RU2285189C2 - Device for cutting off operating pipeline - Google Patents

Abstract

FIELD: pipeline engineering.

SUBSTANCE: device comprises expandable flexible chamber secured to the central pin of the rotatable unit and bearing extensible member composed of tabs that are in a contact one with the other. The tabs are arranged over periphery, pivotally interconnected, and bear on the inner side of the pipeline. The rotatable unit is pivotally connected with the plunger that is movably mounted in the pipe provided with the flange. The plunger is sealed within the pipe by means of seals. The plunger receives the rack gearing that has the pinion and rack with a seal. The rack is pivotally connected with the rotatable unit through the tie. The axle of the pinion is provided with the handle having locator for permitting the handle to be locked on the plunger at the initial and working positions.

EFFECT: enhanced reliability.

5 cl, 3 dwg

Description

The invention relates to the field of pipeline transport and can be used in the operation and repair of pipelines for their overlap when replacing damaged sections.

Known devices for blocking the cross-section of pipelines, for example, a plug for pipelines (1), containing a blocking element made in the form of an inflatable pillow mounted on a hinge device connected with a plunger, by means of which the inflatable pillow is introduced in the folded state through a side opening in the pipeline.

In this device, the main disadvantage is its low operational ability when blocking pipelines with high pressure. This is explained by the fact that the overlapping element has support only in the center of the pipe and, since it must be thin enough to be inserted into the pipeline through the lateral hole in the folded state, it cannot withstand the increased pressure in the pipeline, which often leads to its movement along the pipeline, which means a loss of tightness of the ceiling.

Also known is a “damping rubber cord device for blocking pipelines” (2), comprising an outer cylindrical shell made of rubberized material reinforced with threads, and also two end walls reinforced with threads, connected to the shell to form an inner chamber, while the end wall is provided with a pipe fitting.

The disadvantage of this device is that with such a design, the cylindrical shell cannot be elastic enough to be folded and inserted into the pipe through a small side opening. That is, for its introduction into the pipeline, a side hole with a diameter equal to the diameter of the pipeline itself is required. And for cutting such a hole and its subsequent jamming requires expensive equipment.

It is also known a device for blocking the internal cavity of the pipeline (3), comprising a blocking element made in the form of an expanding elastic chamber located on a coil with flanges and provided with friction pads articulated by levers with a coil, and a fitting for filling the chamber, as well as a mechanism input and removal of the camera from the pipeline.

The disadvantage of this device is the lack of support for an elastic chamber over the entire cross section of the pipeline. Friction linings keep the elastic chamber from axial movement, but the end walls of the chamber must be of considerable thickness in order to absorb pressure in the pipeline. An increase in the thickness of the walls of the chamber leads to an increase in the diameter of the side hole through which the chamber is introduced, which in turn increases the cost of equipment and the complexity of installing the side pipe and cutting the hole in the pipe wall. In addition, increasing the diameter of the side opening reduces the strength of the wall of the pipeline itself.

A device for blocking a cavity of a gas pipeline under pressure (4), comprising a plug with a sealing plug and a drive for moving the plug. The sealing plug is made in the form of metal expandable sectors, of which two sectors are external and two sectors are internal, and each of them is equipped with an elastic sealing element.

However, in the specified known device, the sealing elements are located only on the peripheral part of the sectors, and the gaps between the sectors remain not sealed. In addition, in the presence of an elliptical internal cavity of the pipeline, rigid metal sectors cannot completely block it. Thus, with this known device it is not possible to achieve complete tightness of the pipeline shut-off.

The closest to the proposed technical solution in terms of features is a device for blocking the existing pipeline, described in the patent of the Russian Federation (5). The known device consists of a blocking element made in the form of an expanding elastic chamber (inflated by a gas flexible bag), one of the end walls of which is connected to the mechanism of its input-output into the pipeline - from the pipeline and is equipped with a fitting for filling the chamber with gas, and is additionally equipped with a sliding support means for preventing axial movement of the camera in the form of a sliding frame. The presence of a sliding frame that takes on part of the mechanical load when the pipeline is closed, allows you to reduce the volume of the elastic chamber, as well as reduce its cost.

The disadvantage of this known device is that the supporting sliding means in the form of a sliding frame cannot create support for the entire end surface of the elastic chamber, therefore, when using the device in a pipeline with high pressure or in a pulsating mode, it is necessary to strengthen this end wall, which may can only be achieved by increasing its thickness while reducing elasticity. In this case, the diameter of the side opening through which the camera is introduced into the pipeline inevitably grows. And an increase in the diameter of the side opening leads to an increase in the cost of tapping into the pipeline and to a decrease in the strength of the pipeline itself.

The technical result achieved by the present invention is to increase the reliability of the pipeline shutoff by ensuring guaranteed sealing under any conditions, namely at high pressure, with various ranges of pipeline diameters and their cross-sectional shapes, by eliminating the movement of the expanded elastic chamber along the pipeline under these conditions , while reducing the cost of tapping into the pipeline by reducing the diameter of the side hole required for the introduction of elasti hydrochloric chamber into the conduit.

The specified technical result is achieved by the proposed device for blocking the existing pipeline, including a blocking element made in the form of an expanding elastic chamber, one of the end walls of which is connected to the I / O mechanism in the pipeline — from the pipeline and is equipped with a fitting for filling the chamber and supporting sliding means to prevent axial movement of the chamber, while the supporting sliding means is made in the form of a group of petals in contact with each other, placed on about of circles rotatably and movably attached at one end to the central member, connected to the input-output mechanism through a swivel, which is further provided with said mechanism.

The petals of the supporting sliding means are arranged uniformly fan-shaped around the circumference with the possibility of formation of a continuous disk surface when sliding.

The petals of the supporting sliding means are made with the possibility of their interaction with the inner surface of the pipeline at their full turn.

The petals of the supporting sliding means are spring-loaded and pivotally mounted on a central element connected to the rotary assembly of the input-output mechanism.

The overlapping element is provided with an elastic gasket made in the form of a cuff and placed between the overlapping element and the supporting sliding means.

The expanding elastic chamber is made in the form of a hollow cylinder with an end wall concave into the chamber and facing the muffled section of the pipeline.

The task posed by the creation of the invention is solved by the following.

Thanks to the implementation of the supporting sliding means in the form of a group of petals in contact with each other, rotatable around the circumference, it is possible to create a reliable diametrical support (practically over the entire cross-section of the pipeline) of the support for the overlapping element, which guarantees sealing in any conditions, namely at high as well as pulsating pressure, at various ranges of diameters of pipelines and their cross-sectional shapes. The design of the supporting sliding element, made in the form of spring-loaded petals, pivotally mounted on the central element connected to the rotary part of the input-output mechanism, ensures their sliding and return to the folded position with the possibility of holding in this initial position. In this position, the elastic chamber is also located inside the folded petals, which allows the diameter of the side hole in the pipeline to be inserted into the device to a minimum. This ensures the preservation of the strength of the pipe wall and reduces the cost of inserting a side hole.

The supporting sliding means perceives the axial force, which arises from the pressure in the pipeline and acts on the elastic chamber. An elastic gasket located in the proposed device between the petals and the elastic chamber protects the latter from contact with the petals and, accordingly, from its premature wear. In addition, the implementation of the elastic strip in the form of a cuff creates an additional sealing effect.

The design of the elastic chamber in the form of a hollow cylinder with an end wall curved into the chamber facing the damped section of the pipeline ensures reliable sealing of the chamber in the pipeline, because the pressing of the cylindrical surface to the inner surface of the pipeline provides not only the pressure inside the elastic chamber, but also the pressure in the pipeline, which, when the end wall is concave inward, additionally presses the chamber against the sealing surface like a lip seal.

Thanks to such features of design features, the specified technical result is achieved.

The proposed device is illustrated by drawings, in which Fig. 1 shows a schematic general view of the device, in Fig. 2 - view A - supporting sliding means in the operating (open) position, Fig. 3 - view A - supporting sliding means in the folded position.

The proposed device for blocking the existing pipeline contains an elastic chamber 1, mounted on the central pin 2 of the rotary assembly 3, and a supporting sliding means, consisting of petals 4 in contact with each other, arranged around the circumference and pivotally connected at one end with the help of axis 5 with the central element in in the form of a flange 6 and resting in an open position on the inner surface of the pipeline 7. The petals 4 can interact with the flange 6, which is the central element, and without using the axis 5, for example, by placing the ends of the petals 4 in the groove at the end of the flange 6. In this case, it is possible to fix the petals 4 on the end wall of the elastic chamber 1 opposite to the blocked flow, which in turn is mounted on the flange 6. The petals 4 are in interaction with the springs 8 located on the flange 6. Instead of the flat springs 8 shown in FIG. 1, one spring surrounding the petals 4 can be used: either a rubber band or a band of another elastic material. To keep the petals 4 in the initial (folded) position, a thread of design strength can also be applied, which tears when the elastic chamber 1 expands, releasing the petals 4.

Between the petals 4 and the elastic chamber 1 is an elastic gasket 9, made in the form of a cuff. The rotary assembly 3 with the help of the axis 10 is pivotally connected to the plunger 11, movably and hermetically located in the pipe 12 with the flange 13. The sealing of the plunger 11 in the pipe 12 is provided by the gaskets 14. In the plunger 11 there is a rack gear consisting of a gear 15 and a rack 16 with a seal 17. The rod 16 is pivotally connected via a rod 18 with a rotary node 3. The axis of the gear 15 is equipped with a handle with a lock (not shown) with the possibility of fixing it on the plunger 11 in two positions - the original and working. Instead of a rack and pinion transmission, a screw or other mechanism can be used. The plunger 11 is equipped with a screw 19 and a nut 20 mounted in the lid of the cup 21 having a longitudinal groove 22 through which the axis of the gear 15 passes and fixed to the pipe 12. A valve 23 is installed on the pipeline 7 through the pipe 24, coaxially with which in the wall of the pipe 7 slotted hole. To fill the elastic chamber 1, the plunger 11 has a fitting 25 and a flexible sleeve 26 connected to the elastic chamber through a channel in the rotary assembly 3. The lower part of the plunger 11 has a diameter smaller than the diameter of the side opening of the pipeline 7, and the diameter of the upper part of the plunger 11 is larger than the diameter of this hole , therefore, between the upper and lower parts of the plunger 11 there is an end ledge.

The work of the proposed device for blocking existing pipelines is as follows. On the closed valve 23, mounted on the pipe 24, which is connected by welding to the pipe 7 and through which a hole is coaxially cut in the wall of the pipe 7, install the device by tightly connecting the flange 13 with the flange of the valve 23. The following preparatory work is carried out first. By turning the gear 15, the rack 16 with the thrust 18 is lowered to the lower position. In this case, the elastic chamber 1 with the central pin 2, together with the rotary assembly 3, rotate around the axis 10 by 90 ° and occupy a vertical position. Through the nozzle 25, the flexible sleeve 26 and the channel in the rotary assembly 3 relieve pressure in the elastic chamber 1. The springs 8 rotate the petals 4 on the axles 5 relative to the flange 6, which fold into their original (folded) position without leaving contact with each other, while form an internal cavity in which the folded elastic chamber 1 with the elastic gasket 9 is placed. By rotating the nut 20, the screw 19 with the plunger 11 and, accordingly, with the elastic chamber 1 are brought to the upper (initial) position. After carrying out the indicated preparatory work and fixing the flange 13 to the valve 23, the specified valve 23 is opened and the nut 20 is rotated by the screw 19 to move the plunger 11 together with the rotary unit 3 and the elastic chamber 1 located inside the folded petals 4 through the hole in the pipe wall 7. When The tightness of the device is ensured by the seals 14 and 17. As the folded petals 4 move with the elastic chamber 1 through the hole in the wall of the pipeline 7, the gear 15 is rotated, moving the rail with the rod 18 up and turning I swivel 3 on the axis 10 to the right. The axis of the gear 15 is moved along the groove 22 of the cup 21, mounted on the pipe 12. The plunger 11 is moved to the end of its end ledge to the outer surface of the pipeline 7 (this is the working position of the device). The gear 15 is turned to a fixed position, while the rack 16 will occupy the upper position, and the elastic chamber 1 with the central pin 2 and the axis 10 will be located along the axis of the pipeline 7. Then, pressure is supplied through the fitting 25, the flexible sleeve 26 and the channel in the rotary unit 3 inwards elastic chamber 1. The magnitude of the supplied pressure is slightly greater than the pressure in the pipeline 7, so the elastic chamber 1 expands and fills the cross section of the pipeline 7, while it acts through the elastic gasket 9 on the petals 4 of the supporting sliding means a, rotates them on the axes 5 relative to the flange 6 all the way into the inner surface of the pipeline 7. In this case, the petals 4 do not come out of contact with each other and create support for the elastic chamber 1 in the form of a rigid continuous end wall of a plate shape. After that, the pressure is removed in the left (relative to the elastic chamber 1) part of the pipeline 7. The liquid pressure in the plugged part of the pipeline 7 (the right part of the pipeline 7 relative to the elastic chamber 1) acts on the concave end wall of the elastic chamber 1 and additionally presses it on the inner surface of the pipeline 7 , increasing the tightness of the overlap. Increasing the tightness and contributes to the implementation of the elastic strip 9 in the form of a cuff. In addition, it is possible to make the petals 4 in the supporting sliding means of various lengths, as well as placing such petals in certain groups, which, when extended, would make it possible to obtain a diametrical support in the form of an ellipse or in the form of another figure, which will guarantee the tightness of the overlap of pipelines having an ellipsoidal cross cross section and cross section of a different shape. After performing the indicated operations, the pipeline 7 will be closed and repair work can be performed on the defective area located to the left of the nozzle 24. After the repair work, the pressure is equalized to the left and right of the device, the pressure in the elastic chamber 1 is relieved, and the springs 8 rotate the petals 4 to center, fold them together with an elastic gasket 9 and an elastic chamber 1 in the initial folded position. The rotation of the nut 20 and the simultaneous rotation of the gear 15 bring the rotary assembly 3 into the vertical position as described above, take it out of the pipeline 7 and close the valve 23. After that, the device is removed from the valve 23. And it can be used on another pipeline.

The proposed device allows you to quickly and safely seal the internal cavity of the pipeline and reliably hold in a stationary state without axial movement of the overlapping element even with a possible increase in pressure in the blocked cavity. Moreover, due to the small diameter of the hole in the side wall of the pipeline, this wall will not weaken and its strength will not change. All this will increase the reliability of the overlap and reduce costs.

INFORMATION SOURCES

1. US patent No. 3842864, CL. F 16 L 58/12, 1973

2. Auth. USSR certificate. No. 1499049, class F 16 L 55/10, 1987

3. RF patent No. 2187744, cl. F 16 L 55/32, 1998

4. RF patent No. 2173 810, cl. F 16 L 55/124, 1999

5. RF patent No. 2226640, cl. F 16 L 55/16, 2001

Claims (6)

1. A device for blocking an existing pipeline, comprising a blocking element made in the form of an expanding elastic chamber, one of the end walls of which is connected to the input / output mechanism of the pipeline — from the pipeline and equipped with a fitting for filling the chamber and supporting sliding means to prevent axial movement of the chamber characterized in that the supporting sliding means is made in the form of a group of petals in contact with each other, arranged around a circle with the possibility of rotation and movably akreplennyh one end of the central element, connected to the input-output mechanism through a swivel, which is further provided with said mechanism. 2. The device according to claim 1, characterized in that the petals of the supporting sliding means are arranged uniformly fan-shaped around the circumference with the possibility of forming a continuous disk surface when extending in the radial direction. 3. The device according to claim 1, characterized in that the petals of the support sliding means are made with the possibility of their interaction with the inner surface of the pipeline with their full turn in the radial direction. 4. The device according to claim 1, characterized in that the petals of the supporting sliding means are spring-loaded and pivotally mounted on a central element associated with a rotary node of the input-output mechanism. 5. The device according to claim 1, characterized in that the overlapping element is provided with an elastic gasket made in the form of a cuff and placed between the overlapping element and the supporting sliding means. 6. The device according to claim 1, characterized in that the expanding elastic chamber is made in the form of a hollow cylinder with an end wall concave into the chamber facing the muffled section of the pipeline.

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