SU1051261A1 - Percussive hydraulic mechanism - Google Patents

Abstract

D. THE HYDRAULIC MECHANISM OF SHOCK ACTION, containing the 1st casing, the energy accumulator, the cocking chamber, the firing pin, the stepped valve that forms with the casing an overflow chamber, and with a striker - a restrictive cavity, which is periodically connected to the overflow cage, characterized by In order to increase operational reliability, the overflow chamber is made with the possibility of periodic co-operation with a restrictive cavity through the annular gap between the inner surface of the clan and the body of the striker, while the HNveer mechanism atny valve which is mounted in the annular gap. 2. A mechanism according to claim 1, characterized in that the check valve is designed as an elastic cuff. (L

Description

The invention relates to construction and road engineering and can be used as a working body of machines designed for the development of frozen and rocky soils, crushing of non- ₅ dimensions, as well as soil compaction.

Known hydraulic shock mechanism, comprising a housing, an energy accumulator, a striker, cocking chamber and a step valve [I].

The disadvantage of this device is the low ¹⁰ efficiency, which is explained by the high resistance arising during the working stroke of the striker.

Closest to the proposed one is a hydraulic mechanism of impact ₁₅ , comprising a housing, an energy accumulator, a cocking chamber, a striker, a step valve that forms an overflow chamber with the housing, and with a striker a restrictive cavity, which periodically communicates with the overflow chamber [2]. 20

The disadvantage of this mechanism is the low operational reliability due to the presence of axial and radial channels in the striker reducing its strength.

The purpose of the invention is to increase the oxide .... athetical reliability.

The goal is achieved by that. The yoke hydraulic shock mechanism comprises a housing, an energy accumulator, a cocking chamber, a striker, a step valve that forms an overflow chamber 39 with the housing, and with a striker a restriction cavity which is periodically in communication with the overflow chamber, and the overflow chamber is arranged to periodically communicate with a restrictive cavity through an annular gap between the inner surface of the valve and the body of the striker, while the mechanism has a check valve that is installed in the annular gap.

In addition, the check valve is made in the form of an elastic cuff.

The drawing shows a diagram of the proposed device.

The hydraulic mechanism of the shock action comprises a housing 1 with an energy accumulator 2 and a cocking chamber 3, in which 45 the striker 4 and the lower part of the step valve 5 are located, the surface of which forms the restriction cavity 6 and the gap 7 with the check valve 8 with the body of the striker 4, for example an elastic cuff, and the check valve freely passes fluid into the restriction cavity 6 of the step valve 5 and prevents its return. The outer surface of the valve 5 forms an overflow chamber 9 with the housing 1. In the step valve 5, channels 10 and 11 are made.

The mechanism works as follows.

The liquid entering the cocking chamber 3 acts on the active area of the striker 4 and valve 5 and, overcoming the force of the energy accumulator 2, moves them to the upper position. In this case, the liquid from the chamber 9 is forced into the outlet line 14 through the channel 12, and then the channel 12 is blocked by the valve 5. Further movement of the hammer 4 and the valve 5 to the upper position leads to an increase in pressure in the chamber 9, and through the check valve 8 --- --- in the cavity 6, and to the separation of the striker with the valve m 5 as a result of their mutual movement. Under the influence of liquid. the striker 4 coming from the supply line 15 starts to move downward, increasing the degree of opening of the striker 4 with valve 5. Following the striker 4, valve 5 starts to move under the action of energy accumulator 2. When channel 12 is opened, the fluid entering the charging chamber 3 will flow through the channel 11 into the chamber 9 and through the channel 12 - into the discharge line 14, and the opening of the striker 4 with the valve 5 will stop. There is an accelerated joint movement of the striker 4 and the valve under the action of the energy accumulator 2 from the upper position to the lower. At the same time, the liquid locked in the restriction cavity 6 does not allow the valve 5 to connect to the striker 4. In the lower position, when striking the striker 4 with an instrument (channel not shown}), the channel K connects the cavity with the chamber 9 and through the channel 12 with the discharge line 14. Under the action of the energy accumulator 2, the valve 5 displaces the liquid, from the cavity 6 to the discharge line 1'4 and with its lower part is connected to the striker 4. Next, the cycle repeats.

The application of the proposed hydraulic mechanism of shock action will improve operational reliability by eliminating radial and axial drilling (stress concentrates) in the body of the striker.

Claims (2)

1. HYDRAULIC MECHANISM OF SHOCK ACTION, comprising a housing, an energy accumulator, a cocking chamber, a striker, a stepped valve that forms an overflow chamber with the housing, and with a striker, a restriction cavity which is periodically communicated with the overflow chamber, characterized in that, for the purpose of increase operational reliability, the overflow chamber is made with the possibility of periodic communication with the restrictive cavity through the annular gap between the inner surface of the valve and the body of the hammer, while the mechanism has reverse valve that is mounted in the annular gap. 2. The mechanism by π. 1, characterized in that the check valve is made in the form of an elastic cuff.