RU150696U1 - PNEUMAHYDRAULIC DEVICE FOR VIBRATION DAMPING - Google Patents

Abstract

A device for damping oscillations, comprising a cylinder filled with magnetic fluid, axially movable rod with a piston placed in the cylinder, a solenoid coil enclosing the cylinder, connected to an adjustable power source, containing meters for the position and direction of movement of the piston, the outputs of which are connected to the first and the second information inputs of the logical unit, the power input of which is connected to the power source, and the output is connected to the control input of the switch, and the outputs of the switch connected to the inputs of the sections of the solenoid coil, characterized in that the cylinder is equipped with a pneumatic elastic element placed in the punch coaxially with the rod and piston and rigidly connected to the rod, and a compensation chamber with a separator, the piston connected with the rod is equipped with at least one through channel, and the solenoid the coil consists of two sections and is rigidly fixed to the punch so that it overlaps the side surface of the piston, and the solenoid coil is mounted with the possibility of movement along the cylinder along with the punch and, in addition, the punch is equipped with a sleeve rigidly fixed in its lower part, covering the cylinder, and a sealing ring, fixedly mounted on the sleeve and movably mounted relative to the cylinder.

Description

The utility model relates to the field of damping of mechanical vibrations and can be used to eliminate harmful vibrations in various mechanical systems.

A known air suspension is predominantly a vehicle seat, comprising a damper in the form of a body and a rod located therein, a cover connected to the rod, a sleeve-type rubber cord shell fixed to the body with one end, and a cover covering the rubber cord shell with the other end equipped with a sleeve mounted on the housing and rigidly connected to the housing and a sealing ring installed between the latter and the housing (AS USSR 1539424, IPC F16F 9/04, publ. 30.01.1990, bull. No. 4.

The disadvantages of the suspension are the relatively low damping properties of the rubber-cord shell and the inability to control the process of damping vibrations

The closest set of features for the same purpose is a device for damping oscillations, containing a cylinder filled with magnetorheological liquid, axially movable rod with a piston placed in the cylinder, a solenoid coil covering the cylinder and connected to an adjustable power source containing position meters and the direction of movement of the piston, the outputs of which are connected to the first and second information inputs of the logical unit, the power input of the logical unit, connected to the power source, and the output is connected to the control input of the switch, and the outputs of the switch are connected to the inputs of the sections of the solenoid coil (RF patent 2426922, IPC F16F 9/53, F16F 6/00, F16F 15/03, publ. 08/20/2011 (prototype )

The disadvantages of the prototype are:

- limited dynamic range of regulation of the coefficient of resistance of the shock absorber due to the constant stiffness of the shock absorber springs;

- the need for initial technological adjustment of the relative positioning of the system elements, which is determined by the initial positions of the shock absorber springs and other suspension elements, as well as the load on the vehicle suspension,

- large dimensions and design complexity of the solenoid coil,

- increased energy costs for the operation and management of the shock absorber, as well as the insufficient efficiency of damping object vibrations.

The technical result from the use of the proposed device is to increase the dynamic range of regulation of the drag coefficient of the pneumatic elastic element and eliminate the need for initial technological adjustment of the relative position of the moving parts and the inactive parts of the system, as a result, reducing energy costs for operation and device control and increasing the damping efficiency of the sprung object.

The specified technical result is achieved by the fact that in a pneumohydraulic device for damping oscillations containing a cylinder filled with magnetorheological fluid, axially movable piston rod placed in the cylinder, a solenoid coil enclosing the cylinder connected to an adjustable power source containing position and direction meters displacement of the piston, the outputs of which are connected to the first and second information inputs of the logic unit, the power input of which is connected to the sources power supply, and the output is connected to the control input of the switch, and the outputs of the switch are connected to the inputs of the sections of the solenoid coil, the cylinder is equipped with a pneumatic elastic element placed in the punch coaxially to the rod and piston and rigidly connected to the rod, and a compensation chamber with a separator connected to the piston rod equipped with at least one through channel, and the solenoid coil consists of two sections and is rigidly fixed to the punch so that it overlaps the side surface of the piston, and the solenoid the carcass is installed with the possibility of moving along the cylinder together with the punch, in addition, the punch is equipped with a sleeve rigidly fixed in its lower part, enclosing the cylinder, and a sealing ring fixedly mounted on the sleeve and movably mounted relative to the cylinder.

In FIG. 1 is a schematic longitudinal sectional view of an oscillation damping device; FIG. 2 - node A in FIG. 1, in FIG. 3 is a section BB in FIG. one.

The device for damping oscillations comprises a housing 1 with a mounting unit 2, in which a cylinder 3 is placed, filled with magnetorological fluid 4. In the cylinder 3 with magnetorheological fluid is placed a piston 5 with at least one through-channel 6 made in it, connected to the rod 7. The piston 5 and the stem 7 are made of soft magnetic material. The cylinder 3 is equipped with a pneumatic elastic element 8, located in the punch 9, rigidly connected at one end with the rod 7, and the other end with the installation node 10.

A solenoid coil 11 is fixed on the punch 9, covering the cylinder 3 with the possibility of movement along the cylinder together with the punch, consisting of two sections - the lower 12 and the upper 13, located in the ferromagnetic housing 14 so that it overlaps the side surface of the piston, i.e. . the height of the solenoid coil exceeds the height of the piston, according to fig. one.

The inputs of sections 12 and 13 of the solenoid coil 11 are connected to the outputs of the electrical voltage switch 15, one of the inputs of which is connected to the power source 16, and the second to the output of the logic unit (microprocessor) 17. One of the inputs of the logic unit 17 is connected to the output of the position sensor 18, and the second, with the output of the displacement direction sensor 19. The position sensor 18 and the displacement direction sensor 19 determine, respectively, the position and direction of movement of the piston 5 of the damping element.

A separator 20 is installed in the under-piston part of the cylinder, forming a compensation chamber 21 in the cylinder filled with compressed gas.

In addition, the punch 9 is equipped with a sleeve 22 rigidly fixed in its lower part, covering the cylinder 3, and a sealing ring 23, fixedly mounted on the sleeve 22 and movably mounted relative to the cylinder 3. Thus, between the pneumatic elastic element 8 and the sleeve 22 with the sealing ring 23 an additional closed volume 24 filled with gas is formed.

The mounting unit 10 of the sprung object, the piston 5, the rod 7, the punch 9, the solenoid coil 11, the sleeve 22 and the o-ring 23 are in the same position relative to each other.

The mounting unit 2 and the housing 1 with the cylinder 3 are also in the same position relative to each other.

Between the housing 1 and the punch 9 has a protective cover 25.

The device operates as follows.

In the initial state, in the absence of oscillations and relative movements of the sprung object with the mounting unit 10 and the unsprung base with the installation node 2, the load from the side of the sprung object is absorbed by the pneumatic elastic element 8 located in the punch 9.

The relative position of the mounting unit 10 of the sprung object, the piston 5, the rod 7, the punch 9, the solenoid coil 11, as well as the sleeve 22 and the sealing ring 23 is unchanged, therefore, the initial technological adjustment of the entire system is not required.

When the piston moves downward (the compression stroke for the pneumatic elastic element 8), the magnetorheological liquid 4 begins to flow through the channels 6 of the piston 5 between the piston and piston cavities of the cylinder 3 in the opposite direction to the piston movement. As the piston 5 approaches the lower position in Fig. 1, the gas is compressed in the pneumatic elastic element 8, which is supported by the punch 9 and cylinder 3, the separator 20 compresses the gas in the compensation cavity 21.

At the same time, the position meters 18 and the direction of movement 19 of the piston 5 provide a signal to the logic unit 17, from the regulated power source 16 the lower section 12 of the solenoid coil 11 is turned on, which leads to an increase in the viscosity of the magnetorheological fluid and due to this the dissipative force is generated, and due to the excitation of pulses magnetic field creates an additional dissipative resistance force. Thus, vibration damping is carried out both by increasing the viscosity of the magnetorheological fluid when exposed to a magnetic field, and by applying an additional dissipative resistance force to the system that occurs when magnetic pulses are excited in the damping magnetorheological fluid, and an additional dissipative resistance force is created in the region of the damping magnetorheological fluid located at the front along the end of the end of the piston.

In a magnetorheological fluid, which is a nonpolar medium, a flow occurs in the region of the highest magnetic field strength, i.e. this means that when the piston 5 moves down (the compression stroke for the pneumatic elastic element 8), the magnetorheological fluid in the channels 6 of the piston 5 will flow in the direction of movement of the piston 5.

It should be noted that when moving the piston 5 in the absence of a field, the magnetorheological liquid 4 in the channels 6 of the piston 5 and the cylinder 3 always moves opposite to the piston movement (the Navier-Stokes equation and the flow profile, as a rule, have the so-called Poiseuille profile).

There are two speeds of the magnetorheological fluid 4 channels 6 of the piston 5: V _M - the mechanical speed of the magnetorheological fluid due to the movement of the piston 5 in the cylinder 3, which is independent of the magnetic field and is always directed opposite to the movement of the piston 5; V _N is the magnetic velocity of the magnetorheological fluid due to the presence of a magnetic field gradient in the channels 6 when applying voltage to the section located at the front along the part of the piston 5 in the cylinder 3 (i.e., always directed towards the movement of the piston 5).

Consequently, the following conditions are possible: V _M > V _H - damping is normal and piston 1 can move because the magnetic field does not completely slow it down; V _M = V _H -

there is no damping, since there is no relative movement of the parts of the device (the movable and fixed parts are “connected” into a single whole); V _M <V _H - the magnetic field enhances the vibrations of the mobile system, transferring it under certain conditions from a stable position to an unstable one.

When compressing the pneumatic elastic element 8, a pressure drop occurs in the closed volume 24 due to the fact that when moving down the punch 9 with the sleeve 22 and the sealing ring 23 on the stroke h, the bend of the pneumatic elastic element 8 when it is rolled between the punch 9 and cylinder 3 only moves by the value of h / 2. The protective cover 25 prevents the ingress of contaminants onto the surface of the cylinder 3, along which the o-ring 23 moves.

The first damping factor occurs due to a change in the viscosity of the magnetic fluid under the action of the applied magnetic field.

The second damping factor occurs when magnetic field pulses are excited in a damping magnetorheological fluid, and an additional dissipative resistance force is created in the area of the damping magnetorheological fluid, which makes up the front front of the moving part of the moving system immersed in the magnetorheological fluid in the direction of travel.

An increase in the efficiency of vibration damping as a result of the action of these factors is carried out both by increasing the viscosity of the magnetorheological fluid when exposed to a magnetic field, and by applying an additional dissipative resistance force to the system that occurs when magnetic field pulses are excited in the damping magnetorheological fluid, and an additional dissipative resistance force is created in the area of the damping magnetorheological fluid located at the front along the movement tion of the end part of the piston.

The third damping factor occurs due to the formation between the pneumatic elastic element 8 and the sleeve 22 with the sealing ring 23 of an additional closed volume 24 filled with gas and the creation of additional elastic resistance due to the pressure drop across the sleeve 22 with the sealing ring 23 due to the pressure drop in the closed volume 24 due to the fact that when moving down the punch 9 with the sleeve 22 on the stroke h, the bend of the pneumatic elastic element 8 when it rolls between the punch 9 and the cylinder 3 moves t lko by an amount h / 2. As a result, the drag coefficient of the damping device is further increased and, therefore, the damping efficiency of the vibrations is increased.

When the piston 5 moves up (rebound stroke due to the energy stored in the pneumatic elastic element 8), the position meters 18 and the direction of movement 19 of the piston 5 signal to the logic unit 17, the upper section 13 of the solenoid coil 11 is turned on, which leads to an increase in viscosity magnetorheological fluid, and due to the excitation of magnetic field pulses creates an additional dissipative resistance force. The processes occurring in the upper section 13 are similar to the processes that occur when the lower section 12 of the solenoid coil 11 is turned on, that is, the main and additional dissipative forces are created that provide damping. At the same time, the pressure in the pneumatic elastic element 8 drops, and in a closed volume 24 increases, which provides a more intensive decrease in the load on the suspension.

The use of a pneumatic elastic element in the device instead of a metal spring is preferable, because the ratio of the perceived load to its own weight for a metal spring is ~ 0.1, and for a pneumatic elastic element it is ~ 0.03, ceteris paribus. The stiffness of the pneumatic elastic element is controlled by changing the pressure, which makes it possible to increase the dynamic range of regulation of the resistance coefficient of the proposed device for damping vibrations.

The placement of the separator in the cylinder and the formation of a compensation chamber ensures the elimination of the destructive action of shock effects and elimination of the difference in the volume of the piston and piston cavities that occurs when the piston and the rod move.

The implementation of the solenoid coil rigidly fixed to the punch and, therefore, stationary relative to the piston and movable relative to the cylinder eliminates the need for initial technological adjustment of the relative positioning of the system elements.

The implementation of the two-section solenoid coil is due to the sufficiency of two sections to perform the given functions in full due to the constant relative location of the coil and piston and, as a result, simplifies the control system of its operation and reduces energy costs for operation and control of the device and increases the damping efficiency object.

As a result of the implementation of the proposed technical solution, the elimination of the need for initial technological adjustment of the relative position of the moving parts and the inactive parts of the system, the reduction of energy consumption for operation and control of the shock absorber, and the increase in the dynamic range of regulation of the drag coefficient of the damping device, which is ensured by the possibility of changing the gas pressure inside the pneumatic elastic element 8, and the formation between the latter and the sleeve 22 with the sealing ring 23 of an additional closed volume 24 filled with gas, and as a result of this creating a pressure drop across the sleeve 22 with the sealing ring 23 due to the pressure drop in the closed volume 24 due to the fact that when moving down the punch 9 with the sleeve 22 on the stroke h is the bend of the pneumatic elastic element 8 when it is rolled between the punch 9 and the cylinder 3 only moves by the value h / 2.

Since the elastic resistance force created on the pneumatic elastic element 8 depends on the pressure difference inside and outside the pneumatic elastic element 8, and the pressure outside the pneumatic elastic element 8 is the pressure in the additional closed volume 24, then when the pressure drops in the latter during the compression, the specified difference pressure increases, leading to an increase in the force of elastic resistance on the pneumatic elastic element 8.

The regulation of the stiffness of the pneumatic elastic element 24 is also possible by changing the gas pressure inside it.

The increase in the damping efficiency of the sprung object is thus ensured by the presence of two factors: the possibility of changing the gas pressure inside the pneumatic elastic element and creating an additional closed volume between the external environment and the pneumatic elastic element.

Claims (1)

A device for damping oscillations, comprising a cylinder filled with magnetic fluid, axially movable rod with a piston placed in the cylinder, a solenoid coil enclosing the cylinder, connected to an adjustable power source, containing meters for the position and direction of movement of the piston, the outputs of which are connected to the first and the second information inputs of the logical unit, the power input of which is connected to the power source, and the output is connected to the control input of the switch, and the outputs of the switch connected to the inputs of the sections of the solenoid coil, characterized in that the cylinder is equipped with a pneumatic elastic element placed in the punch coaxially with the rod and piston and rigidly connected to the rod, and a compensation chamber with a separator, the piston connected with the rod is equipped with at least one through channel, and the solenoid the coil consists of two sections and is rigidly fixed to the punch so that it overlaps the side surface of the piston, and the solenoid coil is mounted with the possibility of movement along the cylinder along with the punch and, in addition, the punch is equipped with a sleeve rigidly fixed in its lower part, covering the cylinder, and a sealing ring, fixedly mounted on the sleeve and movably mounted relative to the cylinder.

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