KR100902259B1 - Sliding disc valve - Google Patents

Abstract

A sliding disc valve is provided to apply the same pressure to two sealing discs always and compensate for abrasion of a packing member caused by repetitively opening and closing a valve. A sliding disc valve comprises housing, a pair of sealing discs(200a,200b), a pressing unit(300), and an actuating unit(400). The housing comprises left and right covers(110,120). An inlet(111) and an outlet(121) are formed in the left and right covers. A pair of sealing discs are mounted between the inner sides of the outlet and the inlet and opens and closes the inlet and the outlet at the same time. The pressing unit presses a pair of sealing discs by using one elastic member(310). The actuating unit operates the pressing unit in a flow direction and a vertical direction of the fluid according to the opening and closing degree of a pair of sealing discs.

Description

Sliding Disc Valve

The present invention relates to a sliding disc valve, and more particularly, a sliding disc valve to pressurize two sealing discs evenly using a single spring at all times, and to compensate for this even when the packing of the operation means is worn out. It is about.

In general, the valve is a flow rate control, pressure control and blocking element of the fluid, there are various types depending on the flow rate, the nature of the fluid and the installation location. Among various types of valves, a ball valve is widely used as a pressure reducing valve for automatically reducing the pressure of a fluid and maintaining a constant pressure after the pressure reduction.

1 is a cross-sectional view showing an example of a conventional ball valve. The ball valve 10 includes a body 13 in which flow passages 11 and 12 for inlet and outlet are formed. In addition, a ball portion 20 having a flow path switching flow path 21 therebetween is provided between the inlet and outlet flow paths 11 and 12. The ball 20 is operated by the adjusting means 30 including a handle or a motor, not shown.

The ball valve made in this way is fluid as the induction conversion flow path 21 opens and closes the inlet and outlet flow paths 11 and 12 as the ball portion 20 is rotated left and right in the 90 ° angle range by the adjusting means 30. Enables flow blocking and supply

However, the conventional ball valve has the following problems.

1) Since the valve opens and closes as the ball rotates at an angle of 90 °, fluid flows into the outer circumferential surface of the ball during opening and closing of the valve. The fluid introduced in this way becomes stagnant around the ball part, and the valve may be broken due to volume expansion of the fluid.

2) Particularly in the case of the transfer of fluid in which foreign matter is contained or in a pipeline for supplying powder, etc., foreign matter or powder is sometimes caught between the ball parts and interferes with the opening and closing action of the valve. This is a risk of accidents in case of dangerous fluids such as chemicals.

3) If the ball valve is not fully opened (90 ° rotation of the ball), noise and cavitation may be the cause of water hammer.

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The present invention has been devised in view of this point, and more specifically, it is configured to press two sealing discs by using one elastic means, so that the sliding force can always provide the same pressing force on the two sealing discs. It is a first object to provide a disc valve.

Further, the present invention further comprises a compensation means according to the wear of the packing member in the operating means for operating the sealing disc, so that even if the packing member is worn by the opening and closing of the valve repeatedly made it is possible to compensate for the life of the valve It is a second object to provide a sliding disc valve that can be extended as well as can prevent leakage in advance.

In addition, the present invention is further provided with a sensor for detecting the pressing force of the sealing disc, it is possible to detect the degree of leakage of the fluid, it is possible to easily detect the replacement time of the sealing disc as well as the detection of leakage of the fluid. A third purpose is to provide a sliding disc valve.

The sliding disc valve according to the present invention for achieving this object is,

A housing (100) having left and right covers (110, 120) formed with an inlet (111) and an outlet (121), respectively, at positions facing each other to allow fluid to flow in one direction;

A pair of sealing discs 200a and 200b mounted between the inlet 111 and the inner surface of the outlet 121 and simultaneously opening and closing the inlet 111 and the outlet 121;

Pressing the pair of sealing discs 200a and 200b to press the pair of sealing discs 200a and 200b to the inner surfaces of the inlet 111 and the outlet 121 by using one elastic means 310, respectively. Giving pressing means 300;

And operating means (400) for operating the pressing means (300) perpendicularly to the flow direction of the fluid in a state of airtightness according to the opening and closing degree of the pair of sealing discs (200a, 200b); .

And, the inner surface of the left cover 110 is characterized in that the leakage sensor for detecting more oil (112) for detecting a leak from the sealing disk (200a).

On the other hand, the pressing means 300, the elastic means 310; Pin portions 320a and 320b respectively inserted at both ends of the elastic means 310 to press the pair of sealing discs 200a and 200b to the outside; And a drive hub part 330 for integrally operating together with the fin parts 320a and 320b to surround the elastic means 310. And, the elastic means 310 is characterized in that the compression spring. In addition, the drive hub 330 may include a cylindrical first hub 330a installed between the pair of sealing discs 200a and 200b; And a second hub 330b inserted into the outside to be positioned at the center of the first hub 330a and connected to the operation means 400.

In addition, the operating means 400, the actuator 410 is mounted to the housing 100, connected to the drive hub portion 330 to operate perpendicular to the flow direction of the fluid; And leakage preventing means (420) for preventing the leakage of the fluid according to the operation of the actuator 410. At this time, the actuator 410 is characterized in that the hydraulic or pneumatic cylinder, or a drive motor. The leakage preventing means 420 may include a spacer 421 installed at a reduced pressure on the stepped portion 131a formed in the housing 100; A packing member 422 installed on the spacer 421; Compensation means 430 for compensating for the amount of wear of the packing member 422; And a closing plate 423 for closing and closing the upper portion of the housing 100. In addition, the packing member 422 is characterized in that made of one or more materials selected from RTFE fiber, aramid fiber, glass fiber, REEK fiber, PPS fiber, metal wire woven or non-woven fabric.

Finally, the compensation means 430, the cylindrical spacer 431 inserted between the housing 100 and the closing plate 423, and sequentially stacked in the spacer 431 to press the packing member 422 Position compensation cartridge 432, the compensation compression spring 433 and the packing member for pressure 434 is characterized in that it is made. And, the packing member for pressure 434 is characterized in that the gland packing.

According to the present invention has the following effects.

1) Since two sealing discs are operated by using one compression spring, it is possible to supply equal pressure to each sealing disc. Accordingly, the opening and closing action of the valve can be prevented from being leaned to either side.

2) Compensation means due to abrasion, etc. are provided in the sealing (packing) of the operation means for operating the sealing disc to compensate even if the sealing is worn. Therefore, even if the seal is worn due to the repeated operation of the valve, it is possible to prevent the leakage of the fluid or gas as well as the extension of the valve life.

3) By further providing a sensor to measure the pressing force of the sealing disk, it is possible to know the timing of replacement of the valve or the sealing disk by detecting the leakage of fluid in advance.

4) Full confidentiality can be guaranteed even when supplying dangerous toxic gases as well as fluids such as construction, industrial, industrial or chemical.

Hereinafter, the configuration of the sliding disk valve according to the present invention in more detail.

Figure 2 is a perspective view for showing the configuration of the sliding disk valve according to the present invention, Figure 3 is a cross-sectional view for showing a closed state of the sliding disk valve according to the present invention.

The sliding disc valve according to the present invention includes a housing 100 for inducing fluid flow, a pair of sealing discs 200a and 200b for opening and closing a flow path in the housing 100, and a pair of sealing discs 200a. It comprises a pressing means 300 to provide a pressing force evenly to the, 200b to maintain the airtight, and an operating means 400 for substantially operating the pair of sealing disks (200a, 200b).

Hereinafter, the configuration and operation of these components will be described for each component as follows.

The housing 100 is formed with a space portion 100a which functions as a flow path so that the fluid can flow therethrough. The space part 100a is formed to have an inner diameter of at least twice the diameter of the sealing discs 200a and 200b which will be described later. This is to ensure sufficient space for the sealing disks 200a and 200b to move up and down.

The housing 100 is finished by the left and right cover (110, 120) on both sides. In particular, the inlet 111 and the outlet 121 are formed in the left and right covers 110 and 120 to guide the flow of the fluid in the center, respectively. In a preferred embodiment of the present invention, the inlet portion 111 and the outlet portion 121 are formed in the lower portion of the left and right cover 110, 120, respectively, the inlet portion 111 and the outlet portion when the lifting and lowering of the sealing disc (200a, 200b) It is preferable that the 121 be opened and closed at the same time.

In addition, the inner surface of the left cover 110 is provided with a leakage oil detecting sensor 112 to determine whether the fluid leaks through the pressing force, that is, the airtightness of the sealing disks (200a, 200b) to be described later. The sensor 112 for oil leakage detection means a detection element that detects an electrical signal according to a pressure change, such as a piezoelectric element, and determines that the oil is leaked when the pressure is below a predetermined pressure.

In addition, the housing 100 has a mounting portion 130 protrudingly formed on the outer circumferential surface to install the operation means 400 to be described later. The mounting portion 130 is provided with a mounting hole 131 in a direction perpendicular to the fluid flowing inside the housing 100. In particular, the mounting hole 131 is formed to be stepped in two stages so that the step 131a is formed on the inner circumferential surface. At this time, the mounting hole 131 is formed in the inner diameter of the housing 100 smaller than the outer inner diameter. This step 131a is used when the leakage preventing means 420 will be described later, which will be described later.

The sealing discs 200a and 200b are components that open and close the inlet 111 and the outlet 121, respectively. The sealing discs 200a and 200b have pressure holes 210a and 210b formed on their rear surfaces, respectively. In addition, the sealing discs 200a and 200b may be made of various materials in consideration of the type of fluid and use temperature. Generally usable materials include cast iron, cast steel, rubber, plastic, stainless steel, and the like. In a preferred embodiment of the present invention, it is preferable to use S45C as the material of the sealing discs 200a and 200b.

The sealing discs 200a and 200b formed as described above are installed such that the pressing holes 210a and 210b face each other and closely adhere to the left and right covers 110 and 120, respectively. The sealing discs 200a and 200b pressurize and seal the inlet part 111 and the outlet part 121 while being subjected to a predetermined pressure by the pressing means 300 installed between the above-mentioned pressing holes 210a and 210b. Given.

The pressurizing means 300 pressurizes the elastic means 310 to substantially press the sealing discs 200a and 200b, and the sealing discs 200a and 200b to be in close contact with the left and right covers 110 and 120 by elastic force. It comprises a pair of pin portions (320a, 320b), and a drive hub portion 330 for connecting the pressing means 300 and the operating means 400 to be described later.

The elastic means 310 presses the sealing discs 200a and 200b through a pair of pin portions 320a and 320b mounted at both ends thereof. In other words, the entire length of the elastic means 310 having the pins 320a and 320b mounted at both ends thereof is made longer than the length between the pair of pressing holes 210a and 210b described above. The elastic means 310 is installed to be inserted into each of the pair of pressing holes (210a, 210b) corresponding to each pin portion (320a, 320b) forcibly compressed. Accordingly, the pins 320a and 320b pressurize the sealing discs 200a and 200b by the compressive force of the elastic means 310 to obtain an airtight effect. In a preferred embodiment of the present invention, by way of example the elastic means 310 shows an example using a compression spring.

The drive hub part 330 includes first and second hubs 330a and 330b to prevent distortion of the elastic means 310 and to cope with weakening of the compressive force.

The first hub 330a is configured to surround the outside of the elastic means 310. In this case, the length of the first hub 330a is preferably shorter than the distance between the pair of pressing holes 210a and 210b. The first hub 330a configured as described above prevents the elastic means 310 from being excessively compressed or warped by foreign matter.

The second hub 330b is installed to be inserted into the outer circumferential surface of the first hub 330b in the form of a sleeve. In particular, the second hub 330b is provided with a mounting portion 331 to be mounted on the outer circumferential surface and the operating means 400 to be described later.

The drive hub 330 made as described above is movable up and down by the operation means 400, and in particular, the first hub 330a can flow in the axial center direction of the second hub 330b. .

The actuating means 400 is connected to the drive hub 330 described above to provide an actuating force to move the pressurizing means 300 up and down, and to prevent the leakage of fluid due to the operation of the actuator 410 It comprises a leakage preventing means 420 for giving.

In a preferred embodiment of the present invention, the actuator 410 may use a cylinder or a motor so that the pressing means 300 can move up and down. In particular, in the case of a cylinder, both a hydraulic cylinder and a pneumatic cylinder may be employed, but in consideration of the accuracy of the valve operation, it is more preferable to employ a hydraulic cylinder. In the case of using a motor, it is preferable to further constitute a means capable of converting the rotational motion of the motor into a linear motion, for example, a ball joint or a rack pinion structure.

In addition, in the preferred embodiment of the present invention, the actuator 410 is preferably determined in consideration of the mounting distance to the pressing means 300 and the length thereof. For example, in the case of using a cylinder, a multi-stage cylinder may be used, and in the case of a motor, it may be used in connection with the pressurizing means 300 using an intermediate shaft or a coupling.

In addition, the actuator 410 is inserted into the rod or the intermediate shaft penetrates the leakage preventing means 420 to be connected to the pressing means 300.

The leak preventing means 420 compensates for the amount of wear of the spacer 421 inserted to be caught by the step 131a described above, the packing member 422 inserted into the spacer 421, and the packing member 422. Comprising means for 430 and the closing plate 423 for closing the upper portion is made. These components are inserted into the mounting hole 131 of the housing 100 in a stacked structure in the above-described order.

Packing member 422 is preferably made of a variety of materials in consideration of the purpose of the valve, that is, the type of fluid or the operating temperature. In the preferred embodiment of the present invention, the packing member 422 may be made of one or more materials selected from RTFE fiber, aramid fiber, glass fiber, REEK fiber, PPS fiber, metal wire or non-woven fabric selected from the group. have.

In particular, the packing member 422 is inserted into the mounting hole 131 to be caught on the top of the spacer 421. Then, the packing member 434 for pressurization of the compensating means 430 is seated thereon.

Compensation means 430 is a cylindrical spacer 431 inserted between the mounting portion 130 and the closing plate 423 and the position compensation for pressing the packing member 422 is sequentially stacked in the spacer 431 And a cartridge 432, a compensating compression spring 433, and a pressing packing member 434.

Here, the spacer 431 is used to secure a predetermined space between the mounting portion 130 and the closing plate 423. In addition, a compensation compression spring 433 is provided at both ends thereof by the position compensation cartridge 432 and the pressurizing packing member 434. In particular, the position compensation cartridge 432 is inserted and fixed to the closing plate 423, the pressing packing member 434 is inserted into the mounting hole 131 so that the lower end can press the packing member 422. .

Therefore, the compensating compression spring 433, one end of which is fixed to the closing plate 423, will always press the pressing packing member 434 by the compression force. Accordingly, since the packing member 422 is pressed by the compensating compression spring 433 by the amount of wear, it is possible to always maintain a constant airtightness.

And, in the preferred embodiment of the present invention, it is preferable to use the gland packing used for preventing the leakage phenomenon by inserting between the rotating body and the fixed body, such as a pump for the pressure packing member 434.

Finally, the closing plate 423 is fixed to the upper portion of the spacer 431 described above. In addition, the actuator 410 described above is mounted on the top of the closing plate 423, and the end thereof is configured to be mounted on the operating means 400.

Hereinafter, the operation of the sliding disk valve according to the present invention with reference to the drawings.

4 is a cross-sectional view for showing the opened state of the sliding disk valve according to the present invention.

In the sliding disc valve according to the present invention, the inlet 111 and the outlet 121 are closed by the pair of sealing discs 200a and 200b as shown in FIG. 3. The sealing discs 200a and 200b are pressed by the pressing means 300 to the left and right cover 110 and 120, respectively, and are in close contact with each other.

When operating the actuator 410 in this state, the pressing means 300, that is, the second hub 330b connected to the rod or the intermediate shaft is pulled up. Accordingly, the sealing discs 200a and 200b open up the inlet 111 and the outlet 121 while moving up along the left and right cover 110 and 120, respectively.

On the other hand, the left cover 110 may detect the pressure applied by the sealing disk 200a by the leak detection sensor 112 provided in the inlet portion 111, and may determine whether or not the leakage based on the detected pressure. Will be.

The sealing discs 200a and 200b thus opened close the inlet 111 and the outlet 121 by the opposite action.

In the preferred embodiment of the present invention, even if the packing member 422 is worn by such repeated opening and closing action, the compensating compression spring 433 of the compensating means 430 continuously presses the packing member 422. This prevents fluid from leaking from the sliding disc valve.

Although the present invention has been described in connection with the above-mentioned preferred embodiments, it is possible to make various modifications or variations without departing from the spirit and scope of the invention. Accordingly, the appended claims will cover such modifications and variations as long as they fall within the spirit of the invention.

1 is a cross-sectional view showing an example of a conventional ball valve.

Figure 2 is a perspective view for showing the configuration of the sliding disk valve according to the present invention.

3 is a cross-sectional view for showing a closed state of the sliding disk valve according to the present invention.

4 is a cross-sectional view for showing the opened state of the sliding disk valve according to the present invention.

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

100: housing 100a: space part

110: left cover 111: entrance

112: leak detection sensor 120: right cover

121: outlet 130: mounting portion

131: mounting hole 131a: step

200a, 200b: sealing disc 210a, 210b: pressing hole

300: pressing means 310: elastic means

320a, 320b: pin portion 330: drive hub portion

330a, 330b: first and second hub 331: mounting portion

400: operating means 410: actuator

420: leak prevention means 421: spacer

422: packing member 423: finishing plate

430: compensation means 431: spacer

442: position compensation cartridge 433: compensating compression spring

434: packing member for pressure

Claims (11)

A housing (100) having left and right covers (110, 120) formed with an inlet (111) and an outlet (121), respectively, at positions facing each other to allow fluid to flow in one direction; A pair of sealing discs 200a and 200b mounted between the inlet 111 and the inner surface of the outlet 121 and simultaneously opening and closing the inlet 111 and the outlet 121; The pair of sealing discs 200a and 200b are brought into close contact with the inner surfaces of the inlet portion 111 and the outlet portion 121 using one elastic means 310, respectively. Pressing means for pressing the pressure 300; And operating means (400) for operating the pressurizing means (300) perpendicularly to the flow direction of the fluid in a state where airtightness is maintained according to the opening and closing degree of the pair of sealing discs (200a, 200b). The operating means 400, An actuator (410) mounted to the housing (100) and connected to a drive hub (330) and configured to be a hydraulic or pneumatic cylinder or a drive motor to operate perpendicular to the flow direction of the fluid; And And leakage preventing means (420) for preventing the leakage of the fluid according to the operation of the actuator (410), The leakage preventing means 420, A spacer 421 installed at a reduced pressure on the stepped portion 131a formed in the housing 100; A packing member 422 installed on the spacer 421; Compensation means (430) for compensating the amount of wear of the packing member (422); And Includes; closing plate 423 for closing and closing the upper portion of the housing 100, The compensation means 430, A cylindrical spacer 431 inserted between the mounting portion 130 and the closing plate 423, Position compensation cartridge 432, the compression compression spring 433 and the pressure packing member 434 to be sequentially stacked in the spacer 431 to press the packing member 422. Sliding disk valve comprising a. The method of claim 1, Sliding disk valve, characterized in that the inner surface of the left cover 110 is further provided with a leak detection sensor 112 for detecting a leak from the sealing disk (200a). The method of claim 1, The pressing means 300, Pin portions 320a and 320b inserted into both ends of the elastic means 310 to press the pair of sealing discs 200a and 200b to the outside, respectively; And And a drive hub portion (330) for integrally operating together with the pin portions (320a, 320b) surrounding the elastic means (310). The method according to claim 1 or 3, The elastic means 310 is a sliding disk valve, characterized in that the compression spring. The method of claim 3, wherein The drive hub 330 may include a cylindrical first hub 330a installed between the pair of sealing discs 200a and 200b; And a second hub (330b) inserted into the outside so as to be positioned at the center of the first hub (330a) and connected to the operation means (400). delete delete delete delete delete delete

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