RU183775U1 - SPRING SHOCK ABSORBER FOR EXTINGUING RESONANCE VIBRATIONS IN VIBRATION CONSTRUCTION MACHINES - Google Patents

Abstract

The utility model can be used to damp resonance vibrations in vibrating machines during start-up and braking. The technical result is a decrease in the value of the resonant vibrations of the vibrating machine. The problem is solved due to the new design of a spring shock absorber containing a cylinder, in which a rod with a piston and a spring are located, which is equipped with two movable centering bushings located above and below the piston and made with a diameter less than the diameter of the shock absorber cylinder by one millimeter and with a central hole larger than the diameter of the rod by one millimeter, and the height of the upper centering sleeve is two times less than the diameter of the lower centering sleeve, with a holding sleeve made on both five threaded ends with an internal diameter less than the piston diameter, while both centering sleeves are screwed onto the holding sleeve and secured with washers, the spring being installed in the lower part of the shock absorber and resting at one end on the cylinder bottom and the other on the washer, two flat springs are fixed above and below the piston, the lower end of the rod passes through the central holes of the centering sleeves and the holding sleeve and protrudes beyond the washer located by the centering sleeve. 4 ill.

Description

The utility model relates to the field of mechanical engineering and can be used to damp resonance vibrations in vibrating machines during start-up and braking.

Most of the vibrating transport-technological machines operate in the resonance zone of oscillations. Therefore, during acceleration and braking, there is a sharp increase in the amplitude of oscillations (ten or more times), which increases the dynamic load on the machine and thereby reduces their resource.

The shock absorber must have two operating modes:

- operating mode - with a low coefficient of resistance to minimize power losses due to vibration;

- start-brake mode - with a high coefficient of resistance for damping resonant oscillations, and the resistance should increase in proportion to the amplitude of the oscillations.

The shock absorber should also have a long resource, namely, a service life of at least 1 year, while about 300 million vibrations will be committed (based on the oscillation frequency of 50 Hz).

The closest analogue in design is a suspension with adjustable force and damping according to the patent of the Russian Federation No. 2467223 ,. Suspension with adjustable force and damping contains a working cylinder and a damper body with two springs. One spring is installed between the damper body and the piston connected to the collapsible rod. The stem consists of the upper half, inside which a channel for supplying fluid to control damping is drilled, and the lower half. A piston with throttle valves is fixed between the halves of the stem. A second spring is installed between the piston connected to the rod and the piston forming a fluid cavity in the lower part of the cylinder to change the force. The possibility of stepless regulation of effort and damping is achieved. The disadvantages of the prototype are the design complexity, which does not provide a small coefficient of resistance and the lack of free travel of the pusher, which is necessary for the pre-resonant mode of operation of the vibrating machine.

The objective of the claimed utility model is to reduce the magnitude of the resonant vibrations of a vibrating machine.

The problem is solved due to the new design of a spring shock absorber for damping resonance vibrations in vibrating construction machines, containing a cylinder in which the piston rod is located, the spring, in contrast to the prototype, is equipped with two movable centering bushings located above and below the piston and made smaller in diameter the diameter of the cylinder of the shock absorber by one millimeter and with a central hole with a diameter greater than the diameter of the rod by one millimeter, the height of the upper centering sleeve being two to three times less than the diameter of the lower centering sleeve, the holding sleeve made at both ends with a thread and with an inner diameter less than the piston diameter by five to eight millimeters, while both centering sleeves are screwed onto the holding sleeve and secured with washers, the spring being installed in the lower part of the shock absorber and abuts against one end of the cylinder bottom and the other by the washer, two flat springs are fixed on the piston above and below, the lower end of the rod passes through the central holes of the centering bushings and the retainer Tulku and advocates for the puck, located centering sleeve.

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 FIG. 2 presents a top view of the centering sleeve along the longitudinal axis of the inventive device shock absorber;

in FIG. 3 schematically shows a shock absorber mounted on a vibrating machine;

in FIG. 4 is a schematic side view of a shock absorber mounted on a vibrating machine.

The shock absorber for damping resonance vibrations in vibrating machines contains a cylinder 1, in which there is a rod 2 with a piston 8. Four flat springs 9 are mounted on the piston 8 above and below 9. Moving centering sleeves 3 and 5 are located on both sides of the piston 8. 5 the sleeve is working, i.e. she makes a movement. It holds the rod and makes a certain movement - for this purpose, a spring is located in the lower part of the shock absorber, it replaces the gas, which is usually used in this type of shock absorbers, where the entire shock absorber is filled with liquid, and its upper part is with an additional piston, which can shrink due to the physical properties of a gas, as opposed to a liquid. Through the central holes of the centering bushings 3 and 5, the rod 2 passes. The centering bushings 3 and 5 are made with a central hole with a diameter greater than the diameter of the stem 2 by one millimeter, and the diameter of the bushings 3 and 5 themselves is less than the diameter of the cylinder 1 by one millimeter to ensure their free movement inside cylinder 1 shock absorber. The height of the sleeve 5 is greater than the height of the sleeve 3 in two to three times. This is necessary so that the sleeve 5 at the time of increasing amplitude could withstand a large load. The centering sleeves 3 and 5 are separated by a holding sleeve 7, and the sleeve 3 is located above the piston 8. The sleeve 7 has threads at both ends for fixing the sleeves 3 and 5. The inner diameter of the holding sleeve 7 is five to eight millimeters smaller than the diameter of the piston 8 due to which free movement of the piston 8 inside the sleeve 7 is ensured.

The centering sleeve 3 is fixed to the holding sleeve 7 by means of a threaded connection and a washer 4. The centering sleeve 5 is also fixed to the holding sleeve 7 by means of a threaded connection and washer 6. The lower end of the rod 2 passes through the central holes of the centering bushes 3 and 5 and the holding sleeve 7 and stands for the working centering sleeve 5 with the washer 6. Below the centering sleeve 5, a spring 10 is installed, resting on the washer 6. A cover 11 is screwed onto the cylinder 1, through which the rod 2 passes through the central hole.

The technical result of the utility model is to reduce the magnitude of the resonant vibrations of a vibrating machine.

The shock absorber is as follows.

The shock absorber 14 for damping resonant vibrations is installed between the oscillating 12 and the base 13 parts of the vibrating machine. The required number of installed shock absorbers 14 is determined depending on the characteristics of the equipment, such as the position of the center of mass of the equipment, working amplitude, mass and others. The vibrations are excited by the vibrator 16. The springs 15 support the oscillating part 12 of the vibrating machine. The operating mode of the vibrating machine is influenced by: the exciting force F _{0 of the} vibrator 16, the stiffness from the springs 15. In the operating mode of the vibrating machine, the oscillatory movement of the piston 8 occurs in the inner space of the sleeve 7. In this mode, the resistance to the movement of the rod 2 is due to the compression force of the flat springs 9 and the inertia force of the moving parts — the rod 2 with the piston 8. The coefficient of resistance of the shock absorbers 14 in this mode is minimal.

At the moments when the vibrating machine starts and stops, resonant oscillations arise with an amplitude that exceeds the working amplitude by approximately an order of magnitude (ten times) (this would be the case in the absence of shock absorbers). But, as soon as the amplitude exceeds twice the magnitude of the working amplitude, the piston 8 together with the centering sleeves 3 and 5 will exert pressure on the spring 10, accompanied by a sharp increase in the resistance of the spring. The coefficient of resistance of the shock absorber will increase proportionally. The amplitude of the resonant oscillations will be reduced.

The required coefficient of resistance of the shock absorber is set according to the stiffness of the flat springs 9 and the height of the sleeve 7. The magnitude of the amplitude limitation is set according to the stiffness of the spring 10.

Thus, the claimed structural design of the spring shock absorber for damping resonance vibrations in vibrating machines allows the operating mode of the vibrating machine with a low resistance coefficient to minimize power losses due to vibration and the brake mode with a high coefficient of resistance for damping resonant vibrations, and the resistance increases stepwise when reaching the set value of the amplitude of the oscillations.

Claims (1)

A spring shock absorber for damping resonance vibrations in vibrating construction machines, comprising a cylinder inside which a rod with a piston is located, a spring, characterized in that it is equipped with two movable centering sleeves located on opposite sides of the piston and made one millimeter in diameter less than the diameter of the shock absorber cylinder and with a central hole with a diameter greater than the diameter of the stem by one millimeter, and the height of the centering sleeve located above the piston is half the diameter of the second center a sleeve, a retaining sleeve, made on both ends with a thread and with an inner diameter less than the diameter of the piston by five to eight millimeters, while the centering sleeves are fixed to the holding sleeve with a threaded connection and washers, a spring is installed at the bottom of the shock absorber, which is one end rests against the bottom of the cylinder, and another into the washer located under the lower centering sleeve, two flat springs are fixed on the piston above and below, the lower end of the rod passes through the central holes of the centering ulok and retaining sleeve and supports the lower centering sleeve.

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