SU768958A1 - Hydraulic percussion mechanism - Google Patents

Description

Before starting the operation of the mechanism, and thus eliminating both the start-up and the operation time, the mechanism-destroying blows of the striker body to the front and rear end positions, as well as a steady start of the impact mechanism at any position of its moving elements is ensured.

The invention is illustrated in the drawing, which shows a diagram of a hydraulic shock mechanism.

The percussion mechanism according to the invention includes a housing 1 in which the head 2 is located, which interacts with the idling plungers 3 and the working stroke plunger 4 located in cavities 5 and 6. The plunger cavities 5 and 6 are constantly connected via channels 7 and 8 respectively. cavities 9 and 10 hydraulic springs. The cavity 6 of the plunger 4 working stroke through the channel 11 and the valve 12 of the hydraulic type communicates with the pressure line 13, and the cavities 5 of the plungers 3 idle are communicated with the valve 12 through the channel 14 and the controlled channel 15. The channels I and 14, which communicate the plunger cavities 6 and 5 with a pressure line 13 and a controllable channel 15, are located at the extreme positions of the plungers.

The cavity of the brake hydraulic spring 9 communicates with the control channel 15 of the hydraulic distributor 12 via channel 16 with the return channel 17 installed on it, and the cavity of the hydraulic brake piston 10 communicates with the discharge line 13 of channel 18, in which line the check valve 19 is turned on.

In the pressure line 13 and the drain 20 are installed hydro. Accumulators 21 and 22.

The percussion mechanism has a working tool 23. The grooves 24 are made on the surface of the hydraulic distributor.

Works hydraulic shock mechanism as follows.

At steady state, the cavities of the brake hydraulic springs 9 and 10 are completely filled with liquid, and the tool 23 (by placing it in the material to be destroyed) is moved to the extreme right position (according to the drawing). The drawing shows the position of the striker 2 at the moment of striking the tool 23. At this time, the cavities 5 of the idle plungers 3 through the controlled channel 15 of the hydraulic distributor 12 are connected to the drain line 20. The fluid pressure in the cavities 5 is the same as in the drain highways 20.

During the subsequent rotation of the hydraulic distributor 12, the cavity 5 of the plungers 3 idling through the channel 14, the controlled channel 15 and the grooves 24 communicate with the pressure line 13. Due to the fact that the forces developed by the idlers of the plunger 3 are more powerful, we develop the 4th stroke with 4 plugs (the total cross-sectional area of the idle plungers is larger than the cross-sectional area of the working plunger), the firing pin 2 moves to the right (according to the drawing), making an idling speed. When this plunger 4 fluid from the cavity 6 is forced (under pressure) into the pressure line 13.

At the end of the idle stroke, the cavities 5 of the plungers 3 are connected by means of the hydraulic distributor 12 to the drain 20, the firing pin 2 is braked by the action of the plunger 4, stops and moves to the left (according to the drawing), making a working stroke, before the collision with the tool 23.

Next, nickel is repeated.

The ratio of forces developed by the workers 4 and idle 5 stroke plungers during the period of time during which the cavities 5 of the idle plungers 3 communicate with the pressure line 13 is calculated so that in the established mode the channels 14 and 11 of the idle plungers 3 and the working stroke plunger 4 do not overlap and brake hydraulic springs 9 and 10 do not enter the work.

By reducing the frequency of impacts below the minimum value designed for this mechanism, the firing pin 2 for a period of time until the iolost 5 of the plungers 3 are communicated by the hydraulic distributor 12 to the pressure line 13, has time to pass the distance at which the plunger 4 blocks the potial 11, the fluid in the hydraulic spring 10 is removed , the pressure increases dramatically, and the striker 2 is braked.

In the event that tool 23 comes out of the motive with destructible material, it moves to the left, and the striker 2, makes a working stroke, goes beyond the usual one and the idle plungers 3 overlap the kaial 14, the fluid in the hydraulic spring 9 is compressed, the pressure increases and the striker 2 is braked.

At start-up, when the brake hydraulic springs 9 and 10 are not filled with fluid, the mechanism works as follows.

Claims (2)

At the initial moment from the pressure line 13, the liquid enters only the cavity 6 of the plunger 4 of the working stroke and hydraulic circuit 10. At the subsequent moment, the rotating valve 12 communicates the controlled channel 16 with the pressure line 13, and the brake spring 9 and the mechanism goes to normal operation. If at the moment of launching the mechanism, the plungers 3 and 4 will be in such a position when they overlap the channels 11 and 14, the filling of the cavities of the hydraulic circle 9 and 10 will occur through the channels 16 and 18 and the return channels 17 and 19. Until complete filling of the hydraulic springs 9 and 10, the pressure of the fluid in the channels and cavities of the percussion mechanism cannot rise to working pressure and the mechanism cannot start operation. Thus, under options for the mode and launch of the proposed mechanism, the striker does not strike the mechanism body and makes sure that it starts. Claims of the Invention Hydraulic impact mechanism, including a housing, a distributor, a firing pin, driven by the working and idling plungers, which are installed in cavities communicated with the supercharging line and with hydraulic brake springs, and a working tool, characterized in that increase the operational reliability of the mechanism, each hydraulic spring is additionally connected to the discharge line, with check valves mounted in the communication channels. Sources of information taken into account in the examination: 1.Basht T.M. Mashchinostroitelnaya hydraulics, M., Mashchinostroenie, 1971, p. 453. 2. USSR author's certificate number 447506, cl. Е 21С 3/20, 12.01.71.