RU188147U1 - SHOCK ABSORBER TO REDUCE RESONANCE VIBRATION IN VIBRATION MACHINES - Google Patents

Abstract

The utility model relates to the field of mechanical engineering and can be used to reduce resonance vibrations in vibrating transport and technological machines. SUBSTANCE: shock absorber comprises a cylinder in which a rod guide with a hydraulic piston, a hydraulic sleeve fixedly installed inside the cylinder, additional hydraulic and centering sleeves fixedly installed inside the cylinder are located. Hydraulic bushings are made with an inner diameter larger than the diameter of the hydraulic piston for its free movement inside the hydraulic bushings, and the centering sleeve is made with four equally symmetrical holes and with a central hole with a diameter larger than the diameter of the hydraulic piston rod to move the rod through the centering sleeve. The hydraulic piston is made with eight equal grooves symmetrically located on each end of the piston, while the lower end of the piston rod is located inside the central hole of the centering sleeve and protrudes beyond it. The rod, made integral, includes coaxially located leading and driven parts with a gap required to exclude vibrations transmitted to the driven part of the rod, an inductor is rigidly mounted on the lower end of the driving part of the rod with the possibility of introducing the upper end of the driven part of the rod into it. Effect: preservation in the operating mode of the drive efficiency of a vibrating machine equipped with shock absorbers to reduce resonance vibrations. 2 ill.

Description

The utility model relates to the field of mechanical engineering and can be used to reduce resonant vibrations in vibrating transport and technological machines, for example, in vibrating conveyors during start-up and braking. When starting and braking these machines as a result of resonance, there is a sharp increase in the amplitude of their oscillations, which increases the dynamic load on the machines and thereby reduces their resource.

A shock absorber with a hydraulic rebound buffer is known, comprising a cylinder, a rod with a working piston, a pneumatic separator piston, a rod guide, a throttling system, a hydraulic sleeve fixedly mounted in the cylinder, and a hydraulic piston with grooves mounted on the rod. Moreover, in the space between the hydraulic sleeve and the rod guide, a cavity of the hydraulic rebound buffer is formed, filled with liquid from the working cavity of the shock absorber, and the grooves of the hydraulic piston are beveled (see RF Patent No. 2279582, IPC F16F 9/06).

A disadvantage of the known shock absorber is its high coefficient of resistance at the end of the rebound stroke, which causes an increased power consumption of the drive of the vibrating machine to overcome this resistance, thereby reducing the efficiency of the drive. In addition, a decrease in the rigidity of shock loads occurs only at the end of the rebound stroke.

The closest analogue to the claimed utility model is a shock absorber for damping resonance vibrations in vibrating machines, comprising a cylinder in which a rod guide with a hydraulic piston is located, a hydraulic cavity filled with a working fluid and separated by a hydraulic piston into lower and upper hydraulic parts connected by channels , gas cavity separated from the lower hydraulic part by a pneumatic piston, hydraulic sleeve fixedly mounted inside the cylinder additional hydraulic and centering sleeves fixedly installed inside the cylinder, and the hydraulic sleeves are made with an inner diameter larger than the diameter of the hydraulic piston for its free movement inside the hydraulic sleeves, and the centering sleeve is made with four identical symmetrically arranged holes and with a central hole with a diameter larger than the diameter of the hydraulic rod piston for moving the rod through the centering sleeve, while the hydraulic bushings are spaced apart distance greater than their height by an amount equal to twice the working amplitude of the oscillatory system, a hydraulic piston is formed with eight identical grooves symmetrically disposed at each end of the piston, the lower end of the hydraulic piston rod disposed within the central bore of the centering sleeve and protrudes beyond it (see. RF patent No. 170737, IPC F16F 9/49, F16F 9/36).

It is known that the specified shock absorber is installed between the oscillating and the base parts of the vibrating machine (vibration conveyor) and it operates in two modes: working (with a low coefficient of resistance) and start-brake (with a high coefficient of resistance), to damp resonant vibrations of the vibrating part of the machine. The upper end of the shock absorber rod is pivotally connected to the oscillating part of the machine, and the lower end to its base part. With the prevailing operating mode in time to overcome local hydraulic resistance in the shock absorber (especially at low ambient temperatures), as well as mechanical friction in their movable rod-cylinder interface, some part of the drive power of the vibrating machine is constantly consumed, thereby reducing its efficiency. In the vibratory conveyor are two known shock absorbers on each side, that is, there are four in all. They are constantly connected between the oscillating and the base parts of the machine and are a significant additional load on its drive during operation.

Therefore, the disadvantage of the known shock absorber is to reduce the efficiency of the drive of the vibrating machine.

The essence of the utility model lies in the fact that in the known shock absorber for reducing resonance vibrations in vibrating machines containing a cylinder in which a rod guide with a hydraulic piston is located, a hydraulic cavity filled with a working fluid and divided by a hydraulic piston into lower and upper hydraulic parts connected between channels, a gas cavity separated from the lower hydraulic part by a pneumatic piston, a hydraulic sleeve fixedly installed inside the cylinder, up to additional hydraulic and centering sleeves fixedly installed inside the cylinder, and the hydraulic sleeves are made with an inner diameter larger than the diameter of the hydraulic piston for its free movement inside the hydraulic sleeves, and the centering sleeve is made with four identical symmetrically arranged holes and with a central hole with a diameter larger than the diameter of the hydraulic piston rod to move the rod through the centering sleeve, while the hydraulic bushings are spaced apart In order to increase their height by an amount equal to the double working amplitude of the vibrating machine, the hydraulic piston is made with eight equal grooves symmetrically located at each end of the piston, while the lower end of the piston rod is located inside the central hole of the centering sleeve and protrudes beyond it, according to the change , the rod, made integral, includes coaxially located leading and driven parts with the gap required to exclude vibrations transmitted to the driven part of the rod, at the lower end riding of the stem is rigidly mounted coil to input therein the upper end portion of the driven shaft.

The implementation of the shock absorber rod composite provides the gap between the ends of its coaxial driving and driven parts with the operation prevailing in time, required to exclude vibrations transmitted to the driven part of the rod, and disconnecting the shock absorber from the vibrating part of the vibrating machine, which eliminates the additional load on its drive during operation, maintaining drive efficiency.

Providing the lower end of the stem stem part with a rigidly mounted inductor and the possibility of introducing the driven stem portion into it allows pulling the stem stem part (armature) into the coil while supplying voltage to the stop against the end of the stem stem portion and hold the parts of the composite stem together with the magnetic power lines of the coil inductance, that is, to selectively turn on the shock absorber only when starting and stopping the vibration machine, while maintaining the efficiency of its drive in operating mode.

The technical result provided by the utility model is to maintain the operating efficiency of the drive of a vibrating machine equipped with shock absorbers in order to reduce resonance vibrations.

The essence of the claimed utility model is illustrated by drawings, where:

- in FIG. 1 schematically shows a General view of the shock absorber in operating mode;

- in FIG. 2 schematically shows a general view of the shock absorber in the brake starting mode.

The shock absorber for reducing resonance vibrations in vibrating machines contains a cylinder 1, in which there is a guide 2 of the driven part of the rod 3 (anchors) with a hydraulic piston 4. On both sides of the hydraulic piston 4 are hydraulic bushings 5 and 6, the inner diameter of which is larger than the diameter of the hydraulic the piston 4 for its free movement inside the hydraulic bushings 5 and 6. The pneumatic piston 7 divides the inner space of the cylinder 1 into hydraulic A and gas B cavities. As a gas, neutral nitrogen can be used at a pressure of 0.5-2.0 MPa. The hydraulic cavity A is filled with a working fluid, which can be used as a special fluid for automobile shock absorbers, such as AZ-12T. Inside the cylinder 1, a centering sleeve 8 is fixedly mounted, made with four symmetrically arranged holes that allow free flow of the working fluid through the sleeve 8, and with a central hole with a diameter larger than the diameter of the rod 3 of the hydraulic piston 4 to move the driven part of the rod 3 (anchor) through the centering sleeve 8 The hydraulic piston 4 is made with eight equal grooves 9, symmetrically located at each end of the piston 4. The number, profile and dimensions of the grooves 9 of the hydraulic piston 4 elyayut resistance characteristic hydraulic rebound buffer (or contraction) at the end of rebound (or compression) of the shock absorber, and also promote freer movement of the piston 4 at the operating vibrations as compared with a hydraulic piston without grooves. The leading part of the rod 10 is located coaxially with the driven part of the rod 3 (anchor) with the gap required to exclude vibrations transmitted to the driven part of the rod, a gap which exceeds the working amplitude of the oscillations of the leading part of the rod 10, pivotally connected to the vibrating part of the vibrating machine. An inductor 11 is rigidly mounted on the lower end of the stem stem 10 with the possibility of introducing the upper end of the stem stem 3 into it. The length of the stem stem 3 (armature) immersed in the inductor 11 and the length of the coil 11 can be determined when calculating the winding and traction characteristics of an electromagnet according to the method described in the training manual “Design and calculation of an electromagnetic device of low voltage” (Tsopov G.I. Design and calculation of an electromagnetic device of low voltage: training methodological manual / G.I. Tsopov, V.A. Sergeev, V.N. Ovsyannikov.- Samara: Samara State University, 2013.P. 32-35).

The inventive shock absorber to reduce resonant vibrations in vibrating machines works as follows.

The shock absorber is installed between the oscillating and the base parts of the vibrating machine. In the operating mode (Fig. 1), the driven part of the rod 3 under its own weight occupies the lower position in the hydraulic cavity A. In this case, the upper end of the driven part of the rod 3 freely enters the inductor 11, rigidly mounted on the lower end of the driving part of the rod 10, providing the gap with the end of the driving part of the rod 10 required to exclude vibrations transmitted to the driven part of the rod, exceeding the maximum operating amplitude of the oscillations the leading part of the rod 10. Thus, the oscillations of the leading part of the rod 10 with the inductor 11 fixed on it are not transmitted to the driven part of the rod 3 (anchor) and the inventive damper is disconnected from the oscillating I am part of a vibrating machine.

In the starting braking mode (Fig. 2), when a voltage is applied to the inductor 11, the magnetic flux generates traction, and the upper end of the driven part of the rod 3 (armature) is drawn into it against the end of the end of the leading part of the rod 10. In this case, the hydraulic piston 4 occupies the middle the position between the bushings 5 and 6. Parts 3 and 10 of the composite rod are held together by magnetic lines of force of the inductor 11 (solenoid), the shock absorber is included in the work of damping resonant oscillations. The amount of traction when moving the armature depends on the ratio of the lengths of the coil and the armature immersed in it. As soon as the amplitude of the oscillations of the composite rod exceeds the magnitude of the working amplitude by a factor of two, the hydraulic piston 4 will go inside the sleeve 5 or 6, depending on the direction of the resonant vibrations. This will push the working fluid through the grooves 9 of the piston 4 and the gaps formed between the sleeve 5 or 6 and the hydraulic piston 4, accompanied by a relatively sharp increase in hydraulic resistance. The amplitude of the resonant oscillations will be reduced. The pneumatic piston 7 compensates for the change in the internal volume of the hydraulic cavity A during the movement of the rod 3 due to compression-expansion of the gas chamber B.

Thus, the inventive shock absorber to reduce resonance vibrations in vibrating machines allows you to operate the vibrating machine without limiting the amplitude of the operating vibrations and without reducing the efficiency of its drive (the shock absorber is turned off), and when voltage is applied to the inductor (the shock absorber is turned on), it reduces start-stop of the vibrating machine of resonant vibrations, provided that the working amplitude increases by more than two times, thereby increasing the life of the vibrating machine when and the efficiency of its drive.

Claims (1)

A shock absorber to reduce resonance vibrations in vibrating machines, comprising a cylinder in which a rod guide with a hydraulic piston is located, a hydraulic cavity filled with a working fluid and divided by a hydraulic piston into lower and upper hydraulic parts connected by channels, a gas cavity separated from the lower hydraulic parts by pneumatic piston, hydraulic sleeve fixed inside the cylinder, additional hydraulic and centering sleeves, fixed but installed inside the cylinder, and the hydraulic bushings are made with an internal diameter larger than the diameter of the hydraulic piston for its free movement inside the hydraulic bushings, and the centering sleeve is made with four identical symmetrically arranged holes and with a central hole with a diameter larger than the diameter of the hydraulic piston rod to move the rod through the centering sleeve while the hydraulic bushings are spaced a distance greater than their height by an amount equal to the double working the amplitude of the vibrating machine, the hydraulic piston is made with eight equal grooves symmetrically located at each end of the piston, while the lower end of the hydraulic piston rod is located inside the central hole of the centering sleeve and protrudes beyond it, characterized in that the rod made integral includes coaxially located leading and driven parts with a gap required to exclude vibrations transmitted to the driven part of the rod, an inductance coil is rigidly mounted on the lower end of the driving part of the rod tee with the ability to enter into it the upper end of the driven part of the rod.

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