KR20030086952A - Ball valve - Google Patents

Abstract

PURPOSE: A ball valve is provided to smoothly perform the opening/closing operation of a valve ball, and to prevent the leakage of water by improving the support structure of the valve ball. CONSTITUTION: In a ball valve, a stem-side elastically compressing unit is installed between a bolt(60) coupled with a stem housing(52) and a flange(58a) in a stem(58). A couple of upper/lower uneven couplings(64,66) are located between the flange and the bottom of the stem housing, and are coupled by a concave part(64a) and a convex part(66a). Rubber packings are interposed between the upper uneven coupling(64) and the flange, and the lower uneven coupling(66) and the bottom of the stem housing, and have protruding lines, respectively.

Description

Ball valve

The present invention relates to a ball valve, and more particularly to a ball valve that improves the durability and operability by improving the rotational support structure of the valve ball for controlling the flow rate and at the same time fundamentally blocking leakage during opening and closing operation and minimizing the operating load .

In general, a ball valve is provided with a spherical ball having a hole penetrated on the fluid passage of the valve body. The ball is in close contact with the ball support ring disposed in the fluid passage and is connected to the stem to allow rotational operation. have.

Therefore, the ball opens and closes the fluid passage while the ball rotates between the seals according to the operating direction of the stem.

On the other hand, conventionally, as a ball valve installed in the piping line for hot water boiler, the ball valve of the Korean Utility Model Publication No. 98-3966 (1998.03.30) is shown in FIG.

This is to connect the valve ball 2 inserted into the valve body 1 with the stem 4 of the vertical pipe part 3 so as to be opened and closed, and the stem inside the vertical pipe part 3 with the top open. (4) is inserted together with the packing (5) (5 '), and the lower end is connected to the valve ball (2), and on the upper surface, the screw (7) and the screw having the fixing bolt (6) cut on the inner wall of the vertical pipe part (3) It is composed by combining.

Looking at the configuration of such a general ball valve or a conventional ball valve in Figure 1, when rotating the stem (4) the valve ball (2) causes surface friction with the ball support ring 10, which is the It causes the load to be received by the frictional force with the ball support ring 10 during rotation.

The ball support ring 10 in FIG. 1 is subjected to a constant axial force by the connecting pipe 11 in order to cause airtight face friction in the ball 2.

Therefore, the rotation of the stem 4 requires a lot of rotational force. In addition, if the dimensions are slightly different when machining and assembling the part where the ball support ring 10 is located, more torque is required when the ball 2 is rotated. This occurs even when foreign matter (scale) is caught around the ball 2 during long-term use.

Therefore, when the ball valve is used as the electric valve of the hot water dispenser, the power of the driving motor becomes weaker as time passes when the stem (4) is operated by electric power, and the operation becomes excessive when the foreign matter is caught excessively around the ball (2). Will cause malfunctions.

In addition, the packing (5) (5 ') is worn when subjected to frequent rotation and temperature changes of the stem (4) causes the leakage around the stem (4).

And when the leakage occurs, the packing (5) (5 ') can be replaced, but the action can be taken only after the user's damage occurs.

The present invention is to solve the problems of the prior art as described above, to improve the support structure of the valve ball disposed on the fluid passage smoothly opening and closing operation of the valve ball even if some dimensional error occurs during processing and assembly It does not require a large torque, and improves the sealing structure around the stem to provide a ball valve that can be reliably prevented from leaking regardless of the number of operations, temperature changes, and machining or assembly errors.

The following drawings, which are attached in this specification, illustrate preferred embodiments of the present invention, and together with the detailed description of the present invention, serve to further understand the technical spirit of the present invention. It should not be construed as limited to.

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

Figure 2a, 2b is an assembled sectional view of the ball valve according to the present invention the valve open and closed state.

Figure 2c is a modification of the ball valve body in accordance with the present invention.

3 is a plan view of FIG. 2A;

Figure 4 is a state of use of the ball valve according to the present invention.

Figure 5 is a cross-sectional view of the upper rubber packing applied to the ball valve of the present invention.

Figure 6 is a cross-sectional view of the lower rubber packing applied to the ball valve of the present invention.

Figure 7 is an enlarged uneven coupling of the uneven coupling ring applied to the ball valve of the present invention.

Figure 8 is a modified example of the ball-side elastic pressing means applied to the ball valve of the present invention.

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

52: stem housing

56: valve ball

58: stem

60: tightening bolt

62: coiled spring

64,66: uneven coupling ring

68,70: Rubber swelling

80,82: Ball Support Ring

84,86: Coiled Spring

84a: hollow part

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

First Embodiment

The first embodiment of the present invention improves the leak prevention structure on the side of the stem 58 for operating the ball valve as shown in Figs. 2A and 2B, and at the same time enables the rotational operation of the stem 58 with less torque, thereby enabling the stem 58 to be operated. ) Is to reduce the load when controlling the drive to the electric motor (M) of the remote automatic driver 100 as shown in FIG.

Here, the remote autonomous driver 100 may be, for example, that the applicant has been registered as Korean Patent Office Registration No. 0347343 (2002.07.22), and the present invention is not limited to such a remote autonomous driver 100.

The valve body 50 of the present embodiment is composed of a first body 53 having a stem housing 52 and a second body 54 screwed onto the fluid passage 51 of the first body 53. have.

And the present invention is of course that the valve body 50 may be composed of a single body as shown in Figure 2c.

A valve ball 56 having a hole 56a for opening and closing the fluid passage 51 is located at the center of the valve body 50, and a stem is provided in the stem housing 52 to rotate the valve ball 56. 58 is rotatably positioned, and the stem 58 has a disk-shaped flange 58a integrally formed at the center thereof. At this time, the stem 58 is fitted in the groove 56b of the ball 56. An upper end of the stem 58 is provided with an operation groove 58b of a rectangular cross section for operating the stem 58.

Tightening bolt 60 is screwed to the upper end of the stem housing 52, the tightening bolt 60 has a hole (60a) for penetrating the stem 58 in the center for its annular spring support The circular groove 60b is formed.

At this time, the tightening bolt 60 has a polygonal shape as shown in Figure 3 the outer peripheral surface to facilitate the rotation operation.

Under the tightening bolt 60, the stem side elastic pressing means is arranged so that the stem 58 is pushed toward the lower ball 56 side.

In this embodiment, the stem-side elastic pressing means may be composed of a coiled compression spring 62 or a plate-shaped spring that exhibits other elastic force.

One end of the compression spring 62 is supported by a spring supporting circular groove 60b of the tightening bolt 60, and the other end thereof is supported by an upper surface of the flange 58a of the stem 58.

Resin, which is coupled between the stem side flange 58a and the stem housing 52 side bottom 52b by one or more sliding uneven portions 64a and 66a and is in surface contact with the elastic repulsive force of the pressure spring 62. For example, a pair of upper and lower concave-convex coupling rings 64 and 66 made of fluorine resin (Teflon) is disposed (see Fig. 7).

At this time, the coupling end surface of the uneven parts 64a and 66a may be formed in a circular shape or a quadrangular shape as shown in FIG. 7 so that one recessed part 64a surrounds the convex part 66a. Substantially, it is preferable that lubricants used in conventional mechanical moving parts are used for the uneven parts 64a and 66a for the purpose of sealing and reducing friction.

The upper concave-convex coupling ring 64 may further include a bent portion 64b bent to surround the stem side flange 58a on an outer circumferential surface thereof.

Rubber packings 68 and 70 are interposed between the upper uneven coupling ring 64 and the stem flange 58a and between the lower uneven coupling ring 66 and the bottom of the stem housing 52, respectively. .

At this time, the upper rubber packing 68 has a hole 68a penetrating the stem 58 in the center and may be made of rubber or silicon as a flat ring shape, respectively, for preventing leakage on the upper and lower surfaces as shown in FIG. 5. A circular projection line 68b is formed.

In addition, the lower rubber packing 70 has a hole 70a through which the stem 58 penetrates in the center, and an annular recess groove 70b opened upward, and the lower recess coupling portion is formed in the recess recess groove 70b. The ring 66 is coupled, and as shown in FIG. 6, the rubber packing 70 has a recessed groove 70b and a circular protrusion line 70c formed on the outer circumferential surface, the inner diameter, and the lower surface of the rubber packing 70, respectively.

Reference numeral 91,92 is a rubber ring for preventing leakage.

The first embodiment configured as described above can obtain the following actions.

The compression spring 62 exerts an elastic repulsion force between the tightening bolt 60 and the flange 58a of the stem 58, and the tightening bolt 60 is screwed onto the stem housing 52 to be fixed. Therefore, the lower end of the compression spring 62 always pushes the stem 58 downward in FIGS. 2A and 2B.

Therefore, the pressing force of the compression spring 62 applied to the stem 58 acts perpendicularly to the upper rubber packing 68 and the upper and lower uneven coupling rings 64 and 66 and the lower rubber packing 70.

Therefore, the upper and lower concave-convex coupling rings 64 and 66 are engaged with each other, and the concave-convex 64a and 66a are in close contact with each other.

On the other hand, since the lower rubber packing 70 has a protrusion line 70c, the lower rubber packing 70 is in close contact with the bottom 52b and the inner wall of the stem housing 52 and the outer circumferential surface of the stem 58.

Thus, the leak that escapes the stem 58 primarily is blocked by the lower rubber packing 70 in close contact with the stem 58.

If a leak occurs through the rubber packing 70 here, it is again the second uneven coupling ring 64, 66 is a rubber spring (64a, 66a) and the rubber packing ( 68 is blocked by the projection line 68b.

At this time, lubricant is applied to the uneven parts 64a and 66a so that the rotation is more smoothly maintained during the rotation of the stem 58.

When the stem 58 is rotated, that is, when the stem 58 is driven by the electric motor M of FIG. 4, for example, the upper rubber packing 68 has a friction force and the stem 58 and the upper uneven coupling ring 64. This rotates together, and the ball 56 connected to the lower end of the stem 58 rotates to open and close the fluid passage 51 of the valve.

When the stem 58 is rotated in this way, the sliding force is generated by the pressing force of the pressure spring 62 only at the rotational part, that is, the irregularities 64a and 66a of the uneven coupling rings 64 and 66, so that a small frictional force is generated. (M) does not take much load.

Therefore, the ball valve, for example, when used in the heating boiler hot water control driven by the electric motor (M) can have a long life.

In addition, even if the machining bolts in the tightening bolt (60) does not have the correct dimension (L1) after assembly, since the pressure spring 62 elastically absorbs the machining errors, it does not affect the smooth and smooth rotation of the stem (58).

This can be seen that the conventional stem is difficult to rotate by being forced by a lot of direct pressing directly to prevent the leakage by the vertical pipe portion provides an excellent advantage compared to the load on the drive motor.

Second Embodiment

The second embodiment of the present invention improves the support structure for supporting the valve ball 56 of the ball valve as shown in Figs. 2a and 2b so as not to take a lot of load when rotating the stem 58 and at the same time processing dimensions Even if there is a slight error in the L2, the load is not applied to the rotation operation of the stem 58.

As shown in FIGS. 2A and 2B, a valve ball 56 for opening and closing a fluid passage is located at the center of the valve body 50 having the stem housing 52, and the stem housing is configured to rotate the valve ball 56. A ball valve having a stem (58) located at (52), wherein the fluid passage is made of a resin material, such as a fluororesin (teflon), which is in surface contact with a spherical surface of the ball 56, and is formed therethrough. Ball support rings 80 and 82 having 82a are located.

One side of each of the ball support rings (80, 82), one end is supported on the fluid passage 51 side of the valve body 50, the other end of the ball-side elastic pressure is supported on the cross-sectional side of the ball support rings (80, 82) Coil-type compression springs 84 and 86 are provided as a means. Or it can be installed as a plate-shaped spring that exhibits an elastic force.

Accordingly, the compression springs 84 and 86 are installed to push the ball support rings 80 and 82 toward the ball 56, respectively.

In this embodiment, the circular stepped portions 50a and 50b are formed on the fluid passage 51 side of the valve body 50, and the circular stepped portions 80b and 82b are formed on the ball support rings 80 and 82 side thereof. The compression springs 84 and 86 are supported between the stepped portions 50a and 80b and 50b and 82b, respectively.

As such, the pressure springs 84 and 86 are positioned at the left and right contact portions of the valve ball 56, and the ball 56 uses the elastic variable of the pressure springs 84 and 86 to support the left and right ball support rings 80. And 82).

Therefore, the valve ball 56 and the ball support rings 80 and 82 are in close contact with the elastic force of the pressure springs 84 and 86, so that the rotation is smooth.

In addition, even when an error occurs in the dimension L2 during processing and assembly of the valve body 50 where the pressure springs 84 and 86 are located, the first body 53 is caused by the expansion and contraction of the pressure springs 84 and 86. Even after the second body 54 is assembled with the screw, the rotation of the valve ball 56 is smooth.

As a result, it is possible to operate with a small force during the rotation operation of the stem 58, which acts as the axis for operating the ball 56, so that the load of the electric motor M driving the stem 58 can be reduced.

The ball-side elastic pressing means may be configured to have a hollow portion 84a filled with a gas such as air or gas in the ball support rings 80 and 82 as a modified example.

Third Embodiment

The third embodiment of the present invention is a combination of the first embodiment and the second embodiment as shown in Figs. 2a and 2b to enable smooth and low load operation of the stem 58 and at the same time leak the stem 58 side. Will be prevented.

According to the third embodiment, since the configuration and operation of the first and second embodiments are included, a detailed description thereof will be omitted.

In the third embodiment, since the ball 56 and the stem 58 are respectively supported by the pressure springs 84 and 86 and 62, the rotational operation of the stem 58 is more smooth and connected to the stem 58 of FIG. When the electric motor M is driven, the load on the electric motor M is further reduced.

Therefore, not only the life of the driving motor is long but also the leakage of water leakage around the stem 58 is improved, thereby improving durability of the valve.

In addition, the stem 58 for operating the ball 56 by the buffer deformation of the pressure spring (84,86) even if excessive foreign matter between the ball support ring (80,82) in contact with the valve ball 56 There is no need for a large torque.

Therefore, the present invention is configured as the third embodiment is the best mode, but of course the present invention can be implemented in any one of the first and second embodiments.

As described above, although the present invention has been described by way of limited embodiments and drawings, the present invention is not limited thereto, and the technical idea of the present invention and the following by those skilled in the art to which the present invention pertains. Of course, various modifications and variations are possible within the scope of equivalents of the claims to be described.

As described above, according to the present invention, the stem 58 for controlling valve opening and closing is installed to receive the compression spring 62 force, and the uneven sealing between the uneven coupling rings 64 and 66 is caused by the compression spring 62 force. This enables smooth and smooth rotational operation of the stem 58 and reduces the load on the electric motor that can be used as a drive source for rotating the stem 58. The valve ball 56 is supported by the spring means on both sides. Thus, smooth and smooth operation can be expected even in the machining and assembling error, thereby reducing the operating force (torque) of the stem 58 for rotating the valve ball 56, which contributes to reducing the load of the electric motor.

In addition, the present invention is a concave-convex coupling ring (64,66) made of a fluorine resin material around the stem 58 to perform the sealing while receiving the compression spring 62 force, so that frequent operation of the stem 58 and the valve body Leakage does not occur even if the temperature change occurs.

Claims (6)

A valve ball 56 is located in the center of the valve body 50 having the stem housing 52, and a stem 58 positioned in the stem housing 52 for rotating the valve ball 56. In the ball valve having: Install between the tightening bolt 60 screwed to the stem housing 52 and the flange 58a of the stem 58 to provide a stem-side elastic pressing means for exerting a compression repulsion force, The flange 58a of the stem 58 and the bottom of the stem housing 52 side are joined by one or more sliding recesses and protrusions 64a and 66a to be in surface contact with the pressing force of the stem-side elastic pressing means. A pair of upper and lower concave and convex coupling rings (64, 66) are arranged, Each of the upper uneven coupling ring 64 and the stem 58 side flange 58a and between the lower uneven coupling ring 66 and the bottom of the stem housing 52 have projection lines 68b and 70c, respectively. Ball valve characterized in that the rubber packing (68, 70) is interposed. A valve ball 56 is positioned at the center of the valve body 50 having the stem housing 52 to open and close the fluid passage, and the stem 58 located at the stem housing 52 for rotating the ball 56 is positioned. In the ball valve having, The fluid passage is provided with ball support rings (80, 82) of the resin material in surface contact with the spherical surface of the ball 56, One side of the ball support rings (80, 82), one end is supported on the valve body 50 and the other end is supported on the end surface side of the ball support rings (80, 82), respectively, the ball-side elastic pressing means for exerting a compression repulsion force Ball valve, characterized in that installed. A valve ball 56 is located in the center of the valve body 50 having the stem housing 52, and a stem 58 positioned in the stem housing 52 for rotating the valve ball 56. In the ball valve having: The fluid passage is provided with a ball support ring (80, 82) of the resin material in surface contact with the spherical surface of the valve ball 56, One side of the ball support rings (80, 82), one end is supported on the valve body 50 and the other end is supported on the end surface side of the ball support rings (80, 82), respectively, the ball-side elastic pressing means for exerting a compression repulsion force Installed; Install between the tightening bolt 60 screwed to the stem housing 52 and the flange 58a of the stem 58 to provide a stem-side elastic pressing means for exerting a compression repulsion force, The flange 58a of the stem 58 and the bottom of the stem housing 52 side are joined by one or more sliding recesses and protrusions 64a and 66a to be in surface contact with the pressing force of the stem-side elastic pressing means. A pair of upper and lower concave and convex coupling rings (64, 66) are arranged, A projection line 68b, 70c between the upper uneven coupling ring 64 and the stem 58 side flange 58a and between the lower uneven coupling ring 66 and the bottom of the stem housing 52, respectively. Ball valve characterized in that the rubber packing (68, 70) is interposed. The method according to any one of claims 1 to 3, The stem side elastic pressing means is a ball valve, characterized in that the coiled spring (62). The method according to claim 2 or 3, The ball-side elastic pressing means is a ball valve, characterized in that the coil spring (84,86). The method according to claim 2 or 3, The ball-side elastic pressurizing means is a ball valve, characterized in that consisting of a hollow portion (84a) is filled with gas in the ball support rings (80,82).