RU111228U1 - CRANE CYLINDER - Google Patents

Abstract

 1. The crane is cylindrical, comprising a housing with an internal cavity adjacent to the inlet and outlet nozzles, a rotary shut-off element with inlet and outlet windows, characterized in that the inlet and outlet nozzles are made at an angle of 90 ° relative to each other, the shut-off element is equipped with sealing elements and a branch segment, has the shape of a glass, the input window of which is made on the side surface perpendicular to the axis of rotation of the latter in the form of an elliptical hole, equal in cross-sectional area to the pipe channel moreover, the closed end of the glass is equipped with a spindle installed in the sliding bearing of the housing cover coaxially mounted to the outlet pipe, and the open end of the glass is installed in the sliding bearing fixed in the output section of the latter. ! 2. The crane according to claim 1, characterized in that the shut-off element is mounted with limited rotation around the axis from a kinematically connected drive. ! 3. The crane according to claim 1, characterized in that the inlet sealing element is installed in the channel of the inlet pipe in the form of a conical sleeve with a circular opening at the inlet and an elliptical outlet, the cross-sectional areas of which are equal, and the output sealing element is fixed in the upper part of the housing.

Description

The utility model relates to valve engineering, in particular, to pipeline valves, designed to be used as a locking device, blocking the flow of various working media (water, oil, gas, steam, etc.) in pipelines for various purposes, and can be widely used in technological piping of compressor, distribution stations, gas pipelines, oil pipelines, water pipelines, etc.

Known conical stopcocks (see DF Gurevich "Reference designer of pipe fittings." M .: Mechanical Engineering, 1987, p. 72, Fig. 2.4). This crane has a body and a conical plug, which is a locking element, in the cross section of which a hole is made for the passage of the working medium. When turning 90 °, the valve closes. The size and shape of the hole should ensure that in the closed position of the valve overlap with a stopper of the body, sufficient to seal the locking element.

The main advantages are: simplicity of design, low height, low hydraulic pressure.

The disadvantages of the known crane include the following: to control cranes with a large nominal diameter of the passage of the working medium, large torques are required, careful maintenance and lubrication of the sealing surfaces of the conical plug and housing are necessary to avoid “sticking” of the plug to the housing, and the fitting (lapping) of the conical plug is complicated to the body, wear of conical plugs uneven in height, which during operation leads to a decrease in the sealing of the shut-off element.

Widely known are ball valves on supports with a movable sealing ring for pipelines with large nominal diameters of the passage of the working medium (see DF Gurevich "Handbook of Pipe Fittings Constructor". M: Mechanical Engineering, 1987, p. 78, Fig. 2.126). This ball valve has a housing, a locking member and two sealing bodies (seats). The housing contains a through channel for the working medium, at the ends of which there are two pipeline flanges with a working medium through-hole, moreover, a hole is made symmetrically to the flanges, perpendicular to the axis of the working medium channel under the shut-off element, which contains a spindle, two bearings and a working surface that is perpendicular to the axis of the supports a through hole of the passage of the working medium, and it is smaller than the jumper in cross section, a centering sleeve with sealing elements is installed from the end in the hole for the locking element a bearing support, and on both sides of the blocking member working surface mounted sealing bodies with a central hole of passage of working environment and to seal working fluid channel, which are pressed by springs to the working surface.

The main advantage of the known technical solution is the possibility of using in pipelines with a conditional passage Dy≤1400 mm or more at a pressure Py≤16 MPa. On the linear part of the main gas pipelines, ball valves are the main locking devices. They have been widely used at other gas pipeline facilities.

The disadvantages of the known technical solutions include: the low-tech design of the ball valve during machining and assembly of the valve, leading to the complexity of manufacturing the valve and increased cost, as well as viscous and contaminated working environments lead to rapid wear of the sealing bodies. Contaminated working media when they get into the interface between the sealing seats and the valve body disrupt their mobility, which leads to planar misalignment of the sealing seats and their uneven pressing against the surface of the shut-off element, resulting in leakage of the ball valve. The design of the crane eliminates the possibility of restoration repair work to eliminate the skew and restore the tightness of the crane due to the lack of technological access to the sealing seats. In case of loss of elasticity of the sealing elements of the seats, there is also no possibility of replacing them and, as a result, to ensure the tightness of the valve due to the “leaving” of the lubricant in the pipeline cavity.

Also known is a shut-off, cylindrical crane (see RF patent for utility model No. 63012, IPC F16K 5/00, published on 05/10/2007), having a housing that consists of two pipes of different cross-sections that are mutually perpendicular and tightly interconnected, moreover a pipe of a smaller cross section has a pipe channel for the passage of the working medium, and a pipe of a larger cross section has a channel for a locking body with a locking cylindrical surface, in the cross section of which a hole is made for a conditional passage of the working medium D _y , which is smaller than the jumper L in this section, and there are plugs on both sides of this surface along the support and the spindle, and plugs are installed in the pipe, while at the ends of the pipe there are fixed centering sleeves with bearings under the bearings, and sealing bodies are installed in the pipe channel on both sides of the cylindrical locking surface made in the form of bushings with a hole D _y , a seal in the pipe channel and an end sealing surface corresponding to the reciprocal locking cylindrical surface, which compress connecting to it with elastic elements, the compression of which is ensured by the pipe flanges installed motionlessly at the ends of the pipe with an opening D _y and a seal in the pipeline channel. A control element is installed on the spindle, which provides the opening and closing of the crane when turning 90 °.

The main advantage, as well as for ball valves, is the ability to use in pipelines with nominal bore Dy≤1400 mm or more at a pressure of Py≤16 MPa, the manufacturability of the crane design during mechanical processing and assembly of the valve. The design of the crane allows you to perform restoration repairs in the conditions of existing production.

The disadvantages of the known crane are: the complex design of the crane body, overall dimensions and weight. The locking hollow cylinder is made of two mutually perpendicular, hermetically connected to each other pipes of different sections, the pipe of a smaller section having an opening D _y , and the pipe of a larger section has an external locking cylindrical surface. Thus, the diameter of the pipe of larger cross section (D mbs) should be at least the length of the diagonal of the inscribed square with a side equal to D _y and can be expressed as:

So at D _y = 1000 mm Dmbs = 1414 mm.

This means that in order to shut off a pipeline with a passage diameter of 1000 mm, a cylindrical shut-off element with a diameter of more than 1400 mm must be placed in the body of a cylindrical valve. The body of this crane will have not only a complex structure, but also a large mass in relation to the mass of existing types of valves.

Closest to the claimed utility model in technical essence is the design of the crane according to the patent of the Russian Federation No. 2148198, IPC F16K 5/04, publ. 04/27/2000, the invention of the "Cylindrical crane", comprising a housing with an internal cavity, adjacent to the inlet and outlet nozzles, a rotary locking element with inlet and outlet windows.

The disadvantages of the known crane are: the design of the crane involves using it only to control the flow of fluid in water and heat supply systems, designed for pressures up to 25 atm. and does not provide for the possibility of repairing the main elements, with the exception of the spindle seal assembly. In addition, the diameter of the passage channel of the shutter does not correspond to the diameter of the connecting pipes, which increases the hydraulic resistance.

The objective of this utility model is to create a device having a relatively simple design, thereby ensuring high operational reliability.

The problem underlying this utility model is solved by the fact that in a cylindrical crane containing a body with an internal cavity, to which the inlet and outlet nozzles are adjacent, a rotary shut-off element with inlet and outlet windows, the inlet and outlet nozzles are made at an angle of 90 ° relative to each other friend, the locking body is equipped with sealing elements and a branch segment, has the shape of a glass, the input window of which is made on the side surface perpendicular to the axis of rotation of the latter in the form of an elliptical hole, the cross-section of the pipe channel is equal in area, and the closed end of the glass is equipped with a spindle installed in the sliding bearing of the housing cover, coaxially mounted to the outlet pipe, and the open end of the glass is installed in the sliding bearing fixed in the output section of the latter.

In addition, the locking element is mounted with limited rotation around the axis from a kinematically associated drive.

In addition, the inlet sealing element is installed in the channel of the inlet pipe in the form of a conical sleeve with a circular opening at the inlet and an elliptical outlet, the cross-sectional areas of which are equal, and the output sealing element is fixed in the upper part of the housing.

The proposed utility model allows for repair work in an enterprise without dismantling the crane.

The design of the shut-off element, the inlet window of which is made on the lateral surface perpendicular to the axis of rotation in the form of an elliptical hole, equal in cross-sectional area to the pipeline channel, allows to reduce the metal consumption of the valve, and its supply with the outlet segment allows to reduce the pulsation of the gas flow (or other working medium), providing laminarity when turning in a lock on 90 °.

A comparative analysis of the proposed technical solution with identified analogues of the prior art, from which the utility model does not explicitly follow for a specialist in the field of valve engineering, showed that it is not known, and taking into account the possibility of industrial serial production of a cylindrical crane, we can conclude that the patentability criteria are met .

Preferred embodiments of the utility model are described below based on the drawings, where:

- figure 1 shows an example of a cylindrical crane, General view;

- figure 2 is a section aa in figure 1;

- figure 3 is a section bb in figure 1.

In graphic materials, the corresponding structural elements of a cylindrical crane are indicated by the following positions:

1. - case;

2. - a locking organ;

3. - pipe;

4. - pipe;

5. - the spindle of the locking element;

6. - a segment of tap locking;

7. - input sealing element;

8. - housing cover;

9. - drive housing;

10. - drive lever;

11. - plain bearing;

12. - plain bearing;

13. - output sealing element.

The proposed cylindrical crane comprises a housing 1, a locking member 2 with a retraction segment 6, an inlet sealing member 7, an output sealing member 13, a sliding bearing 11 with a seal of the spindle 5 of the locking member 2, a sliding bearing 12 with a seal, two pipe connections 3 and 4, the housing 9 drive, lever 10 drive.

The housing 1 consists of a cylinder with a lateral inlet 4 and end outlet 3 nozzles made at an angle of 90 ° relative to each other, from the end opposite the outlet nozzle 3 there is a connector for fixing the cover 8 with an opening for the installation of the sliding bearing 11 and the seal of the spindle 5 of the locking member 2.

The locking element 2 has the shape of a glass, the input window of which is made on the lateral surface perpendicular to the axis of rotation of the latter in the form of an elliptical hole of equal cross-sectional area of the pipe channel and is mounted with the possibility of limited rotation around the axis from a kinematically connected drive.

The inlet window on the lateral surface of the locking member 2 (cup) is made in the form of an elliptical hole equal in cross-sectional area to the pipe channel to reduce the diameter of the locking member itself. The section shows that the diameter of the locking element (glass) does not exceed the diameter of the inlet channel, which reduces the metal structure of the crane. In the case of the use of an inlet of circular cross section equal to d1, the diameter of the locking element d ₃ should significantly exceed the diameter of the inlet channel d1, which will lead to an increase in the mass and size of the crane. The output sealing element in this case cannot be placed strictly in the upper part of the housing, but will be shifted to the left and the rotation of the locking element to block the input channel will exceed 90 degrees, which will require complication of the drive design.

The closed end of the cup is equipped with a spindle 5 mounted in the sliding bearing 11 of the housing cover 8, coaxially mounted to the outlet pipe 3, and the open end of the cup is installed in the sliding bearing 12 fixed in the output section of the latter.

The inlet sealing element 7 is installed in the channel of the inlet pipe 4 in the form of a conical sleeve with an opening of circular cross section at the inlet and elliptical at the outlet, the cross-sectional areas of which are equal. Fluoroplastic and rubber o-rings ensure tightness of the connection with the valve body 1, and in order to achieve a high degree of tightness, a polyurethane ring is installed on the elliptical plane in connection with the lateral surface of the locking element 2 (these rings are not shown in the drawings). The preliminary pressing of the sleeve of the sealing element to the lateral surface of the locking element is provided by springs, and in the closed position it is additionally pressed by the pressure of the working medium.

The output sealing element 13 is made in the form of a sector repeating the contours of the input elliptical hole, is attached to the upper part of the valve body and has a polyurethane ring for tightness of the connection.

Two pipe flanges of the nozzles 3 and 4 have a hole D _y and are intended for fastening between the flanges on the pipeline supplying the working medium using sealing gaskets and fasteners.

Assembly of the cylindrical crane is as follows.

A sliding bearing 12 with a seal is installed in the housing 1, an input sealing element 7 is installed in the pipe channel 4, an output sealing element 13 is attached to the upper part of the housing 1. A cylindrical locking element 2 is inserted into the crane housing 1 until it is fully interfaced with the sliding bearing 12. At the end the connector of the housing 1 install the cover 8 with a sliding bearing 11. To the cover 8 fasten the housing 9 of the actuator, ensuring the coupling of the lever 10 with the spindle 5 of the locking member 2.

Opening and closing of the cylindrical crane is carried out by turning the lever 10 of the actuator 90 °.

The design of the crane allows you to restore the tightness of the cylindrical locking element in the conditions of production during planned shutdowns of technological equipment. If there is an exchange fund of components, the repair time will be minimized, and factory equipment for dismantling and assembling parts of large-diameter cranes will greatly simplify the repair procedure. It is important that repair work can be carried out at an existing hazardous production facility without stopping it, since repair work does not require hot work.

Claims (3)

1. The crane is cylindrical, comprising a housing with an internal cavity adjacent to the inlet and outlet nozzles, a rotary shut-off element with inlet and outlet windows, characterized in that the inlet and outlet nozzles are made at an angle of 90 ° relative to each other, the shut-off element is equipped with sealing elements and a branch segment, has the shape of a glass, the input window of which is made on the side surface perpendicular to the axis of rotation of the latter in the form of an elliptical hole, equal in cross-sectional area to the pipe channel moreover, the closed end of the glass is equipped with a spindle installed in the sliding bearing of the housing cover coaxially mounted to the outlet pipe, and the open end of the glass is installed in the sliding bearing fixed in the output section of the latter. 2. The crane according to claim 1, characterized in that the shut-off element is mounted with limited rotation around the axis from a kinematically connected drive. 3. The crane according to claim 1, characterized in that the inlet sealing element is installed in the channel of the inlet pipe in the form of a conical sleeve with a circular opening at the inlet and an elliptical outlet, the cross-sectional areas of which are equal, and the output sealing element is fixed in the upper part of the housing.