RU67674U1 - WORKING ELASTIC ELEMENT FOR HYDRAULIC SHOCK COMPENSATOR - Google Patents

Abstract

Usage: in various devices, and more precisely, in shock absorbers designed to protect hydraulic and pneumatic systems, in particular, their components and elements, in particular fuel meters, from water hammer and pressure fluctuations of a moving working medium when it is pumped by pumps, including fuel, in the fuel systems of engines for any purpose. Essence: the working elastic element of the shock absorber is made in the form of a liner of elastic material. The liner has the shape of a ball, and as an elastic material, oil and petrol resistant or other rubber or plastic is used. The dimensions, rigidity, resilience and elasticity of the ball are selected depending on the operational characteristics (pressure and dimensions) of the hydra or pneumatic system, which use a shock absorber of any shape and size. Technical advantages: increase in the term of operation (practically unlimited) until the natural wear of elastic elements; improving manufacturability and simplifying the design; insensitivity to the direction of movement of the working fluid; reliability of quenching of water hammer; the ability to regulate performance; universality. 1 independent.

Description

The utility model relates to means of pneumohydraulic technology and can be used in various devices, and more specifically, in shock absorbers designed to protect hydraulic and pneumatic systems, in particular, their components and elements, in particular fuel meters, from water hammer and vibrations pressure of a moving working medium when it is pumped by pumps, including fuel, in the fuel systems of engines for any purpose.

A device for damping hydraulic shocks is known, comprising a flow-through housing installed inside the protected pipeline, as well as a nozzle coaxially placed in the housing and a diffuser and a confuser connected in series. The device contains an external (outside the pipeline) auxiliary capacity connected to the said housing through a tube. A nozzle is installed near the diffuser containing a control mechanism in the form of a rotary element with an aerodynamic profile directed along the flow and equipped with two stops. This device is used in trunk pipelines. In the established mode of water withdrawal, the housing through an additional tube constantly takes a certain amount of water from the auxiliary tank. When the pumping unit is stopped, the water pressure wave formed meets with an additional tube, and part of the water returns to the auxiliary tank, where the said wave loses most of its energy [see Russian patent No. 2111405 for class F16L 55/04 published on 05/20/1998].

The main disadvantage of this device is the complexity and irrationality of its design, due to the absence in its composition of working elastic elements. It is this circumstance that makes it necessary to place one part of the device in the pipeline itself, and the second from the outside. For this reason, the operation of such a device makes it necessary to constantly feed the auxiliary tank with water, and this, in turn, requires the supply of the device itself with an additional water supply system. When mounting the device on the pipeline, there is a need to violate its integrity for placement inside the device. All this creates certain inconveniences and leads to increased costs for installation and operation of the known device for absorbing water hammer.

This disadvantage is eliminated in the device for absorbing water hammer, comprising a housing, and a normally open valve placed in it, made in the form of rotary non-perforated dampers connected to each other by means of elastic coupling and damping elements, and installed in the housing: one in front of the valve and the other - after the valve, while the damping or working elements of the device are made in the form of a fixed shaped core with annular grooves and a supporting element, thrust elements in the form of a set of ribs rigidity and rotary profiled and perforated petals pivotally connected to the core. The hinges are placed in the grooves, and the petals are interconnected by an elastic element. In this case, the petals of the damping elements installed before and after the valve can have different perforations, and the angle of inclination of the petals of the damping devices in the initial position can be less than or equal to the angle of inclination of the dampers in their initial position. When a water hammer occurs, an increased pressure wave at its front opens the petals of the damping element installed in front of the valve, overcoming the resistance of the elastic element. Opened perforated lobes dampen peak pressure loads of the disturbed medium. Further, the increased pressure wave closes the rotary damper of the valve, and the increased pressure in the cut-off area in front of the valve continues to be extinguished by the perforated petals, and fixing the petals in the open position intensifies the process of energy dissipation and expenditure of the flow energy to fold the petals and reset them. At the same time, in the zone behind the valve, the fluid moves by inertia, while due to the slipped part of the flow energy, the perforated lobes of the damping element installed behind the valve open, which leads to further dispersion of the flow energy to an acceptable level [see Russian patent No. 2031300 for class F16L 55/04 published on March 20, 1995].

The main disadvantage of this device for damping water hammer is the excessive complexity of the design of its working bodies, or rather those of its nodes that directly provide damping of water hammer and high-pressure waves of the working medium. This is due to the presence of a large range of miniature parts in their design. At the same time, despite the complexity of the working bodies of this hydraulic shock compensator, they nevertheless have a high inertia, due to which an unbalanced part of the energy of the working medium flows through a normally open valve, which is unacceptable for some devices installed

in the hydraulic system, in particular for fuel meters used in fuel systems of engines operating on liquid fuel.

The closest in essence and the achieved effect, taken as a prototype, is a working elastic element of the shock absorber made in the form of a cylindrical tube made of elastic material (membrane) and envelopes of elastic material covering it, made in the form of rings with recesses distributed over their surface in the form of annular, or radial, or spiral grooves or recesses of arbitrary shape and / or in their volume by cavities in the form of longitudinal or radial grooves, and also the liners are divided rings of smaller diameter forming annular grooves. The working elastic element of the described construction is installed inside the cylindrical body of the shock absorber and is worn with it on the perforated section of the pipeline. With a sharp increase in the pressure of the working medium, it breaks the elastic membrane through the perforations in the pipeline, and the unbalanced pressure wave is extinguished due to energy dissipation at the perforations, as well as due to the ductility of the tube and the liner from the elastic material, which under the influence of the pressure wave are deformed and squeezed out into recesses or cavities [see Russian patent No. 2144641 for class F16L 55/04 published on January 20, 2000].

The main disadvantage of the known working elastic element of the hydraulic shock compensator is the one-time use of it due to rupture of the membrane (violation of its integrity) due to the dynamic influence of the pressure of the working medium at the time of quenching of the hydraulic shock of significant force.

The second disadvantage of this working elastic element of the shock absorber is the inefficiency of using its individual parts, in particular the liners, with a small force of the hydraulic shock, since in this case the membrane does not break and there is no access to the liners.

The third disadvantage of the known working elastic element of the shock absorber is the low technological quality of its manufacture due to the presence in its design of several varieties of liners. This drawback necessitates the use of special casting molds for the manufacture of inserts having a non-standard and rather complex spatial design. In addition, since the liners have different types of grooves and recesses, different casting molds are needed, respectively, and this, of course, affects the cost of working elastic elements for the worse, increasing their cost.

And the last, fourth, drawback of the known working elastic element of the hydraulic shock compensator is the limited scope of its use. The presence of this drawback is due to the fact that it is manufactured individually for each diameter of the pipeline, since a membrane is included in its design, which should cover it tightly. Therefore, due to the specific size of the membrane and the size of the liners: the compensator housing must have a strictly cylindrical shape of adequate diameter and length. In a housing of other sizes and on a pipe of a different diameter, such a working elastic element cannot be inserted or put on accordingly. Therefore, due to the large assortment of pipeline diameters, there is a need for the manufacture and the corresponding range of working elastic elements.

The utility model is based on the task of simplifying the design of the working elastic element of the hydraulic shock compensator while expanding the scope of its application and increasing its operational characteristics, in particular, the service life and insensitivity to the power of hydraulic shock, due to the absence of parts that are destroyed during the hydraulic shock of the working elastic element and its constant readiness to absorb shock by ensuring their constant contact with the flowing working medium, independently depending on the direction of movement of the latter in the compensator.

The solution to this problem is achieved by the fact that the working elastic element of the shock absorber made in the form of an insert made of an elastic material, according to the proposal, the insert has the shape of a ball made of an elastic material, which is used as oil-resistant or other rubber or plastic, dimensions, rigidity, elasticity and the elasticity of which (ball) is selected depending on the operational characteristics (pressure and dimensions) of the hydraulic or pneumatic system, in which a hydraulic shock compensator is used but any shape and size.

The implementation of the working elastic element in the form of a ball greatly simplifies its design, and also, when filling in any amount of elastic balls of the housing of the shock absorber, allows you to use only one design of the working elastic element.

The implementation of the working elastic element in the form of a ball makes it insensitive to the direction of flow of the working medium, since for a spherical surface it does not matter where it is exerted pressure from.

In the event of a water hammer, the pressure wave is suppressed due to compression of the working elastic element. Regulation of the frequency range of unbalanced waves

pressure and the degree of reduction in their amplitude is achieved by varying the sizes of the elastic balls, their rigidity and elasticity, which makes them universal and suitable for use in any form and size of shock absorbers.

The spherical shape of the working elastic element is not chosen randomly. It is this form that does not allow adjacent liners to stick together along the planes, therefore, the damping properties of the compensator always remain the same. It is the spherical shape that makes the compensator insensitive to the direction of movement of the working medium. Any other form of working elements only worsens the operation of the compensator from this point of view.

The further essence of the proposed technical solution is explained in conjunction with the principle of operation of the proposed working elastic element of the shock absorber, made, for example, in the form of a conventional container (case) tightly filled with liners with fittings at the ends for connection to the hydraulic system.

With a constant mode of movement of the working medium in the hydraulic system, it under pressure enters through the fitting into the housing of the compensator, which is completely filled with working elastic elements in the form of rubber balls. Here, the working environment collides with the liners and washes them. When a water shock occurs, a wave of increased pressure, or an unbalanced flow of the working medium, stumbles on the liners, which, due to their suppleness (elasticity), dissipate the energy wave to an acceptable level, and the spherical shape repeatedly changes the direction of movement of the working medium, which also contributes to energy dissipation unbalanced pressure.

A significant difference between the claimed object of the utility model and the previously known ones is that the working elastic element of the hydraulic shock compensator is made in the form of an insert in the form of a ball of elastic material, which is used as oil and petrol resistant rubber. This difference simplifies the design of the working bodies as much as possible and they become universal, which allows them to be used in shock absorbers of any shape and size. None of the known working bodies of compensators can have the indicated properties, since they either contain structurally destructible elements or require mechanical fastening.

The technical advantages of the proposed technical solution, in comparison with the prototype, include the following:

- an increase in the service life (practically unlimited) until the natural wear of working elastic elements due to the absence of destructible and moving parts in the structure;

- improving the manufacturability and simplification of the design through the use of spherical elements, that is, the most common and simple form;

- insensitivity to the direction of movement of the working medium for the same reason;

- the reliability of the quenching of hydraulic shock due to the constant flow of the working medium through a large number of working elastic elements;

- the ability to regulate operational characteristics through the use of elements of different stiffness, elasticity and size;

- versatility due to the small size and sphericity, which allows them to be used in compensators of any size and shape.

The social effect of the implementation of the proposed technical solution, in comparison with the use of the prototype, is obtained by expanding the field of application of the working elastic element of the shock absorber, as well as the high reliability of its operation and complete damping of the energy of the unbalanced medium. For this reason, well-known compensators are not used in fuel systems of vehicle engines, since they do not provide complete damping of water hammer. This is especially true if fuel counters are included in the fuel system. As you know, these devices are very sensitive to pressure drops and give incorrect readings in the presence of such drops that necessarily occur during the operation of fuel pumps. The presence of fuel meters allows you to not only accurately control its consumption, but also to prevent its unauthorized removal.

The economic effect of the implementation of the proposed technical solution, in comparison with the use of the prototype, is obtained by reducing the cost of the working elastic element of the shock absorber, as well as by reducing the complexity of its manufacture and reducing the number of equipment.

Claims (1)

The working elastic element of the hydraulic shock compensator, made in the form of an insert made of an elastic material, characterized in that the insert is made in the form of a ball of elastic material, which is oil and petrol-resistant or other rubber or plastic, the dimensions, rigidity, elasticity of which (ball) are selected depending on the operational characteristics (pressure and dimensions) of the hydra- or pneumatic system, which use a hydraulic shock compensator of any shape and size.