KR200438619Y1 - Air chamber system for prevention of water hammer - Google Patents

Abstract

The water hammer prevention air chamber system according to the present invention connects the main pipe passage 1 through which the fluid flows and the air chamber 2 by the connecting pipe 3, and the gate valve 1 (4) provided in the connecting pipe (3). A water hammer relief check valve 20 is installed between the gate valve 2 and the gate valve 2, and the water hammer relief check valve 20 includes a plurality of check valves 21 that are opened and closed only in the direction of the main pipe line 1. Since the processing orifice 22 is formed to reduce the pressure and flow rate of the fluid flowing from the main pipeline 1, the capacity and thickness of the air chamber 2 can be reduced, so that the space utilization for the installation of the air chamber 2 can be reduced. This improves and has the effect of economic cost reduction.

In addition, since the same function as that of the existing side pipe 7 can be performed without forming the side pipe (bypass) 7, the space utilization due to the omission of the side pipe 7 is improved, and the economic cost is reduced. Has the effect of.

Pump, Water Hammer, Air Chamber, Check Valve, Orifice

Description

Water chamber prevention air chamber system {AIR CHAMBER SYSTEM FOR PREVENTION OF WATER HAMMER}

1 is a schematic diagram schematically showing the structure of a conventional main pipe and an air chamber connecting pipe,

Figure 2 is a schematic diagram schematically showing that the side pipe is added to the structure of the conventional main pipe and the air chamber connecting pipe,

Figure 3 is a schematic diagram schematically showing the structure of the water hammer prevention air chamber system according to the present invention,

4 is a cross-sectional view of the water hammer relief check valve installed in the air chamber connector of FIG.

5 is a front view of the water hammer relief check valve of FIG.

<Description of Symbols for Main Parts of Drawings>

1: Main line 2: Air chamber

3: connector 4: gate valve 1

5: check valve 6: gate valve 2

7: side pipe 8: gate valve 3

9: Orifice 10: Gate Valve 4

20: check valve for water hammer relief 21: check plate

22: machining orifice 23: hinge

The present invention relates to a water hammer prevention device, and in particular, the main pipe flows through which the fluid flows and the air chamber is connected by a connecting pipe, a plurality of processing orifices on the check plate between the gate valve 1 and the gate valve 2 provided in the connecting pipe It is provided with a water hammer relief check valve is formed to reduce the pressure and flow rate of the fluid flowing from the main pipeline to a water hammer prevention air chamber system.

In general, a water hammer in which the pressure in the pipe rises or falls due to a sudden change in the flow rate in the pipe is called a water hammer.

When the pump stops suddenly, suddenly loses power due to a power failure during normal operation, or when the valve opening is changed rapidly, the pressure increases or decreases rapidly when the flow velocity in the pipeline changes suddenly. Will cause.

In addition, when the pressure wave reciprocates from one end to the other due to a sudden flow rate change in the pipeline, the pressure in the pipeline causes the fluid to fall below the saturated steam pressure depending on the shape of the pipeline, resulting in the formation of vapor cavity. (Column separation) will result.

The water column separation phenomenon means that when the flowing liquid stops suddenly, a pressure drop of the liquid occurs, and the liquid rapidly boils to generate bubbles in the liquid.

Therefore, if the pressure in the pipeline is lower than atmospheric pressure, it may cause buckling in the pipeline, high pressure may be caused when the water column separated by the steam cavity is recombined, and the pipeline may be damaged. Abnormally rising pressure in the pipe or rupture of pumps, valves, piping, and other facilities may result in flooding of the pump station.

An apparatus commonly used to avoid or mitigate such water hammer is the air chamber.

The air chamber stores an appropriate amount of liquid in the pressure vessel and pressurized air or gas thereon to supply liquid to the pipeline when the pressure in the pipeline drops, thereby preventing water separation and effectively suppressing a sudden rise in pressure. .

In addition, the air chamber is highly adaptable to pressure waves and responds immediately to any pressure fluctuations, greatly improving the stability of the system.

In general, the air chamber is composed of a shell (shell) forming a body, a plurality of sensing devices for measuring the water level, a control device for controlling the water level, etc., as shown in FIG. The chamber 2 is connected by a connecting pipe 3, which serves to transfer the fluid, in which the pressure or negative pressure generated in the main pipe line 1 is formed, to the air chamber 2. .

At this time, the connection pipe 3 is provided with a gate valve 1 (4) to control the fluid transfer of the main pipe line 1 and the air chamber (2).

That is, since the air chamber 2 is intended to protect the pump and other equipment in the event of water hammer, the gate valve 1 (4) should always be open and ready to receive water shock, and the air chamber 2 If a problem occurs in the above or the pipeline, the gate valve 1 (4) is closed to protect the air chamber (2).

However, in the conventional air chamber (2) facility having only the gate valve 1 (4) in the connecting pipe (3), a large amount of fluid flows in or out during a short period of time when water hammer occurs, resulting in water hammer and negative pressure. Separation can be alleviated, and since only the connecting pipe 3 is installed, it can be installed even in a narrow space and has the advantage of being not complicated. On the other hand, the water hammer generated in the main pipeline 1 is directly connected to the air chamber 2. As a large amount of fluid and a large pressure flow into the air chamber 2 instantaneously, the capacity of the air chamber 2 increases and the thickness of the air chamber 2 becomes thick, which takes up a lot of space, Falling, there is a problem that the economic efficiency is lowered by increasing the cost of the facility.

The inflow flow rate can be obtained by the following equation.

Where Q = flow rate, A = pipe cross-sectional area, and v = inlet flow rate.

Therefore, the cross-sectional area of the orifice whose diameter decreases in the above flow rate formula allows the inflow flow rate to be about 70% of the design flow rate. Therefore, even if the water in the pipeline flows into the air chamber 2, the water flow is instantaneously generated. Since only about 70% is introduced, even if the size of the air chamber 2 is small, there is no problem in performing the function.

On the other hand, the thickness of the air chamber 2 is determined by the following equation.

Where tc = minimum calculated shell thickness (mm), p = design pressure (kg _f / cm ² ), d = inner diameter of the shell (mm), E = welding efficiency (%), sa = permissible tensile strength (kg _f / cm ² ), Ca = corrosion tolerance (mm).

In the formula for obtaining the thickness of the air chamber 2 above, the thickness of the shell is proportional to the pressure, so that when the pressure flowing into the air chamber becomes small, the thickness of the air chamber 2 becomes thin.

In addition, there is a sudden change in the water level and pressure of the air chamber (2) to damage the accessories such as the sensing device (pressure sensor, pressure transmitter, water gauge, level transmitter, etc.) or the control device (safety valve, compressor, etc.). There is a problem that results.

On the other hand, the newly proposed method by improving the conventional air chamber connector is a connector structure to which a by-pass (7) as shown in Figure 2 is added.

The connection pipe (3) has a gate valve (1) for blocking the inflow of fluid from the main conduit (1), a check valve (5) for controlling the inflow of fluid, to block the outflow of the fluid from the air chamber (2) Gate valve 2 (6) is provided.

In addition, the side pipe (7) has a smaller diameter than the connecting pipe (3), the gate valve 3 (8) for blocking the flow of fluid from the main pipe (1), the orifice (9) and the air chamber made of a small diameter A gate valve 4 (10) for blocking the outflow of fluid from (2) is provided.

Accordingly, the fluid flowing from the main pipe line 1 flows through the side pipe 7 to primarily reduce the pressure and speed thereof, and then the pressure and flow rate of the fluid in the process of passing through the orifice 9 having a reduced diameter. Since it is secondaryly reduced and transmitted to the air chamber 2, the capacity of the air chamber 2 can be reduced due to the reduction of the flow rate, and the thickness of the air chamber 2 can be made thin due to the reduction of the inflow pressure. Since it can be, it shows a differentiated effect in terms of space utilization and economics for the installation of the air chamber (2).

However, the connection pipe structure to which the side pipe 7 is added has a problem in that additional costs of a predetermined space and facilities are required for the installation of the side pipe 7, and in particular, in a narrow space, it is difficult to configure the side pipe 7. There is this.

The present invention has been made in order to solve the above problems, by using a connection pipe equipped with a water hammer relief check valve formed with a plurality of processing orifices on the check plate when the main pipe flows through the fluid chamber and the air chamber, It is an object to provide a water hammer prevention air chamber system that can reduce the capacity and thickness of the air chamber while at the same time maintaining the efficiency of water shock prevention by mechanical changes, while limiting the installation space.

The water hammer prevention air chamber system according to the present invention for achieving the above object is a water shock prevention device for connecting the main pipe and the air chamber through which the fluid flows by the connecting pipe, the connecting pipe to block the fluid flowing from the main pipe The gate valve 1, a water hammer relief check valve formed with a plurality of processing orifices in the check plate to restrict the flow of the fluid, and the gate valve 2 for blocking the fluid flowing out of the air chamber, the check plate A pair of processing orifices are formed symmetrically in the center and opened and closed in the direction of the main pipeline by the hinge at the upper side, and prevents the rapid inflow of the fluid from the main pipeline, and rapidly discharges the fluid from the air chamber. To be able to, characterized in that it is installed inclined to one side.

Hereinafter, a water hammer prevention air chamber system according to the present invention will be described in detail with reference to the accompanying drawings.

Figure 3 is a schematic diagram showing the structure of the water hammer prevention air chamber system according to the present invention, Figure 4 is a cross-sectional view of the water hammer relaxation check valve installed in the air chamber connecting pipe of Figure 3, Figure 5 is a water hammer of Figure 4 Front view of a relief check valve.

As shown in FIG. 3, the present invention is connected to a main pipe 1 through which a fluid flows and an air chamber 2 preventing water shock by a connecting pipe 3 having a reduced diameter compared to the main pipe 1. It is. At this time, the main pipe line (1) and the connecting pipe (3), the connecting pipe (3) and the air chamber (2) can maintain the airtightness by the expansion pipe (not shown), etc. to facilitate installation without fluid leakage. To be connected.

The connection pipe 3 is provided with a gate valve 1 (4) for blocking the fluid flowing from the main pipe line 1, and a gate valve 2 (6) for blocking the fluid flowing out of the air chamber (2), the gate Between the valve 1 (4) and the gate valve 2 (6) is provided with a water hammer relief check valve 20 in which a plurality of processing orifices 22 are formed on the check plate 21.

Since the structure and function of the gate valve 1 (4) and the gate valve 2 (6) is the same as that of the prior art, further description is omitted.

The water hammer relief check valve 20 is newly created to achieve the object of the present invention, a pair of processing orifices 22 are formed symmetrically in the center and opened and closed in one direction by an upper hinge 23. Since the check plate 21 is provided, the inflow and outflow of the fluid is automatically controlled according to the direction in which the fluid flows.

On the other hand, since the check plate 21 is rotated about the hinge 23 in a state in which the check plate 21 is installed to be inclined to one side, the check plate 21 is always opened only in the direction of the main pipe 1 from the air chamber 2. This partially blocks the fluid flowing into the air chamber 2 from the main pipe line 1, while the negative pressure generated in the main pipe line 1 discharges a large amount of the fluid inside the air chamber 2 to quickly solve the problem. Technical features of the present invention.

Therefore, when a water shock occurs on the main pipe line 1 and the fluid rapidly flows into the connecting pipe 3, the check plate 21 is automatically closed, so that the pair of fluid is formed at the center of the check plate. The orifice 22 is transmitted to the air chamber 2 with the flow rate and pressure reduced.

At this time, the diameter of the processing orifice 22 should be determined according to the diameter of the connecting pipe (2) so as to pass 65 to 75% of the flow rate of flow through the connecting pipe (2).

This reduces the inflow flow rate by about 70% by the processing orifice 22 to protect the air chamber 3 even when a momentary water hammer occurs in which the inflow flow rate of the connecting pipe 3 exceeds the design flow rate. For sake.

On the other hand, when a sudden negative pressure is generated on the main pipeline 1, the check plate 21 is automatically opened so that a large amount of fluid flows from the air chamber 2 to the main pipeline 1 instantaneously, The negative pressure generated in the main conduit 1 is released.

The present invention as described above is not limited to the specific embodiments described above, any person having ordinary knowledge in the field to which the present invention belongs without departing from the gist of the present invention claimed in the claims may be variously modified. will be.

The water hammer prevention air chamber system according to the present invention connects the main pipe passage 1 through which the fluid flows and the air chamber 2 by the connecting pipe 3, and the gate valve 1 (4) provided in the connecting pipe (3). A water hammer relief check valve 20 is installed between the gate valve 2 and the gate valve 2, and the water hammer relief check valve 20 includes a plurality of check valves 21 that are opened and closed only in the direction of the main pipe line 1. Since the processing orifice 22 is formed to reduce the pressure and flow rate of the fluid flowing from the main pipeline 1, the capacity and thickness of the air chamber 2 can be reduced, so that the space utilization for the installation of the air chamber 2 can be reduced. This improves and has the effect of economic cost reduction.

In addition, since the same function as that of the existing side pipe 7 can be performed without forming the side pipe (bypass) 7, the space utilization due to the omission of the side pipe 7 is improved, and the economic cost is reduced. Has the effect of.

Claims (3)

In the water shock prevention device for connecting the main passage through which the fluid flows and the air chamber by a connecting pipe, The connecting pipe 3 has a water hammer mitigation formed with a plurality of processing orifices 22 in the gate valve 1 (4) for blocking the fluid flowing from the main pipe (1), and the check plate 21 for restricting the flow of the fluid It includes a check valve 20 and a gate valve 2 (6) for blocking the fluid flowing out of the air chamber (2), The check plate 21 has a pair of processing orifices 22 formed at the center thereof in a symmetrical direction, and is opened and closed in the direction of the main conduit 1 by an upper hinge 23, and the fluid in the main conduit 1 Is prevented from rapidly entering, and the fluid from the air chamber (2) so as to be discharged rapidly, water hammer prevention air chamber system, characterized in that installed inclined to one side. The method of claim 1, The diameter of the processing orifice (22) is water hammer prevention air chamber system, characterized in that determined according to the diameter of the connecting pipe (2) to pass through 65 to 75% of the flow rate through the connecting pipe (2). delete

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