SU1751276A1 - Working member of percussion ripper - Google Patents

Abstract

The working body includes a housing 1 with a hydraulic cylinder 1L, the rod 3 of which is connected to the block 4 and the rope 5 of the lifting mechanism. The cavity 6 is communicated by hydroline 7 through a check valve 8 to the control valve 9. The second valve control valve 9 by hydraulic valve 10 communicates with the hydraulic accumulator 11. Through the valve 12, the hydraulic accumulator 11 communicates with the drain, and through the hydraulic valve 13 - with a detachable coupling 14. The third hydraulic distributor 9 by means of a hydroline 15 communicates with a cavity 16 of horizontal hydraulic cylinders 17 and 18 for driving the teeth 19 and 20. The pistons are spring-loaded with springs 21 and 22. The hydraulic distributor 9 has a spring-loaded spool and a spring control mechanism 23. Cavities 6 and 16 are communicated through a controlled valve 25, the control chambers of which with hydroline 26 are connected to cavity 6. When the body 1 hits the ground, the weight 24 switches the valve of the hydraulic distributor 9, the cavity 6 connects to the hydraulic accumulator 11. When braking the housing 1, the hydraulic distributor 9 is converted into the initial position, with the pistons of the hydraulic cylinders 17 and 18 pushing the teeth 19 and 20 out of the limits of the housing 1. When recessed, the teeth 19 and 20 return to the initial position. The hydroaccumulator 11 is charged from the base machine. 1 il.

Description

The invention relates to earth moving machinery and can be used in impact looseners when loosening frozen and solid soils.

A working body of a ripper of a lifting-impact action is known, comprising a body of a wedge-shaped form with a loading unit mounted on it and scaling teeth.

A disadvantage of the known working body is the low efficiency of loosening. This is due to the fact that the chipping teeth are located vertically and carry out the grinding of already cleaved soil, but do not increase the cleavage zone, which limits productivity and increases energy consumption.

The closest to the invention in its technical essence and the achieved result is the lifting and impacting action of the cultivator, including a wedge-shaped body with vertical hydraulic cylinders located inside, the rod of which is connected to the cargo block and horizontal hydraulic cylinders, the pistons of which are rigidly connected with retractable teeth. , spring-loaded relative to the body.

However, in the known device, the chipping teeth are arranged horizontally, which makes it possible to increase the cleavage zone of the soil and to use the force of raising the working body to detach the soil from the array. At the same time, the known device has drawbacks that reduce the effectiveness of its use. This is due to the fact that when the working tool strikes the ground, the piston of the vertical hydraulic cylinder is lowered under the action of the inertia forces of the cargo block and pushes out the cutting teeth through the working fluid. The scaling teeth move out simultaneously with the deepening of the wedge-shaped body and this creates additional resistance, overcoming of which it is necessary to expend additional energy. In addition, the premature extension of the shear teeth significantly reduces the amount of penetration of the wedge-shaped body, and therefore reduces the cleavage zone and the performance of the work.

The aim of the invention is to increase the productivity and reduce the energy consumption of loosening.

The goal is achieved by the fact that the working body of the cultivator of lifting and impacting action, including a wedge-shaped body with a vertical hydraulic cylinder located inside, the rod of which is connected to the cargo block and the horizontal hydraulic cylinders, the pistons of which are rigidly connected to the sliding chipping teeth springed relative to the body hydroaccumulator. controlled hydrovalves, non-return valve, detachable coupling and two-way control valve, the spool of which is spring-loaded and supplied inertial load control, wherein

0 the piston cavity of the vertical hydraulic cylinder is communicated through a non-return valve with the first line of the hydraulic distributor, the second line of which is connected to the hydraulic accumulator, and a third line - with the piston

5 cavities of horizontal hydraulic cylinders communicated with the piston cavity of a vertical hydraulic cylinder through a controlled hydraulic valve, the control chamber of which communicates with the said cavity

0 of the vertical hydraulic cylinder, the hydroaccumulator communicating with the drain through the valve and with the detachable coupling through a controlled hydraulic valve, and the valve is configured to communicate

5 hydroaccumulators with a piston cavity of a vertical hydraulic cylinder in one position and communication with piston cavities of horizontal hydraulic cylinders in its other position.

0 The drawing shows the working body loosening lifting and impacting.

The working body contains a wedge-shaped body 1 with a built-in vertical hydraulic cylinder 2 of unilateral action,

5 the piston of which through the rod 3 is connected with the cargo block 4 attached to the cable 5 of the lifting mechanism. Hydraulic cavity 6 of hydraulic cylinder 2 is communicated by hydroline 7 through a check valve 8 to a control valve 9, the second line of which by hydraulic line 10 communicates with hydraulic accumulator 11. Hydraulic accumulator 11 communicates through valve 12 with drain and through hydraulic valve 13 with detachable coupling

5 14. A third of the line of the hydraulic distributor 9 with the hydroline 15 communicates with the hydraulic cavity 16 horizontal integrated hydraulic cylinders 17 and 18 of the drive of the sliding shear teeth 19 and 20. The cutting teeth 19 and 20 are rigidly attached to the pistons of the hydraulic cylinders 17 and 18, which are spring loaded by springs 21 and 22 The valve 9 is made with a spring-loaded valve and with a mechanism 23

5 controls the elastic force of the spring, for example a screw, and has an inertial control mechanism in the form of a weight 24 connected to the spool. The hydraulic cavities b and 16 communicate with each other through a controllable valve 25 having a control chamber connected by a hydraulic line 26 of the control to the hydraulic cavity 6 of the hydraulic cylinder 2. All elements of the operating member are integrated into the wedge-shaped body 1.

The working body of the ripper operates as follows.

In the initial position shown in the drawing, the working member is held by the cable 5 of the lifting mechanism in the upper position. The control valve 9 is pressed upward. The hydroaccumulator 11 is charged at a predetermined pressure value, which, however, is not sufficient to overcome the force of the springs 21, 22 and advance the shear teeth 19 and 20, therefore, they are pressed by the springs in the initial positions. The hydraulic valve 25 is closed, because in it, the control chamber maintains the charging pressure of the hydraulic accumulator 11.

When the working body falls, the wedge-shaped body 1 interacts with the ground and begins to slow down due to the resistance of the ground. The force of inertia of the weight 24 arising when slowing down overcomes the spring force and switches down the valve of the hydraulic distributor 9, which communicates the hydraulic cavity 6 of the hydraulic cylinder 2 through the non-return valve 8 with the hydraulic accumulator 11. The piston of the hydraulic cylinder 2 under the force of the inertia of the cargo unit 4 lowers and displaces the working fluid from cavity 6 into the hydroaccumulator 11. As the body 1 is buried in the ground, the slowing down of its movement tends to zero and, accordingly, the inertia force of the weight 24 tends to zero. When the force decreases and power supply 24 up to size; Corresponding to the almost complete stop of the housing 1, the spring raises the valve of the hydraulic distributor 9 upwards to the initial position in which it communicates the hydraulic accumulator 11 with the cavity of 16 hydraulic cylinders 17 and 18. The pressure of the working fluid from the hydraulic accumulator 11 overcomes the force of the springs 21 , 22 and pushing the chipping teeth 19, 20 beyond the limits of the wedge-shaped housing 1, which facilitates the cleavage of the soil.

To lift the tool, the lift mechanism is actuated, which through the cable 5 acts on the cargo block 4 and the piston of the hydraulic cylinder 2 connected to it by the rod 3. When the piston is lifted in the hydraulic cavity of the hydraulic valve 25 connected to it, the pressure of the working fluid decreases. Therefore, the hydraulic valve 25 opens and communicates the cavity b with the hydroaccumulator 11 through

the hydraulic valve 9 and the hydraulic line 10. Having reached the upper position, the piston of the hydraulic cylinder 2 abuts against the cover of the housing 1 and transmits the lifting force to it

the cable 5. The lifting force of the wedge-shaped body 1 is deepened, and the shearing teeth 19 and 20 provide the separation of the soil from the array. After the separation of the ground, the pinching of the cleaving teeth 19, 20 is stopped and they return to their original position under the action of the springs 21, 22. The working fluid from the cavity 16 of the hydraulic cylinders 17, 18 is displaced into the hydraulic accumulator 11 through the hydraulic lines 15, 10 through

valve 9. Then the duty cycle is repeated.

The charging of the hydroaccumulator 11 by a predetermined amount, set by the hydraulic valve 13 and the valve 12, is carried out

from the hydraulic system of the base machine through a flexible pipe, which is connected through the sleeve 14. The switching moment of the hydraulic distributor 9 is controlled by the mechanism 23, and the moment of switching on the hydraulic valve 25 by the corresponding tightening of its spring. All of these adjustments are made depending on the operating conditions (type, composition and condition of the soil being developed).

The positive effect obtained by applying the proposed tool is expressed in increased efficiency by increasing productivity and reducing energy costs. it

This is achieved by the fact that the shearing teeth are extended after the working body is fully sunk to the maximum. In the prototype, the chipping teeth are advanced during the penetration of the tool, which reduces the depth of penetration, creates additional resistance and increases the power consumption of loosening.

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Claims (1)

Invention Formula The working body of the ripper of lifting and impact action, which includes a wedge-shaped body with inside, a vertical hydraulic cylinder, the rod of which is connected to the cargo block and horizontal hydraulic cylinders, the pistons of which are rigidly connected to the sliding chipping teeth, which are spring-loaded relative to the housing, characterized in that, in order to increase productivity and reduce the power consumption of loosening, it is equipped with a hydraulic accumulator, controlled hydraulic valves, a check valve, a detachable coupling and two-position the hydraulic valve, the spool of which is in communication with the cavity, is spring-loaded and equipped with a vertical hydraulic cylinder, with hydraulic inertia control, the piston accumulator communicating with the drain through the vertical cylinder of the hydraulic cylinder and the plug-in coupling through the controller through the return valve, a hydraulic valve, and the hydraulic distribution valve, the first line of the hydraulic distributor, the second one is configured to communicate the line of which is connected to the hydraulic accumulator with a piston cavity, and a third line - with piston vertical hydraulic cylinders in one cavity of horizontal hydraulic cylinders and communication with piston cavities communicated with piston cavities of 10 horizontal hydraulic cylinders - in a vertical hydraulic cylinder through control of its other position, le control valve