SU1571235A1 - Percussion action device - Google Patents

Abstract

The invention relates to the mining industry and is intended for the destruction of rocks and artificial materials. The goal is to increase the performance of the device by increasing the frequency of impacts. The device comprises a housing 1, a main hammer (OB) 4 with an inertial element 5 and additional grooves and a boring, an additional die (DB) 6, a spool 3 and a tool 2. Element 5 forms with the housing 1 cavities 11, 12 working and reverse passages and cavity energy storage 13. Additional bore OB 4 forms with the body 1 an additional chamber 9. In an additional bore, ABOUT 4, DB 6 is installed and spring-loaded with a spring 7 relative to OB 4. The surface of the additional boring forms a piston chamber 8 with DB 6 connected to the chamber 9 communicating with the second pressure reservoir 24. When cocked torus ON 4 under the action of the working fluid to be expelled from the chamber 9 into the chamber 8, DB 6 performs a work stroke. With the working stroke ABOUT 4 under the action of the spring, 7 dB 6 is cocked. The pressure pulses generated in the force chambers OB and DB 6 contribute to better insertion of DB 6 and OB 4, respectively, with tool 2 into the material being processed. 1 hp f-ly, 1 ill.

Description

The invention relates to the mining industry, and in particular to shock devices for the destruction of rocks and artificial materials.

The purpose of the invention is to increase the productivity of the device by increasing the frequency of shock.

The drawing shows a device.

The impact device comprises a housing 1, (a tool 2 and an axial spool 3 and a main spike 4 axially located in the body, in the bore of which there is an inertial element 5, and an additional spike 6, spring-loaded with a spring 7, is installed in the extra bore. The spike 6 forms an additional bore with the surface the piston chamber 8, in communication with the additional chamber 9, formed by the housing 1 and the additional groove of the hammer 4, through the channel 10.

The firing pin 4 forms with the housing 1 the cavities of the working stroke 11, the return stroke 12 and the energy store 13, and with the slide valve 3 - control chambers 14 and 15. The firing pin 4 forms, with the inertial element 5, the control chambers 16 and 17 communicated by the channels 18 and 19 with the chambers 14 and 15. The spool 3 is made with a drain 20 and a pressure head 21 grooves, and the housing with channels 22 and 23. A hydraulic accumulator 24 is connected to the chamber 9 , i.e. the camera is made with water. The cavity 11 of the working stroke is constantly connected to the pressure line 25 through the channel 23 and the groove 21. The drain groove 20 is constantly connected to the drain pipe 26. The working area of the striker 4 in the cavity 11 of the working stroke is less than in the cavity of the reverse stroke.

The device operates as follows.

The drawing shows the initial ₄ position of the device. In this case, the control chambers 14-17 and the chambers 8 and 9 are filled with liquid. We first consider the operation of the device in the destruction of absolutely ”solid material, t, e. the amount of penetration of tool 2 into the processed material is infinitesimal with each impact. Before applying the pressure, the housing 1 is pushed onto the tool 2 until it stops under the influence of | the compression cylinder or operator’s hands (not shown), partially compressing the energy accumulator 13. Since the hammer 4 is stationary, and the housing 1 with the inlet 3 moves to the right, the inertial element 5 moves to the right due to the displacement of fluid from the chamber 14 into the chamber 16 through the channel 18 and due to the displacement of liquid Yu from the chamber 17 into the chamber 15 through the channel

19. In this case, the firing pin 6 moves to the right, partially compressing the spring 7, due to the displacement of fluid from the chamber 9 into the chamber 8 through the channel 10. The liquid from the chamber 9 also partially enters the hydraulic accumulator 24. As soon as the housing 1 abuts, the inertial element stops.

Further, when the pressure 2Q enters the cavity 11 of the working stroke and into the cavity 12 of the reverse stroke through the pressure pipe 25, the pressure channel 21 and the channels 23 and 22, the striker 4 begins to move to the left, continuing.

compress energy store 13. In this case, the inertial element is stationary.

At the end of its return stroke, the firing pin 4 strikes the inertial 3Q element 5, and the firing pin 6 hits the instrument.

In this case, the firing pin 6 transfers its kinetic energy to the tool, and the firing pin 4 transfers part of its kinetic energy to the inertial element 5, which then spends it to switch the spool 3 to the right, creating a pressure differential in chambers 14 and 15, and the other part of the energy is spent on energy storage 13 and hydraulic accumulator 4Q 24. As soon as the spool 3 switches to the right, the inertia element 5 stops, and the return cavity 12 is disconnected from the pressure and communicates with the drain line 45 26 through channel 22 and drain channel 20. In this case, 4 begins to accelerate to the right due to the pressure of the pressure in the cavity 11 of the working stroke, the efforts of the energy storage device 13 and the pressure in the chamber 9 created by the spring 7 and the accumulator 24. The inertial element 5 remains stationary, and the liquid from the chamber 16 flows into the chamber 14 through the channel 18, and from chamber 13 to chamber 17 through channel 19. The striker 6 partially moves to the left under the action of the spring 7, creating a force of fluid continuity in the power chambers 9 and 8.

1571235 ⁶

At the end of its acceleration to the right, the firing pin 4 strikes both the tool 2 and the inertial element 5. At the same time, the inertial element 5 creates a pressure differential in chambers 15 and 14, as a result of which the spool switches to the left, and after switching the spool, the inertial element 5 stops by liquid in the power chamber 8, the energy of which is transferred to the accumulator 24, after which the movement of the first striker 4 to the left begins.

If, upon impact of the first striker 4, a partial introduction of tool 2 into the material to be processed, then due to the introduction of tool 2 into the material during impact, the striker 4 moves to the right with some lag from the inertial element. Switching of the spool 3 is partly due to the movement of the end face of the hammer 4 in the control chamber 15 by the amount of tool penetration. At the same time, the pressure impulse created in the power chambers by the striker 6 contributes to the better penetration of the striker 4 with the tool 2 into the processed material.

If, when the striker 6 hits the tool 2, penetration into the material takes place, then the spool 3 is switched to the right by partially moving the end of the striker 4 in the control chamber 14 by the amount of penetration of the tool 2, and the pressure pulse created in the power chambers by the striker 4 contributes to better penetration striker 6 with tool 2 in the processed material. The lower the hardness value of the processed material, the greater the penetration rate of the tool 2 together with the striking striker 5 and the greater the switching of the spool due to the movement of the end of the striker 4 in the corresponding control chamber. After each impact, the housing 1 moves to the right by the amount of penetration due to the pressure of the operator or the handle of the excavator (not shown).

Claims (1)

U claims 1. The percussion device, comprising a housing in which the spool and the main firing pin with an inertial element are placed coaxially, forming an energy storage cavity, working and return strokes with the housing, a tool, characterized in that, in order to increase 25 device performance by increasing the frequency strokes, it is equipped with an additional striker, and the main striker is made with an additional groove forming an additional chamber with the body ed, and with an additional boring in which an additional striker is installed, the piston chamber that communicates with the additional chamber, which forms with the surface of the additional bore. 35 2. The device pop. 1, excellent: characterized in that it has a hydraulic accumulator, which is connected to an additional chamber, and the additional striker is spring-loaded relative to the main striker.