SU1172605A1 - Self-exciting hydraulic oscillator - Google Patents

Abstract

I. AUTO-VIBRATING HYDRAULIC RADIATOR, containing a pump with a pressure line, a spool valve connected to it, a drain and pressure lines connected to it, and a double-acting hydraulic cylinder connected to it, connected with a feedback valve to the slide valve, DIFFERENCES WITH the fact that, with the expansion of the range of regulation of the part and reduction of energy consumption, it is equipped with spring oscillators pivotally connected to the rod and installed with the possibility of adjustment their angular position is relative. each other. 2. The emitter according to claim 1, about t and in that, in order to regulate the amplitude of oscillations, (L feedback is executed in the form of two end sensors installed with the possibility of movement relative to the rod.

Description

The invention relates to a vibration technique, is designed to produce mechanical oscillations with adjustable frequency and amplitude, and can be used in various vibration machines to create acoustic signals, to test materials and samples, to intensify technological processes, such as drying.

The purpose of the invention is to expand the frequency control range, reduce energy consumption and control the amplitude of oscillations.

The drawing shows a schematic diagram of a self-oscillating hydraulic radiator.

The self-oscillating hydraulic emitter contains a pump 1 with a pressure line 2, spring oscillators 3, the rods 4 of which are connected to the rod 5 of the piston 6 of the hydraulic cylinder 7 and the working body 8 of the radiator. The spring oscillators 3 are mounted on rails 9, allowing the angle between them to vary.

The emitter also contains injection lines 10 and 11 connecting the cavities of the hydraulic cylinder 7 through the spool valve 12 to the pressure line 2 and to the drain line 13. The spool valve 12 is controlled by the action of the stem 5 on the end sensors 14 and 15, the distance between which is controlled, for example, by means of a screw mechanism 16 and auxiliary controls, for example an electric circuit including a start button 17, a stop button 18, two relays P 19 and Pj 20 with contact groups and a power source.

Self-oscillating hydraulic emitter works as follows

When the button P is pressed, the relay Pj is activated, switching the spool valve to supply the working medium from the pump 1 through the pressure line 2 and through line 10 to the piston cavity of the hydraulic cylinder 7. At the same time, the piston begins to move, acting through the puller 5 on the working element 8

the radiator and through the rods 4 on the spring oscillators 3, which accumulate energy. The movement occurs before the closure by the rod 5 of the end sensor 14, which includes the relay P 19, which switches the spool valve 12 to the position when the working medium from the pump 1 through the pressure line 2 enters the hydraulic cylinder 7 through the fisturized cavity and the 4th piston cavity line 10 connects to line 13 drain. The piston starts to move in the opposite direction due to the accumulated energy of the spring oscillators 3 and the pressure of the working medium in the over-piston cavity. Having passed the neutral position, the oscillators 3 again begin to accumulate energy. Move along with the piston 6 of the hydraulic piston 7, the rod 5 acts on the end sensor 15,

20

which again includes relay P,

and turns off the relay P 19. Turning on the self-oscillating hydraulic radiator is performed by turning off spool valve 12 using the stop button C 18. The end sensors 14 and 15 are located on the screw mechanism 16, with which the distance between them, and hence the amplitude of oscillation, is adjusted. The oscillation frequency depends on the rigidity of the system, which mainly consists of the rigidity of the spring oscillators 3, which can be adjusted by changing the angle between the spring oscillators 3, and placing them on the guides 9.

In a self-oscillating hydraulic emitter, oscillations of the working member occur under the action of spring oscillators, and the hydraulic cylinder serves to compensate for energy losses, i.e. When reaching the operating conditions, much less energy is required. The oscillation frequency can be varied by adjusting the stiffness of the system, which is mainly composed of the geometric sum of the stiffnesses of each oscillator and, therefore, depends on the angle between their rods.

Claims (2)

1. SELF-OSCILLATING HYDRAULIC RADIATOR, comprising a pump with a pressure line, a spool valve connected to it, drain and discharge lines connected to it, and a double-acting hydraulic cylinder connected to the latter with a rod connected by feedback to the spool valve, characterized in that that, with the Purpose of expanding the range of regulation of parts and reduce energy consumption, it is equipped with spring oscillators pivotally connected to the rod and installed with the possibility of regulating them angular position relative to '. each other. 2. The emitter according to claim 1, about t and • characterized in that, for the purpose of § regulating the amplitude of the oscillations, the feedback is made in the form of two end sensors installed with the possibility of movement relative to the rod. SU „„ 1172605 1 1172605 2