RU2183278C1 - Exhaust gas system pipeline flexible connector - Google Patents

Abstract

FIELD: mechanical engineering. SUBSTANCE: invention can be used for thermal compensations and compensation of vibrations transmitted from internal combustion engine to exhaust gas system, for reduction of loads and damping of internal and external noise. Proposed device has bellows, bellows travel limiter and damping members. Travel limiter is made of strips or wires. Bellows consist of narrow corrugations and at least one wide corrugation. Ratio of radius R of convex surface of wide corrugation to radius r of convex surface of narrow corrugation is chosen from 1.5 to 2.5. Ratio of radius R₁ of concave surface between wide corrugation and narrow corrugation to radius r₁ of concave surface between narrow corrugations is chosen from 1.0 to 2.2. Damping members for both opposite sides of bellows are arranged at both of support rings. EFFECT: increased service life and reduced operating noise. 8 cl, 3 dwg

Description

 The invention relates to mechanical engineering and can be used for thermal compensation and compensation of vibrations transmitted from an internal combustion engine to an exhaust system, reducing loads, as well as internal and external noise.

 Currently, various designs of expansion joints are used, containing a bellows and a screen located in it, which are used in various fields of mechanical engineering for mechanisms and pipelines with a gas or liquid medium.

 A known compensator for the exhaust system, containing a bellows made with various corrugations, a cylindrical screen, which is installed along the gases coaxially inside the bellows with a gap (1).

 In this compensator, the corrugations in the middle part of the bellows are made of a larger diameter than the extreme ones, but with the same width, which allows to slightly reduce the load on the extreme corrugations under axial action.

 The advantages of such a compensator are the simplicity of design. Its limitations are: such a compensator does not take into account the frequency of the oscillatory processes of the exhaust gas stream and does not sufficiently compensate for the thermal cyclic loads of the gas stream; such a device does not allow to reduce the resonant vibrations of the bellows and to effectively absorb the radial loads from the vibrations transmitted by the engine; the design has poor noise characteristics.

 A device for flexible connection of the pipeline of the exhaust system, containing a bellows, the walls of which are made in the form of rings, and the rings are interconnected by convex surfaces and concave surfaces, respectively, and at least two elastic plates mounted outside the bellows (2) .

 The bellows in this technical solution is made of two corrugated parts connected by a segment of the pipeline (platform), which gives additional rigidity to the device. The presence of a cylindrical screen inside the bellows is not described in this technical solution. The advantages of this design over similar ones are the connection of the bellows body with the external environment, which allows efficiently dissipating thermal energy, as well as damping radial vibrations.

 Limitations are: unilateral action of the bellows, as under axial loads, it can only work on compression, and the bellows travel is limited; the segment of the pipeline between the two corrugated parts increases the rigidity of the structure, which worsens the load perception during radial vibrations and leads to uneven loading of the bellows corrugations during axial and radial cyclic vibrations; due to the rigidity of the fastening of the elastic plates to the flanges on both sides of the bellows, the device practically does not absorb tangential loads, and when the input and output pipes of the bellows rotate, the elastic plates break and the life of the device as a whole is reduced.

 The closest is a device for flexible connection of the pipeline of the exhaust system, containing a bellows, the walls of which are made in the form of rings, while the rings are interconnected by convex surfaces and concave surfaces, respectively, of the bellows stopper mounted above the outer surface of the bellows and made with support rings damping elements located along the longitudinal axis on both sides of the bellows and elastically connected with the support rings of the bellows limiter (3).

 In addition, the device contains a wire braid connecting the ends of the bellows, and the damping elements are made in the form of pillows from a pressed thin metal wire.

 The limitations of the device are: the use of a wire braid leads to the fact that the bellows is not connected to the external environment and, under the influence of high-temperature gases, prematurely fails, which leads to insufficiently high reliability and service life due to significant thermal load on it also due to lack of an internal screen; the wire braid limits vibration compensation and functions one-sidedly - it works only on compression, and the bellows - on tension and compression; the use of damping pads made of pressed metal wire sharply reduces the bellows stroke in the axial direction, which does not allow to sufficiently use the characteristics of the bellows as the main unit of vibration compensation; the use of damped pillows made of pressed metal wire leads to their gradual shrinkage during operation, which reduces the reliability of the design and the operating time; the design is metal-intensive and provides only one-sided perception of the applied load due to the location of the damping elements only on the outer opposite sides of the support rings, which leads to structural rigidity and poor damping; a bellows with the same corrugations has an unequal stroke for each corrugation and usually the third corrugation along the gas paths is prematurely destroyed, which leads to a decrease in the life of the device; due to the use of a metal braid, the bellows travel is limited by its linear dimensions, which does not allow to fully use the useful parameters of the bellows as the main vibration compensation unit.

 The problem solved by the invention is improving the quality and reliability of the device, improving the technical and operational characteristics during its operation under conditions of axial, radial and tangential instability and periodic exposure to exhaust gases.

 The technical result that can be obtained by performing the device is an increase in durability and a decrease in noise characteristics by providing compensation for various thermocyclic loads of a gas stream, an increase in durability, and a reduction in size.

To solve the problem with achieving a technical result in the device for flexible connection of the pipeline of the exhaust system containing the bellows, the walls of which are made in the form of rings, while the rings are interconnected by convex surfaces and concave surfaces, respectively, the bellows stopper mounted above the outer surface bellows and made with support rings, a damping element located along the longitudinal axis on both sides of the bellows and elastically connected with the support the bellows stop rings, according to the invention, the bellows stop is made in the form of plates or wires, the bellows is made of narrow corrugations and at least one wide corrugation, the convex surfaces and concave surfaces of the bellows are made in its longitudinal section in the form of semicircles, the ratio of the radius R of the convex surface wide corrugation radius r to the convex surface of the male corrugation is selected in the range of from 1.5 to 2.5, the ratio of the radius r ₁ of the concave surface between the wide and narrow corrugation to corrugation radius r ₁ of the concave poverhnos and between narrow corrugations - in the range from 1.0 to 2.2, wherein the damping elements to both opposite sides of the bellows are arranged on both sides of the support rings.

Additional embodiments of the device are possible, in which it is advisable that:
- a cylindrical screen was made inside the bellows, which is installed along the gases coaxially inside the bellows with a gap, and on the gas inlet side, the end of the cylindrical screen was connected to the inlet of the bellows;
- damping elements were made in the form of spring washers;
- spring washers were made dish-shaped;
- spring washers were made in the form of plates equipped with slots around the circumference of the circle with the formation of petals, which are alternately bent relative to each other in the opposite direction;
- spring washers were made in their longitudinal section C-shaped;
- the device was equipped with bushings with a longitudinal groove and rigid washers mounted on both sides on the bellows nozzles, respectively, and the support rings were placed in the longitudinal grooves between the bushings and the rigid washers;
- the bellows stop plates were made in the form of a tape perforated with longitudinal slots.

These advantages, as well as features of the present invention are illustrated by the best option for its implementation with reference to the accompanying drawings:
figure 1 schematically depicts the main embodiment of the claimed device, a quarter cross-section of the structure along the longitudinal axis;
figure 2 - the possible design of spring washers, their own longitudinal sections;
figure 3 - appearance of a spring washer with petals.

 The device (figure 1) contains a bellows 1, the walls of which are made in the form of rings. The rings are interconnected by convex surfaces 2 and concave surfaces 3, respectively. The bellows displacement limiter 4 is mounted above its outer surface and is made with support rings 5. The damping elements 6 are located along the longitudinal axis on both sides of the bellows 1 and are elastically connected with the support rings 5.

The limiter 4 of the bellows 1 is made in the form of plates or wires. The bellows 1 is made of narrow corrugations 7 and at least one wide corrugation 8. Convex surfaces 2 and concave surfaces 3 of the bellows 1 are made in its longitudinal section in the form of semicircles. The ratio of the radius R of the convex surface 2 of the wide corrugation 8 to the radius r of the convex surface 2 of the narrow corrugation 7 is selected in the range from 1.5 to 2.5. The ratio of the radius R _{1 of the} concave surface 3 between the wide corrugation 8 and the narrow corrugation 7 to the radius r _{1 of the} concave surface 3 between the narrow corrugations 3 is selected in the range from 1.0 to 2.2. The damping elements 6 for both opposite sides of the bellows 1 are located on both sides of the support rings 5.

 To ensure thermal compensation inside the bellows 1, a cylindrical screen 9 can be made. The cylindrical screen 9 is installed along the gases coaxially inside the bellows 1 with a gap, and on the gas inlet side, the end face of the cylindrical screen 9 is connected to the inlet pipe 10 of the bellows 1.

 The damping elements 6 are made in the form of spring washers. Possible, but not exhaustive designs of spring washers are shown in figure 2, 3.

 Spring washers can be made dish-shaped. In addition, the spring washers (Fig. 3) can be made in the form of plates equipped with slots around the circumference of the circle to form petals 11, which are alternately bent relative to each other in the opposite direction. Spring washers can be made in its longitudinal section C-shaped (figure 2).

 The device for ensuring the tightening of the support rings 5 may be provided with bushings 12 (Fig. 1) with a longitudinal groove and rigid washers 13. The bushings 12 and the rigid washers 13 are fixed on both sides to the inlet pipe 10 and the outlet pipe 14 of the bellows 1. respectively. The support rings 5 are placed in the longitudinal grooves between the bushings 12 and the rigid washers 13.

 In addition, to simplify the manufacture of the plate stopper 4 of the bellows 1 can be made in the form of a tape 15 (the lower part of figure 1). The tape 15 is perforated with longitudinal slots 16. The ends of the tape 15 are connected, for example, by welding with support rings 5.

 The device operates (figure 1) as follows.

 Introduction to the design of a wide corrugation 8 with the indicated dimensions allows to increase the technical and operational performance when the bellows 1 is operating under conditions of axial instability and in the presence of internal pressure.

 As tests have shown, the geometry of narrow corrugations 7 and wide corrugations 8 has changed the nature of the load on narrow corrugations 7 and in general bellows 1, regardless of the length and diameter of the bellows 1, as well as the location of the wide corrugations 8. The stability of the bellows 1, loaded with internal pressure and increased axial force. Narrow corrugations 7 (Fig. 1) began to work with a symmetrical load distribution and with the same stroke regardless of other geometrical dimensions of the corrugations, their number and location symmetry. The implementation of the convex surfaces 2 and concave surfaces 3 of the narrow corrugations 7 and wide corrugations 8 in the longitudinal section of the bellows 1 in the form of semicircles can reduce the stress concentration at the vertices of the said corrugations.

 The tests were carried out at overpressure and forced operation on a mechanical bench. The geometry of the wide corrugation 8 (Fig. 1) differs from the narrow corrugations 7, it changed the stiffness and sensitivity of the bellows 1. But most importantly, it changed the nature of the load distribution on all narrow corrugations 7 and the wide corrugation 8, increased the stability of the bellows 1. Narrow corrugations 7 left and right began to work with a symmetrical load distribution and the same stroke. With various combinations of pressure and axial force (or a given stroke), the stress cycle is distributed evenly across all corrugations 7, 8, reducing critical stresses at individual points and increasing the operating time of bellows 1 to failure. Bellows 1 acquires improved performance and becomes more durable.

 The exhaust gases and vibrations from the engine, entering the inlet pipe 10, act on the cylindrical screen 9, which is a thermal cyclic reflector. The bellows 1 is movably connected through the damping elements 6 and the support rings 5 to the stop 4. Vibrations through the stop 4 are transmitted to a similar assembly located on the outlet pipe 14. The support rings 5 of the stop 4 are pressed on both sides, which allows the bellows to freely extend and expand along the longitudinal axis due to the uniform movement of narrow corrugations 7 and wide corrugation 8. With tangential overloads, the support ring 5, located on one side of the bellows 1, rotates freely relative to the other support ring 5 With a radial displacement of the inlet pipe 10 relative to the outlet pipe 14, the support rings 5 move together with the narrow corrugations 7 and the wide corrugation 8 of the bellows 1, and the support rings 5 remain pressed on both sides by damping elements 6, which does not cause distortions of the support rings 5, such , as when using damping elements located only on one side of the support ring 5.

 At the same time, during operation of the device, there is no restriction of the stroke of the bellows 1 due to the use of a wire braid, since the damping elements 6 are located on both sides of the support rings 5. The implementation of the limiter 4 in the form of plates or wires allows the bellows 1 to be connected to the external medium, which allows you to effectively dissipate heat from its outer surface. This increases the reliability and life of the device as a whole, while the bellows 1 operates depending on thermocyclic loads, both in compression and in tension.

 The use of spring washers as damping elements 6 increases the stroke of the bellows 1 in different directions, while the spring properties of such washers are preserved longer than when using damping pads made of pressed metal wire. The location of the damping elements 6 on both sides of the support rings provides a peculiar softness of the structure as a whole and improves the damping of vibration components of different frequencies.

 The most successfully claimed device for flexible connection of the pipeline of the exhaust system is industrially applicable for thermal compensation and vibration compensation transmitted from the internal combustion engine to the exhaust system, and can be used for various types of engines and exhaust systems.

Sources of information
1. German patent 893734, F 16 L 51/02, publ. 1949

 2. British patent 1450555, F 16 L 51/00, publ. 1976

 3. Patent of the Russian Federation 2133399, F 16 L 27/10, publ. 1999 year

Claims (8)

1. A device for flexible connection of the pipeline of the exhaust system, containing a bellows, the walls of which are made in the form of rings, while the rings are interconnected by convex surfaces and concave surfaces, respectively, the bellows stopper mounted above the outer surface of the bellows and made with support rings, damping elements located along the longitudinal axis on both sides of the bellows and elastically connected with the support rings of the bellows stopper, characterized in that the stopper si The phone is made in the form of plates or wires, the bellows is made of narrow corrugations and at least one wide corrugation, the convex surfaces and concave surfaces of the bellows are made in its longitudinal section in the form of semicircles, the ratio of the radius R of the convex surface of the wide corrugation to the radius r of the convex surface the narrow corrugation is selected in the range from 1.5 to 2.5, the ratio of the radius R _{1 of the} concave surface between the wide corrugation and the narrow corrugation to the radius r _{1 of the} concave surface between the narrow corrugations is in the range from 1.0 to 2.2, while e The components for both opposite sides of the bellows are located on both sides of the support rings.  2. The device according to claim 1, characterized in that a cylindrical screen is made inside the bellows, which is installed along the gases coaxially inside the bellows with a gap, and from the gas inlet side, the end of the cylindrical screen is connected to the inlet of the bellows.  3. The device according to p. 1, characterized in that the damping elements are made in the form of spring washers.  4. The device according to p. 3, characterized in that the spring washers are made disk-shaped.  5. The device according to p. 3, characterized in that the spring washers are made in the form of plates equipped with slots around the circumference of the circle to form petals, which are alternately bent relative to each other in the opposite direction.  6. The device according to p. 3, characterized in that the spring washers are made in their longitudinal section C-shaped.  7. The device according to p. 1, characterized in that it is equipped with bushings with a longitudinal groove and rigid washers mounted on both sides on the bellows nozzles, respectively, and the support rings are located in the longitudinal grooves between the bushings and the rigid washers.  8. The device according to p. 1, characterized in that the plates of the bellows stopper are made in the form of a tape perforated by longitudinal slots.

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