RU79637U1 - COMPENSATING DEVICE FOR DUST AND GAS AIR PIPES - Google Patents

Abstract

The utility model is aimed at creating the design of a compensating device that provides the ability to compensate for spatial thermal displacements (deformations) of dust and gas ducts of large diameters when supplying hot air, as well as an air environment containing abrasive particles. The specified technical result is achieved in that the compensating device for dust and gas ducts, containing two pipes connected by a telescopic connection, each of which is equipped with a spherical connection, while sealing units are installed in the telescopic and ball joints. Ball and telescopic connections are equipped with a compression mechanism of the rings of the sealing units in the axial direction. The compensating device is equipped with inlet and outlet nozzles, an additional compression mechanism is installed on the ball joints, and the compression mechanisms are made in the form of hinged bolts with nuts located in the eyes, evenly fixed to the outer surface of the telescopic and ball joints. In addition, on the inner surface of the compensating device deposited a layer of surfacing material resistant to abrasion. 4 C.p.F., 9 ill.

Description

The utility model relates to the field of power engineering, and in particular to devices that provide a tight, movable connection of dust and gas ducts in hot air supply systems with temperatures up to + 400 ° С and transportation of aerated dust-air mixture containing abrasive particles.

The closest technical solution to the proposed utility model is a compensating device for pipelines (PM No. 46554, IPC F16L 51/00). This compensating device contains two pipes connected together by a telescopic connection, each of which has a ball connection at the end. Sealing units are installed in the housings of the telescopic and ball joints, each of which is made in the form of at least two metal rings, between which at least one ring is made of thermally expanded graphite, and the ball and telescopic joints are equipped with a compression mechanism of the rings of the sealing units in the axial direction, made in the form of a union nut screwed onto the housing of each of the joints.

Ball joints provide angular movement, and telescopic - longitudinal-axial. In total, the compensating device provides a movable connection of pipeline sections within specified limits.

The disadvantage of this design is that the use of the axial compression mechanism of the rings of the sealing assemblies made in the form of a union nut screwed onto the housing of each of the joints is not possible on large diameter pipelines, and the design of this compensating device does not allow medium to pass through content of abrasive particles.

The technical task of this utility model is to create a design of a compensating device that provides the ability to compensate for spatial thermal displacements (deformations) of dust and gas ducts of large diameters when supplying hot air, and

also the air environment containing abrasive particles, and at the same time quite simple to manufacture, assemble and operate.

The problem is solved in that the compensating device for dust and gas ducts, containing two pipes connected by a telescopic connection, each of which is equipped with a ball connection, while the telescopic and ball joints have sealing assemblies made in the form of at least two metal rings, between which at least one ring of elastic sealing material is installed, and the ball and telescopic connections are provided with a compression mechanism for the rings axial direction of assemblies, equipped with inlet and outlet nozzles, an additional compression mechanism is installed on the ball joints, while the compression mechanisms are made in the form of hinged bolts with nuts located in the eyes, evenly fixed to the outer surface of the telescopic and ball joints.

In addition, on the inner surface of the compensating device deposited a layer of surfacing material resistant to abrasion.

In addition, the spherical connection is made in the form of a housing with a sealing assembly and an inner spherical surface, articulated with a ring having the shape of a spherical segment with an annular liner located at one end of its outer surface, while the hinged bolts with nuts are located in the eyes evenly fixed to the housing and ring liner.

In addition, the eyes of the hinged bolts of the compression mechanisms of the telescopic connection are fixed to the metal rings of the latter.

In addition, the inlet and outlet nozzles are provided with flanges.

The tracing of the gas ducts of the boiler often has a spatial position with many bends. In the working cycle, equipment and dust-gas-air ducts move axially, in the lateral direction, angular movements also take place. Compensation of these displacements is solved using the proposed compensating device, and when compensating for angular displacements, ball joints are used, and when compensating for longitudinal displacements, a displacement along the cylindrical surfaces of the telescopic joint occurs.

When compensating lateral movements, ball joints are involved and at the same time, displacement occurs along the cylindrical surfaces of the telescopic joint.

Schematic diagram of the compensating device and its options are presented in the attached drawings, where:

figure 1 shows a General view of a compensating device;

figure 2 - a view of figure 1;

figure 3 is a view of B in figure 1;

figure 4 is a section bb in figure 1;

figure 5 shows the ball connection;

6 shows an embodiment of a compensating device for a medium with abrasive particles;

7 shows an embodiment of a compensating device with flange connection;

on Fig - remote element I in Fig.7;

figure 9 is the same use cases of fasteners.

Compensating device for dust and gas ducts consists of a left ball joint 1, a right ball joint 2, a telescopic joint 3, a sealing assembly 4 of a ball joint, a sealing assembly 5 of a telescopic joint, connecting inlet pipe 6 and outlet pipe 7.

Ball joints 1 and 2 consist of a cylindrical conical body 8 with an inner spherical surface, articulated with a ring 9 having the shape of a spherical segment, and located on the free end of its outer surface of the annular liner 10. A ring 11 of elastic sealing material is placed in the annular groove of the housing 8, which is clamped by a metal ring 12.

Ball joints 1, 2 and ball joint sealing unit 4 are clamped by compression mechanisms 13, made in the form of hinged bolts 14 with nuts 15, pivotally mounted in the eyes 16 and evenly mounted on the outer cylindrical surface of the housing 8, and the clamping force of the compression mechanism 13 is provided by force contact of the nuts 15 with the end surfaces of the eyes 17, evenly mounted on the annular liner 10.

The telescopic connection 3 contains telescopically connected pipes 18 and 19, metal rings 20 and 21, a ring 22 made of elastic sealing material between them. To ensure the compression of the sealing unit 5 of the telescopic connection during assembly, a compression mechanism 13 is used, made in the form of hinged bolts 14 with nuts 15, pivotally mounted in the eyes 16 and evenly mounted on the outer cylindrical surface of the metal ring 20, and the clamping force of the compression mechanism 13 is provided by force contact of the nuts 15 with the end surfaces of the eyes 17, evenly mounted on the outer cylindrical surface of the metal ring 21.

An embodiment of a compensating device for a medium with abrasive particles further comprises a layer 23 of surfacing of a material (from 3 to 4 mm) that is resistant to abrasion, deposited on the inner surfaces of the compensating device. In this case, surfacing is carried out by manual arc welding, type of electrode is E-80X4C GOST 10051-75 (grade-13KN / LIVT). It is allowed to use other types of electrodes used for surfacing parts operating under abrasive conditions.

The installation of the compensating device is as follows:

In a specific place of the dusty gas and air duct (hereinafter - PGVP) at the design stage, according to the calculations for strength and stiffness, the section of PGVP is determined where the installation of a compensating device is necessary.

The spherical segment 9 is welded to the pipe 18 of the telescopic assembly 3 and then inserted into the housing 8, which is mounted on the inlet pipe 6. The spherical segment 9 is held together with the telescopic assembly by an annular liner 10 by means of a compression mechanism 13, which can freely move around the ball the trajectory of segment 9. The compression mechanism 13 also serves to regulate the gap between the inner spherical surface of the housing 8 and the spherical segment 9, which occurs during thermal expansion. The compression mechanism 13 is welded to the housing 8 and the annular liner 10 evenly around the entire circumference (in this case, in the amount of 8 pieces) and have the ability to release the ring of pos. 11 from the housing of pos. 8 making the ball assembly completely collapsible and, accordingly, repair fit.

Similarly mount the right ball joint 2, while the cylinder-conical body 8 is welded to the pipe 19 of the telescopic assembly 3, and the ball segment 9, respectively, to the outlet pipe 7.

Butt joint option: after preliminary processing the edges of the two ends of the connected ПГВП for welding, the compensating device is installed and fixed by butt welding, in compliance with the requirements of current technical documentation, as a rule, by manual arc welding according to GOST 9467-75.

Flange connection option: by welding the flanges 24 on the inlet 6 and outlet 7 pipes, the compensating device is connected to the PGWP using fasteners 25 or 26 (for example, bolts or couplers with washers and nuts) and gasket material. The fasteners are tightened crosswise, providing a tight connection of parts, excluding warping and warping of the cushioning material, with a tightening force defined for each type of fastener.

The compensating device for dust-gas-air ducts works as follows: when feeding an aerated dust-gas-air mixture containing abrasive particles, which always has a high temperature and is supplied under pressure, pre-clamped ball joint sealing unit 4 and telescopic joint sealing unit 5 ensure tight joints. With a further increase in temperature and heating of the structure due to the difference in the linear expansion coefficients of the components of the ball joints 1, 2 and the telescopic joint 3, additional compression of the sealing metal rings 12 and 20 will occur, which will ensure a high degree of tightness of the movable joints under operating conditions.

The abrasion-resistant surfacing layer 23 protects the internal surfaces of the compensating device from premature wear, which increases the service life of the compensating devices.

When you turn off the supply of dust and gas mixture, the compression ratio of the sealing rings will fall, which also increases the life of the compensating devices. In the event of a forced movement of one of the connected pipelines, the ball and telescopic joints will move and provide a tight, movable joint of the pipelines,

transporting dust and gas mixture. In this case, when compensating for angular displacements, spherical joints are involved, when compensating for longitudinal displacements, displacement occurs along the cylindrical surfaces of the telescopic joint, and when compensating for transverse displacements, spherical joints are involved and simultaneously displacement along the cylindrical surfaces of the telescopic joint.

During operation, loosening the nuts 15 and folding the hinged bolts 14, you can easily disassemble the compensating device and, if necessary, replace the sealing units 4, 5 and the ring inserts 10.

Thus, the use of the proposed utility model will compensate for the entire range of possible movements of the ends of the dust and gas duct relative to each other.

The compensating device for dust and gas ducts is reliable in operation, its design is simple, manufacturable and repairable.

Claims (5)

1. Compensating device for dust and gas ducts, containing two pipes connected to each other by a telescopic connection, each of which is equipped with a ball connection, while in the telescopic and ball joints there are sealing units made in the form of at least two metal rings, between which it is installed, at least one ring of elastic sealing material, and the ball and telescopic connections are equipped with a compression mechanism of the rings of the sealing nodes in the axial direction ii, characterized in that it is provided with inlet and outlet pipes, on ball joints an additional compression mechanism, the compression mechanism is configured as a hinged bolts and nuts disposed in the eyes, uniformly attached on the outer surface of the ball joints and telescoping. 2. The device according to claim 1, characterized in that on the inner surface of the compensating device is applied a layer of surfacing of a material resistant to abrasion. 3. The device according to claim 1, characterized in that the ball connection is made in the form of a housing with a sealing assembly and an inner spherical surface, articulated with a ring having the shape of a ball segment with an annular liner located at one end of its outer surface, with hinged bolts with nuts are located in the eyes, evenly mounted on the body and the annular liner. 4. The device according to claim 1, characterized in that the eyes of the hinged bolts of the compression mechanisms of the telescopic connection are mounted on the metal rings of the latter. 5. The device according to claim 1, characterized in that the inlet and outlet nozzles are provided with flanges.