KR101313050B1 - Valve and rising stem ball valve with groove - Google Patents

Abstract

The present invention relates to a valve having a groove-type groove, and more particularly, a valve having a groove-type groove which can be formed to have a depth less than the thickness of the stem so as not to penetrate, unlike the related art, thereby reducing driving torque. For rising stem ball valves.

Description

Valve and rising stem ball valve with groove

The present invention relates to a valve having a groove-type groove, and more particularly, a valve having a groove-type groove which can be formed to have a depth less than the thickness of the stem so as not to penetrate, unlike the related art, thereby reducing driving torque. For rising stem ball valves.

In general, a ball valve is a ball valve having an opening formed in a direction perpendicular to a connection path connecting an inlet and an outlet of a valve body to interrupt a flow of fluid by a rotational operation of the ball. Say.

This ball valve is held in close contact to prevent fluid from leaking between the valve body and the ball.

In this case, when the ball is rotated in close contact with the valve body, there is a problem in that friction is severely generated, and a rising stem (rising stem) technology for preventing this has been proposed.

This will be described with reference to FIG. 1, which is a conceptual diagram of the rising stem.

As shown, the lower stem LS mounted to the ball B for the rising stem and the lower stem LS can be smoothly moved up and down, and additionally the valve body ( A trunnion B2 inserted into the bottom of VB may be formed on the bottom surface of the ball B. FIG.

At this time, the lower stem LS is formed in a vertical direction (direction I) and a vertical actuating part LS3 installed in the ball B and a ball operating part for driving the lower stem LS (not shown). And an inclined portion LS2 connected to the connecting portion LS1 and the vertical portion LS3 while being inclined.

At this time, the roller (R) is disposed on both sides of the inclined portion (LS2) to facilitate the lifting and lowering movement of the lower stem (LS).

When the lower stem LS having such a shape is lowered, the right side of the inclined portion LS2 continuously presses the right roller of the roller R, so that the ball B is clockwise (direction II). Tilting or tilting.

In other words, when the lower stem LS is lowered, the ball B is brought into close contact with the valve body VB.

If the lower stem LS is raised, the ball B is tilted in the opposite direction (direction III) so that the ball B is spaced apart from the valve body VB.

Therefore, when the ball B is to be rotated, the lower stem LS is raised and then the lower stem LS is rotated, and the ball B is to be in close contact with the valve body VB. What is necessary is just to lower the said lower stem LS.

On the other hand, when the ball (B) is tilted, the entire portion of the lower stem (LS) is also formed to be inclined slightly in conjunction with this.

That is, the dual action of the tilting or rotation is possible according to the lifting and lowering of the stem, and the ball valve having such action is a rising stem ball valve.

The mechanism of such a rising stem is described in detail in US Patent Nos. 3,207,468, 3,515,371, 4,917,354, etc., and thus redundant description is omitted.

Meanwhile, a ball valve having the rising stem mechanism described above will be described with reference to FIG. 2.

As shown in the related art, the conventional ball valve 1 has a valve body VB incorporating a ball B in which the lower stem LS is installed as described above, and the lower stem LS is lowered or rotated. And a ball operating part BD for tilting or rotating the ball B, the ball operating part BD, and a driving part WH for driving the ball operating part BD.

In this case, when the lower stem LS is lifted and lowered by the ball driving part BD, the ball B makes a tilting motion in close contact with or spaced from the valve seat of the valve body VB, and the lower stem LS When the rotational movement, the ball (B) is interlocked with the rotational movement to interrupt the flow of fluid.

However, the movement of the lower stem LS is determined by the pin P inserted into the groove LS4 formed in the lower stem LS, as shown in FIG. 3.

That is, as described above, the lower stem LS moves up or down, and the lifting movement displacement or the rotation movement displacement is determined by the trajectory of the groove LS4 to which the pin P is coupled. do.

At this time, the groove LS4 is formed to penetrate the surface of the lower stem LS, and then the pin P is inserted into the groove LS4.

That is, since the grooves LS4 and the pins P mutually move in a state where they are engaged with each other, there is a problem that a lot of torque is required to drive the lower stem LS.

In addition, since the relative movement is performed while the groove LS4 and the pin P are engaged with each other, there is a problem in that the wear and tear are often damaged.

The present invention is to solve the above-mentioned problems, and the groove is formed to be recessed on the lower stem, and then the spherical shape of the spherical shape can be arranged in the groove to reduce the driving torque of the lower stem unlike the prior art. It is an object of the present invention to provide a valve and a rising stem ball valve that can enhance durability.

The present invention for achieving the above object is a valve body (VB) in which fluid flows, the ball (B) is installed inside the valve body (VB) to regulate the flow of the fluid, the device in the ball (B) A lower stem 600 for tilting and rotating the ball B, and an upper stem 100 and an upper stem 100 and a lower portion connected to the lower stem 600 to rotate the lower stem 600. Rising stem type including coupling 200 to receive the stem 600 and groove 121 formed in the upper stem 100 to determine movement of the lower stem 600. As a ball valve, the groove 121 is grooved on the surface of the upper stem 100, the depth of the groove 121 has a rising stem type having a groove-shaped groove smaller than the thickness of the upper stem 100 The ball valve has one feature.

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At this time, the upper stem 100 has a hollow cylindrical shape, but the upper stem body 120 and the groove 121 is formed on its outer surface, and extends in the upper direction to the upper end of the upper stem body 120 But it may include a threaded portion 110 is formed with a thread 111 on the outer surface.

In addition, to rotate the upper stem 100, the cylindrical shape has a screw thread (410a) is formed on the inner surface further comprises a drive nut 400 to which the threaded portion 110 of the upper stem 100 is coupled. can do.

In addition, the driving nut 400 may further include a drive handle (WH) for rotating the drive nut 400.

In addition, the housing 200 may further include a through hole 210a which is mounted on the groove 121 after the coupler SP penetrates.

In addition, the coupling sphere (SP) further comprises a coupler cover (SPC) in close contact with the groove 121, the coupler cover (SPC) is a disk-shaped cover body covering the through hole (210a) ( SPC1, and may include a coupler pressing portion (SPC2) for protruding from the cover body (SPC1) and penetrates the through hole (210a) and pressurizes the coupler (SP), the coupler pressing portion SPC2 may be formed to have a circular circular shape so that the coupler (SP) can be in close contact.

In addition, it is also possible to further include a non-lubricating bushing 300 which is installed inside the housing 200 and has a hollow cylindrical shape for receiving the upper stem 100.

In addition, the oil free bushing 300 includes a first oil free bushing 310 and a second oil free bushing 320 for receiving the upper stem body 120 of the upper stem 100, wherein the first oil free bushing ( 310 and the second non-lubricating bushing 320 may be spaced apart from each other to expose the groove 121.

According to the present invention as described above, since the coupler and the groove which determine the movement of the lower stem are in contact only at a specific part, unlike the related art, the driving torque for driving the lower stem can be reduced and mutual wear of the groove and the coupler can be reduced. It can be made small, there is an effect that can increase the durability.

1 to 3 is a conceptual diagram for a conventional rising stem ball valve.
4 to 6 are conceptual views of the rising stem ball valve of the present invention.
7 is a conceptual diagram of a pluggable valve of the present invention.

Before describing the various embodiments of the present invention in detail, it will be appreciated that the application is not limited to the details of construction and arrangement of components described in the following detailed description or illustrated in the drawings.

The invention may be embodied and carried out in other embodiments and carried out in various ways.

In addition, device or element orientation (e.g., "front", "back", "up", "down", "top", "bottom" The expressions and predicates used herein with respect to terms such as "," left "," right "," lateral ", etc. are used merely to simplify the description of the present invention, It will be appreciated that the element does not simply indicate or mean that it should have a particular direction.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Reference will now be made in detail to the preferred embodiments of the present invention, examples of which are illustrated in the accompanying drawings. Prior to this, terms and words used in the present specification and claims should not be construed as limited to ordinary or dictionary terms, and the inventor should appropriately interpret the concepts of the terms appropriately It should be interpreted in accordance with the meaning and concept consistent with the technical idea of the present invention based on the principle that it can be defined.

Therefore, the embodiments described in the specification and the drawings shown in the drawings are only the most preferred embodiment of the present invention and do not represent all of the technical idea of the present invention, various modifications that can be replaced at the time of the present application It should be understood that there may be equivalents and variations.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings and embodiments.

Example 1

The present invention is coupled to the stem 12 to operate the ball (B) or plug (PL) of the valve as shown in Figure 4, and the groove (12b) formed in the stem 12, the stem 12 A valve including a coupler (SP) to determine the movement of the groove, the groove 12b is formed grooved on the surface of the stem 12, the depth of the groove 12b is greater than the thickness of the stem 12 The valve 10 is formed to be small.

That is, conventionally, the groove was formed to penetrate the surface of the stem, and then the pin was inserted and coupled.

However, in the conventional case, since the grooves and the pins move in a state where the grooves are engaged with each other, a lot of torque for driving the stem is required, and the grooves and the pins are often abrasion mutually, and thus durability is impaired.

However, in the case of the present invention, the groove 12b does not penetrate the stem 12 but has a certain depth (that is, formed to be smaller than the thickness of the stem 12) and has a recess on the surface of the stem 12. After being formed so as to form a spherical coupling sphere (SP) to the groove (12b).

In the case of the present invention, since the coupler SP moves on the groove 12b, it becomes easier to rotate the stem 12 than in the related art, so that the driving torque can be reduced.

In addition, the wear and tear of the coupler (SP) and the groove (12b) can also be reduced, thereby increasing the durability.

On the other hand, the present invention is formed in the groove 12b to be grooved as described above, which is applicable to all the general valve.

In other words, in addition to the rising stem ball valve described later, the plug PL shown in FIG. 7 can be mounted and used in the stem 12 described above.

Example 2

6 and 7, a valve body VB through which a fluid flows, a ball B installed inside the valve body VB to control the flow of the fluid, and the ball ( A lower stem 600 mounted to B) to tilt and rotate the ball B, and an upper stem 100 and an upper stem connected to the lower stem 600 to rotate the lower stem 600; And a coupler (SP) coupled to the housing (200) for receiving the lower stem (600) and the groove (121) formed on the upper stem (100) to determine movement of the lower stem (600). It is to be applied to the rising stem ball valve (20).

That is, the groove 121 is formed to be recessed on the surface of the upper stem 100, but the depth of the groove 121 is formed to be smaller than the thickness of the upper stem 100.

Since the rising stem ball valve has already been described, a detailed description thereof will be omitted.

In addition, the upper stem 100 and the lower stem 600 of the rising stem ball valve 20 of the present invention are not integrated as in the prior art but are separated.

In other words, the upper stem 100 and the lower stem 600 are arranged separately so that the pins are coupled, and by this configuration, the upper stem 100 or the lower stem 600 can be replaced more easily. This will be described later again.

Meanwhile, the upper stem 100 has a hollow cylindrical shape, but the upper stem body 120 having the groove 121 formed on an outer surface thereof and extending upward in an upper end portion of the upper stem body 120. But it may include a threaded portion 110 is formed with a thread 111 on the outer surface.

At this time, as the upper stem 100 to rotate, having a cylindrical shape, a thread (410a) is formed on the inner surface further includes a drive nut 400 to which the threaded portion 110 of the upper stem 100 is coupled. It is also possible.

That is, in order to more easily drive the upper stem 100 may further include a drive nut 400 as described above, wherein the drive handle (WH) is further coupled to the drive nut 400 It is also possible.

Meanwhile, the key groove 410b is formed on the outer surface of the drive nut 400 to couple the drive handle WH and the drive nut 400, and then a key is mounted to the drive handle WH. It is also possible to combine the keys.

In addition, it is also possible to install the bearings BR1 and BR2 on the upper and lower sides of the driving nut 400 so that the driving handle WH can be driven more easily.

In addition, as shown in the figure, it is also possible to further include a cover 500 having a disc shape on the drive nut 400, the center portion of which is open to allow the drive nut 400 to pass therethrough.

In addition, it is also possible to further include an indicator (I) mounted on the drive handle (WH) to easily check the degree of rotation of the drive handle (WH) and the upper stem (100).

To this end, it is also possible to further include an indicator shaft IS which is arranged between the indicator I and the upper stem 100.

The ball B (refer to FIG. 6) can be driven by the above-described configuration, which will be described.

First, the user drives the driving handle WH, and the degree of rotation may be checked by the indicator (I).

When the drive handle WH is rotated, the drive nut 400 coupled with the drive handle WH is rotated.

The upper stem 100, which is screwed with the drive nut 400, is rotated by the rotation of the wing drive nut 400.

At this time, the movement of the upper stem 100 is determined by the coupling sphere (SP) disposed in the groove 121, which is the same as the conventional relationship between the groove and the pin overlapping description is omitted.

The ball B is tilted or rotated by the rotational movement or the elevating movement of the upper stem 100.

Meanwhile, in the present invention, the upper stem 100 and the lower stem 600 (see FIG. 6) are separate.

That is, the upper stem 100 has a hollow cylindrical shape as described above, wherein the lower stem 600 is inserted into the upper stem 100.

Thereafter, the pins P are inserted into the pin holes 122 and 600a formed in the upper stem 100 and the lower stem 600, respectively, so that the upper stem 100 and the lower stem 600 are coupled to each other.

When formed in a mutually separated form as described above it is possible to replace only the upper stem 100 or the lower stem 600 at the time of any component is easy to work.

Meanwhile, as described above, the upper stem 100 has a movement determined by the groove 121 and the coupling sphere SP. For this purpose, the upper stem 100 is formed at one side of the housing 200 to pass through the coupling sphere SP. It is also possible to further include a through hole 210a to be mounted to the groove 121.

At this time, the coupler (SP) may further include a coupler cover (SPC) for close contact with the groove 121.

The coupler cover SPC for this purpose is a disk-shaped cover body SPC1 covering the through hole 210a and protrudes from the cover body SPC1 to penetrate the through hole 210a and then the coupler. The coupler press part SPC2 which presses SP can be provided.

In this case, the coupler pressing portion (SPC2) has a hollow circular shape so that the coupler (SP) is disposed at the end thereof, the coupler (SP) can be in close contact with the coupler cover (SPC). It is possible to do so.

On the other hand, to form a flat surface 210b to be in close contact with the coupler cover (SPC) around the through hole (210a) to be more firmly seated in the coupler cover (SPC) and the housing 200 It is also possible.

In addition, the fastener F may pass through the coupler cover SPC to be mounted on the flat surface 210b so that the coupler cover SPC may be fixed on the housing 200.

Meanwhile, the grooves 121 may be formed on the front and rear surfaces of the upper stem body 120, and then the coupling holes SP and the coupling cover SPC may be disposed on the grooves 121, respectively.

On the other hand, the housing 200 has a hollow cylindrical shape as shown, the upper body 220 formed on the upper and lower surfaces of the housing body 210 and the housing body 210, the through-hole 210a is formed, respectively It may include a lower flange 230.

In this case, the cover 500 described above may be disposed on the upper flange 220, and the lower flange 230 may be disposed on the valve body VB (see FIG. 6).

It is also possible to further include an oil-free bushing 300 mounted inside the housing 200 and having a hollow cylindrical shape for receiving the upper stem 100.

The upper stem 100 may be in close contact with the housing 200 to arrange the oil-free bushing 300 as described above to reduce friction.

The oil-free bushing 300 serves as a bearing of a kind of self-lubrication method, which is made of a multilayer plastic material, which is coated with PTFE and a mixture of sintered bronze powder on the cold steel plate and then sintered with PTFE.

Such oil-free bushing 300 has a low friction coefficient can be used without lubricating oil, and has an excellent effect on high load or impact load.

In addition, it has high wear resistance, thin thickness, and light weight, which enables compact design.

Meanwhile, the oil free bushing 300 may include a first oil free bushing 310 and a second oil free bushing 320 for receiving the upper stem body 120 of the upper stem 100.

In this case, the first oil free bushing 310 and the second oil free bushing 320 may be spaced apart from each other to expose the groove 121.

Meanwhile, FIG. 5 illustrates an upper side configuration of the housing 200 and the upper stem 100, and FIG. 6 illustrates the lower stem 600 and the valve body VB coupled to the upper stem 100.

100: upper stem 121: groove
200 housing 300 oil-free bushing
400: driving nut 500: cover
600: lower stem VB: valve body
SP: Splice Splice SPC: Splice Cover
B: ball

Claims (11)

delete A valve body VB through which fluid flows, a ball B disposed inside the valve body VB to interrupt the flow of the fluid, and a ball B mounted on the ball B to tilt the ball B and A lower stem 600 for rotating and a housing for receiving the upper stem 100 and the upper stem 100 and the lower stem 600 connected to the lower stem 600 to rotate the lower stem 600. A rising stem ball valve including a coupling sphere (SP) coupled to a groove 121 formed in the upper stem 100 and the upper stem 100, and determining the movement of the lower stem 600.
The groove 121 is formed to be recessed on the surface of the upper stem 100, the depth of the groove 121 is formed smaller than the thickness of the upper stem 100,
Rising stem ball valve having a groove-type groove formed on one side of the housing 200 and further including a through hole 210a for mounting to the groove 121 after the coupler SP penetrates. . 3. The method of claim 2,
The upper stem 100 has a hollow cylindrical shape, but the upper stem body 120 having the groove 121 formed on an outer surface thereof, and extending upward in an upper end portion of the upper stem body 120. Rising stem ball valve having a groove groove, characterized in that it comprises a threaded portion (110) is formed on the surface of the thread 111. The method of claim 3,
By rotating the upper stem 100,
A rising stem having a groove-shaped groove, characterized by further comprising a drive nut 400 having a cylindrical shape and having a threaded portion 410a formed therein, to which the threaded portion 110 of the upper stem 100 is coupled. Type ball valve. 5. The method of claim 4,
Rising stem ball valve having a groove groove, characterized in that it further comprises a drive handle (WH) coupled to the drive nut (400) to rotate the drive nut (400). delete 3. The method of claim 2,
Further comprising a coupler cover (SPC) for closely coupling the coupler (SP) to the groove 121,
The coupler cover (SPC) and the disk-shaped cover body (SPC1) covering the through hole 210a,
Rising stem having a groove-shaped groove, characterized in that it comprises a coupler pressing portion (SPC2) for protruding from the cover main body (SPC1) and penetrates the through hole (210a) and then press the coupler (SP). Type ball valve. 3. The method of claim 2,
Rising stem ball valve having a groove-shaped groove, characterized in that it further comprises an oil-free bushing (300) installed inside the housing (200) and having a hollow cylindrical shape for receiving the upper stem (100). 9. The method of claim 8,
The oil free bushing 300 includes a first oil free bushing 310 and a second oil free bushing 320 for receiving the upper stem body 120 of the upper stem 100,
The first oil free bushing 310 and the second oil free bushing 320 are spaced apart from each other so that the groove 121 is exposed so that the rising stem ball valve having the grooved groove. The method of claim 7, wherein
Rising stem ball valve having a groove groove, characterized in that the coupling sphere pressing portion (SPC2) has a hollow circular shape is formed to be in close contact with the coupling sphere (SP). 3. The method of claim 2,
The upper stem 100 has a hollow cylindrical shape,
The lower stem 600 is inserted into the upper stem 100,
The pins P are inserted into the pin holes 122 and 600a respectively formed in the upper stem 100 and the lower stem 600 so that the upper stem 100 and the lower stem 600 are coupled to each other. Rising stem ball valve with grooved groove.

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