RU2726918C1 - Locking device for connection into pipeline under pressure - Google Patents

Abstract

FIELD: pipeline valve production.SUBSTANCE: invention relates to pipeline valve industry and can be used in main pipelines transporting working medium. Locking device for connection into pipeline under pressure includes housing made of two interconnected parts and crossed through channel with flanges on its ends. In the cavity of the housing there is a shutter configured to move by the drive. In the housing parts above and below the shutter there are two channels communicating with the through channel and connected by the channel crossing the housing parts with the pressure balancing valve. Knife type shutter has a drive for movement in the form of a lead screw with multi-start thread fixed along the body cavity, and a nut fitted on the lead screw, which is connected to one side of the knife gate, the other side of the shutter is inserted into the slot made in the body on the side of the through hole. Shutter is located and moves parallel to running screw.EFFECT: invention is aimed at improvement of device operation reliability due to simplification of flap control when full coverage and opening of through channel is achieved.6 cl, 6 dwg

Description

The invention relates to mechanical engineering, and more specifically, to pipeline valves and can be used in main pipelines transporting the working environment. The locking device (ZI) is designed to separate the working, mainly gaseous, medium in the pipeline during pipeline maintenance work, when it is necessary to insert into the pipeline and promptly change the working modules.

Known locking devices - gate valves (https://www.ukenerqomash.ru/shibernie_zadvizki_zatvory), (http://www.armatek.ru/about/truboprovodnaya_armatura/shibernve_zadvizhki/)

A gate valve is a design of an armature with a shutter (damper) in the form of a disc. The locking device consists of a body, a gate, a gate drive and connecting flanges extending from the body, with which the device is connected to the pipeline. The gate valve moves along the sealing surfaces of the body seat and perpendicular to the flow of the working medium. This type of device belongs to parallel valves, the design of which assumes that the sealing surfaces are parallel to each other. The gate valve gate is a thin metal flat disc that blocks the transported medium. A through hole is provided in the valve body through which the working medium passes. The bolt of the valve is placed inside the body and moves up and down, similar to a knife. The gate valve is usually controlled via an actuator or manually. When manually operated by turning the handle, the spindle transmits movement to the valve, which, rising, opens the passage inside the valve body for the working medium. With mechanical control, the movement is transmitted from the drive. In the closed position, the valve is lowered, blocking the medium passage.

Known locking device - a valve (patent RU No. 2145022, publ. 27.01.2000). The valve contains a body with at least one seat, a knife shut-off element (valve), a gland seal interacting with it, and a gland cover. The gland seal is wedge-shaped. The wedge is facing away from the body. A gasket is located between the gland cover and the body.

The disadvantage of these gate valves is that they cannot be used to shut off pipelines that are under pressure, when it is necessary to insert into the pipeline under pressure and, after the connection, replace the working modules required to shut off the pipeline section.

As a prototype, you can choose a locking device - a plate valve (patent RU No. 2485377, publ. 20.06.2013). The plate valve contains a body made of two interconnected parts, crossed by a through channel with flanges at its ends and a rotary damper moving at a certain angle inside the body cavity. The butterfly valve, made in the form of a petal, rotates around a pin having an axis of rotation parallel to the possible direction of flow of the fluid. The body has shapes and sizes defined by the outer boundary of the positions taken by the flap moving from the closing position to the opening position. In the body parts above and below the damper, two channels are made, communicating with the through channel and connected by a channel crossing the body parts with the valve to equalize the pressure in the channel when the damper is closed.

This device can be used to shut off pressurized pipelines when it is necessary to open and close the valve for tapping into the pipeline. However, its disadvantage is that the butterfly valve has a sharp and fast control when opening and closing a channel with a pressurized medium flowing through the pipeline, which complicates the process of controlling the valve. With a sharp control, it is possible to cause shock and deformation of the body and obtain incomplete overlap and opening of the through channel, which reduces the reliability of the locking device.

The technical task of this technical solution is to create a locking device that improves the reliability of the device by simplifying the control of the damper when a complete overlap is achieved and the through channel is opened.

The task is achieved by the fact that the locking device for tapping into the pipeline under pressure comprises a body made of two interconnected parts and crossed by a through channel with flanges at its ends. In the body cavity there is a damper made with the possibility of movement by the drive. To equalize the pressure in the body parts above and below the damper, two channels are made, communicating with the through channel and connected by a channel crossing the body parts with the valve. The novelty is that the knife-type damper has a displacement drive in the form of a lead screw with a multi-thread thread, fixed along the body cavity and a nut mounted on the lead screw, which is connected to one side of the knife damper. The other side of the shutter is inserted into a slot made in the body from the side of the through hole. The damper is located and moves parallel to the lead screw. In addition, the lead screw is fixed along the housing on one side through a bearing installed in a hole in the housing, and on the other side with a support bearing inserted into a groove made in the housing from the side of the through hole. The nut, mounted on the lead screw, has a square outer shape and is inserted into a longitudinal groove made along the upper part of the body with respect to the pipeline. The nut has a rectangular protrusion and is connected to the knife flap by a groove and tenon connection. In parts of the body there are longitudinal grooves with sealing material parallel to the lead screw. The pressure equalization valve is made in the form of a rubber seal connected to a screw inserted into a channel located in the body below the flap with the possibility of closing the channel crossing the body parts, and the lead screw head is located outside the body.

The invention is illustrated by drawings, where Fig. 1 shows a general view of the locking device connected to the pipeline, FIG. 2 - General view of the device in longitudinal section, Fig. 3 shows the design of the damper drive, FIG. 4 is the upper part of the housing with grooves for the drive and sealing material, and FIG. 5 the lower part of the housing with a knife flap, FIG. 6 - pressure equalization valve.

A locking device (ZI) for tapping into a pipeline under pressure, contains (Fig. 1) a body made of two parts: the lower part 1 in relation to the pipeline on which the ZI is installed and the upper part 2. The parts of the body are rigidly connected to each other along the perimeter bolts 3. The body is crossed by one through channel with flanges 4 and 5 at its ends. Flanges 4 and 5 are used to connect the locking device on the one hand to the fittings 23 welded to the pipeline 24, on the other hand to the assemblies necessary for tapping into the pipeline under pressure. A rectangular cavity is formed inside the body (Fig. 2), into which a knife-type shutter is inserted 6. The shutter is an octagonal metal plate with rounded corners and edges (Fig. 5). The knife shutter 6 is made with the possibility of moving inside the body from the "closed" position, in which it completely closes the through channel, to the "open" position, in which it is located in the rectangular cavity of the body, and the flowing medium freely passes through the through channel. The body has a shape and size, which are determined by the size of the knife gate 6 in the "open" position and the size of the through channel. The shutter 6 is moved by means of a drive 7 with a handle 26 at the end, which is located outside the housing. The drive is used to control the valve. The drive for displacement 7 of the damper (Figs. 2, 3) is made in the form of a lead screw 8 located along the rectangular cavity of the body. The lead screw 8 has a multi-start thread along its entire working surface. One end of the lead screw 8 from the side of the handle 26 is installed through the bearing 9 into the housing bore, and the other end is located in the support bearing 10 inserted into the groove made in the housing part 2 adjacent to the through hole. A nut 12 is mounted on the lead screw 8, which moves along the lead screw 8 (Fig. 3). Nut 12 has a square outer shape. On one side of the square there is a rectangular protrusion 14. The nut 12 is inserted on the opposite side to the protrusion into a longitudinal groove 11 cut along the upper part 2 of the body (Fig. 4). When screw 8 rotates, the nut moves along the multi-start thread of the lead screw from one end to the other along the body cavity along the groove 11. Due to this connection and location, the nut moves smoothly without distortions along the ZI body when the screw rotates. On the nut 12 is fixed one side of the knife shutter 6, opposite to the through hole. On this side of the shutter, a hole (groove) 13 is made in the shape of repeating the size of the projection 14 of the nut, which is inserted (pushed) into this hole, forming a groove-tenon connection. The other side of the shutter is inserted into the transverse slot 25 with a seal formed in the body from the side of the through hole. The damper 6 is located parallel to the lead screw 8. When the handle is turned, the lead screw transmits movement to the drive nut, which moves the damper to the "closed" or "open" position, while closing or opening the through hole for the working medium. In the body cavity along the upper and lower 1 and 2 parts of the body there are two grooves 15, which are located parallel to the groove 11 located between them, and the lead screw 8. In the grooves 15 there is a sealing material (gasket) - strips of antifriction material. When moving, the damper 6 moves (slides) along these gaskets in the body perpendicular to the movement of the working medium flow. This type of device refers to parallel dampers, the design of which assumes that the sealing surfaces of the gaskets are parallel to each other. The locking device has a unit for equalizing the pressure above and below the damper in the "closed" position in the through channel, when the locking device is connected to the pipeline and the unit for tapping into the pipeline under gas pressure. In the wall of the housing adjacent to the through hole there are two longitudinal through channels 16 and 17 (Fig. 6), located in two parallel parts 1 and 2 of the housing. Longitudinal channels 16 and 17 communicate with a through channel above and below the shutter 6. Longitudinal channels 16 and 17 are connected by a channel 18 crossing the two body parts. One longitudinal channel 16 upstream of the working medium from the closing flap 6 from the outside of the housing is closed with a plug 19, and the other has a valve for pressure equalization. The pressure equalization valve is made in the form of a rubber seal 20 inserted into the channel 17 and connected to the screw 21, which is screwed into the longitudinal channel 17 downstream from the closing flap 6. The length of the screw 21 is selected from the condition that when screwed into the longitudinal channel 17 a rubber seal 20 closes the channel connecting the longitudinal channels 17 and 16. The lead screw head 22 is located outside the housing.

The device works as follows.

The locking device is a valve structure with a shutter in the form of a knife-type shutter 6 of an octagonal shape. With the help of the drive 7, the damper is controlled by turning the handle 26 of the drive. In this case, the lead screw 8 transmits the movement to the drive nut 12, which moves together with the shutter 6 along the multi-start thread and opens or closes the through channel for the passage or stop of the working medium. The multi-start thread made on the lead screw 8 ensures the uniformity of the stroke and the strength of the connection between the nut and the screw. At the same time, the multi-start thread changes the gear number of revolutions, which reduces the force during the rotation of the screw and reduces the number of revolutions. The damper drive is located inside the housing, and the damper moves parallel to the ZI body and perpendicular to the flow of the working medium, similar to a knife. The locking device is in the "closed" position, in which the shutter 6 closes the through channel in the body and the nut 12, on which the shutter 6 is fixed, is located at one end of the lead screw 8 from the side of the through hole. To transfer the locking device to the "open" position, for example, to perform a tie-in into the pipeline, turn the drive handle 7 in the opposite direction. The handle connected to the lead screw 8 rotates it and the nut 12 moves along the lead screw 8 towards the handle, moving the shutter 6 parallel to the lead screw 8 into the body cavity. When the nut 12 reaches the second end of the lead screw 8 from the handle side, one side of the shutter 6 connected to the nut will reach the edge of the housing cavity from the handle side, while the other side of the shutter will be located in the slot 25 made in the housing from the side of the through hole. Thus, the flap will be located in the rectangular cavity of the body and will completely open the through hole. The lead screw 8 is fixed along the body through bearings 9 and 10 installed at both ends from the body cavity and it rotates inside the body, therefore, when the handle rotates, work is carried out in one place, which simplifies the process of controlling the lead screw. The damper 6 moves in the housing along the guide grooves with a sealing material 15 made in two parts of the housing, which prevents skewing and ensures smooth movement of the damper. With this design of the drive, the opening and closing of the damper 6 with the help of the handle occurs smoothly without jolts and distortions, which simplifies the control of the drive and the movement of the damper.

Before moving the locking device to the "open" position after tapping into the pipeline 24, the pressure is equalized above and below the damper in the through channel. To do this, the valve in the form of a rubber seal 20 is unscrewed from the channel 17 below the flap using the screw 21 and the channel 18 is opened, connecting the longitudinal channels 16 and 17. At the same time, the medium flowing through the pipeline, which is under the closed valve 6 along the longitudinal channels 16 and 17, and also channel 18 enters the space above the damper 6 and the pressure above and below the damper 6 is equalized. Due to this, when opening the shutter 6 after tapping into the pipeline 24, there is no impact on it by the medium under pressure. This also helps to simplify the control of the drive and the locking device as a whole.

Thus, the proposed locking device makes it possible to simplify the control of the damper when reaching full overlap and opening the through channel, which increases the reliability of the device.

Claims (6)

1. A locking device for tapping into a pipeline under pressure, containing a body made of two interconnected parts and crossed by a through channel with flanges at its ends, a damper is located in the body cavity, which can be moved by an actuator, in parts of the body above and below the damper two channels are made, communicating with the through channel and connected by a channel crossing the body parts with a valve to equalize the pressure, characterized in that the knife-type damper has a movement drive in the form of a lead screw with a multi-start thread, fixed along the body cavity, and a nut mounted on the lead screw , which is connected to one side of the knife shutter, the other side of the shutter is inserted into a slot made in the body from the side of the through hole, while the shutter is located and moves parallel to the lead screw. 2. A locking device for tapping into a pipeline under pressure according to claim 1, characterized in that the lead screw is fixed along the housing on one side through a bearing installed in a hole in the housing, and on the other side with a support bearing inserted into a groove made in the body from the side of the through hole. 3. A locking device for tapping into a pipeline under pressure according to claim 1, characterized in that the nut mounted on the lead screw has a square outer shape and is inserted into a longitudinal groove made along the upper part of the body relative to the pipeline. 4. A locking device for tapping into a pipeline under pressure according to claim 1, characterized in that the nut has a rectangular protrusion and is connected to the knife gate by a groove-and-tenon connection. 5. A locking device for tapping into a pipeline under pressure according to claim 1, characterized in that longitudinal grooves with sealing material are made in the body parts, parallel to the lead screw. 6. A locking device for tapping into a pipeline under pressure according to claim 1, characterized in that the pressure equalization valve is made in the form of a rubber seal connected to a screw inserted into the channel located in the body below the valve with the possibility of closing the channel crossing the body parts , and the lead screw head is located outside the housing.

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