KR20230036942A - Water hammer arrestor - Google Patents

Abstract

The present invention relates to an apparatus which prevents a water hammer, an impact which occurs when a kinetic energy of a fluid is converted into a pressure energy due to rapid decrease in a fluid velocity when a valve at an end of a pipe is closed, when the fluid is flowing at the pipe interior. The apparatus, as a water hammer arrester which includes a permanent magnet and a shield and is directly coupled to a pipe, causes a repulsive force of the permanent magnet to be generated in both directions and weakened in one direction using the shield to generate a stronger repulsive force. According to the present invention, the repulsive force no longer affects the exterior of the water hammer arrestor. Therefore, interference due to the repulsive force between other apparatuses or products does not occur. Also, elasticity of an absorbing impact is not weakened. The water hammer arrestor of the present invention comprises: a cylindrical body (100); a first fixation unit (110); a first movement unit (120); and a second fixation unit (140).

Description

Water hammer arrestor

The present invention relates to a water hammer arrestor, and more specifically, to a water hammer arrestor installed in a pipe to prevent vibration, shock and noise caused by a sudden pressure change of a fluid flowing in the pipe.

When an incompressible fluid such as water is flowing in a pipe, when the valve at the end of the pipe is closed, the shock caused by the rapid drop in fluid velocity converts the kinetic energy of the fluid into pressure energy is called water hammer. Vibration and noise are generated by impact on pipelines, damage and leakage of pipes and junctions, and consumption and damage of related machines and instruments are caused.

This phenomenon is frequently observed not only in industrial sites but also in everyday life, and it is characterized by occurring regardless of the method and type of controlling the fluid such as mechanical, electrical, or pneumatic and elastic force by spring.

Techniques belonging to the invention include not only domestic households such as water and washing machines, but also the entire industry, including a power transmission system that transmits fluid as power and operates and regulates hydraulic pressure. Common to these broad fields of art is the regulation of the pressure and regulation of the flow of a fluid. Therefore, when the flow in the pipe is interrupted in the process of controlling the fluid flowing through the pipe to an appropriate pressure and sending it to the device, shock and vibration inevitably occur due to the increase in pressure in the pipe.

As described above, a method using an elastic body such as a spring, a method using a permanent magnet, a gas ( Although many devices such as gas) injection compression method and rubber bag expansion method have been proposed, the proposed prior art has the following problems.

In the case of using an elastic body such as a spring, if the fluid pressure exceeds the elastic limit of the material, it is difficult to effectively absorb water hammer by reaching the plastic region. In addition, as water hammer occurs repeatedly, the elastic body is deteriorated and ruptured, which causes a shortened lifespan.

In the case of the gas injection compression method, there is a risk of leakage of the charged gas, and as a result, the gas pressure is lowered and the impact is not effectively absorbed. Therefore, there is a hassle of recharging the gas at regular intervals. In addition, there is a possibility that the gas dissolves in the liquid and changes the composition of the fluid or contamination, along with performance degradation due to the decrease in the amount of filling gas. In the case of the gas injection compression method, since the compression rate is high, miniaturization is difficult, and thus application is limited, and performance is highly dependent on temperature. In addition, it is not easy to easily check the internal pressure of the gas or the amount of residual gas during use, and it is difficult to manage the after-sales service. In addition, in the case of forcibly injecting gas into a sealed container, installation and manufacturing processes are complicated.

In the case of a method using a permanent magnet, the same poles of the permanent magnets are placed facing each other so that the fluid pressure is resisted by the repulsive force generated therefrom. However, when absorbing the sudden rise in shock, the fluid pressure exceeds the repulsive force of the permanent magnet, and the permanent magnets collide with each other, resulting in damage to the permanent magnet or corrosion due to damage. It becomes difficult to effectively alleviate the impact.

As mentioned above, various methods and devices have been proposed in order to solve various problems caused by adjusting the pressure of the fluid flowing through the pipe and rapidly regulating the flow. However, as can be seen in the prior art data, the prior art partially or temporarily solved the problems caused by the rapid regulation of incompressible fluids, but failed to present a solution in which functional implementation, economic feasibility, and maintenance cost aspects were comprehensively considered. In addition, the proposed method for solving the problem did not fundamentally solve the technical contradiction inherent in the problem because it provided a factor causing other problems.

Conventional water hammer arresters using permanent magnets generally have permanent magnets inside the device to prevent water hammers, as disclosed in the prior literature below. However, this structure generates the magnetic force of the permanent magnet in an unnecessary direction, so that elasticity due to the magnetic force is weakened, and interference with other devices or products is caused by the repulsive force.

Republic of Korea Utility Model Registration No. 20-0201243 (2000.11.01. Notice) Republic of Korea Utility Model Registration No. 20-0237820 (Announced on October 18, 2001) Republic of Korea Utility Model Publication No. 20-2012-0007192 (published on October 19, 2012)

An object of the present invention is to provide a water hammer preventer including a permanent magnet and a shield therein to prevent water hammer caused by a sudden pressure change of a fluid. Other objects of the present invention can all be achieved by the detailed description of the present invention described with reference to the accompanying drawings.

In order to achieve the above object, the water hammer arrestor of the present invention includes a permanent magnet and a shield, including a cylindrical body with both ends open; A first fixing part coupled to the front end of the cylindrical body to connect the pipe and the cylindrical body; a first moving part located at a rear end of the first fixing part, having an outer diameter smaller than an inner diameter of the cylindrical body, and having a first permanent magnet at the rear end; and a second fixing unit coupled to the rear end of the cylindrical body to seal the opened rear end of the cylindrical body and having a third permanent magnet at the front end.

In addition, the present invention may further include a second moving part formed between the first moving part and the second fixing part and having a second permanent magnet.

In addition, the present invention may further include a first straight shield formed at a front end of the first permanent magnet and a second straight shield formed at a rear end of the third permanent magnet.

In addition, the present invention may further include a first D-shaped shield formed at a front end of the first permanent magnet and a second D-shaped shield formed at a rear end of the third permanent magnet.

In addition, one or more grooves are formed on the outer circumferential surface of the first moving unit, and an O-ring inserted into the grooves may be further included.

According to the water hammer arrestor of the present invention, a permanent magnet is provided to stably absorb the pressure caused by water hammer, so the life is semi-permanent, the structure is simple, the construction is simple, and inspection and repair are easy as needed. In implementing the function, the temperature dependence of the performance is very small and stable.

In addition, by arranging the magnetic poles of the permanent magnets to face each other, the pressure generated when the fluid is intermittent is absorbed on the principle of repulsive force that pushes the same poles together, and sealed to prevent collision between the permanent magnets when absorbing a momentary strong pressure. It serves as an air cushion by filling the space surrounded by a cylindrical body and permanent magnet with gas.

In addition, by providing a shield, the repulsive force of the permanent magnet can be induced in one direction rather than in both directions, and as a result, it has a stronger repulsive force, so that the problem of weakening elasticity does not occur, so it is possible to respond flexibly according to the size of the fluid impact. .

In addition, since the repulsive force does not occur outside the water hammer arrestor due to the shield, interference due to the repulsive force between other devices or products does not occur, thereby providing a water hammer arrestor capable of precise control.

1 is an external appearance and assembly cross-sectional view of a water hammer arrestor equipped with a permanent magnet and a straight shield according to the present invention;
2 is a cross-sectional perspective view of a water hammer arrestor equipped with a permanent magnet and a straight shield according to the present invention;
3 is an assembled cross-sectional view of a water hammer arrestor equipped with a permanent magnet and a DIG-shaped shield according to the present invention; and
4 is an external appearance and assembly cross-sectional view of a water hammer arrestor before a permanent magnet and a shield are provided according to the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. Terms or words used in this specification and claims should not be construed as being limited to ordinary or dictionary meanings, but should be interpreted as meanings and concepts consistent with the technical details of the present invention.

1 is an exterior and assembled cross-sectional view of a water hammer arrestor equipped with a permanent magnet and a line-shaped shield according to the present invention, FIG. 2 is a cross-sectional perspective view of a water hammer arrestor equipped with a permanent magnet and a line-shaped shield according to the present invention, and FIG. An assembled cross-sectional view of a water hammer arrestor equipped with a permanent magnet and a DIG-shaped shield according to the present invention.

1 to 4, the water hammer arrestor of the present invention includes a cylindrical body 100, a first fixing part 110, a first moving part 120, a first permanent magnet 220, and a second moving part. (130), a second permanent magnet (230), a second fixing part (140), and a third permanent magnet (240).

The cylindrical body 100 is a cylinder formed in a cylindrical shape, both ends of which are open and hollow, and includes components such as the first moving unit 120 and the second moving unit 130 therein. can do.

In addition, the cylindrical body 100 should be made of a material having excellent tensile stress such as metal to sufficiently withstand a large internal pressure, and moisture may vary depending on the pipe in which the cylindrical body 100 is installed and the surrounding environment. And it is preferable to be rust-proof to prevent rust due to water vapor.

The first fixing part 110 is fixed to the front end of the cylindrical body 100, and the fluid pressure in the pipe generated by water hammer by connecting the pipe and the cylindrical body 100 is reduced to the cylindrical body 100. ) is an inlet that can be drawn into the interior of the

In addition, a locking jaw is formed at the rear end of the first fixing part 110 to prevent the first moving part 120 from being separated from the cylindrical body 100 .

In addition, a screw thread may be formed on the inner or outer circumferential surface of the first fixing part 110, which facilitates the coupling operation with the pipe, thereby reducing the time required for the coupling operation, and the water hammer arrestor Confidentiality and watertightness can be secured.

The first moving part 120 is located at the rear end of the first fixing part 110, has an outer diameter smaller than the inner diameter of the cylindrical body 100 so that it can freely move back and forth when fluid flows in and out, and the first moving part 120 is formed at the rear end of the first moving part 120. 1 is provided with a groove in which a permanent magnet 220 can be formed.

In addition, a hemispherical protrusion is provided at the front end of the first moving unit 120 so that the surface of the protrusion is more closely adhered to the end of the first fixing unit 110, and the fluid enters and exits more easily. In addition, when the fluid pressure inside the pipe generated by water hammer enters and exits the cylinder body 100, the fluid pressure is gradually applied to prevent rapid movement of the first moving unit 120.

The first permanent magnet 220 is a permanent magnet capable of exerting magnetic force on other nearby permanent magnets by forming a magnetic field around it, and is inserted into the rear end of the first moving unit 120 to It can move together according to the up and down motion of

The second movable part 130 is located between the first movable part 120 and the second fixing part 140 and has a cylindrical shape having an outer diameter smaller than the inner diameter of the cylindrical body 100 so as to freely move back and forth. It is composed of, and a hollow for mounting the second permanent magnet 230 is formed in the center.

The second permanent magnet 230 is a permanent magnet capable of exerting magnetic force on other nearby permanent magnets by forming a magnetic field around it in the same way as the first permanent magnet 220. It is inserted into the hollow and can move together with the back and forth movement of the second moving unit 130, and can exert a repulsive force against each other by placing a part facing the first permanent magnet 220 at the same pole.

For example, if the left side of the first permanent magnet 220 is the N pole and the right side is the S pole, the second permanent magnet 230 is arranged so that the left side is the S pole and the right side is the N pole so that mutual repulsive force is generated, , can also be arranged with the opposite polarity.

The second moving unit 130 and the second permanent magnet 230 may be omitted from the components due to limitations such as the size and characteristics of the space in which the water hammer arrestor according to the present invention is installed.

Even if the second moving unit 130 and the second permanent magnet 230 are not provided, there is no major obstacle in the water hammer arrestor performing its intended role, but since the repelling force is somewhat weakened, the second moving unit ( 130) and the second permanent magnet 230 are preferably included.

The second fixing part 140 is fixedly located at the rear end of the cylindrical body 100, seals the open rear end of the cylindrical body 100, and has the third permanent magnet 240 formed at the front end. A groove that can be can be provided.

The third permanent magnet 240 is a permanent magnet capable of exerting magnetic force on other nearby permanent magnets by forming a magnetic field around it in the same way as the first permanent magnet 220 and the second permanent magnet 230, It is inserted into the front end of the second fixing part 140, and a part facing the second permanent magnet 230 may exert a repulsive force against each other by placing the same pole.

As a preferred embodiment, as shown in FIGS. 1 and 2 , the water hammer arrestor of the present invention may further include a first straight shield 200 and a second straight shield 210 .

The first straight shield 200 is a plate-shaped shield inserted between the first moving unit 120 and the first permanent magnet 220, and the magnetic force of the first permanent magnet 220 is applied to the first permanent magnet 220. 2 It is induced in the direction where the permanent magnet 230 is formed and shielded in the opposite direction so that the repulsive force exerted on each other due to the magnetic force can be further strengthened.

In addition, the first straight shield 200 prevents the magnetic force of the first permanent magnet 220 from affecting the outside of the water hammer arrestor according to the present invention, so that other external devices or products are not affected by the magnetic force. It also has the effect of preventing unwanted interference from occurring.

The second straight shield 210 is a plate-shaped shield formed by being inserted between the second fixing part 140 and the third permanent magnet 240, and converts the magnetic force of the third permanent magnet 240 to the third permanent magnet 240. 2 It is induced in the direction where the permanent magnet 230 is formed and shielded in the opposite direction so that the repulsive force exerted on each other due to the magnetic force can be further strengthened.

In addition, the second straight-shaped shield 210 prevents the magnetic force of the third permanent magnet 240 from affecting the outside of the water hammer arrestor according to the present invention, so that other external devices or products are not affected by the magnetic force. It also has the effect of preventing unwanted interference from occurring.

As another preferred embodiment, as shown in FIG. 3, the water hammer arrestor of the present invention is a tubular shield in which the plate-shaped shield extends in the outer circumferential direction, and includes a first dig-shaped shield 201 and a second dig-shaped shield ( 211) may be further included.

The first DIG-shaped shield 201 is a cylindrical shield formed by being inserted between the first moving unit 120 and the first permanent magnet 220, and the magnetic force of the first permanent magnet 220 is It is induced in the direction in which the second permanent magnet 230 is formed and shielded in the opposite direction so that the repulsive force exerted on each other due to the magnetic force can be further strengthened.

In addition, the first dig-shaped shield 201 prevents the magnetic force of the first permanent magnet 220 from affecting the outside of the water hammer arrestor according to the present invention, so that other external devices or products are not intended by magnetic force It also has the effect of preventing unwanted interference from occurring.

The second dig-shaped shield 211 is a cylindrical shield formed by being inserted between the second fixing part 140 and the third permanent magnet 240, and the magnetic force of the third permanent magnet 240 is It is induced in the direction in which the second permanent magnet 230 is formed and shielded in the opposite direction so that the repulsive force exerted on each other due to the magnetic force can be further strengthened.

In addition, the second dig-shaped shield 211 prevents the magnetic force of the third permanent magnet 240 from affecting the outside of the water hammer arrestor according to the present invention, so that other external devices or products are not intended by magnetic force It also has the effect of preventing unwanted interference from occurring.

As another preferred embodiment, as shown in FIGS. 1 to 4 , the water hammer arrestor according to the present invention may further include a plurality of O-rings 121 as components.

The first moving part 120 has one or more grooves that can accommodate the O-ring 121 in the circumferential direction on its outer circumferential surface, and the O-ring 121 is inserted into the groove to form the cylinder body. The airtightness and watertightness of (100) can be further improved.

Therefore, it is preferable that the material of the O-ring 121 be made of rubber or the like having excellent airtightness and watertightness.

Although the preferred embodiments of the present invention have been shown and described above, the present invention is not limited to the specific embodiments described above, and conventional techniques in the technical field to which the present invention pertains without departing from the gist of the present invention claimed in the claims. Various modifications are possible by those with knowledge.

In addition, matters that can be easily inferred from the accompanying drawings should be considered to be included in the content of the present invention even if not described in the detailed description, and various modified embodiments should not be individually understood from the technical spirit or prospect of the present invention It won't.

100: cylindrical body
110: first fixing part
120: first moving part 121: O-ring
130: second moving unit
140: second fixing part
200: first straight shield 201: first dig-shaped shield
210: second straight shield 211: second dig-shaped shield
220: first permanent magnet
230: second permanent magnet
240: third permanent magnet

Claims (5)

As a water hammer arrestor coupled to the pipe,
Cylindrical body 100, both ends of which are open;
A first fixing part 110 coupled to the front end of the cylindrical body 100 and connecting the pipe and the cylindrical body 100;
A first moving part 120 located at the rear end of the first fixing part 110, having an outer diameter smaller than the inner diameter of the cylindrical body 100, and having a first permanent magnet 220 at the rear end; and
A second fixing part 140 coupled to the rear end of the cylindrical body 100 to seal the open rear end of the cylindrical body 100 and having a third permanent magnet 240 at the front end;
Water hammer arrestor comprising a. The method of claim 1,
The water hammer arrestor further comprises a second moving part (130) formed between the first moving part (120) and the second fixing part (140) and having a second permanent magnet (230). . According to claim 1 or claim 2,
Water hammer characterized in that it further comprises a first straight shield 200 formed at the front end of the first permanent magnet 220 and a second straight shield 210 formed at the rear end of the third permanent magnet 240 preventer. According to claim 1 or claim 2,
Characterized in that it further comprises a first D-shaped shield 201 formed at the front end of the first permanent magnet 220 and a second D-shaped shield 211 formed at the rear end of the third permanent magnet 240. water hammer arrestor. According to claim 1 or claim 2,
The water hammer arrestor further comprises one or more grooves formed on an outer circumferential surface of the first moving part (120) and an O-ring (121) inserted into the grooves.

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