RU2290548C1 - Adaptive fluid-operated bearing - Google Patents

Abstract

FIELD: mechanical engineering.

SUBSTANCE: adaptive fluid-operates bearing comprises hollow housing composed of side (1) and rod (2), which are interconnected through elastomeric members (3), and base (4). The housing receives flexible diaphragm (5) that, together with elastomeric member, defines a closed hollow chamber filled with fluid. Diaphragm (5) and base (4) define space A of variable volume filled with compressed gas. The hollow chamber receives baffle (6) that separates the hollow chamber into two chambers B and C of variable volume. Baffle (6) has throttling openings (11) for flowing fluid with valving device (14) for control of the total cross-section of the opening. Baffle (6) receives rod (2) whose end is provided with thrust (16). Base (4) is provided with valve (18). Baffle (6) has additional throttling opening (11) and is provided with rubber damper (10). The top and bottom surfaces of damper (10) have grooves with semicircular cross-section (13). Rod (2) has flange (7) provided with elastomeric member (3). Rod (2) is mounted in baffle (6) for permitting movement in central deflecting opening (12). Flange (7) and thrust (16) have openings (17) of small diameter.

EFFECT: expanded functional capabilities.

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Description

The invention relates to mechanical engineering, and in particular to means for damping vibrations of elements of various structures, in particular power units.

A support is known comprising a housing filled with working fluid, a rod placed therein with a membrane at the end having throttling holes, and a cup made spherical fixed to the rod end face and provided with a diaphragm forming a cavity filled with gas and having for the housing interaction with the inner spherical surface of the cup spherical protrusion (AS USSR No. 1732076, Ml. F 16 F 9/14, F 16 F 13/00, bull. No. 17, 1992).

The main disadvantage of this support is that due to the sticking effect between the spherical surfaces of the membrane and the diaphragm, there is a delay in the natural vibrations of the support. As a result, the working chambers do not have time to accept the initial working state, and with instant reload, their work is generally reduced to zero.

A support structure is known consisting of a rubber cylinder vulcanized to a car frame, filled with a viscous liquid and reinforced with a steel ring, to the top of which a flange is vulcanized, to which a steel box is fastened, consisting of two parts separated by a membrane, while the steel box is welded to the top of the steel box a pin for mounting the engine, and a throttle hole is made in the lower part, which communicates the cylinder cavity with a cavity under the membrane (Japanese application No. 57-84220, MKI B 60 K 5/12, F 16 F 15/00, publ. . 11/14/1980).

The operation of this support in the compression process consists of two stages: first, the rubber cylinder is compressed and fluid flows through the throttling hole into the cavity under the membrane, and then, after filling this cavity, the membrane begins to deform and the air pressure in the airtight cavity above the membrane plays the role of an additional elastic element, the energy of which (like the energy of a compressed rubber part) is released in the process of recoil. In the case of off-design shock loads, the fluid pressure in the cylinder cavity is reduced by releasing part of the fluid outside through the safety valve.

The main disadvantage of this support is that the support does not absorb radial load, and when the rubber cylinder ruptures, it completely loses its working capacity. In addition, at high shock loads, part of the fluid is released to the outside and a loss of the working medium occurs, for this reason, with prolonged use in such conditions, the support will cease to function at all.

Also known is an elastic support, selected as the closest analogue, containing two anchors, one of which is made in the form of a rod, and the other forms the side of the hollow body connected by an elastomeric element, an elastic membrane located on the side, which together with the elastomeric element forms a closed hollow a chamber filled with a viscous liquid, a partition is provided inside the hollow chamber, which divides the hollow chamber into two chambers of variable volume and is made with an opening for the passage of viscous liquid from one amers in another, while the elastic membrane and the base form a third chamber of variable volume, filled with compressed gas and receiving at least part of the mass of the suspended element, in addition, valve supports are provided in the support for adjusting the total cross section of the passage channel connecting the variable volume chambers filled with viscous liquid (application of Germany (DE) No. 3408003, MKI F 16 F 13/00, 60 K 5/12, RZ No. 39, 09/27/1984).

The disadvantages of this design is that the elastic support perceives only the axial load, and the application of the radial load leads to its destruction, in addition, this design does not provide the ability to adjust the pressure in the gas cavity.

The task was to qualitatively improve the performance of the support, expand its functionality, as well as achieve adaptation of the support to a different mass of structures protected from vibrations (vibration).

This problem is solved in that in the known hydropneumatic support containing a hollow body, consisting of a side part and a rod connected by an elastomeric element, and a base, an elastic membrane installed inside the body, forming together with the elastomeric element a closed hollow chamber filled with working fluid, and together with base - a cavity of variable volume filled with compressed gas, a partition installed inside the hollow chamber, dividing the hollow chamber into two chambers of variable volume and having an opening for passage and the working fluid with valve devices for adjusting the total cross section of the passage channel of the hole, while the rod is placed in the partition, the stop is fixed at the end, the support base is additionally equipped with a valve for connecting to the pneumatic system of the gas cavity and providing variable pressure in it, and the partition has additional holes for the passage of the working fluid and is made with a rubber buffer, the upper and lower surfaces of which have grooves of a semicircular section, while the stem is equipped with a flange on which to close An elastomeric element made of reinforced is insulated and installed in the partition with the possibility of movement in the guide hole, in addition, the flange and emphasis have holes of small diameter.

The distinguishing features of the proposed adaptive hydropneumatic support from the one closest to the one indicated above is the implementation of the support base with a valve for connecting the gas cavity to the pneumatic system, which ensures the maintenance of the necessary variable pressure in the gas cavity of the support, which is set in proportion to the mass of the object installed on the support, while compressed air is used as a load-bearing element, which allows to qualitatively improve performance, as well as to achieve adaptation pores to different weight structures protected from vibrations.

The partition with the rubber buffer and additional holes for the passage of the working fluid, as well as the execution of the rod with the flange and its installation in the partition with the possibility of movement in the guide hole allows you to smoothly limit the movement of the rod in all directions, because the baffle serves as a guide for the stem, and in conjunction with the stem – baffle, a minimum gap is guaranteed, while the rubber buffer assumes the function of a vibration damper when the diaphragm ruptures, which ultimately positively affects the performance of the support.

The execution on the upper and lower surfaces of the rubber buffer of the grooves of a semicircular cross-section, forming additional closed cavities with a working fluid, which under high pressure in the rebound modes under heavy loads in rebound modes, which flows through the holes of the flange and stop into variable volume chambers, additionally provides energy loss shock and allows for smooth movement of the rod.

In the aggregate, the listed signs make it possible to ensure the operability of the support when exposed to radial forces and to dampen shock loads.

Based on the foregoing, we can conclude that the claimed technical solution meets the criterion of "novelty."

An analysis of the known technical solutions in this technical field showed that the proposed support has features that are not in the analogues, and their use in the claimed combination of essential features allows to obtain a new technical result. Therefore, the claimed technical solution meets the condition of "inventive step".

Figure 1 presents the proposed adaptive hydropneumatic support, a General view in section.

Figure 2 - valve device of the adaptive hydropneumatic support, view G in figure 1.

The proposed adaptive hydropneumatic support comprises a hollow body consisting of a side part 1 and a rod 2 connected by a reinforced elastomeric element 3, and a base 4. An elastic membrane 5 and a partition 6 are installed inside the body.

The lateral part 1 is made with a circular groove into which the reinforced elastomeric element 3 is inserted and is pressed tightly by the partition 6 by means of bolts through the membrane 5 and the base 4. The central part of the elastomeric element 3 is attached to the rod flange 7 by pressing it against the boss 8 using the fastening elements 9.

The membrane 5 forms, together with the elastomeric element 3, a closed hollow chamber filled with a working fluid, the viscosity of which has little dependence on temperature. With base 4, membrane 5 forms a cavity A of variable volume filled with compressed gas.

The partition 6 is made with a rubber buffer 10 and divides the hollow chamber into two chambers B and C of variable volume. In the partition 6 there are throttling holes 11 for the passage of the working fluid and a central guide hole 12 in which the rod 2 is placed with a minimum clearance. The upper and lower surfaces of the buffer 10 have grooves 13 of a semicircular section. The holes 11 are closed by valve devices 14 for adjusting the passage channel of the holes. The valve devices 14 are made reverse in the form of a flat ring with protrusions 15 for blocking the alternating half of the throttling holes 11 and are installed on both sides of the partition so that the lower valve overlaps the remaining openings not blocked by the upper valve.

At the end of the rod 2 there is an emphasis 16, made in the form of a bolt, restricting the movement of the rod upward, protecting the elastomeric element 3 from breaking. The flange 7 and the rod stop 16 have openings 17 of small diameter for the passage of the working fluid from the cavities formed by the grooves 13 together with the flange 7 and the stop 16 in the extreme positions of the rod 2.

The base 4 of the support is equipped with a pressure valve 18 for connecting to the pneumatic system (not shown) of the gas cavity A and providing variable pressure therein.

The proposed adaptive hydropneumatic support works as follows.

The pneumatic support chamber A through the pressure valve 18 is filled with compressed air, which, in turn, creates pressure in the chambers B and C filled with the working fluid through the elastic membrane 5. This pressure is transmitted through the reinforced elastomeric element 3 to the boss 8 and rod 2, creating a force that balances the gravity of the shock-absorbing object, such as a power unit. During oscillations of the power unit, the force acting on the boss 8 and the rod 2 changes. In this case, a change in pressure inside the support occurs. With increasing pressure in the support, the air in the chamber A begins to compress and the liquid from the chamber B through the throttling holes 11 in the partition 6 flows into the chamber B. In this case, the rod 2 moves down. The pressure in the support rises until it balances the pressure created by the disturbing force of the power unit.

With a decrease in the force on the rod 2, the pressure in the support decreases, the compressed air in the chamber A begins to expand and the liquid, through the throttling holes 11 in the partition 6, flows from the chamber B to the chamber B. In this case, the rod 2 moves up. When the fluid flows through the throttling holes 11 and the check valve device 14, the pressure energy of the liquid is lost and transferred to thermal energy. The stop 16 protects the elastomeric element 3 from rupture during large movements of the power unit.

Under heavy loads during rebound modes, the rubber buffer 10 in the partition 6 is connected to work, the grooves 13 of which form a closed cavity with liquid on the stem flange 7, which, when the buffer 10 is deformed, flows through the holes in the base of the bolt 9 and holes 17 in the flange under high pressure. This additionally provides impact energy loss and smoothly limits the movement of the rod. The valve 18 maintains a certain pressure in the chamber A, which allows you to adjust the stiffness of the support and to adapt it to different masses and operating modes of the shock-absorbing object.

The main feature of this support is that the supporting element is compressed air. This makes it possible to use the support to damp the vibrations of objects with different masses, in addition, when the diaphragm ruptures, the support continues to function due to the rubber buffer of the partition, which also, due to the grooves filled with liquid, made in it, allows damping shock loads.

The proposed adaptive hydropneumatic support meets the condition of industrial applicability and can be manufactured on standard equipment using previously mastered technologies.

Claims (1)

An adaptive hydropneumatic support containing a hollow body, consisting of a side part and a rod connected by an elastomeric element, and a base, an elastic membrane installed inside the body, forming together with the elastomeric element a closed hollow chamber filled with working fluid, and together with the base, a cavity of variable volume, filled with compressed gas, while a partition is installed inside the hollow chamber, dividing the hollow chamber into two chambers of variable volume and having throttling holes for the passage of the working fluid bones with valve devices for adjusting the total cross section of the passage channel of the holes, while a rod is placed in the partition, at the end of which a stop is fixed, characterized in that the base of the support is additionally equipped with a valve for connecting to the pneumatic system of the gas cavity and providing variable pressure in it, and the partition has additional throttling holes for the passage of the working fluid and is made with a rubber buffer, the upper and lower surfaces of which have grooves of a semicircular section, while the stem is equipped with a flange on which an elastomeric element, reinforced, is fixed and installed in the partition with the possibility of movement in the central guide hole, in addition, the flange and the stop have holes of small diameter.

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