RU2129050C1 - Vibration machine - Google Patents

Abstract

FIELD: vibration technology; vibration tables, vibration conveyers, vibroshaker, and other machinery. SUBSTANCE: device includes working member, pneumohydraulic system made in form of housing with hydraulic cavity where flexible chamber communicated with fluid medium pulsator is mounted. Hydraulic cavity is connected with flexible envelopes on which working member is mounted. Flexible envelopes are mounted on either side of working member which is provided with guides which spring-loaded relative to base. Guides are provided with hold-down plates for envelopes. Working member and base are provided with impact members. EFFECT: enhanced reliability and durability. 2 cl, 3 dwg

Description

 The invention relates to vibration technology and can be used in various industries in vibration platforms, vibrating conveyors, vibrating screens and other devices.

 Known vibration machines, including a base, a working body, a pneumohydraulic system, an elastic chamber [SU 1793112 A1, 02/07/93; SU 1672017 A1, 08/23/91; DE 4332921 A1, 03/30/95; Bashta T.M. Hydraulic drive and hydropneumatic automation. - M.: Mechanical Engineering, 1972, p. 54-56].

 Closest to the proposed one is a vibration machine, including a base, a working body, a pneumohydraulic system in the form of a body with a hydrocavity, in which an elastic chamber is installed, connected with a pneumopulsator [SU, copyright certificate, 1341406, cl. B 06 B 1/18; F 15 B 21/12, 1987]. Here the translational pairs “cylinder - piston” are introduced into the drive system of the working body. This complicates the design, in addition, difficulties arise in eliminating fluid leaks in the movable cylinder-piston pair, which reduces the reliability and durability of the machine.

 The purpose of the invention is to increase the reliability and durability of the machine.

 This goal is achieved by the fact that the vibrating machine, including the base, the working body, the pneumohydraulic system in the form of a housing with a hydrocavity, in which an elastic chamber is connected, connected with the pneumatic pulsator, is equipped with elastic shells connected to the hydrocavity, while the working body is mounted on these elastic shells and is made with guides spring-loaded to the base with clamping strips for elastic shells, while the clamping strips are located on the opposite side of the base p bochego body.

 In order to expand the technological capabilities of the vibrating machine, the working body and the base are made with shock elements.

 The drawings show schematic diagrams of one of the possible options for a vibrating machine: FIG. 1 - frontal, fig. 2 is a horizontal section through a pneumatic-hydraulic drive; FIG. 3 - node mounting the working body.

 The vibration machine (Figs. 1–3) includes a working body 1, a pneumohydraulic system in the form of housings 2 with hydraulic cavities 3, in which elastic chambers 4 are mounted, dressed on perforated pipes 5, connected through pneumatic accumulators 6, a pipe 7, and an air pulsator in the form of a pneumatic distributor 8 with pneumatic line and atmosphere. Hydrocavities 3 by nozzles 9 are connected with elastic shells 10 (for lower hydrocavity 3) and 11 (for upper hydrocavity 3).

 Elastic shells 10 are installed between the working body 1 and the base 12, and the shell 11 is pressed from above to the working body by pressure bars 13 attached to the guides 14 connected to the base 12 by the springs 15. The working body 1 and the base 12 are made with impact elements 16 and 17 .

 The vibration machine operates as follows.

 When connecting the lower pneumatic adder 6 with a pneumatic distributor 8 to the pneumatic line, compressed air enters from the perforated pipe 3 from two sides into the perforated pipe 3 and through its perforations into the cavity of the elastic chamber, acts on it from the inside, while the elastic chamber 4 increases in volume, displaces part of the liquid from the lower hydrocavity 3 through nozzles 9 into elastic shells 10, which increase in volume and cause the working body 1 to move up along the guides 14, partially compressing the elastic shells 11, and through the straps 13 sec guides 14 and a spring 15.

 After switching the pneumatic distributor 8, compressed air from the lower pneumatic accumulator 6 and the elastic shells 10 is discharged into the atmosphere, and the upper pneumatic accumulator 6 is connected to the pneumatic line and the elastic shells 11, increasing in volume, move the working body 1 down. After this, the next switching of the air distributor follows and the cycle repeats; the system oscillates. In the presence of shock elements 16 and 17, the vibrator can also work in vibration-shock mode, which expands technological capabilities (for example, a machine in the form of a vibrating platform can compact more rigid concrete mixes).

 Since the working fluid circulates in a closed volume "hydrocavity - elastic shells", its leaks are eliminated, and the reliability and durability of the vibratory drive are increased.

 The installation of elastic shells both from below and from above the working body allows to increase its acceleration down, which intensifies the process (for example, when compacting concrete mix).

 The implementation of the working body with guides spring-loaded to the base with clamping strips for elastic shells and the location of the clamping strips on the opposite side of the working body side make it possible to establish constant contact with elastic shells, which increases the reliability and stability of the vibrator.

Claims (2)

 1. A vibrating machine, including a base, a working body, a pneumohydraulic system in the form of a housing with a hydraulic cavity, in which an elastic chamber is connected in communication with a pneumatic pulsator, characterized in that it is equipped with elastic shells connected to the hydraulic cavity, while the working body is mounted on said elastic shells and is made with guides spring-loaded to the base with clamping bars for elastic shells, while the clamping bars are located on the opposite side of the working side rgana.  2. The machine according to claim 1, characterized in that the working body and the base are made with percussion elements.

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