RU2740420C2 - Hydraulic vibration exciter - Google Patents

Abstract

FIELD: vibration equipment.

SUBSTANCE: invention can be used in vibroactive working members of excavating machines and on equipment for molding construction articles. Hydraulic vibration exciter comprises gear pump 1, hydraulic cylinder 7 with spring-loaded piston along axis in direction of piston cavity, hydraulic line connecting piston cavity of hydraulic cylinder 7 with drain of hydraulic cylinder 7, in which adjustable throttle 8 is installed. On driven gear 3 of pump 1 there are two radial channels 10 and 11, the outlets of which are interconnected in the center of pinion 3 axis. Inlets are made with possibility of simultaneous connection of one of them with suction cavity 4, and the other one—with pressure cavity 5 for liquid discharge from cavity 5 into cavity 4 and pressure release in piston cavity of hydraulic cylinder 7.

EFFECT: invention is aimed at simplifying design of hydraulic vibration exciter.

1 cl, 1 dwg

Description

The invention relates to vibration technology and can be used in vibroactive working bodies of earth-moving machines and equipment for molding construction products.

Known hydraulic vibration exciter containing a pump, a hydraulic cylinder, the working cavity of which is connected to the pressure line and to the drain, while in the drain line parallel to each other there are two chokes with elastic shells, and the drain line is equipped with a hydraulic resistance installed parallel to the first choke and in series to the second choke, moreover, the control cavity of this throttle is connected to the drain line between the adjustable hydraulic resistance and the second throttle (USSR author's certificate No. 954653, class F15B 21/12, 05.09.1982).

The disadvantage of the known hydraulic vibration exciter is the complexity of the design, which consists in the presence of two hydraulically controlled chokes with elastic locking and regulating elements, which are connected according to the scheme described above.

For the prototype, a hydraulic vibration exciter was selected containing a pump, a hydraulic cylinder having a piston spring-loaded along the axis, the piston cavity of which is connected with a pressure line, two parallel-mounted chokes having each elastic element, and a constant choke, the input and control cavity of the first and the input of the second chokes are intended for communication with a pressure line and with a piston cavity of the hydraulic cylinder, the outlet of the first and the control cavity of the second throttles through a constant throttle and the outlet of the second throttles are designed to communicate with the drain line, while the piston is equipped with a diaphragm sealing and distribution device located on the outer surface of the piston with a control cavity and a second constant throttle, the outlet of which is connected to the control cavity of the diaphragm sealing and distribution device, and its inlet is connected to the pressure line, while the throttles are located in the piston and the inputs of the first and second constant throttle are intended for connecting with a pressure line in series through the piston cavity of the hydraulic cylinder, and the outputs of the second and first constant throttles are designed to be connected to the drain line through the rod cavity. In addition, the working element of each choke is made in the form of a sleeve for interaction with an elastic element, which has radial grooves and axial holes on the surface adjacent to the latter (Inventor's certificate SU No. 1489845, A1, class B06B 1/18, 06/30/1989.

The disadvantage of the known hydraulic vibration exciter is the complexity of the design due to the presence of two hydraulically controlled throttles with membrane locking and regulating elements and a membrane sealing and distributing device, which are installed in the piston of the hydraulic cylinder and are connected to each other and the pressure line, according to the scheme described above. In addition, in the known technical solution, it is difficult to adjust the amplitude-frequency characteristic of the vibration exciter.

The technical problem solved by the proposed invention is to simplify the design of the hydraulic vibration exciter.

The technical result is achieved by the fact that in a hydraulic vibration exciter containing a pump, a hydraulic cylinder with a spring-loaded piston axially in the direction of the piston cavity, a hydraulic line connecting the piston cavity of the hydraulic cylinder with a hydraulic cylinder drain, and a throttle, according to the invention, in a hydraulic line connecting the piston cavity of the hydraulic cylinder with a drain, an adjustable throttle is installed, while a gear pump is used as a pump and two radial channels are made on the driven gear of the pump, the outputs of which are interconnected in the center of the gear axis, and the inputs are made with the possibility of simultaneous connection of one of them with the suction cavity, and the other with the pressure head cavity for dumping liquid from the pressure cavity into the suction cavity and for relieving pressure in the piston cavity of the hydraulic cylinder.

The execution of two radial channels on the driven gear of the pump, so that their outputs are connected to each other in the center of the gear axis, and the inputs are made with the possibility, during the rotation of the gear, the simultaneous connection of one of them with the suction cavity, and the other with the pressure cavity allows During its rotation, the gears periodically (once during one revolution of the gear), connect the pressure cavity of the gear pump with its suction cavity. As a result of this, once during one revolution of the gear, a certain volume of liquid is discharged from the pressure chamber into the suction cavity of the pump, and this, in turn, leads to a release of pressure in the piston cavity. As a result, the oscillatory movement of the hydraulic cylinder piston with the rod is achieved.

Thus, the use of a gear pump as a source of hydraulic power on a vibration exciter, in which radial channels are made on the driven gear, periodically connecting the pressure and suction cavities during the rotation of the gear, makes it possible to excite vibrational movements of the hydraulic cylinder piston with the rod, without using two complex structures. hydraulically controlled chokes and a sealing and distribution device. This design of the hydraulic vibration exciter greatly simplifies its design.

The design of the hydraulic vibration exciter is shown in the drawing and includes a gear pump 1 with a driving gear 2 and driven gears 3, suction 4 and pressure 5 cavities, a safety valve 6, a hydraulic cylinder 7, an adjustable throttle 8 and a hydraulic tank 9, while the driven gear 3 is radial channels 10 and 11, which once in one revolution of the gear 3 connect the suction 4 and 5 pressure cavities to each other, and the piston of the hydraulic cylinder 7 is spring-loaded by an elastic element 12 axially towards the piston cavity of the hydraulic cylinder 7, which, in turn, is connected to the pressure cavity 5 gear pump 1 and drain through an adjustable throttle 8.

The radial channels 10 and 11 on the driven gear 3 are made in such a way that when the channel 10 is connected to the suction cavity 4, the channel 11 is connected to the pressure cavity 5. This design of the radial channels 10 and 11 on the driven gear 3 allows for one revolution of the gear 3, connect the suction 4 and pressure 5 cavities with each other and discharge a certain volume of liquid from the pressure cavity 5 into the suction cavity 4, as a result of which there will be a corresponding periodic pressure drop in the pressure cavity 5 of the pump 1 and the piston cavity of the hydraulic cylinder 7.

The hydraulic vibration exciter works as follows.

At the beginning of the operation of the hydraulic vibration exciter, the pressure created by the gear pump 1, partially compressing the elastic element 12, moves the piston with the rod of the hydraulic cylinder 7 upward, and then balances when the elastic resistance of the spring and the force developed by the hydraulic cylinder under the action of the fluid pressure in the piston cavity are equal. Further, as the pressure in the pressure cavity 5 of the gear pump 1 increases, and in the piston cavity of the hydraulic cylinder 7, when the radial channel 10 on the gear 3 coincides with the suction cavity 4, and the radial channel 11 with the pressure cavity 5, due to the discharge of a certain volume of liquid from pressure cavity 5 into the suction cavity 4, there is a drop in pressure in the pressure cavity 5 and the piston cavity of the hydraulic cylinder 7. The drop in fluid pressure in the piston cavity of the hydraulic cylinder 7 leads to the lowering of the piston of the hydraulic cylinder 7 downward under the action of the load on the rod of the hydraulic cylinder 7 and the elastic element 12. Further rotation of the driven gear 3, the connection between the pressure head 5 and the suction 4 cavities through the radial channels 10 and 11 breaks, and this leads to an increase in pressure in the pressure head cavity 5 of the gear pump 1 and the piston cavity of the hydraulic cylinder 7. In this case, the elastic element 12 is compressed and the piston with the rod hydraulic cylinder 7 moves up. Further, when the radial channels 10 and 11 coincide with the pressure 4 and the suction cavities 5, the liquid is released and the corresponding pressure drop, etc. As a result, as the driven gear 3 rotates, the piston with the hydraulic cylinder rod 7 will oscillate with a frequency equal to the rotation frequency of the driven gear 3 of the gear pump 1. In this case, the amplitude of the vibration movement of the piston with the hydraulic cylinder 7 rod can be partially adjusted by changing the throughput adjustable throttle 8.

Thus, the use in the hydraulic vibration exciter of the gear pump 1 on the driven gear 3 of which radial channels 10 and 11 are made, connecting during one revolution the gears, the suction 4 and the pressure 5 cavities of the pump 1 to each other to discharge a certain volume of liquid from the pressure 5 cavity into the suction 4, the cavity allows for the oscillatory (vibration) movement of the piston with the rod of the hydraulic cylinder 7 without using a structurally and technologically complex control system, consisting of two hydraulically controlled throttles with diaphragm locking and regulating elements and a membrane sealing and distribution device.

Claims (1)

A hydraulic vibration exciter containing a pump, a hydraulic cylinder with a spring-loaded piston axially in the direction of the piston cavity, a hydraulic line connecting the piston cavity of the hydraulic cylinder with the hydraulic cylinder drain, and a throttle, characterized in that an adjustable throttle is installed in the hydraulic line connecting the piston cavity of the hydraulic cylinder to the drain, while a gear pump is used as a pump and two radial channels are made on the driven gear of the pump, the outputs of which are interconnected in the center of the gear axis, and the inputs are made with the possibility of simultaneous connection of one of them with the suction cavity, and the other with the pressure cavity for discharging liquid from pressure cavity into the suction and pressure relief in the piston cavity of the hydraulic cylinder.

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