SU1102929A1 - Pneumatic percussion mechanism - Google Patents

Abstract

1. PNEUMATIC IMPACT MECHANISM, including a housing with air supply channels and outlets, a hammer piston with annular guide shoulders, mounted in the housing with the ability to block the air passage channel into the idling chamber at the lowest position of the working tool, which has a spring and made step-wise with a shank entering the idle-chamber through the protrusion of the housing, characterized in that, in order to increase the reliability of the device during the destruction of prone to oobrazovaniyu rock by reducing the likelihood of transmission of impact effects on the mechanism housing, on the tool shank has a groove, and a housing ledge - additional outlets whose inputs are placed in the projection to periodically communicate with the cavity of the shank bore. I 2. The mechanism according to claim 1, characterized in that the piles of the impactor are formed (L vanes are removable segments. C

Description

The invention relates to the mining industry, in particular to pneumatic devices for impact crushing of oversized blocks and the destruction of rocks by a large chip.

A pneumatic percussion mechanism is known, including a cylinder body with a piston-hammer, a working tool and a safety spring 1.

The disadvantage of the mechanism is its relatively low reliability in the destruction of hard rock, prone to the formation of stabbing in the downhole area.

The closest to the invention in terms of technical dryness and the achieved result is a pneumatic percussion mechanism, including a housing with an air supply w, channels and outlet openings, a piston impact with circular guides mounted in the housing The air passage channel into the idling chamber with the extreme lower position of the working tool, which has a spring and is stepped with a shank, the cavity entering the chamber through the protrusion of the housing 2.

However, in the well-known pneumatic impact fur, the lowness is not sufficiently high in operation due to the low probability of protecting the body of the mechanism from perceiving the shock loads from the impactor when the working tool is jammed in rock cracks prone to stabbing during fracture.

The purpose of the invention is to increase the reliability of the device while destroying rock-bearing rocks by reducing the likelihood of transmitting an impact to the mechanism case.

The goal is achieved by the fact that, in a pneumatic percussion mechanism, including a housing with air inlet channels and outlet openings, a piston-drummer with annular guide collars mounted in the housing with the ability to block the air inlet channel in the idling chamber at the extreme lower position of the working tool which has a spring and is made stepped with a shank, which enters the idle chamber through the protrusion of the housing, a groove is made on the shank of the working tool, and in the projection of the housing until Additional outlets, the entrances of which in the protrusion are placed with the possibility of periodical communication with the cavity of the shank.

In addition, the collars of the impactor piston are formed by removable segments.

FIG. 1 shows the mechanism, a longitudinal section; in fig. 2 - node T in FIG. 1 (fixing the segments on the piston-hammer).

The pneumatic percussion mechanism includes a body in the form of cylinders 1 and 2 interconnected. In the upper cylinder 1 there is a spool box 3. In the cylinder 1, the piston-hammer 4 is reciprocating, transferring the shock load to the stepped working tool 5. The body has a protrusion 6, between the lowermost surface 7 of which and the protrusion 8 of the tool 5, a cylindrical spring 9 is installed, covering

shank 10 tool 5.

In the shank 10 of the tool 5, the groove 11 is made, and in the protrusion 6 there are convex holes 12. Air enters the idle chamber 13 from the spool valve.

3 through the channel 14 through the opening 15. The exhaust of the air chamber of the working stroke 16 is carried out through the opening 17, and from the chamber 13 through the opening 18. Air from the compressor (not shown) to the slide valve box 3 flows through the opening 19. In the upper

and the lower parts of the impacting piston 4 are provided with stepped grooves into which the segments 20 and 21 are inserted, forming the guide shoulders of the impacting piston 4.

Tznevichsky shock mechanism works as follows.

The air from the compressor goes through aperture 19 to spool box 3. At this moment, the position of the spool is such that air entering the upper chamber flows into the atmosphere through the opening 17. The difference in static pressure allows the spool to transfer, due to which channel 14 is connected with the network. Air begins to flow through the hole 15 into the chamber 13 of the pneumatic percussion mechanism. Versions 12 are overlapped by the cylindrical surface of the destructive tool 5, and the piston-hammer 4 moves upwards. After the lower edges of the impact piston 4 rise above channel 18 and connect the measure 13 to the atmosphere, the pressure in it drops, which makes it possible to transfer the spool in the spool box 4 and connect the network with the camera 16. The impact piston 4 moves down until hitting tool 5 and opening channel 17. In

0 further cycles are repeated.

In the event that the shock pulse from tool 5 is not completely transmitted to the rock due to its jamming in the crack, the spring 9 is fully or partially extended and the tool 5 is lowered downwards. Together with the destructive tool 5, the piston-drummer 4 is lowered. The latter

Claims (2)

1. PNEUMATIC SHOCK MECHANISM, comprising a housing with air supply channels and outlet openings, a piston hammer with annular guide collars mounted in the housing with the possibility of overlapping the air supply channel into the idle chamber at the lowermost position of the working tool, which has a spring and is made stepwise with a shank entering the idle chamber through the protrusion of the housing, characterized in that, in order to increase the reliability of the device during the destruction of prone to puncture formation of rocks by reducing the likelihood of shock transmission to the mechanism body, a groove is made on the shank of the working tool, and additional outlet openings are located in the body protrusion, the inlets of which are placed with the possibility of periodic communication with the cavity of the shank groove. _e 2. The mechanism by π. 1, characterized in that the collars of the piston-hammer are formed by removable segments. with