RU38814U1 - BREAKER - Google Patents

Abstract

The utility model relates to road and construction vehicles and is designed to crack road surfaces, to destroy concrete, reinforced concrete and brick structures and structures, for loosening frozen soils. The positive effect achieved by the utility model is to provide stable parameters of the hydraulic hammer, ensuring the reliability of its operation. The hydraulic hammer contains a percussion mechanism, the body of which is composed of interconnected support-guide elements 1, 2, 3 and a sleeve 4. In the support-guide elements 1, 2, 3, a piston-striker 5 with a belt 6 is installed with the possibility of reciprocating the shock mechanism and the piston-striker 5 form the cavity of the platoon 7, drain 8 and the pneumatic accumulator 9. On the body of the shock mechanism is mounted a control unit 12 having a spool cavity 15 with a plunger 16 and channels 18, 19, 11 for alternately communicating the cavity of the platoon 7 with a pressure head line 20 and discharge cavity 8. The piston-striker 5 is made with a girdle 6, which is equipped with at least two annular grooves 14. The plunger 16 is also equipped with at least two annular grooves 17. The housing of the percussion mechanism with a control unit 12 and the axle box 21 is installed in the protective casing 23, while the housing of the percussion mechanism and the protective casing 23 are separated by an air cavity 24. The protective casing 23 is rigidly fixed to the axle box 21. The fastening element 25 fixes the locking pin 26 of the interchangeable tool 22 fixed in the axle box 21.

Description

The utility model relates to road and construction vehicles and is designed to crack road surfaces, to destroy concrete, reinforced concrete and brick structures and structures, for loosening frozen soils.

Known hydraulic hammer (RF certificate for utility model No. 6579, CL 6 E 21 C 3/20, 1997, prototype), comprising a housing with channels, a piston-striker with a belt installed in it, while the supporting- a guide sleeve that forms a drainage cavity with the piston-striker belt, and at least two support-guide elements are installed in the grooves of the support-guide sleeve, and a spacer sleeve, the groove of which forms a platoon cavity with the piston-striker belt. In addition, the hydraulic hammer contains a control unit mounted on the housing and connected by channels with a platoon and drain cavity, a pressure and drain line, a main gas cavity communicating with an additional gas cavity formed by a control and charging unit integrated into the control unit. The housing with the control unit and the axle box are installed in a protective casing. A disadvantage of the known design of the hydraulic hammer is the low reliability of its operation due to the influence of deformations on the parts of the shock mechanism, as a result of which the centering of the piston-hammer and plunger is disrupted, causing the fluid to flow from one cavity to another, resulting in instability of the hydraulic hammer operation parameters. In addition, external influences on the impact mechanism (bending loads, etc.) cause rapid wear of the mating surfaces.

A large number of elements in this design also leads to a decrease in the reliability and maintainability of the product as a whole.

The problem solved by the utility model is to increase the reliability of the hydraulic hammer.

The problem is solved as follows. In a hydraulic hammer containing a percussion mechanism, the body and the piston of which is the head form the platoon, drain and pneumatic accumulator cavities, a control unit mounted on the body and having a spool cavity with a plunger and channels for alternately communicating the platoon cavity with the pressure line and the drain cavity, an axle box with interchangeable tool, while the housing with the control unit and the axle box are installed in a protective casing, and the piston-striker is made with a belt, the body of the percussion mechanism and the protective casing are separated

in this case, the housing of the percussion mechanism is made in the form of support-guiding elements interconnected, and the protective casing is rigidly fixed to the axle box by means of fasteners, in addition, the belt of the piston striker and the plunger are equipped with at least two annular grooves each, and one of the fasteners of the protective casing simultaneously fixes the locking finger of the interchangeable tool installed in the axle box.

The separation of the shock mechanism housing and the protective casing by the air cavity and the rigid installation of the protective casing on the axle box provide isolation of the shock mechanism from external influences (bending loads, etc.), which excludes deformation of its parts. The protective cover and axle box with this design of the hydraulic hammer take on all external loads and forces from the base machine. As a result of this circumstance, the stability of the operating parameters of the hydraulic hammer, which characterizes its reliable operation, is ensured, the wear of the mating surfaces is reduced.

The stability of the hydraulic hammer operation parameters is also due to a decrease in the friction forces when the plunger and the striking piston are stragging.

The supply of the plunger and the striking piston with annular grooves is aimed at reducing the friction forces during straining by reducing the unbalanced radial forces of the fluid pressure on the plunger and the piston striker. It has been experimentally established that if there is one annular groove on the plunger or piston-striker, the friction of both rest and movement can decrease from 100% to 40%, with seven grooves, to 2.7-3%. Therefore, the plunger and piston girdle - the hammer in the claimed hydraulic hammer is equipped with several annular grooves each.

In addition to reducing frictional forces when straining the plunger and piston-striker, the presence of annular grooves helps to maintain their concentric position in the supporting-guide elements, for example, a sleeve, in which there is less fluid leakage than with an eccentric. The latter is also due to equalization of pressure in the radial clearance.

The execution of the housing of the percussion mechanism in the form of support-guiding elements interconnected, as well as the fastening element of the protective casing at the same time two functions — attaching the protective casing to the axle box and fixing the locking finger of the interchangeable hammer tool, reduces the number of structural elements of the declared hydraulic hammer, thereby increasing reliability and maintainability of the product as a whole.

The claimed utility model is illustrated in the drawing.

In FIG. presents a general view of the hydraulic hammer.

The hydraulic hammer contains a percussion mechanism, the body of which is composed of interconnected support-guide elements 1, 2 and 3 and a sleeve 4. In the support-guides 1, 2, 3 with the possibility of reciprocating movement along the axis of the installed piston-striker 5, equipped with a belt 6 .

The piston-striker 5 divides the body of the percussion mechanism into a platoon cavity 7 isolated from each other, a discharge cavity 8 and a cavity

pneumatic accumulator 9, limited by the sleeve 4 and filled with compressed gas.

The platoon cavity 7 is formed by an annular groove 10 of the support-guide element 1 and the girdle 6 of the piston-striker 5 and communicates through the overflow channel 11 with the control unit 12.

The supporting-guide element 3 forms with the piston-striker 5 a discharge cavity 8, limited by the belt 6. The cavity of the pneumatic accumulator 9 is located above the piston-striker 5 with the possibility of communication with an additional gas cavity 13 located in the upper end part of the control unit 12.

At least 6 annular grooves 14 are made on the belt 6 of the piston-striker 5, which during operation of the hydraulic hammer center the piston-striker 5 and reduce the flow of working fluid from one cavity to another.

The control unit 12 is mounted on a support-guide element 1 of the housing of the percussion mechanism and has a spool cavity 15 with a plunger 16 made with at least two annular grooves 17 that center the plunger 16 during operation of the hydraulic hammer.

The spool cavity 15 of the control unit 12 of the channels 18 and 19 is connected to the drain cavity 8. The control unit 12 through the pressure line 20 is connected to the overflow channel 11, through which the platoon cavity 7 is connected to the spool cavity 15.

In the lower part of the guide 1 of the housing of the percussion mechanism mounted axle box 21 with a replaceable working tool 22.

The housing of the percussion mechanism with the control unit 12 and the axle box 21 are installed in the protective casing 23, and the housing of the percussion mechanism and the protective casing 23 are separated by an air cavity 24. The protective casing 23 is rigidly fixed to the axle box 21 by means of fasteners 25, one of which simultaneously fixes

the locking finger 26 of the interchangeable tool 22 installed in the axle box 21.

The hydraulic hammer works as follows. Gas is pumped into the additional gas cavity 13 and into the cavity of the pneumatic accumulator 9, where it is constantly located. The working fluid, flowing through the pressure line 20 through the overflow channel 11 to the platoon cavity 7, moves the piston-striker 5 upward, compressing the gas in the cavity of the pneumatic accumulator 9. At the same time, the liquid is displaced from the discharge cavity 8 through the channel 18 into the drain line 27.

At the end of the platoon, the belt 6 of the striking piston 5 opens a channel 19, through which liquid from the pressure line 20 is supplied to the spool cavity 15 under the end face of the plunger 16. After that, the pressure in the platoon cavities 7 and drain 8 is equalized, and the piston striker 5 under the action of the compressed gas in the pneumatic accumulator 9 begins to accelerate downward.

At the end of the stroke, a blow is made to the working tool 22, while the belt 6 of the striking piston 5 opens the channel 19, and under the action of compressed gas, the plunger 16 returns to its original position. Next, the cycle repeats.

The claimed hydraulic hammer is manufactured and tested. It will find its application as replaceable working equipment for road construction machinery.

Claims (2)

1. A hydraulic hammer containing a percussion mechanism, the body and the piston of which is the head form the platoon, drain and pneumatic accumulator cavities, a control unit mounted on the body and having a spool cavity with a plunger and channels for alternately communicating the platoon cavity with the pressure line and the drain cavity, with interchangeable tool, while the housing with the control unit and the axle box are installed in a protective casing, and the piston-striker is made with a belt, characterized in that the housing of the percussion mechanism and the protective casing are separated by air th cavity, while the body of the percussion mechanism is made in the form of support-guiding elements interconnected, and the protective casing is rigidly fixed to the axle box by means of fasteners, in addition, the belt of the piston striker and the plunger are equipped with at least two annular grooves each. 2. The hydraulic hammer according to claim 1, characterized in that one of the fasteners of the protective casing simultaneously fixes the locking finger of the interchangeable tool installed in the axle box.