KR100246527B1 - Oil type shock absorber - Google Patents

Abstract

The present invention, for example, connected to the pipes, such as apartment water pipes, oil pipes, hydraulic pipes to control the water hammer, pulsation, and relates to a hydraulic type protective device used to protect the piping, parts, pumps, hydraulic components, in particular hydraulic It relates to a hydraulic type prevention device which generates a flow resistance over a predetermined movement section when the hydraulic fluid stored in the type protection device receives an external discharge pressure, so that a buffer action by hydraulic pressure or hydraulic pulsation occurs. The oil chamber 51A, 51B ) Is provided with a cylindrical cylinder (50), and screwing a cylinder fixing flange (70) having a piston rod guide hole (71) to the lower portion of the cylinder (50), and an upper portion of the cylinder (50). The oil cap 62 having the oil injection hole 61 fixed thereto, and the piston 80 having an orifice 81 below the oil cap 62 and slidable in the cylinder 50 is installed. The oil cap 62 and the piston 80 While filling the hydraulic fluid between and the coil spring 120 having a predetermined elastic force is installed, the upper end of the piston rod 90 to the piston 80 and at the same time the lower end of the piston rod 90 The road block 100 is connected, and the road block 100 is configured to be movable up and down in the road block support body 130 fixed by the fastening means to the cylinder fixing flange 130.

Description

Hydraulic Guard

The present invention relates to, for example, a hydraulic protection device used to connect to pipes such as apartment water pipes, oil pipes, and hydraulic equipment to control water hammer and pulsation, and to protect the piping and hydraulic equipment. When the stored hydraulic fluid receives an external discharge pressure, the hydraulic resistance is caused to generate a flow resistance over a predetermined moving section to generate a buffer action by hydraulic pressure or hydraulic pulsation.

The conventional hydraulic type prevention device is provided with an upper air body 10 filled with air at a predetermined pressure through the air nozzle 12 into the air pressure chamber 11 as shown in FIG. 2, and this air body 10 is provided. The lower body 14 is fixedly assembled at the lower part of the bolt 16 and the nut 17 by a fastening, and a rubber diaphragm 18 is disposed between the upper air body 10 and the lower body 14. It is installed.

And the flange 14A of the lower body 14 is connected to the passage of the upstream side conduit 5 of the hydraulic pump P as shown in Figure 1 is completed the installation of the air-type protection port (1).

In this configuration, when the pump P is driven as shown in FIG. 1, the hydraulic pressure oil discharged from the pump P passes through the first conduit 5, and the pressure in the lower body 14 of the air type prevention port 1. It enters the operating chamber 15. At this time, a sudden water pressure is formed in the pressure operating chamber 15 so that the diaphragm 18 contracts upwards as shown by a dashed line, and at the same time, a high pressure is formed in the air pressure chamber 11 of the upper air body 10. It cushions the impact on hydraulic pressure.

In this way, the discharge flow rate is stabilized, that is, by removing the pulsation of the flow rate and flowing the pipe to protect the bent portion of the bent portion of the pipe (5) and (6), as well as to protect the fluctuation of each pipe and the pipe weld crack. It is characteristic.

As described above, the conventional hydraulic type prevention device has the following problems to be installed for water hammering of piping system, pulsation prevention, pressure control of hydraulic equipment, valve protection of sanitary facilities, and clearance of oil pipes.

First, since the diaphragm 18 is always in contact with the fluid for a long time after installation in the pipe, corrosion occurs. As a result, the air filled in the air pressure chamber 11 naturally leaks, and the air pressure drops and functions properly. Was difficult.

Second, the air pressure in the air pressure chamber 11 during the operation after the maintenance work can not be measured, there is an inconvenience to replace or recharge the new one.

Third, when the diaphragm 18, the air nozzle 12 is replaced, the entire upper air body 10 must be dismantled and assembled by a professional technician.

SUMMARY OF THE INVENTION The present invention has been made in view of the above and circumstances, and is an object of the present invention to improve the structure of the hydraulic type protective tool, and to provide a hydraulic type protective tool that is semi-permanent, and does not require parts replacement and lubrication even during recycling construction.

Specific means of the present invention for achieving the above object is provided with a cylindrical cylinder having an oil chamber, screwing the cylinder fixing flange having a piston rod guide hole in the lower portion of the cylinder, the upper portion of the cylinder A fixed oil cap having an oil injection hole therein, a piston having an orifice under the oil cap and slidably movable in the cylinder, injecting hydraulic oil between the oil cap and the piston, Coupling the coil spring having a reaction force, connecting the upper end of the piston rod to the piston and at the same time connecting the road block to the lower end of the piston rod, supporting the road block fixed by the fastening means to the cylinder fixing flange It is characterized by configured to operate up and down sliding in the body.

1 is a state diagram of the conventional air-type protection.

2 is a cross-sectional view of a conventional air type prevention tool.

3 is a cross-sectional view of a hydraulic type preventive device according to an embodiment of the present invention.

4 is an operating state of the piston according to an embodiment of the present invention.

<Description of the symbols for the main parts of the drawings>

50: cylinder 51A, 51B: oil chamber

61: oil injection hole 62: oil cap

70: cylinder fixing flange 71: piston rod guide hole

80: piston 81: orifice

90: piston rod 100: road block

120: coil spring 130: cylinder fixing flange

Hereinafter, with reference to the accompanying drawings will be described an embodiment of the present invention;

As shown in Fig. 3, reference numeral 50 denotes a cylindrical cylinder.

The cylinder 50 has oil chambers 51A and 51B communicating therein, and an oil cap 62 having an oil injection hole 61 is inserted into an upper portion of the oil chamber 51A to allow the cylinder 50 to be inserted therein. ) Is fixed by welding, and an oil nipple (not shown) is assembled in the oil injection hole 61 to inject hydraulic oil into the oil chambers 51A and 51B.

And a cylinder fixing flange 70 having a piston rod guide hole 71 in the lower portion of the cylinder 50 is screwed.

The cylinder 50 is assembled with a piston 80 which is slidable in the oil chambers 51A and 51B, and the piston 80 has an orifice 81 which becomes a hydraulic oil flow path in the oil chambers 51A and 51B. And one end of the piston rod 90 is screwed to the central axis of the cylinder 50, and the rod block 100 is fixed to the other end of the piston rod 90 by a bolt 110. The road block 100 slides in the road block supporting body 130.

And between the oil cap 62 and the piston 50, a coil spring 120 having a predetermined elastic force is installed.

The road block support body 130 forms a through-hole block guide hole 131 through which the road block 100 slides, and the cylinder fixing flange 70 is formed at an upper end of the road block support body 130. The lower flange 133 is connected to the upper flange 132 fixed to the bolt 210 and the connection pipe 200, such as the piping system, with the bolt 212.

Reference numerals 220 and 221 denote airtight O-rings, 222 denotes U-packing, and 223 denotes earth seals.

The operating state of this embodiment configured as described above will be described.

First, the piston 80 assembled to the cylinder 50 is in a state of being lowered below the cylinder 50 by receiving the elastic compressive force of the coil spring 120, and at this time, the operating oil is an oil chamber (the upper side of the piston 80) It is located in 51A).

In this state, if the feeding amount discharged by the pump (not shown) suddenly acts as the fluid pressure through the connecting pipe 200, the fluid pressure overcomes the repulsive force of the coil spring 120 and pushes up the road block 100. Therefore, the piston rod 90 connected to the road block 100 moves the piston 80 upwardly of the cylinder 50.

At this time, as the coil spring 120 is compressed to decrease its height, the pressure in the oil chamber 51A is increased and the volume in the oil chamber 51A is reduced. At the same time, as shown in FIG. 4, the space of the lower oil chamber 51B formed between the bottom of the piston 80 and the top of the cylinder fixing flange 70 is expanded and the pressure is lowered. Therefore, the hydraulic fluid filled in the oil chamber 51A on the upper portion of the piston 80 flows through the orifice 81 by the raised volume of the piston 80 to the bottom surface of the piston 80 and flows into the oil chamber 51B in which the volume is increased. Will enter.

In this way, when the fluid shock acts on the hydraulic type preventer, the coil spring 120 buffers the primary water hammer and at the same time, the hydraulic fluid that is staying in the second space gradually flows through the orifice 81 to the other space while receiving the flow resistance. It is possible to protect the pipes and pipe connections caused by sudden hydraulic oil.

When such a sudden water hammer is statically converted and falls to a predetermined pressure, the piston 80 gradually descends integrally with the piston rod 90 and the road block 100 by the elastic restoring force of the coil spring 120 again. The hydraulic oil located in the lower oil chamber 51B of the 80 is raised through the orifice 81 again by the lowered volume of the piston 80 and flows into the upper oil chamber 51A to the upper portion of the piston 80. Will be located.

As such, the piston 80 operated by the fluid pressure is immersed in the fluid, and thus, the piston 80 is not corroded like a diaphragm formed of a conventional rubber material and can be used semi-permanently without deformation.

In addition, there is no need for separate parts replacement and oiling during recycling, and the manufacturing cost is also lower than that of the conventional diaphragm.

In the above embodiment, but described in the state installed in the piping system, the present invention can be used in various ways, such as for pressure control of hydraulic equipment, valve protection of sanitary equipment, shock (shock) prevention of oil pipes.

As described above, according to the present invention, it is installed in a piping system and the like to buffer the sudden fluid pressure primarily by the elastic force of the coil spring and at the same time to induce a pressure drop gradually by using the fluid flow resistance to protect the piping and the hydraulic equipment. Of course, it is possible to use semi-permanently due to the improvement of the operation durability of the hydraulic type protective device, and it is easy to recycle the construction without the need for parts replacement and oiling.

Claims (1)

A cylindrical cylinder (50) having oil chambers (51A, 51B) is provided, and a cylinder fixing flange (70) having a piston rod guide hole (71) is screwed into the lower portion of the cylinder (50). An oil cap 62 having an oil injection hole 61 fixedly installed on an upper portion of the cylinder 50, and having a orifice 81 below the oil cap 62, the piston slidably movable in the cylinder 50. (80) is installed, hydraulic oil is injected between the oil cap (62) and the piston (80), and the coil spring (120) having a predetermined elastic force is installed, and a piston rod is mounted on the piston (80). The rod block 100 is connected to the upper end of the piston rod 90 and the rod block 100 is connected to the lower end of the piston rod 90, and the rod block 100 is fixed to the cylinder fixing flange 130 by fastening means. Hydraulic type prevention device, characterized in that configured to be movable up and down sliding in the support body (130).

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