SU800348A1 - Hydraulic percussive-action device - Google Patents

Description

BACKGROUND OF THE INVENTION The invention relates to impact mechanisms for the development of rock formations and frozen soils in the mining and construction industry.

A hydraulic percussion device is known that contains a hammer, a piston with a rod, inside which a spool is installed, periodically connecting the cocking and overflow chambers located under the piston t1.

The closest in technical essence and the achieved result to the proposed one is a hydraulic percussion device containing a cylinder with a charging, overflow and accumulating chambers, a movable firing pin with a piston, a control element consisting of a spool which is housed in a housing made with an annular groove, it forms an end control cavity with it and has an axial and periodically overlapping radial channel, pressure and drain lines 12. The axial and radial channels of the spool are constantly communicating enes with the pressure line.

The disadvantage of the device is that the value of opening the window connecting the charging chamber with the overflow during the working stroke depends on the inertia of the striker. And since the striker moves at increasing speed, and the flow area opened by the spool remains constant, the resistance

o from the displacement of fluid from the erecting chamber increases in proportion to the square of the velocity of its displacement, and accordingly the energy loss to displace the fluid increases.

5 This reduces the efficiency of the device.

In addition, the mating surfaces of the spool of this device are stepped, which complicates the design and increases the labor intensity

0 production.

The purpose of the invention is to increase the efficiency of the device.

This goal is achieved as a result of the axial channel

The 5th spool is permanently communicated with the end face of the control cavity, while the cocking chamber of the device communicates with the pressure line through an annular groove of the body

0

controls, and the spool spool channels have the ability to periodically communicate with the specified annular groove.

The drawing schematically shows a hydraulic device of percussion action, a slit.

The device includes a cylinder 1, a face 2 with a piston 3, cocking 4, a f-valve 5, accumulating 6, and a control valve spool 7.

The spool 7 is made with axial 8 and 9 radial channels and has a j-terminal control space 10, which is periodically sorbed with overflow 5 and charging 4 chambers through channel 11 of cylinder 1,

The axial channel 8 of the spool 7 is permanently connected to the front control cavity 10, and the radial channels 9 are periodically blocked by the inner surface of the control body 12 and are arranged to periodically enter the annular groove 13 of the housing 12, which connects the pressure line 14 to the charging chamber 4. The drain line is indicated by the position 15.

The device works as follows.

When fluid is supplied to the charging chamber 4, the striker 2 moves to the up position. The liquid from the overflow chamber 5 is then forced out to the drain. When the bottom piston 3 of the striker 2 approaches the zone of the channel 11 of the cylinder 1, the frontal cavity 10 of the control is connected to the cock-up chamber 4 and the spool 7 begins to move downward by pressing the liquid on its end.

When the valve 7 is moved, first the radial channels 9 will enter the cavity of the annular groove 13, which will connect the pressure line 14 with the control cavity 10, and then the valve 7 will connect the charging chamber 4 to the overflow chamber 5. The fluid pressure in the charging chamber 4 will also drop 2, under the action of the energy of the storage chamber 6, will begin to move downward. The channel 11 of the cylinder 1 will overlap with this), the surface of the piston 3. i .. As the speed of the striker 2 increases, the pressure in the charging chamber 4 will start to increase, since the value of the initial opening by the valve 7 of the flow area

becomes inadequate. This pressure through channels 9 and 8 of spool 7 i will shift it down, which will increase the flow area connecting the charging chamber 4 to the overflow chamber 5, i.e. here, the flow area automatically increases as the flow rate through it increases.

In the lower position of the striker 2, the channel 11 of the cylinder 1 communicates with the overflow

chamber 5, and the fluid pressure in the control cavity 10 will decrease, allowing the spool 7 to return to its original position. Then the cycle repeats.

Thus, the spool design provides automatic control of the flow area connecting the charging chamber to the overflow, which maintains the pressure drop at the same minimum level. it

increases the efficiency of the mechanism. In addition, since the mating surfaces of the spool are of the same diameter, this reduces the labor intensity of manufacturing not only the spool, but also

And his body.

Claims (2)

1. USSR author's certificate 397598, cl. E 21 C 3/20, 1970. 2. Authorskse certificate of the USSR 564415, cl. E 21 C 3/20, 1975.