SU611480A1 - Pneumoshoking device - Google Patents

Description

The invention relates to a mining machine; it can be applied when drilling holes and boreholes. A percussion device is known, comprising a housing with forward and reverse chambers, a blower, an air distribution device with a box and a hollow cylindrical slide valve. However, the small perimeter of the intake target leads to an insufficient shock power of the device. The closest to the described invention to the technical essence and the achieved effect is a hammer, comprising a housing, a piston and a junction box with an annular elastic valve and with a slot along the generatrix. The disadvantage of this air hammer is that the valve has a constant wall thickness around the perimeter of the ring. As a result, the valve is blocked with inlet holes and the free ends of the valve are hindered, and the valve sections near the slot require significant pressure drops . At the same time, the consumption of energy carrier increases and the dynamics of pneumatic shock waves deteriorate. In order to reduce the consumption of compressed air in the proposed pneumatic hammer, the valve is made of variable cross-section with an increase from proz to the middle. Fig. I shows the described air hammer, longitudinal section; figure 2 is the same, the section along aa in fig.i. The pneumatic hammer consists of body 1 and axle box 2 connected to it, in which a two-stage piston 3 is placed. At a lower piston stage, a groove 4 is made. An air distribution box 5 with a ka36 is installed on the surface of the body

Plates 6 and 7. An annular elastic Knanaft fi with variable wall thickness is located in a junction box in a pre-compressed state and installed with a variable clearance with respect to the outer surface of the housing, in which there are inlets 9. The tube 12 and in the case 13 there is a fitting 14 for supplying energy carrier to the chamber 15 of the direct code, which is periodically communicated through the exhaust ports 16 to the cavities of the noise suppressor 17. The return cam is made of two cavities 18 and 19, which are interconnected by channels 20. The reverse camera communicates with the main through radial channels 21 and fitting 22, Shank 23 is installed in the axle box and is connected to the stand of the drill rods.

The hammer is activated in the following sequence.

First, the energy carrier is supplied via fitting 14 into the inner cavity of the casing 13 and the clamps 10 and through the channels 7 to the outer surface of the valve 1. As the camera 15 of the forward run communicates with the atmosphere through the exhaust ports 16 and the silencer 17 of the noise (in the area of the channels 7) is higher than in the internal gap (in the area of the openings 9), and the valve 8 closes the inlet openings 9.

To start the air hammer, the energy carrier is fed through the fitting 22, the radial channels 21 and the groove 4 on the piston 3 enters the cavities 18 and 19 of the backstop chamber. There is a reverse stroke of the piston. After the radial channels 21 overlap with the cylindrical surface of the piston 3, the supply of energy to the backstop chamber is also stopped at some. On the way, the energy carrier works with expansion, and then the piston opens the exhaust ports 16, which inform the backstop chamber with a silencer cavity 7 noise.

During the return stroke of the piston, the pressure in the chamber 15 of the forward stroke increases and the valve 18 under the action of the internal forces of elasticity opens the inlet-from 4

versti 9, form an internal clearance. Camera 15 communicates with the trunk, the piston brakes, and the forward stroke begins.

The increase in the speed of movement of the piston is accompanied by a drop in pressure in the forward stroke chamber and in the internal gap, with the result that valve 8 begins to compress, reducing the flow cross section of the internal clearance inlet. At the end of the forward stroke, the piston opens the exhaust ports 16, the pressure in the chamber 15 drops abruptly and the valve closes the inlets

9. At the same time, the inlet begins.

energy carrier in the reverse camera. The piston strikes the stem -23, and the cycle repeats.

The implementation of a variable cross-section valve reduces the stiffness of the free ends of the valve, and thereby ensures that the gap completely closes at one pressure drop, which reduces the consumption of energy carrier. In addition, the valve has the greatest wall thickness in the section opposite to the slot, which increases its durability.

The installation of the valve 8 relative

to the outer surface of the housing 1 with a variable clearance, decreasing to the middle of the valve, when the valve is reversed, initially pressing it against the sealing surface in the middle thickened part and then distributing the contact to the free end of the valve and then closing the slot. This embodiment reduces the tangential

voltage in the valve increases reliability and improves the dynamics of the hammer.

Claims (1)

Invention Formula , A pneumatic impact valve comprising a housing, a piston and a junction box with an annular elastic valve and with a slit forming, characterized in that, in order to reduce the flow of compressed air, the valve is made of variable cross section with an increase from the slit to the middle. Fiu. / / J w d.2