 psi loss	11.60 psi loss	17.40 psi loss	23.20 psi loss	29.00 psi loss

The amounts of water listed in the table correspond to bucket test values of 30, 25, 20, 15, 13 and 10 seconds. 15 seconds is a good value in practice, anything closer to 10 seconds is a very good value. 30 seconds are very close to the limit for meaningful use.

The table shows that the pipeline hardly slows down with smaller amounts of water, but the pressure loss increases sharply with larger amounts of water. If you have such a potent water extraction point, it could be worthwhile to lay a 1 inch pipeline instead of the 3/4 inch standard pipeline. The pressure loss of a 1 inch pipeline is only about a third of that of a 3/4 inch pipeline.

Curves

The calculated losses are based on straight pipes. In a real scenario, however, you also have to incorporate one or the other curve. If these curves are executed as gently as possible, i.e. with a large radius, as recommended, then they are of little importance in the calculation. With smaller amounts of water, the loss is hardly measurable, with the largest amount of water of 950 gallons / hour it is only 0.29 psi, with 740 gallons only 0.14 psi. So you can either neglect that completely or – if you calculate with large amounts of water – simply add 0.70 or 1.45 psi to it.

T-pieces

Somewhat greater ist the effect of using L- or T-pieces, ie “L” or “T” -shaped connectors, with which a pipeline section can be guided sharply at a 90 degree angle around the curve or can be split in two pipeline sections.

Example of a T-piece connector with which a water line is divided into two water lines at a 90 degree angle

Due to the sharp 90 degree corners, there is more pressure loss here than when the water is guided gently through a long curve. Again in relation to the standard 3/4 inch pipeline, the pressure loss is not dramatically high in absolute terms, but about twice as large as in the curve described above:

Amount of water	Pressure loss
320 gallons	0.07 psi
370 gallons	0.14 psi
470 gallons	0.14 psi
630 gallons	0.29 psi
740 gallons	0.43 psi
950 gallons	0.58 psi

For example, if you have 740 gallons of water and three T-pieces in a sector, you simply add 1.29 psi pressure loss.

Exact calculation with pressure-drop.com

If you want to know exactly, the website www.pressure-drop.com offers an online calculator with which you can exactly calculate the water pressure loss in pipes. The calculator is preset as standard for the most common “straight pipes” application. In order to calculate the pressure loss, the user has to make three entries:

The pipe diameter (again the inner pipe diameter is meant)
The length of the pipe
The volume flow (= the amount of water that flows through the pipeline)

Below is an example for a standard 3/4 inch pipe, with a pipe length of 100 feet and a volume flow of 740 gallons / hour:

Pressure loss calculator – the entries to be made are marked in red

After confirming by clicking on the “Calculation” button, the pressure loss is shown:

Pressure loss result

You can also calculate the pressure loss for curves and L-pieces (menu item “Bends”) and T-pieces (“Brandings of current”) and for more complex things such as narrowing from a larger to a smaller pipe (“Changes of section”). The application is very quick and easy, a really recommendable and useful online tool!

Link tip: Pressure drop online calculator

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Determine the water pressure with a manometer – this is how it works

Johann Kodnar — Fri, 19 Nov 2021 07:21:28 +0000

In order to ensure that the garden can be irrigated with the available water source, not only the amount of water that can be drawn from the water source per hour is relevant, one also needs to know the available water pressure.

In order to measure the correct one, a little theory is necessary: In principle, one can distinguish between three different types of water pressure when using the water from a tap:

The water pressure with which the house is connected to the public water network
The water pressure at which the water comes out of the outside tap
The water pressure in the irrigation pipeline

The counterparts when using a garden pump are the following 3:

The maximum delivery pressure of the garden pump used
The water pressure at which the water comes out of the pump
The water pressure in the irrigation pipeline

The pressure is highest in the first stage and then decreases from stage to stage. The pressure that is ultimately relevant for irrigation is always the last. This pressure is used to derive the amount of water available in the irrigation system and the range of the sprinklers.

Water pressure in the public water network or delivery pressure of the garden pump

Let me just give you some information about water pressure of the first type, i.e. the one with which the house is connected to the public water network. The easiest way to find out this is by looking at the manometer installed at the connection point. If you do not have access to the connection point or if there is no manometer installed, you can also inquire about the water pressure from the responsible water supplier.

The delivery pressure of a water pump can be found in the operating instructions for the pump or on the pump itself or can be found out by researching the Internet.

The water pressure immediately after being connected to the public water network is greater than that at the tap, as the pressure decreases due to the pipe runs that the water must go through in the house before it comes to the water connection for irrigation. The same applies to pumping with a water pump: With this, the specified maximum delivery pressure is that which the pump would create if it didn’t have to pump up the water. Since the water is usually pumped from the depths, the water pressure decreases due to the height difference to be overcome (14.5 psi pressure loss per 3.3 feet of depth).

Measurement of the water pressure at the tap or at the pump outlet

The measurement of the pressure at the tap or pump outlet is suitable to get an impression of whether the water source is in principle suitable for the implementation of irrigation. For this purpose, water pressure gauges are offered on the Internet, which cost from around 10 to 15 USD.

Below is an excerpt from the range of such water pressure gauges on Amazon:

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The function of the water pressure gauge is very simple:

When measuring on a tap:

Step 1: Screw the water pressure gauge onto the tap

The pressure gauge is usually supplied with a small adapter, with which you can reduce a 3/4 inch thread to a 1/2 inch thread if necessary – depending on the outlet of the tap.

Intermediate piece from 3/4 inch to 1/2 inch

Step 2: Turn the tap on fully

Then wait a little to rule out short-term fluctuations. No consumer in the house, such as a washing machine or similar, should be active during the measurement.

Step 3: Read the psi value from the manometer and note it down

Often a bar value is also given on the pressure gauge, which is not relevant for our purpose. This is the usual pressure unit in Europe, 14.5 psi corresponds to 1 bar.

When measuring on a garden pump:

Process exactly as before, only that the pressure gauge has to be screwed onto the pump outlet. Most pumps have an outlet with an internal thread of 1 inch. However, the pressure gauge requires a 3/4 inch external thread. So you also need a suitable connector. Then simply screw on the pressure gauge and carry out the test as described above. Note: Switch off the pump immediately after reading it! Since no water flows through the pump during the measurement, there is no cooling and the pump could become hot when running for a long time.

Measurement of the water pressure in the irrigation pipeline

This would now determine the pressure at the water source, which, together with the measurement of the amount of water, gives an initial indication of how potent the water source is. For the planning of an irrigation system, however, the pressure that is actually available in the pipeline is relevant. This is smaller because it is slowed down by the resistance in the pipeline pipes running through it. See the article Calculating the pressure loss in the pipeline.

And subsequently, the question of how the available pressure in the pipeline is used is relevant: which part of the pressure acts on the side walls of the pipeline pipe and is therefore available to the sprinklers and which part drives the water forward and thus provides a larger amount of water (flow pressure). The two variables are inversely proportional to one another, the greater the pressure on the pipe walls, the lower the flow pressure and vice versa. This interaction and how the appropriate pressure on the pipeline for the irrigation system and the resulting amount of water can be determined can be read in the blog post Determine water flow at certain water pressure.

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