KR101573059B1 - Water hammer prevention apparatus - Google Patents

Abstract

The present invention relates to a water hammer prevention device for preventing a water hammer phenomenon, which is installed in a pipe through which a liquid, which is a non-compressible fluid such as water or oil, flows. The water hammer prevention device has a lower opening, A first port including a first body having through holes formed therein and a mounting flange coupled to a lower end of the first body so as to couple the first body to a pipe through which the fluid flows; A second body that is opened at a lower portion to allow a portion of an upper portion of the first body to enter a predetermined depth and is closed at an upper portion thereof and has a second accommodation space therein; A second port including a second engagement flange coupled to a lower end of the second body for engagement with the first engagement flange; And a buffer part interposed between the first port and the second port to expand the volume when the pressure of the fluid acts on the pipe, thereby relieving the shock caused by the pressure of the fluid.
The water hammer prevention device according to the present invention is excellent in pressure resistance, airtightness and durability as well as constantly absorbing impact through the bellows even when the pressure change is severe or is used for a long time, and semi-permanent use is possible.

Description

Water hammer prevention apparatus

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a water hammer prevention device, and more particularly, to a water hammer prevention device installed in a pipe through which liquid, which is an incompressible fluid such as water or oil, flows to buffer the water hammer phenomenon.

Water hammering is a phenomenon in which when a fluid is suddenly closed or suddenly opened in a fluid flow path, a shock wave is generated in the fluid and a very high pressure instantly occurs. In severe cases, the pipe is broken, It causes vibrations, noise, and vibration in pipelines as a hammer, which damages vulnerable parts such as valves, gauges, joints, and causes leakage.

The strength of such a water hammer phenomenon is larger as the opening and closing time of the oil passage is shorter. The problem of this water hammer phenomenon has recently become more serious as the rotary valve is switched to a one-touch type valve or a pneumatic / pneumatic valve for convenience of use. In addition to the problems of noise and vibration, Thereby damaging the valve or the pump.

A water hammer prevention device is a device having a cavity in which a gas, which is a compressible fluid such as air or nitrogen, is filled in a certain portion of a pipe in order to suppress the above-described water hammer phenomenon, It is a device that the pupil absorbs and the water hammer phenomenon disappears. The pupil separates water and air by a piston, an elastic membrane, and the like.

In the case of the water hammer prevention device, the larger the volume of the pupil, the greater the absorption capacity of the shock wave. The pressure of the compressible gas (hereinafter, referred to as 'air') in the pupil of the water hammer prevention device is set to be equal to or slightly higher than the pressure of the incompressible fluid flowing along the pipe (hereinafter, referred to as 'water'). If the pressure of the water in the pipeline increases, the piston is pushed up toward the compressed air and the volume of the pore decreases. As the pressure increases by the Boyle's law, the pressure of the pipe and the pressure of the air in the pore are kept in equilibrium do.

If a very high pressure is suddenly generated in the water in the duct due to the occurrence of the water hammer, the pressure is propagated along the pipe and then transmitted to the bellows, the elastic membrane or the piston of the water hammer prevention device, The piston is inflated to the upper side or the piston is pushed to the upper side to absorb the pressure inside the pipe to suppress the water hammer phenomenon.

The strength of the water hammer, which is the maximum pressure at the occurrence of the water hammer, varies depending on the diameter and length of the pipe, the kind of the fluid flowing in the pipe, the temperature and pressure, A conventional water hammer prevention device has a cavity in which a compressed gas is injected into a part of a pipe as shown in FIG. 1, and a body is made of metal having a certain thickness so as to withstand high pressure, A bellows type having a bellows made of an extensible material such as a bellows, an elastic film type having an elastic film such as a rubber film, and a piston type having a piston made of metal or plastic.

Among the various types of water hammer prevention devices as described above, the bellows type has a large volume of the compressed gas, so that the shock absorbing capacity is good. However, when the bellows is not very flexible, there is a problem in shock wave absorption. Normally, the bellows is squeezed by the air pressure of the pupil. If the flexible rubber film is squeezed for a long time, the deterioration proceeds quickly at the folded portion, and the bellows may be broken at this portion.

In the case of the elastic membrane type water hammer prevention device, since the relatively thick elastic membrane is used, there is a strong resistance against corrosion, but the volume of the pores becomes small, and when the water hammer occurs, the rubber membrane excessively elongates, and breakage easily occurs at the bonding portion with the body.

On the other hand, the piston-type water hammer prevention system with a piston is smooth and does not easily corrode unlike rubber, so it is durable. However, it takes a lot of cost to process parts, and there is a problem that air filled in the cavity is consumed because the air leaks to the liquid through the side clearance of the piston.

KR 10-2004-0096724 A KR 10-1287701 B1

Disclosure of the Invention The present invention has been made to solve the above-mentioned conventional problems, and it is an object of the present invention to provide a bellows-type shock absorber which is excellent in pressure resistance, airtightness and durability, Device.

In order to achieve the above object, a water hammer prevention device according to the present invention comprises a first body having a lower portion thereof opened, a first accommodation space provided therein, and a plurality of fluid- A first port including a mounting flange coupled to a lower end of the first body for coupling to a flowing pipe; A second body that is opened at a lower portion to allow a portion of an upper portion of the first body to enter a predetermined depth and is closed at an upper portion thereof and has a second accommodation space therein; A second port including a second engagement flange coupled to a lower end of the second body for engagement with the first engagement flange; And a cushioning part interposed between the first port and the second port to expand the volume when the pressure of the fluid acts on the piping, thereby relieving the shock caused by the pressure of the fluid.

Wherein the cushioning portion includes an inner cover and an outer cover which are formed of a rubber material so as to be able to expand and contract in the up and down direction and arranged closely to each other and a bellows including a code paper interposed between the inner cover and the outer cover, And a second code array formed of a plurality of code yarns arranged in parallel to each other so as to intersect with the first code array is formed by weaving the first code array.

Wherein the bellows includes a first support flange for supporting the inner skin, the sheath and the cord, and being press-supported between the first engagement flange and the second engagement flange, and the second engagement flange includes an edge And a first inlet groove led upward from the bottom surface is formed so as to allow a part thereof to enter.

Further comprising a screen portion formed in a mesh structure to prevent foreign matter from entering the first accommodation space and the second accommodation space from the pipe and interposed between the mounting flange and the pipe flange of the pipe, Wherein the portion includes a mesh portion forming a mesh structure and a second support flange formed along an edge of the mesh portion and pressed and supported between the mounting flange and the pipe flange.

And the mounting flange is formed with a second inlet groove which is drawn upward from the bottom surface to a depth corresponding to the thickness of the second supporting flange so as to be able to insert the second supporting flange.

The water hammer prevention device according to the present invention is advantageous in that the shock absorption through the bellows is constant, and the pressure resistance, airtightness and durability are excellent, and semi-permanent use is possible even when the pressure change is severe or for a long time.

1 is an exploded perspective view of a water hammer prevention device according to the present invention;
FIG. 2 is a sectional view showing an operation state of the water hammer prevention device shown in FIG. 1. FIG.
3 is a sectional view showing another operation state of the water hammer prevention device shown in Fig.
4 is a sectional view of the cushion shown in Figs.
5 is a sectional view showing a state in which a screen unit is installed;

Hereinafter, a water hammer prevention device according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1 to 4 show a water hammer prevention device according to the present invention. 1 to 3, the water hammer prevention device includes a first port 10, a second port 20, and a buffer 30.

The first port 10 has a first body 11 which is opened at the bottom and has a first receiving space 12 therein and a plurality of fluid passing holes formed at an upper portion thereof, And a mounting flange 15 coupled to a lower end of the first body 11 so as to be coupled to a piping flange 6 of the piping line 5.

The first body 11 includes a first body portion 13 formed in a circular pipe structure and having an outer diameter smaller than that of the second body portion 23 to be described later and a second body portion 13 formed in a dome- And a first lid portion (14). The fluid passing holes are formed in a first lid part 14 formed in a dome structure, and the first body part 13 and the first lid part 14 are welded to each other. The first body 11 is welded and welded in a state in which the lower end peripheral face of the first body part 13 is in tight contact with the inner peripheral face of the mounting flange 15 and the outer peripheral face of the longitudinal center part of the first body part 13 And the inner circumferential surface of the first coupling flange 25 is welded in close contact.

The second port 20 includes a second body 21 having a lower portion opened to allow the upper portion of the first body 11 to enter a predetermined depth and an upper portion closed and a second accommodation space 22 provided therein, A first coupling flange 25 coupled to an upper end of the first body 11 and a second coupling flange 25 coupled to a lower end of the second body 21 to be coupled to the first coupling flange 25, 2 engaging flange 27. [0034] As shown in Fig.

The second body 21 has a second body portion 23 formed in a pipe structure and having an outer diameter larger than that of the first body portion 13 and a second body portion 23 formed in a dome structure on the second body portion 23, And the second body portion 23 and the second lid portion 24 are welded to each other. The second body 21 is welded to the second body 23 in a state in which the lower end of the second body 23 is in close contact with the inner circumferential surface of the second engagement flange 27. A gas inlet 24b for injecting gas such as nitrogen into the pressure gauge 24a and the second accommodation space 22 or for discharging gas in the second accommodation space 22 is provided on the upper portion of the second body 21 Lt; / RTI >

The first coupling flange 25 is formed to have a length of the first body portion 13 such that the first body portion 13 and the second lid portion 24 can be introduced to a predetermined depth into the second body portion 23, And is fixed to the center side. The degree of entry of the first body 11 into the second body 21 can be adjusted by adjusting the welding engagement position of the first engagement flange 25 with respect to the first body 13. That is, as the first engaging flange 25 is lowered toward the lower side of the first body part 13 with respect to the first body 11, the length of the first body 11 entering the second body 21 becomes longer And the length of the first body 11 entering the second body 21 as the first engagement flange 25 rises to the upper side of the first body 13 with respect to the first body 11 .

The edge of the first support flange 35 of the bellows 31 described later is inserted into or engaged with the second engagement flange 27 and the edge of the first support flange 35 together with the first engagement flange 25 And a first inlet groove 28 is formed at a depth corresponding to the upper and lower thickness of the edge of the first support flange 35 upward from the bottom surface so as to be pressurized.

The first engagement flange 25 has an inner diameter corresponding to the outer diameter of the first body portion 13 and the second engagement flange 27 has an inner diameter corresponding to the outer diameter of the second body portion 23, The engagement flange 25 is formed to have an inner diameter smaller than the inner diameter of the second engagement flange 27 so as to stably support the first support flange 35 interposed between the engagement flange 25 and the second engagement flange 27 have.

The buffer 30 is interposed between the first port 10 and the second port 20 so that when the pressure of the fluid acts on the pipe line 5, An inner skin 32 and an outer skin 33 which are formed of a rubber material having elasticity so as to be stretchable and extendable in the up-and-down direction and arranged so as to be in close contact with each other; And a bellows 31 including a bellows 34.

The bellows 31 is formed at the lower end to support the inner film 32, the sheath 33 and the cord paper 34 and is provided between the first engagement flange 25 and the second engagement flange 27 And a first support flange 35 which is press-supported. The first support flange 35 is installed so that the edge is drawn in the first inlet groove 28 provided in the second engagement flange 27.

The code paper 34 comprises a first code array of a plurality of code yarns arranged in parallel with each other, and a second code array of a plurality of code yarns arranged in parallel with each other, . The first code array and the second code array are arranged so as to cross each other at an angle of 45 degrees. The code yarns forming the first code array and the second code array are formed of natural fibers, carbon fibers, metal fibers, and the like .

Although not shown, the first code array can be formed by alternately arranging the first code yarns twisted in a certain direction and the second code yarns twisted in the direction opposite to the twist direction of the first code yarns alternately in the parallel direction, The code array can also be formed in the same structure as the first code array. When the twisted cord yarns are used in different directions as described above, there is an advantage in that the durability is excellent. For example, even if a warping stress, a compressive force, and a tensile force are applied to the cord paper 34, the external force can be easily canceled by the first cord yarn and the second cord yarn having different twist directions.

5 shows a water hammer prevention device according to the present invention in which foreign matter passing through a pipe line 5 interposed between a mounting flange 15 and a pipe flange 6 of the pipe line 5 is introduced into the first body And a screen unit 40 formed in a mesh structure so as to block entry into the first accommodation space 12 of the first body 11 and the second accommodation space 22 of the second body 21.

5, the screen unit 40 includes a mesh unit 41 formed by alternately arranging wires so as to have a mesh structure, a mesh unit 41 formed along the edge of the mesh unit 41, And a second support flange (45) pressed and supported between the pipe flanges (6).

A second inlet groove 16 is formed in the bottom surface of the mounting flange 15 for interposing the screen unit 40 so as to allow the second supporting flange 45 of the screen unit 40 to be inserted upward . Although not shown in the drawing, the second inlet groove 16 may further include a packing member for preventing the fluid from flowing out between the mounting flange 15 and the pipe flange 6.

Although the water hammer prevention device according to the present invention has been described with reference to the example shown in the drawings, it should be understood that those skilled in the art will appreciate that various modifications, It is understandable.

Accordingly, the scope of the true technical protection of the present invention should be determined by the technical idea of the appended claims.

5: piping line
6: Piping flange
10: First port
11: First body
13: first body part
14: First cover
15: Mounting flange
20: Second port
21: Second body
23: second body part
24: second cover part
25: first coupling flange
27: second engagement flange
30: buffer
31: Bellows
35: first support flange
40:
41:
45: second support flange

Claims (5)

A first body having a bottom opened and a first accommodation space provided therein and having a plurality of fluid passing holes formed therein, and a second body coupled to a lower end of the first body to couple the first body to a pipe through which the fluid flows A first port comprising a mounting flange;
A second body that is opened at a lower portion to allow a portion of an upper portion of the first body to enter a predetermined depth and is closed at an upper portion thereof and has a second accommodation space therein; A second port including a second engagement flange coupled to a lower end of the second body for engagement with the first engagement flange;
A buffer portion interposed between the first port and the second port to expand the volume when the pressure of the fluid acts on the pipe to relieve the impact due to the pressure of the fluid;
And a screen portion formed in a mesh structure to prevent foreign matter from entering the first accommodation space and the second accommodation space from the pipe and interposed between the mounting flange and the pipe flange of the pipe,
The first body includes a first body portion formed in a pipe structure, and a first lid portion welded to an upper portion of the first body portion and formed in a dome structure,
The second body includes a second body portion formed in a pipe structure, and a second lid portion welded to an upper portion of the second body portion and formed in a dome structure,
Wherein the cushioning portion comprises an inner cover and an outer cover which are formed of a rubber material so as to be able to expand and contract in the up and down direction and are closely arranged to each other, a code paper interposed between the inner cover and the outer cover, And a bellows including a first support flange press-supported between the second engagement flange,
A first code array comprising a plurality of code yarns arranged in parallel with each other and a second code array comprising a plurality of code yarns arranged in parallel to each other so as to cross the first code array, Wherein the first code array is formed by alternately arranging a first code yarn twisted in a predetermined direction and a second code yarn twisted in a direction opposite to the twist direction of the first code yarn,
Wherein the first coupling flange is welded to the first body portion to allow the first body portion and the second lid portion to enter a predetermined depth into the second body portion, The first body can be adjusted in the degree of entry,
Wherein the first engagement flange is formed with a first inlet groove that is drawn upward from a bottom surface so as to allow a part of an edge of the first support flange to enter,
Wherein the screen portion includes a mesh portion forming a mesh structure and a second support flange formed along an edge of the mesh portion and pressed and supported between the mounting flange and the pipe flange,
Wherein the second mounting flange is formed with a second inlet groove which is drawn upward from the bottom surface to a depth corresponding to the thickness of the second supporting flange so as to be able to insert the second supporting flange,
And a packing member for preventing fluid from flowing between the mounting flange and the pipe flange is interposed in the second inlet groove.
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