CN207687374U - A kind of double-rod structure high-pressure stop valve - Google Patents

Abstract

The utility model discloses a kind of double-rod structure high-pressure stop valves, it is related to valve arrangement technical field, including valve body, it is characterized in that, the first L-type through-hole and the second L-type through-hole are offered in the valve body, and the valve body is run through at the both ends of the first L-type through-hole and the both ends of the second L-type through-hole, it is connected by connecting hole at the inflection point of the second L-type through-hole at the inflection point of the first L-type through-hole, the first flap towards the valve body center position is provided in the inner cavity on described first L-type through-hole one side, first flap can effectively close the connecting hole close to one end of the connecting hole, the second flap towards the valve body center position is provided in the inner cavity on described second L-type through-hole one side, and second flap can effectively close the connecting hole close to one end of the connecting hole；The utility model can effectively avoid the drawbacks of needing two shut-off valve, can effectively realize the online maintenance that is free from risk, greatly improve equipment installation effectiveness.

Description

A double-rod structure high-pressure globe valve

technical field

The utility model relates to the technical field of valve equipment, in particular to a high-pressure cut-off valve with a double-rod structure.

Background technique

Ordinary globe valve is composed of valve body, single valve disc, single valve stem, single valve cover, packing, bolt, bracket, stem nut, handwheel and other parts. Its working principle is to turn the handwheel, and the stem nut drives the valve stem. And the valve disc moves up and down along the vertical direction of the pipeline center line to realize the function of opening and closing, and mainly plays the role of cutting off the flow of the conveyed medium on the pipeline. Due to the high pressure of the medium, under the full pressure difference between opening and closing, the medium will seriously scorch the sealing surface of the valve seat, which is prone to internal leakage and short service life; at the same time, when the valve needs to be connected to pipes with different diameters, it needs to pass through different diameter pipes. connection, increasing the installation cost.

In order to solve the problem of on-line maintenance in the prior art, most of them adopt the transformation and upgrading of the quality and sealing performance of the single-rod globe valve itself to achieve on-line maintenance. , however, this method leads to a large equipment footprint, complicated connections, high cost, and increases the risk of pipelines.

How to solve the existing technical defects is an urgent problem to be solved now.

Utility model content

The purpose of the utility model is to overcome the deficiencies of the prior art and provide a double-rod structure high-pressure cut-off valve to solve the problems in the prior art that it is difficult to maintain online, the risk of using two single-rod cut-off valves increases, and the space occupied is large. question.

The utility model is achieved through the following technical solutions:

The utility model provides a high-pressure cut-off valve with a double-rod structure, which includes a valve body, and a first L-shaped through hole and a second L-shaped through hole are opened in the valve body, and the two ends of the first L-shaped through hole Both ends of the second L-shaped through hole pass through the valve body, and the inflection point of the first L-shaped through hole and the inflection point of the second L-shaped through hole are both toward the center of the valve body, so The inflection point of the first L-shaped through hole is connected with the inflection point of the second L-shaped through hole through a connection hole, and a first valve facing the center of the valve body is provided in the inner cavity on one side of the first L-shaped through hole. The outer end of the other side of the valve flap is connected to the external pipeline, the end of the first valve flap close to the connection hole can effectively close the connection hole, and the end of the first valve flap far away from the connection hole is connected with The first valve stem, the first valve stem is sleeved with a first valve cover, the first valve cover is fixedly connected with the valve body, and the inner cavity on one side of the second L-shaped through hole is provided with a The second valve clack in the center direction of the valve body is connected to the external pipeline at the other outer end, and the end of the second valve clack close to the connecting hole can effectively close the connecting hole, and the second valve clack The end of the flap away from the connection hole is connected with a second valve stem, and a second valve cover is sheathed on the second valve stem, and the second valve cover is fixedly connected with the valve body.

Further, the first valve flap is connected to the first valve stem through a first split valve flap cover, and a first stuffing box is opened in the inner cavity of the first valve cover, and a first stuffing box of the first stuffing box A first packing layer is arranged in the inner cavity, and a first packing gland and a first packing plate are arranged on the outside of the first packing layer in turn, and the first packing gland and the first packing plate are both sleeved on the on the first valve stem, and the first packing plate is connected to the first valve cover through the first fastening bolt, and the second valve flap and the second valve stem pass through the second split valve Flap cover connection, the inner cavity of the second valve cover is provided with a second stuffing box, the inner cavity of the second stuffing box is set with a second packing layer, and the outer side of the second packing layer is sequentially set with a second stuffing box. Two packing glands and a second packing plate, both of which are sleeved on the second valve stem, and the second packing plate is connected with the second fastening bolt The second bonnet is connected.

Further, the end of the first valve stem far away from the valve body is sleeved with a first valve stem nut, and the first valve stem and the first valve stem nut adopt trapezoidal thread transmission, and the first valve stem The outer side of the stem nut is sleeved with a first stopper, and the first valve stem nut is sequentially sleeved with a first one-way thrust ball bearing group, a first bearing gland, a first The handwheel and the first relatively flat nut, the first thrust ball bearing group is limited in the inner cavity of the first limiting member through the first bearing cover, and the first handwheel is passed through the first A relatively flat nut is fixed on the first stem nut, and the end of the second stem far away from the valve body is sleeved with a second stem nut, and the second stem is connected to the second stem nut. The valve stem nut adopts trapezoidal thread transmission, and the outer side of the second valve stem nut is provided with a second limiter, and the second valve stem nut is sequentially provided with a second single stop in the direction extending away from the valve body. A thrust ball bearing set, a second bearing gland, a second hand wheel and a second flat nut, the second one-way thrust ball bearing set is limited in the second position by the second bearing gland The second handwheel is fixed on the second valve stem nut through the second flat nut.

Further, the first bearing gland is tightly connected to the first limiting member through the first limiting nut, and the second bearing gland is tightly connected to the second limiting member through the second limiting nut. connect.

Further, a first gasket is embedded between the first valve cover and the valve body, and a second gasket is embedded between the second valve cover and the valve body.

Further, the first limiting member is fixedly connected to the first valve cover through a first bracket, and the second limiting member is fixedly connected to the second valve cover through a second bracket.

Further, the first L-shaped through hole and the second L-shaped through hole are symmetrical about the center of the valve body, and the first valve stem and the second valve stem are located at the center of the valve body. sides.

Further, the first L-shaped through hole and the second L-shaped through hole are axisymmetric with respect to the center of the valve body, and the first valve stem and the second valve stem are located in the valve body side.

Further, the first L-shaped through hole, the second L-shaped through hole and the connecting hole are all on the same plane.

Further, the inner diameter of the end of the first L-shaped through hole connected to the external pipeline is not smaller than the inner diameter of the end of the second L-shaped through hole connected to the external pipeline.

Compared with the prior art, the utility model has the following advantages: the utility model provides a double-rod structure high-pressure stop valve, by opening a first L-shaped through hole and a second L-shaped through hole in the valve body, and the first L-shaped through hole The through hole and the second L-shaped through hole are connected through a connecting hole, and the first valve disc is set in the inner cavity of the first L-shaped through hole, and the first valve disc can be driven by the first valve stem to effectively move the valve in the first L-shaped through hole. The reciprocating movement in the through hole can effectively control the opening or closing of the connecting hole. At the same time, a second valve flap is arranged in the inner cavity of the second L-shaped through hole, and the second valve flap can be effectively driven by the second valve stem. The reciprocating movement of the second L-shaped through hole can effectively control the opening or closing of the connecting hole. Through this setting, zero-risk online maintenance can be effectively realized, and the disadvantages of the traditional single-lever globe valve online maintenance are avoided. When the first When the inner diameter of the connection between the first L-shaped through hole and the external pipeline is larger than the inner diameter of the second L-shaped through hole, the equipment can effectively connect pipelines with different diameters, which can effectively avoid the disadvantages of using two single-lever globe valves to achieve zero-risk maintenance. It can effectively improve the utilization rate of space, save installation costs, reduce the loss of manpower and material resources, effectively avoid the risks brought by the use of reducers, and improve the safety performance of equipment.

Description of drawings

Fig. 1 is a structural schematic diagram of a double-rod structure high-pressure stop valve in the first embodiment of the present invention;

Fig. 2 is a structural schematic diagram of a valve body of a double-rod structure high-pressure stop valve in the first embodiment of the present invention;

Fig. 3 is a schematic structural view of a double-rod structure high-pressure stop valve in the second embodiment of the present invention;

Fig. 4 is a structural schematic diagram of a valve body of a double-rod structure high-pressure stop valve in the second embodiment of the present invention;

Fig. 5 is a structural schematic diagram of a double-rod structure high-pressure stop valve in the fifth embodiment of the present invention;

Fig. 6 is a structural schematic diagram of a valve body of a double-rod structure high-pressure stop valve in the fifth embodiment of the present invention.

In the figure: 1. Valve body; 2. The first L-shaped through hole; 3. The second L-shaped through hole; 4. Connecting hole; 5. The first disc; 6. The first valve stem; 7. The first valve Cover; 8. The second disc; 9. The second stem; 10. The second cover; 11. The first split disc cover; 12. The first packing layer; 13. The first packing gland; 14 1. The first packing plate; 15. The first fastening bolt; 16. The second split disc cover; 17. The second packing layer; 18. The second packing gland; 19. The second packing plate; 20. The second Two fastening bolts; 21. The first valve stem nut; 22. The first limiter; 23. The first one-way thrust ball bearing group; 24. The first bearing gland; 25. The first handwheel; 26. The first A relatively flat nut; 27, the second valve stem nut; 28, the second limit piece; 29, the second one-way thrust ball bearing group; 30, the second bearing gland; 31, the second hand wheel; 32, the second Two relatively flat nuts; 33, the first limit nut; 34, the second limit nut; 35, the first gasket; 36, the second gasket; 37, the first bracket; 38, the second bracket.

Detailed ways

The technical solutions in the embodiments of the present invention will be clearly and completely described below in conjunction with the accompanying drawings in the embodiments of the present invention. Obviously, the described embodiments are only part of the embodiments of the present invention, not all of them. example. Based on the embodiments of the present utility model, all other embodiments obtained by persons of ordinary skill in the art without making creative efforts belong to the scope of protection of the present utility model.

Please refer to Figure 1 and Figure 2, the first embodiment:

A double-rod structure high-pressure stop valve, including a valve body, a first L-shaped through hole and a second L-shaped through hole are opened in the valve body, and the two ends of the first L-shaped through hole and the two ends of the second L-shaped through hole Both ends go through the valve body, the inflection point of the first L-shaped through hole and the inflection point of the second L-shaped through hole are both toward the center of the valve body, and the inflection point of the first L-shaped through hole and the inflection point of the second L-shaped through hole pass through the The connecting hole is connected, and the first valve flap is provided in the cavity on one side of the first L-shaped through hole. The first valve flap can reciprocate in the axial direction in the cavity on this side, and the first valve flap is close to one end of the connecting hole. It can effectively close the connection hole, that is, the outer diameter of the end of the first disc close to the connection hole is not less than the inner diameter of the connection hole, and then when the equipment is running, it can effectively cut off the flow of the medium from the first L-shaped through hole to the second through the connection hole. L-shaped through hole, the end of the first disc away from the connection hole is connected with the first valve stem, the first valve stem can effectively drive the first valve disc to move, the first valve stem is covered with the first valve cover, the first valve The cover can effectively limit the position of the first valve stem, the first valve cover is fixedly connected with the valve body, and a second valve disc is arranged in the inner cavity on one side of the second L-shaped through hole, and the second valve disc can be positioned inside the side. The cavity reciprocates along the axial direction, and the end of the second disc close to the connecting hole can effectively close the connecting hole, that is, the outer diameter of the end of the second disc close to the connecting hole is not smaller than the inner diameter of the connecting hole, and when the equipment is running, It can effectively cut off the medium from the second L-shaped through hole to flow into the first L-shaped through hole through the connecting hole. The second valve disc is connected to the second valve stem at the end far away from the connecting hole, and the second valve stem can effectively drive the first valve disc. movement, the second valve stem is sleeved with a second valve cover, the second valve cover can effectively limit the first valve stem, and the second valve cover is fixedly connected with the valve body.

The first valve disc and the first valve stem are tightly connected through the first split valve disc cover, and the first stuffing box is provided in the inner cavity of the first valve cover, and the first packing layer is arranged in the inner cavity of the first stuffing box , which can effectively prevent the medium from leaking through the gap between the first valve stem and the first valve cover, which improves the safety and sealing performance of the equipment. The first packing layer is provided with the first packing gland and the first The packing retainer, the first packing gland and the first packing retainer are all sleeved on the first valve stem, and the first packing retainer is connected to the first valve cover through the first fastening bolt, and the second valve disc is connected to the second valve stem. Connected by the second split disc cover, the inner cavity of the second valve cover is provided with a second stuffing box, and the inner cavity of the second stuffing box is provided with a second packing layer, which can effectively prevent the medium from passing through the second valve stem. The gap between the second valve cover and the second valve cover is leaked, and the second packing layer is provided with a second packing gland and a second packing pressure plate in sequence, and the second packing gland and the second packing pressure plate are both sleeved on the second valve stem. and the second packing plate is connected to the second valve cover through the second fastening bolts.

The end of the first valve stem away from the valve body is sleeved with a first valve stem nut, and the first valve stem and the first valve stem nut are driven by trapezoidal threads, and the outer side of the first valve stem nut is sleeved with a first stopper, The first valve stem nut extends away from the valve body and is sequentially sleeved with the first one-way thrust ball bearing group, the first bearing gland, the first hand wheel and the first flat nut, and the first thrust ball bearing group passes through The first bearing gland is limited in the inner cavity of the first limiter, the first handwheel is fixed on the first valve stem nut through the first flat nut, and the end of the second valve stem away from the valve body is sleeved with a The second valve stem nut, and the second valve stem and the second valve stem nut adopt trapezoidal thread transmission, the outer side of the second valve stem nut is provided with a second limiter, and the second valve stem nut extends away from the direction of the valve body The second one-way thrust ball bearing group, the second bearing cover, the second hand wheel and the second flat nut are set on the top in turn, and the second one-way thrust ball bearing group is limited in the second position by the second bearing cover. In the inner cavity of the limiter, the second handwheel is fixed on the second valve stem nut through the second relatively flat nut;

The second bearing cover is tightly connected with the second limiting member through the second limiting nut;

A first gasket is embedded between the first valve cover and the valve body, and a second gasket is embedded between the second valve cover and the valve body;

The first limiting member is fixedly connected to the first valve cover through the first bracket, and the second limiting member is fixedly connected to the second valve cover through the second bracket;

There can be various positional relationships between the first L-shaped through hole and the second L-shaped through hole, it is only necessary to ensure that the end of the first valve disc can effectively close and open the corresponding connecting hole, and the second valve disc can It is enough to effectively close and open the ends of the corresponding connecting holes. In this embodiment, the first L-shaped through hole and the second L-shaped through hole are symmetrical about the center of the valve body, and the first valve stem and the second valve stem The rod is located on both sides of the valve body. This structure facilitates the installation of the equipment and can effectively reduce the manufacturing cost of the equipment.

When the equipment is running, the medium flows in from one side of the first L-shaped through hole and flows out through the side of the second L-shaped through hole. During this process, when it is necessary to replace the second packing layer in the second valve cover, it is only necessary to turn the first handwheel to drive the first disc to close the connection hole through the first valve stem, and then the valve on one side of the equipment can be blocked. Medium circulation, and then can effectively replace the second packing layer and other equipment, to achieve zero-risk online maintenance of equipment, greatly improving the efficiency of equipment maintenance.

Please combine Figure 3 and Figure 4, the second embodiment:

In this embodiment, the first L-shaped through hole and the second L-shaped through hole are axisymmetric with respect to the center of the valve body, and the first valve stem and the second valve stem are located on one side of the valve body, and other settings are similar to those of the first embodiment. Similarly, at this time, the two valve stems of the device are on the same side of the device. This structure can effectively improve the utilization efficiency of the installation space of the device and improve the scope of application of the device.

Third embodiment:

In this embodiment, the first L-shaped through hole, the second L-shaped through hole and the connection hole are all on the same plane, and other structures are the same as those in the first embodiment. This structure facilitates the manufacture of equipment and saves manufacturing costs.

Fourth embodiment:

In this embodiment, the inner diameter of the end of the first L-shaped through hole connected to the external pipeline is equal to the inner diameter of the end of the second L-shaped through hole connected to the external pipeline, and other settings are the same as in the first embodiment. At this time The equipment can effectively connect external pipes with the same diameter on both sides, avoiding the disadvantage of installing two identical single-lever globe valves in traditional equipment, and greatly improving the installation efficiency of the equipment.

Fifth embodiment:

Please combine Figure 5 and Figure 6, in this embodiment, the inner diameter of the end of the first L-shaped through hole connected to the external pipeline is greater than the inner diameter of the end of the second L-shaped through hole connected to the external pipeline, and other settings and The same as the first embodiment, at this time, the equipment can effectively connect external pipes with different diameters on both sides, avoiding the need to install two different single-rod globe valves in traditional equipment and the need for different-diameter pipe connections between the two single-rod globe valves Disadvantages, greatly improving the installation efficiency of the equipment and the stability of the equipment.

Claims (10)

1. A double-rod structure high-pressure cut-off valve, comprising a valve body, is characterized in that a first L-shaped through hole and a second L-shaped through-hole are provided in the valve body, and the two of the first L-shaped through-holes end and both ends of the second L-shaped through hole pass through the valve body, the inflection point of the first L-shaped through hole and the inflection point of the second L-shaped through hole are both toward the center of the valve body, The inflection point of the first L-shaped through hole is connected with the inflection point of the second L-shaped through hole through a connecting hole, and a first L-shaped through hole is provided in the inner cavity on one side of the first L-shaped through hole toward the center of the valve body. A valve flap, the outer end of the other side is connected to the external pipeline, the end of the first valve flap close to the connection hole can effectively close the connection hole, and the end of the first valve flap far away from the connection hole is connected There is a first valve stem, the first valve stem is sleeved with a first valve cover, the first valve cover is fixedly connected with the valve body, and the inner cavity on one side of the second L-shaped through hole is provided with The second valve flap facing the center of the valve body has the other outer end connected to the external pipeline, and the end of the second valve flap close to the connecting hole can effectively close the connecting hole, and the second A second valve stem is connected to the end of the valve flap away from the connection hole, and a second valve cover is sheathed on the second valve stem, and the second valve cover is fixedly connected to the valve body. 2. A double-rod structure high-pressure globe valve according to claim 1, characterized in that, the first disc and the first valve stem are connected through a first split disc cover, and the first The inner cavity of the valve cover is provided with a first stuffing box, the inner cavity of the first stuffing box is provided with a first packing layer, and the outer side of the first packing layer is sequentially provided with a first packing gland and a first packing A pressing plate, the first packing gland and the first packing pressing plate are sleeved on the first valve stem, and the first packing pressing plate is connected to the first valve cover through a first fastening bolt, The second valve flap is connected to the second valve stem through a second split valve flap cover, and a second stuffing box is opened in the inner cavity of the second valve cover, and the inner cavity of the second stuffing box is A second packing layer is set in the middle, and a second packing gland and a second packing plate are arranged on the outside of the second packing layer in turn, and the second packing gland and the second packing plate are both sleeved on the on the second valve stem, and the second packing pressure plate is connected to the second valve cover through second fastening bolts. 3. A double-rod structure high-pressure stop valve according to claim 2, wherein a first valve stem nut is sheathed on the end of the first valve stem away from the valve body, and the first valve stem is The valve stem and the first valve stem nut adopt trapezoidal thread transmission, and the first stopper is sleeved on the outside of the first valve stem nut, and the first valve stem nut is extended in a direction away from the valve body in turn. A first one-way thrust ball bearing set, a first bearing cover, a first hand wheel and a first flat nut are set, and the first one-way thrust ball bearing set is limited by the first bearing cover In the inner cavity of the first limiting member, the first handwheel is fixed on the first valve stem nut through the first flat nut, and the second valve stem is far from the end of the valve body The upper sleeve is provided with a second valve stem nut, and the second valve stem and the second valve stem nut are driven by a trapezoidal thread, and the outer side of the second valve stem nut is provided with a second limiter. A second one-way thrust ball bearing set, a second bearing gland, a second hand wheel and a second flat nut are sequentially sleeved on the second valve stem nut in a direction extending away from the valve body. The thrust ball bearing group is limited in the inner cavity of the second limiter by the second bearing cover, and the second hand wheel is fixed on the second valve stem by the second flat nut on the nut. 4. A double-rod structure high-pressure cut-off valve according to claim 3, characterized in that, the first bearing gland is tightly connected to the first limiting member through the first limiting nut, and the The second bearing cover is tightly connected with the second limiting member through the second limiting nut. 5. A double-rod structure high-pressure stop valve according to claim 1, characterized in that, a first sealing gasket is embedded between the first valve cover and the valve body, and the second valve cover and the valve body A second sealing pad is embedded between the valve bodies. 6. A double-rod structure high-pressure stop valve according to claim 4, characterized in that, the first limiting member is fixedly connected to the first valve cover through a first bracket, and the second limiting member The second bracket is fixedly connected with the second valve cover. 7. A double-rod structure high-pressure stop valve according to claim 1, wherein the first L-shaped through hole and the second L-shaped through hole are symmetrical about the center of the valve body, and The first valve stem and the second valve stem are located at two sides of the valve body. 8. A double-rod structure high-pressure stop valve according to claim 1, characterized in that, the first L-shaped through hole and the second L-shaped through hole are axisymmetric with respect to the center of the valve body, And the first valve stem and the second valve stem are located on one side of the valve body. 9. The high-pressure cut-off valve with a double-rod structure according to claim 1, wherein the first L-shaped through hole, the second L-shaped through hole and the connecting hole are all on the same plane. 10. A double-rod structure high-pressure stop valve according to claim 1, characterized in that the inner diameter of the end of the first L-shaped through hole connected to the external pipeline is not smaller than the second L-shaped through hole The inside diameter of the end connected to the external tubing.