Bernoulli appliance to garden hose

In summary: Pressure will vary linearly along the hose. If you restrict the exit such that P2>0, then P1 will increase as well, but not by the same amount, as your velocity will be reduced, and pressure differential per unit of length will be reduced as well.What your calculating is a delta velocity. The difference in pressure causes net force which drives the fluid. If the diameter stays constant, then the velocity also must due to conservation of mass (for incompressible flow).However, when given a pressure difference, you must
  • #1
Ferex
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I know the topic has been dealt in the past, I read it but still couldn't extrapolate a satisfying answer.
I would like to know how Berboulli equation applies to a hose without restrictions in which fluid (water) exits at atmospheric pressure, the typical garden situation without any nozzle.
I have, let's suppose 3 bars at the initial section (1) and 0 bars (atmospheric pressure) at the discharge section (2). We consider z1 = z2, p1 = 3 bars, p2 = 0, the question is: does v1 = v2?

The second question is: if I put my finger at the exit section causing a little reduction in the section (but still allowing water flow) what happens to pressure??

Many thanks, Ferex
 
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  • #2
Bernoulli's equation would not be applicable in your case unless you had two hoses of differing diameters, at which point the smaller diameter hose would have a faster flow and less pressure, regardless of which hose is first. It's really only applicable to the difference between the pressures immediately before and after the junction between the hoses.

Navier-Stokes, however, covers how pressure varies as a function of flow rate, but for incompressible flows of Newtonian fluids, such as water, it simiplifies to a linear solution involving pressure gradient, viscosity, and other body forces such as smoothness of the pipe or hose.

For a rigid hose, v1 is nearly equal to v2, the very slight difference being due to the very slight compressibility of water. For all practical garden hose purposes, however, they're equal, as water is considered to be incompressible for pressures encountered in a garden hose! Even at the 4 km depth in the ocean, at approximately 6,430 psi, there's only a 1.8% decrease in volume.

Pressure will vary linearly along the hose. If you restrict the exit such that P2>0, then P1 will increase as well, but not by the same amount, as your velocity will be reduced, and pressure differential per unit of length will be reduced as well.
 
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  • #3
What your calculating is a delta velocity. The difference in pressure causes net force which drives the fluid. If the diameter stays constant, then the velocity also must due to conservation of mass (for incompressible flow).

However, when given a pressure difference, you must consider where that pressure is measured. That pressure is going to be at a location where the velocity is zero. Think of the water tower or some other plenum where the velocity of the fluid can be essentially negligible.

As you open the spigot, suddenly there is a delta P across the line, and the net force drives the fluid. So, to answer, no v1 does not equal v2 because they are taken at location of differing pressures (assuming z1=z2 of course).
 
  • #4
Ferex: In scenario 1, the hose outlet is perfectly straight, with no expansion nor contraction. Therefore, the exit head loss, he, is he = 0. Section 1 is immediately after the hose inlet, section 2 is immediately before the hose outlet, and section 3 is immediately after the hose outlet. The pressure at section 1 is given in post 1, p1 = 300 000 Pa.

p2 = p3 = 0, v1 = v2 = v3 = v, z1 = z2 = z3. For water at T = 15 C, density is rho = 998.7 kg/m^3, and absolute viscosity is mu = 1.14e-3 Pa*s. Let's assume the hose absolute roughness is e = 0.010 mm, the hose diameter is D = 15 mm, and the hose length is L = 5 m. The relative roughness is therefore e/D = 0.0007. Friction head loss is hf = 0.5*f*L*(v^2)/D. Initially assume fully turbulent flow. Therefore, going into the Moody chart, we see f = ~0.0180 for e/D = 0.0007. The Bernoulli equation, written between sections 1 and 2, is therefore as follows.

p1/rho + 0.5*v1^2 = p2/rho + 0.5*v2^2 + hf + he​

You could also divide through the above equation by g, if you wish, but I did not. Therefore, (p1 - p2)/rho + 0.5(v1^2 - v2^2) = hf + 0. This gives, p1/rho + 0 = 0.5*f*L*(v^2)/D. Solving for v gives, v = [2*p1*D/(rho*f*L)]^0.5. Therefore, we currently have v = {2(300 000 Pa)(0.015 m)/[(998.7 kg/m^3)(0.0180)(5 m)]}^0.5 = 10.01 m/s.

Now compute the Reynolds number. Re = rho*v*D/mu = 998.7*10.01*0.015/1.14e-3 = 1.32e5. Going back into the Moody chart for e/D = 0.0007, we see f = 0.0191, which does not match our previous value. Therefore, recompute v = [2*300 000*0.015/(998.7*0.0191*5)]^0.5 = 9.714 m/s.

Now Reynolds number becomes Re = 1.28e5. Going back into the Moody chart, we see f = 0.0192, which reasonably matches our previous value. Therefore, v = [2*300 000*0.015/(998.7*0.0192*5)]^0.5 = 9.689 m/s. The flow rate is Q = v*A = 0.001 712 (m^3)/s = 1.71 L/s.

In scenario 2, where the hose exit is contracted by your finger, v1 = v2 ≠ v3, p1 ≠ p2 ≠ p3, p3 = 0. Let v = v1 = v2. Let's say D3 = 10.61 mm; therefore, A3/A2 = 0.50. Compute the hose exit head loss, he, which will now be nonzero due to the outlet contraction. he = 0.5*kc*v3^2, which would perhaps be he = 0.5*0.2*v3^2 (?). We know v3 = v2*A2/A3 = 2*v; therefore, he = 0.4*v^2. Now write the Bernoulli equation between sections 1 and 3, and solve for v, which gives v = {(p1/rho)/[(0.5*f*L/D) + 1.9]}^0.5. Solve for v iteratively, as we did before. I ended up with f = 0.0213, and v = 7.424 m/s. Now write the Bernoulli equation between sections 1 and 2, and solve for p2. Simplifying gives, p2 = p1 - 0.5*rho*f*(L/D)*v^2 = 300 000 - 0.5*998.7*0.0213*(5/0.015)*7.424^2 = 104 590 Pa = 104.6 kPa.
 
  • #5
Oh yes! great work! I couldn't be more satisfied, thanks for your work nvn, and thanks to others who answered me. Now everything is clear!
 
  • #6
I am thinking p1 = 300 kPa is too high at section 1 to be realistic. I am thinking 200 kPa would be a more realistic maximum value; and 100 kPa might be a realistic minimum value (?). You can buy an inexpensive pressure gauge at hardware stores or home supply stores. At the same stores, you can also buy a T (or Y) adapter that temporarily screws onto your outdoor water tap (spigot), where you normally attach your garden hose. Attach the T adapter to your outdoor tap, then screw your water pressure gauge and garden hose onto the adapter. Also buy a cap that screws onto the adapter, or garden hose, so you can measure static pressure, when no water is flowing.

Now fully open your outdoor tap valve, to measure the dynamic water pressure, p1, at section 1 while the water is flowing through your garden hose. This would give us a better p1 value at section 1 for the above calculations. We would also need the exact inside diameter of the garden hose, measured to the nearest tenth of a millimeter.

You can also measure the average horizontal travel distance of the output stream in scenario 1. From this, we can compute the stream exit velocity, v3, at section 3, knowing that the flight time will be exactly t = (2*h/g)^0.5, where h = horizontal stream outlet height.

Also measure the dimensions of a large container, compute the container volume, then measure the time for the scenario 1 output stream to fill the container. This would give us the garden hose flow rate.

Similarly, you can attach the T adapter and water pressure gauge to section 2 of the garden hose, to measure the dynamic water pressure at section 2 in scenario 2.

If anyone ever tries this experiment, and posts any of the above measurements here, we could rerun the calculations in post 4, to obtain more realistic values.
 

FAQ: Bernoulli appliance to garden hose

1. How does the Bernoulli principle apply to a garden hose?

The Bernoulli principle states that as the speed of a fluid increases, its pressure decreases. In the case of a garden hose, as the water flows through the nozzle, its speed increases, causing a decrease in pressure. This decrease in pressure creates a suction force that draws in more water from the hose, resulting in a stronger and more consistent flow.

2. What is the purpose of the Bernoulli appliance on a garden hose?

The Bernoulli appliance, also known as a nozzle or sprayer, is used to increase the speed of the water flowing through the hose. This increase in speed creates a decrease in pressure, allowing for a stronger and more focused spray of water.

3. How does the shape of the nozzle affect the Bernoulli principle?

The shape of the nozzle plays a crucial role in the application of the Bernoulli principle. A constricted nozzle, such as those found on garden hoses, increases the speed of the fluid, resulting in a decrease in pressure. On the other hand, a wider nozzle would decrease the speed and increase the pressure, resulting in a weaker spray.

4. Can the Bernoulli principle be applied to other household appliances?

Yes, the Bernoulli principle can be applied to various household appliances such as vacuum cleaners, air blowers, and even hairdryers. In these appliances, the principle is used to create suction or blowing forces by increasing or decreasing the speed of air flow.

5. Are there any limitations to the application of the Bernoulli principle on a garden hose?

One limitation of the Bernoulli principle on garden hoses is that it only works effectively when there is a consistent flow of water. If the flow of water is interrupted, the pressure may not decrease enough to create the desired suction force. Additionally, the principle may not be as effective for low-pressure water sources or when there is a significant change in elevation.

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