KR20120007192U - Permanent Magnet Fluid Shock Absorber in Pipes Using Permanent Magnets, Permanent Magnets are Easily Laminated, and Permanent Magnets with Permanent Magnets - Google Patents

Abstract

In the present invention, using a permanent magnet that solves the two problems at the same time by using two or more repulsive force arranged to face the shock (surge pressure) and vibration problems caused by rapidly blocking the flow of fluid or gas to the same poles of the permanent magnet In the fluid shock absorber, it is possible to trap the air in the chamber of the device so that the permanent magnets in the device can be easily laminated and maintain a constant pressure and prevent the permanent magnets from colliding with each other when a momentary surge pressure occurs. When shock surge pressure is generated and the piston slides, the air in the body is compressed and flows into the permanent magnet repulsion space to act as an air cushion to prevent the collision of permanent magnets and to use the pressure generated when compressing air for shock absorption. By lowering the permanent magnet repulsion pressure to help absorb shock. It can absorb big shocks, which improves the performance of the device. The fluid shock absorber using permanent magnets according to the present invention is easy to laminate permanent magnets and precise pressure control according to the magnitude of impact (surge pressure). It is simple in construction and easy to check and repair as needed.

Description

Permanent Magnet Fluid Shock Absorber in Pipes Using Permanent Magnets Easy to Stack Permanent Magnets and Permanent Magnet Fluid Shock Absorbers with Permanent Magnets

When an incompressible fluid such as water or gas is flowing through a pipe that is supplied with gas, shock (surge pressure) and vibration are generated in the pipe when the high pressure gas or fluid is closed by an electric or pneumatically operated valve or mechanism. This phenomenon is called batting by gas or fluid. It is a phenomenon frequently observed in industrial sites, and regardless of the method of controlling gas or fluid, such as hand-operated electric or pneumatic operation or force spring, It is characteristic to occur

Machines and various machinery used in daily use and industrial sites are used to control the flow of gas or fluid in pipes as needed and to adjust the pressure of the gas or fluid quickly, especially for the precise functioning of the device. In this case, the faster the opening and closing speed of the intermittent valve is, the more constant pressure cannot be maintained and the pressure applied to the gas or fluid in the pipe increases. In addition to damage to various mechanical devices due to the increase in pressure, it is difficult to precisely adjust the pressure, and damage to various mechanical devices may cause malfunction or shorten the life of the device.

As a result, pressure adjustment and control of the gas or fluid flowing in the pipe are essential in various fields. As a result, various problems mentioned above are caused by pressure changes, shocks, and vibrations in the pipe caused by the rapid cracking of the gas or fluid. Falls into a technical contradiction

The purpose of the present invention is to propose a mechanism that can solve the problems caused by the interruption of the gas or fluid flowing in the pipe and to provide a shock absorbing device of the gas or fluid in the pipe based on the device.

The technologies belonging to the present invention include industries such as a water washing machine and a whole industry including a power transmission system for delivering fluid to a power and controlling hydraulic operation. In a wide range of these technical fields, it is common to regulate the pressure or flow of a gas or fluid. In other words, when the flow in the pipe is interrupted in the process of adjusting the gas or fluid flowing in the pipe to the user device by adjusting the proper pressure on the user's side, shock and vibration are generated due to the pressure increase in the pipe.

Until now, (1) pressure regulator (regulator) using coil spring to adjust the pressure in the pipe, and the shock absorber is a shock absorbing spring or the inventor proposed and registered (prior technical data: Korean Utility Model Registration No. 20-0201243) solved the problem of shock and vibration by attaching a fluid shock absorber using permanent magnets or a shock absorber filled with gas (2).

Proposed conventional techniques include (1) springs (2) permanent magnets (3) gas (gas) injection compression method (4) rubber bag expansion method and the like.

Utility Model Registration Number 20-0201243

As mentioned in the technical field to which the invention belongs and also in the prior art, even if the gas or fluid is adjusted to the appropriate pressure desired by the user, it is caused by the pressure change in the pipe which occurs in the process of interrupting the flow and resulting from shock and vibration. Many devices have been proposed so far for the purpose of solving the problem, and among them, the present invention proposes a fluid shock absorption device using permanent magnets disclosed and registered (Utility Model 20-0201243).

When the same magnetic poles of permanent magnets face each other (ns sn ns sn) and use the repulsive force to absorb shocks that rise immediately, the permanent magnets collide with each other, and the permanent magnets are damaged due to damage caused by breakage and damage. It is difficult to carry out effectively. In addition, due to rupture, the life of the device may be shortened.In addition, when O-rings are assembled in the sliding body with permanent magnets inserted into the middle of the body, air is compressed between the sliding piston and the sliding piston, The distance between the permanent magnet and the permanent magnet is too long to stack and use the same stimulus repulsive force of the permanent magnet, making it difficult to control the shock absorbing pressure in the body due to the shock absorption.

As mentioned above, a shock absorbing device using a permanent magnet has been proposed to solve the problems of sudden pressure rise shock and vibration caused by adjustment of the pressure of gas or fluid flowing in the pipe and rapid interruption. As can be seen, the problems caused by rapid pressure rise (surge pressure) in the process of controlling the flow of city pipes were solved, either partly or temporarily.However, in terms of economic feasibility and maintenance cost, the maintenance cost was not comprehensively solved. I couldn't.

The present invention is made by stacking the magnetic poles of ferromagnetic permanent magnets facing each other (n-s s-n n-s s-n, etc.). Using the same repulsive repulsive force as a winry to absorb the suddenly increased pressure (surge pressure) generated during the control of the fluid (Utility Model 20-0201243) and to prevent the permanent and permanent magnets from colliding when absorbed. Permanent magnets can be used according to the magnitude of the force that causes surge pressure by freely utilizing the intrinsic repulsive force of permanent magnets by opening a passage through which air flows to the magnet inserted body to prevent air compression between the permanent magnets. And size and lamination arrangement can be determined

In addition, if the body is completely sealed after assembly, if the piston is operated during water shock, the natural air inside the body is compressed and flows into the magnetic repulsion space of the permanent magnet, thus acting as an air cushion to prevent the collision of the permanent magnet. In addition, when the piston operates due to the rapid interruption of the flow of fluid, the air compression pressure inside the body increases between the repulsive forces of the permanent magnets, preventing corrosion of the permanent magnets and breaking and absorbing more impact pressure.

Hereinafter, exemplary embodiments of the present invention will be described with reference to the accompanying drawings. In describing the present invention, when it is determined that a detailed description of a related known function or configuration may obscure the subject matter of the present invention, the detailed description thereof will be omitted.

1 is an assembly cross-sectional view showing the internal parts of the fluid shock absorber using a permanent magnet according to the prior art, the body (FIG. 1) by mounting an o-ring (22 in FIG. 1) on an intermediate sliding body 2 (FIG. 1). 14), the sliding body 1 (piston Fig. 12) and air compression occur, and multiple permanent magnets cannot be laminated. In addition, the repulsive force of the permanent magnet is reduced due to the long distance between the sliding bodies 1 and 2, so that the shock cannot be absorbed effectively. If the o-ring (22 in Fig. 1) is removed and the permanent magnet is inserted, the permanent magnets collide with each other when water shock occurs. There are problems such as permanent magnet breakage and corrosion, but Figures 2 and 3 show the appearance and assembly cross section of the shock absorber using the permanent magnet according to the present invention, which solves the problems listed above, and the components of the shock absorber of the fluid using the permanent magnet. It is a section.

In the fluid shock absorber using the permanent magnet according to the present invention, the permanent magnet (18.19 of FIG. 2) is made smaller than the inner body (11 of FIG. 2) so as not to block a passage through which air flows, or the permanent magnet (of FIG. 2). 18.19) make a hole through which air flows (22.23.24 in Fig. 2) and insert it into the air chamber and seal the body completely so that the permanent magnet repulsion and air cushion occur simultaneously when the piston is operated. The rapid cracking of the gas or fluid flowing in the pipe causes the surge pressure to be reversed in the direction of fluid flow by the shock vibration, and the shock wave introduced into the body (chamber) of the shock absorber connected to the main pipe (11 in Fig. 2) is a permanent magnet. It is transmitted to this inserted piston (15 piston movement in FIG. 2). The piston (15 in Fig. 2) into which the permanent magnet is inserted slides in the direction of the permanent magnet (18.19.20 in Fig. 2) while the piston moves due to the pressure of the shock wave. .24 Air also flows into the air chamber inside the body (22.23.24 in Fig. 2) along the passage where air flows into the permanent magnet (18.19 in Fig. 2), and the natural air is compressed and the magnetic repulsion space of the permanent magnet (Fig. 22.23.24) can act as an air cushion to prevent permanent magnets from colliding. In addition, when assembling the device so that the piston (15 in Fig. 2) and the permanent magnet (18.19 in Fig. 2) do not generate air compression, the permanent magnet's inherent repulsive force can be freely used according to the magnitude of the force causing surge pressure. The shape and size of the permanent magnet and the arrangement of the filling can be determined. Also, if the body is completely sealed after assembly, the air compression pressure inside the body increases even between the repulsive forces of the permanent magnet when the piston is operated due to the rapid interruption of fluid flow. Corrosion can be prevented due to breakage and breakage, and it can absorb greater water impact pressure.

The magnitude of the repulsive force and the increase in the air chamber pressure generated in the event of a water shock are inversely proportional to the distance between the piston (Fig. 2) and the permanent magnet (Fig. 2, 17.18.19.20) in the body (Fig. 2). The adjustment and the shock are absorbed as the adjustment value and the shock wave pressure (surge pressure) cancel each other out by the repulsive force of the magnetic force and the air pressure in the air chamber. The mechanism to absorb shocks and vibrations or combinations of valves of gas or fluid in the pipe using the repulsive force of two or more permanent magnets and the closed air chamber compression pressure generated during piston movement In this case, the magnitude of the repulsive force is calculated according to the magnitude of the (shock wave) surge pressure, and the permanent magnet type or size and the number (two or more) or the red insect array are combined according to the purpose.

When the piston with permanent magnet and permanent magnet are assembled in the body so that air compression does not occur, the permanent magnet's unique repulsive force can be freely used according to the magnitude of water impact. In addition, if the body is completely sealed after assembly, if the piston is operated when a water shock occurs, the natural air inside the body is compressed and flows into the magnetic repulsion space of the permanent magnet, which acts as an air cushion, and the permanent magnet collides. It can prevent the permanent magnet from being damaged and the corrosion caused by the damage. In addition, when the piston operates due to the rapid interruption of the flow of fluid, the internal air compression pressure increases between the repulsive forces of the permanent magnets, thereby absorbing a larger water shock surge pressure.

(1) In order to realize the function, the water shock pressure absorption ability is improved and the permanent magnet can be easily laminated, so the repulsive force can be calculated according to the size of the pressure and the permanent magnet can be laminated accordingly. It prevented the collision of the metals and solved the two problems such as permanent magnet damage and corrosion due to the damage. It is easy to install and easy to check and repair as needed.

1 is a cross-sectional view showing the internal components of the fluid shock absorber using the existing permanent magnet
Fig. In the fluid shock absorbing device in the pipe using the permanent magnet according to the present invention, it is easy to stack the permanent magnet, and the appearance and assembly sectional view of the fluid shock device using the permanent magnet with a built-in anti-collision device for protecting the permanent magnet.
3. In the fluid shock absorbing device in the pipe using the permanent magnet according to the present invention, it is easy to stack the permanent magnet and shows the internal parts of the fluid shock device using the permanent magnet with the built-in anti-collision device for protecting the permanent magnet.

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Fig. Assembly cross-sectional view showing the internal components of a fluid shock absorber using the existing permanent magnet
1 (10): main pipe
1 (11): Main pipe nipple
1 (12): sliding body 1 (piston)
1 (13): Body and main pipe (11) Connecting bolt
1 (14): the main body (chamber) of the fluid shock absorber in the pipe using a permanent magnet
Fig. 1 (15): Body Nipple
Fig. 1 (16): Bolts for fastening the parts formed by inserting permanent magnets with the body chamber
Fig. 1 (17): Permanent Magnet
Figure 18 (18): O-ring
Fig. 1 (19): O-ring
Fig. 1 (20): Intermediate sliding body with permanent magnet inserted and O-ring assembled
Fig. 1 (22): O-ring
Fig. 1 (23): O-ring
Fig. Assembly section showing the appearance and internal parts of the fluid shock absorber using the permanent magnet in the fluid shock absorbing device in the pipe using the permanent magnet according to the present invention is easy to stack the permanent magnet and built-in anti-collision device for protecting the permanent magnet
2 (10): Body and main pipe connection bolt
Figure 11 (11): the main body (chamber) of the fluid shock absorber in the pipe using a permanent magnet
FIG. 2 (12): The screw portion for integrally assembling the main body connecting bolt 10 and the main body fastening bolt 13 into which the permanent magnet is inserted into the main body 11 in one body.
Figure 13 (13): Bolt for fastening the permanent magnet with the insertion body chamber
Fig. 2 (14): o-ring for sealing when assembling the body and main pipe bolt
2 (15): the piston of the structure that can insert the permanent magnet
Fig. 2 (16): O-ring for sealing piston compression
2 (17): permanent magnet inserted into the piston 15
Fig. 2 (18): Permanent Magnet
Fig. 2 (19): Permanent Magnet
Figure 20 (20): permanent magnet inserted into the bolt for fastening with the body chamber
Fig. 2 (21): o-ring for sealing when assembling the body fastening bolt inserted body and permanent magnet
Fig. 2 (22): Air chamber
Fig. 2 (23): Air chamber
Fig. 2 (24): Air chamber
3. In the fluid shock absorbing device in the pipe using the permanent magnet according to the present invention, it is easy to stack the permanent magnet and shows the internal parts of the fluid shock device using the permanent magnet with the built-in anti-collision device for protecting the permanent magnet.
Figure 10 (10): the body and the main pipe connection bolt
Figure 11 (11): the main body (chamber) of the fluid shock absorber in the pipe using a permanent magnet
Fig. 3 (12): The screw part for assembling the main body connection bolt 10 and the main body fastening bolt 13 in which the permanent magnet is inserted into the main body 11 in one piece.
Figure 13 (13): Bolt for fastening the permanent magnet with the insertion body chamber
Figure 14 (14): o-ring for sealing when assembling the body and the main pipe bolt
Fig. 3 (15): Piston having a structure capable of inserting a permanent magnet
Fig. 3 (16): O-ring for sealing piston compression
3 (17): permanent magnet inserted into the piston (15)
Fig. 3 (18): Permanent Magnet
Fig. 19 (19): permanent magnet
Figure 20 (20): permanent magnet inserted into the bolt for fastening with the body chamber
Figure 21 (21): o- for sealing when assembling the body fastening bolt inserted body and permanent magnet

Claims (2)

A body (chamber) 11 capable of inserting a piston 15 having a structure capable of inserting permanent magnets into an elongated cylindrical cylinder body and a body capable of inserting permanent magnets for caps into the body The body 11 and the body 11 having an integral threaded portion 12 in the body so that the fastening bolt 13 and the body 11 and the main pipe connecting bolt 10 can be assembled to the body 11. A permanent magnet is inserted into the cylinder body through which the piston 15 with two or more o-rings for sealing is inserted, and a hole is formed in the permanent magnet disk to allow air to flow smaller than the inner diameter of the body 11. The permanent magnets (18.19) are arranged so that the same magnetic poles face each other so that the repulsive force acts on each other, and a sealing o-ring (21) is inserted into the body fastening bolt (13) for the cap for which the permanent magnet is inserted. Sealed in (11), air chamber (22.23.24.) When the piston (15) has a water shock, the air chamber air is compressed during the sliding movement to generate an air cushion into the air chamber space between the permanent magnet and the permanent magnet, thereby preventing the permanent magnet collision or damage and preventing corrosion due to damage. Fluid shock absorber using a permanent magnet, characterized in that According to claim 1, when the permanent magnet (18.19) is inserted into the body 11, it is smaller than the inner diameter of the body or to puncture the permanent magnet disk ((18.19) so that air compression does not occur so that air compression does not occur. Freely stacking two or more permanent magnets to easily cope with pressure. Insert permanent magnets (18.19) and use o-rings (14.16.21) to seal the body 11 after assembly. When sealing or sealing the inside of the body by welding the assembly (10.13) of the body (11), when the water shock occurs, the piston (15) is sliding movement of the internal air chamber (22.23.24) of the body (11) Permanent magnet (17.18.19.20) fluid shock absorbing device using a permanent magnet, characterized in that the compression pressure is generated with a repulsive force to absorb a greater water shock

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