RU49946U1 - COMPENSATOR - Google Patents

Abstract

The utility model relates to mechanical engineering, in particular to pipeline technology, and can be used as a compensatory connection of pipelines for various purposes. The utility model allows to increase the compensating ability of the device in the transverse and angular directions while maintaining its reliability and durability. The compensator contains an elastic pipe 1 of length "L ₁ " with sealing flanges 2 and 3. Outside of the elastic pipe 1, restriction bushings 4 and 5 of length "L ₁ " and "L ₂ " are installed, respectively, forming a radial compensation clearance with the outer surface of the elastic pipe " ΔR ". Opposite end edges 6 and 7 of the restriction bushings 4 and 5 are rounded outward along the radius "r". The restriction sleeves 4 and 5 are also equipped with connecting flanges 8 and 9, pressing sealing flanges 2 and 3 of the elastic pipe 1 to the connecting flanges 10 and 11 of the connected pipelines 12 and 13. The density of the flange connections is provided by the fasteners 14. The length L _{1 of the} elastic pipe 1 exceeds the total length (L ₂ + L ₃ ) of the outer limiting bushings 4 and 5 by the value of the axial compensation clearance "ΔL" formed between the opposite edges 6 and 7 of the limiting bushings 4 and 5. Located in the region of the axial compensation of the clearance “ΔL” and the area of the elastic pipe 1 free of support on the external restriction bushings 4 and 5 is tightened with the help of a reinforcing inclusion 15.

The compensator has high longitudinal flexibility, good lateral elasticity, as well as longitudinal, lateral and angular stability. Effectively absorbs relative displacements of connected pipelines in any direction without compromising the integrity of the device. It has a large resource while maintaining high reliability. 2 ill.

Description

The utility model relates to mechanical engineering, in particular to pipeline technology, and can be used as a compensatory connection of pipelines for various purposes.

Known pipeline compensator, protected by patent GB838560, IPC F16L 51/02, publication date - 06/22/1960. The analog compensator contains an elastic non-metallic pipe with a compensating fold and sealing flanges clamped in the connecting flanges. The cylindrical sections of an elastic non-metallic pipe are reinforced with outer bushings and rings of bar material.

The disadvantage of the analogue is the low compensating ability of the device in the transverse direction due to the lack of a compensation gap between the elastic non-metallic pipe and the external reinforcing elements. This circumstance limits the use of an analog device in the pressure range of the working medium transported through the pipeline.

The prototype of the claimed device is a compensator for axial strain of pipelines, protected by patent RU2083907, IPC ⁶ F16L 51/02, publication date - 07/10/1997. The compensator prototype includes an elastic non-metallic pipe with sealing flanges and external restrictive bushings mounted telescopically in relation to each other. External restriction bushings form radial clearances with an elastic non-metallic pipe. On that part of the length of the elastic non-metallic pipe, which is located inside the outer restriction sleeve of a larger diameter and has a space for expansion expansion, a reinforcing spring is included in the pipe body, which determines the pipe deformation waves. Each sealing flange of an elastic non-metallic pipe is sandwiched between the connecting flange of the pipeline and the connecting flange of the outer limit sleeve.

The disadvantage of the prototype is that the telescopic arrangement of the outer restrictive bushings reduces the compensating ability of the device in the transverse and angular directions.

The inventive utility model allows to increase the compensating ability of the device in the transverse and angular directions while maintaining its reliability and durability.

The claimed technical result is achieved in the compensator, including an elastic pipe with reinforcing inclusion and sealing flanges, as well as

restrictive bushings. The restriction bushings are mounted outside the elastic pipe with a radial clearance. The length of the elastic pipe exceeds the total length of the external restriction bushings, and the reinforcing inclusion is placed on a portion of the length of the elastic pipe, free from support on the external restriction bushings.

The essence of the utility model is illustrated by the drawing, in Fig. 1 of which the inventive compensator is schematically depicted in an unloaded state, and in Fig. 2 is an inventive compensator in a loaded state.

The compensator contains an elastic pipe 1 of length “L ₁ ” with sealing flanges 2 and 3. Outside of the elastic pipe 1, restrictive bushings 4 and 5 of length “1-2” and “La” are installed, respectively, forming a radial compensation clearance with the outer surface of the elastic pipe “ ΔR ". Opposite end edges 6 and 7 of the restrictive bushings 4 and 5 are rounded outward along the radius "g". The restriction sleeves 4 and 5 are also equipped with connecting flanges 8 and 9, pressing the sealing flanges 2 and 3 of the elastic pipe 1 to the connecting flanges 10 and 11 of the connected pipelines 12 and 13. The density of the flange connections is provided by the fasteners 14. The length L _{1 of the} elastic pipe 1 exceeds the total length (L. ₂ + L ₃₎ of the external restrictive sleeves 4 and 5 on the amount of axial compensating «ΔL» gap formed between the opposed edges 6 and 7ogranichitelnyh sleeves 4 and 5. Located in axial cOMPENSATION insulating «ΔL» clearance and free from the support to the outer sleeve 4 restrictive and the elastic portion 5 of the tube 1 via the reinforcing tightened inclusion 15.

The inventive compensator operates as follows.

When installing the compensator on the connected pipelines 12 and 13, unreinforced sections of the elastic pipe 1 due to their radial deformation within the radial compensation clearance "ΔR" and axial deformation within the axial compensation clearance "ΔL" absorb the relative axial, transverse and angular displacements of the connected pipelines, and also various deviations of the geometric dimensions and shapes of the connected pipelines from the nominal ones. The restrictive bushings 4 and 5 perform the functions of guides and protective shells. During operation of the expansion joint, the bushings come together without touching the end edges 6 and 7. The dimensions of the compensation gaps ΔR and ΔL determine the maximum allowable values of these deviations and relative displacements of the pipelines. The elastic pipe section 1, tightened by the reinforcing inclusion 15, retains almost the initial shape during operation of the compensator, does not bulge into the axial compensation gap ΔL, and does not undergo additional wear.

The presence of radial and axial compensation clearances "ΔR" and "ΔL" provides high longitudinal flexibility and good lateral elasticity of the claimed

compensator. In this case, the reinforcement of the elastic pipe 1 by the external limiting bushings 4 and 5, together with the tightening of the section of the elastic pipe 1 free from support on the bushings 4 and 5 by the fittings 15, provides good longitudinal, transverse and angular stability of the compensator.

Thus, the structural differences of the inventive compensator can effectively absorb significant relative displacements of the connected pipelines in any direction without compromising the integrity of the device. The inventive compensator has a large resource while maintaining high reliability.

Claims (1)

Compensator, including an elastic pipe with reinforcing inclusion and sealing flanges, restrictive bushings installed outside the elastic pipe with a radial clearance, characterized in that the length of the elastic pipe exceeds the total length of the external restrictive bushings, while the reinforcing inclusion is placed on a part of the length of the elastic pipe free from reliance on external restriction bushings.