RU1785888C - Pneumatic shock machine - Google Patents

Abstract

Usage: in mechanical engineering. The inventive pneumatic impact machine consists of a casing 1 with a handle 2, a coupling made in the form of a glass 7 with holes, air of the inlet rod 15 and a hammer made in the form of a pneumatic cylinder 4. At the bottom of the glass there is an air distribution chamber 8, on a collar 9 is made with a collar 9 with radial holes 10. The stem is mounted in the air distribution chamber 8 with the possibility of limited axial movement. The pneumocyclic case 11 is mounted with the possibility of periodic communication of the cavities with the atmosphere through the radial openings of the glass. 1 s.p. f-ly, 2 ill.

Description

The invention relates to pneumatic impact machines, in particular to rammers, jack hammers, concrete breakers, etc., which are used in construction, mining and other industries.

A pneumatic impact machine is known in which, in order to increase the convenience of operation, the coupling is made in the form of a sleeve, the end face of which, facing the handle, is rigidly connected to the piston rod and the housing is enclosed by a free end.

However, this machine has low power.

An object of the invention is to increase power.

The goal is achieved in that in a pneumatic impact machine Kasatkin, containing a coaxially placed casing with a handle, a housing with a working tool and a piston with a rod in the upper part of the coupling, an air distribution chamber is made, and a shoulder with radial holes made on the rod is installed in the air distribution the chamber with the possibility of limited axial movement, while the upper part of the housing is made in the form of a piston, forming with the coupling an additional working cavity, connected by channels with the distribution chamber.

The presence of these distinctive features determines the compliance of the proposed technical solution with the novelty criterion.

When analyzing new features of the claimed technical solution, it was found that the known pneumatic impact machines do not possess such features, and therefore their totality, therefore, we can conclude that the claimed technical solution meets the criterion of significant differences.

In FIG. 1 shows a pneumatic machine at idle, longitudinal section; in FIG. 2 - the same, during the working stroke, a partial longitudinal section.

The pneumatic impact machine includes a casing 1 with a handle 2 having an axial hole, a coupling mounted in the casing 1 with the possibility of axial movement and made in the form of a glass 7 with an axial hole 13 in the bottom of the glass .7 and a radial hole 17 in the wall, air supply the rod 15 and the hammer, made in the form of a pneumatic cylinder 4, the housing 11 of which having a radial hole 18, is connected with a working tool (not shown in Fig.), is placed in the nozzle 7 with the possibility of axial movement and they form a cavity (chamber) 12, stock 6 stump motsilindra 4 formed with an axial bore and disposed in the opening 13 of the bottom

5 of the cup 7, and the piston 5 is installed with the possibility of periodic communication of the sub-piston 3 and the supra-piston 16 cavities through the radial hole 18 of the housing 11 with the atmosphere and there is an air distribution device 14 for periodic communication of the sub-piston 3 and the piston 16 cavities with the axial hole of the rod 12. B at the bottom of the cup 7, an air distribution chamber 8 is made, connected with an axial hole 13, at the end of the stem 6 a collar 9 is made with radial holes 10, the outer diameter of which is larger than the axial hole 13 of the glass 7, shoulder 9 disposed in the air races before eating itel0 hydrochloric chamber 8, the piston rod of the pneumatic cylinder 6 4 installed in the axial bore 13 of nozzle 7 with a radial clearance and the possibility of movement for wasp Vågå periodic messages air distribution

5 of the chamber 8 with a cavity 12, the air supply rod 15 is fixed at one bottom of the cup 7 and connected to the air distribution chamber 8, and the other is placed in the axial hole of the handle 2 with the possibility of axial movement relative to the latter, and the housing 11. Of the cylinder 4 installed with the possibility of periodic communication of the cavity 12 with the atmosphere through the radial hole 17 of the glass 7.

5 The machine operates as follows. When you turn on the compressed air through the air supply rod 15 enters the air distribution chamber 8, and from it through the radial holes 10 and the axial bore of the rod 6 to the air distribution device 14 and into the supra-piston cavity 16 of the pneumatic cylinder 54, the casing 11 s with a working tool (not shown) they begin to move upwards, in

5, the rod 4 is in its lower extreme position and the shoulder 9 closes the axial hole 13 and the cavity 12 is isolated from compressed air from the air distribution chamber 8 and is communicated with radial holes 17 to the atmosphere.

After the holes 17 are closed by the housing 11 in the cavity 12, the compression of the air cut off in it begins and its pressure increases, and after the piston 5 of the 5 radial holes 18 in the housing 11 in the sub-piston cavity 3 is blocked, the compression of the air cut off in it and the increase in its pressure begin.

After the piston 5 passes through the holes 18 from the over-piston cavity 16, the exhaust air exhaust is crushed and the pressure in it drops to atmospheric.

Under the action of increased pressure in the sub-piston cavity 3 by air, the switchgear 14 moves to the upper position and blocks air from entering the supra-piston cavity 16, air begins to flow into the sub-piston cavity 3, and also under the action of increased pressure in the cavity 12, the rod 6 with the piston 5 moves to the upper the extreme position and the hole 13 opens and air begins to enter the cavity 12 through the radial holes 10 and the air distribution chamber 8, the housing 11 with a working tool (not shown) starts eremeschats down by the pressure of compressed air in cavity 12 and cavity 16 nadporsh- Neva.

After the holes 18 are blocked by the piston 5 in the supra-piston cavity 16, compression of the air cut off in it begins, and after the holes 18 are opened from the sub-piston cavity 3, exhaust occurs, the pressure in the cavity 3 drops to atmospheric pressure, while the body 11 passes through holes 17, the exhaust from the cavity 12 and the pressure in it drops to atmospheric.

The rod 6 with the piston 5 is moved to the lower end position, the shoulder 9 covers the axial hole 13. At about the same time, the pneumatic cylinder 4 makes a blow. Next, the cycle repeats.

Compared with the known machines, Kasatkin’s pneumatic impact machine is more powerful and, therefore, more productive in operation.

Formula 1. Pneumatic impact machine comprising a casing with a handle having an axial hole, a coupling mounted in the casing with the possibility of axial movement and made in the form of a glass with an axial hole in the bottom and a radial hole in the wall, air supply

the rod and hammer, made in the form of a pneumatic cylinder, the body of which having a radial hole is connected to the working tool, is placed in the glass with the possibility of axial movement and they form a cavity (chamber), the rod of the pneumatic cylinder is made with an axial hole and placed in holes of the bottom of the cup, and the piston is installed with the possibility of periodic communication of the sub-piston and supra-piston cavities through the radial hole of the housing with the atmosphere and an air distribution device is placed in it for periodic communication dorsal and nadporshne cavities with an axial hole of the rod, characterized in that, in order to increase power, an air distribution chamber is made in the bottom of the glass, in communication with the axial hole, a shoulder with radial holes is made at the end of the shaft, the outer diameter of which is larger than the axial hole of the glass, the collar is placed in the air distribution chamber, the pneumatic cylinder rod is installed in the axial hole of the cup with a radial clearance and the possibility of axial movement for periodic communication of the air distribution th chamber with a cavity, the air supply rod is fixed at one bottom of the cup and connected to the air distribution chamber, and the other - in the axial hole of the handle with the possibility of axial movement relative to the latter, and the pneumatic cylinder body is installed with the possibility of periodic communication of the cavities with the atmosphere through a radial glass hole.

2. The machine according to claim 1, with the aim that, in order to reduce the overall dimensions and increase the convenience of operation, the air supply rod is fixed at one bottom of the glass to the bottom of the glass and connected to the air distribution chamber and the other placed in the axial hole of the handle with the possibility of axial movement relative to the latter.

fie. 2