What is the head loss formula for sudden contraction?

What is the head loss formula for sudden contraction?

Head loss due to contraction is 0.5v2^2/2g. Loss if head due to sudden contraction(hc)=Kv^2/2g. Where k=coefficient of contraction. So, the answer should be hc=0.62*v2^2/2g=0.31v2^2/2g.

What is head loss due to sudden expansion?

Loss of head due to sudden enlargement: This is the energy loss due to sudden enlargement. Sudden enlargement in the diameter of pipe results in the formation of eddies in the flow at the corners of the enlarged pipe (Fig. 1). This results in the loss of head across the fitting.

Why is the loss more in a sudden expansion than sudden contraction?

Explanation: Loss Due To Sudden Expansion: It is a type of minor loss at the end of a pipe or when smaller diameter pips meet large diameter pipe due to sudden enlargement in the area of flow. It is larger than loss due to sudden contraction because Eddies are formed at the entrance of a large diameter pipe.

What causes head loss in pipe flow?

The head, pressure, or energy (they are the same) lost by water flowing in a pipe or channel as a result of turbulence caused by the velocity of the flowing water and the roughness of the pipe, channel walls, or fittings. Water flowing in a pipe loses head as a result of friction losses.

What is sudden contraction?

Introduction. The sudden contraction in the area/diameter of a fluid jet after it emerges from a circular aperture in a pressurized reservoir is called as vena contracta. Coefficient of contraction is the ratio of the cross sectional area of the jet at the vena contracta to the area of the orifice.

What is sudden expansion?

A sudden expansion occurs whenever a smaller duct is joined to a larger duct. In this lab, you will study the behavior of air flowing through a sudden expansion.

What affects head loss?

The amount of head loss depends on many factors such as the flow velocity, pipe length and diameter, and the roughness of the pipe, which determines the friction variable and the Reynolds number in the flow. Although the head loss represents a loss of energy, the fluid’s total loss of energy is not certain.

Which equation is used to derive an expression for head loss in the sudden expansion and sudden contraction sections of the pipe network?

In fluid dynamics the Borda–Carnot equation is an empirical description of the mechanical energy losses of the fluid due to a (sudden) flow expansion. It describes how the total head reduces due to the losses.

What is contraction loss?

[kən′trak·shən ‚lȯs] (fluid mechanics) In fluid flow, the loss in mechanical energy in a stream flowing through a closed duct or pipe when there is a sudden contraction of the cross-sectional area of the passage.

How do you reduce head loss in a pipe?

Tips for Reducing Head Loss

1. Keep flow velocity around the optimum value of 1 m/s.
2. Consider changing old pipes into new.
3. Keep the pipe length short.
4. The pipe diameter is decisive for system head loss.

Does viscosity affect head loss?

Overall head loss in a pipe is affected by a number of factors which include the viscosity of the fluid, the size of the internal pipe diameter, the internal roughness of the inner surface of the pipe, the change in elevation between the ends of the pipe, bends, kinks, and other sharp turns in hose or piping and the …

How do you calculate head loss in piping?

How to calculate head loss:

1. Head Loss (Pc) = [Equiv. pipe length + Installation pipe length] x Pc % / 100 x Corrector.
2. Equivalent pipe length. This refers to the equivalent length of the non-straight pipework when compared to straight pipes (in metres).
3. Installation pipe length.
4. Pc % and Corrector.

What is head loss affected by?

Figure 1. Minor head loss caused by obstacles such as changes in the shape of the pipe and elbow joints. The amount of head loss depends on many factors such as the flow velocity, pipe length and diameter, and the roughness of the pipe, which determines the friction variable and the Reynolds number in the flow.

Which of the following are factors that contributed to head loss?

What is head loss of pipe?

The head loss is a measure of the reduction in the total head of the fluid as it moves through a pipeline. Head loss along the pipe wall is called friction loss or head loss due to the friction.

What is piping head loss?

The pipe head loss is the frictional loss in the hydro pipeline, expressed as a fraction of the available head. Water (like any viscous fluid) flowing through a pipe experiences a loss in pressure due to friction.

What is the relationship between Reynolds number and head loss?

Since the Reynolds number is inverse proportional to viscosity, the resulting head loss becomes proportional to viscosity. Therefore, the head loss is reduced by half when the fluid’s viscosity is reduced by half when the flow rate and thus the average velocity are held constant.

Does head loss affect flow rate?

A rule of thumb for pipeline head loss is doubling the flow rate increases the head loss by a factor of four. This is because the flow rate is raised to the second power. As Table 1 shows, doubling the flow rate doubles the fluid velocity and Reynolds number.

What is the main cause of major loss in pipes?

“Major” losses occur due to friction within a pipe, and “minor” losses occur at a change of section, valve, bend or other interruption.