SE447666B - VENTILLOS, PNEUMATIC HAMMER - Google Patents

Description

447 666 The chamber divider is guided in the housing by means of a divided guide ring, which is concentrically arranged in a concentric, annular groove in the housing, the depth of the groove being equal to or less than the depth of an internal thread in the housing.

The chamber divider suitably has a shoulder intended to engage against the split guide ring. The cylinder head end of the chamber divider is arranged to cooperate with the inner end of the cylinder head for fastening the chamber divider between the screwed-in cylinder head and the guide ring.

Furthermore, the depth of the passages in the walls of the house, which form the inflow path, is suitably not deeper than the depth of the internal thread at the ends of the house.

The control rod of the chamber divider includes a continuous passage in connection with a pressure valve at the cylinder head end to increase the air flow through the hammer, if it were to be used at lower pressures, which provide insufficient air flow through the hammer.

An embodiment of the invention is described by way of example with reference to the accompanying figures, in which Fig. 1 is a cross-sectional view of a valveless, pneumatic hammer with piston in a first position, Fig. 2 is an enlarged cross-sectional view of a section of the hammer in Figs. Fig. 1 and Fig. 3 are a cross-sectional view of the valveless pneumatic hammer with the piston in a second position.

A hollow housing 1 has at one end a cylinder head unit 2 and a drill steel part 3 at the other end.

The cylinder head unit is attached to the end of the housing by means of internal thread 4 in the housing. A chamber divider S is arranged in the housing between a divided guide ring 6 and the inner end 7 of the cylinder head unit. The chamber divider has an outwardly widened part 8 at the end facing away from the cylinder head unit and a central guide rod 9 projecting from the same end. An annular groove 10 is provided at this end around the central guide rod 9. A central bore 11 extends through the guide rod from end to end to a pressure valve 12 in the cylinder head unit.

A piston 13 has a bore with a first part 14 with larger diameters at one end and a second part 15 with smaller diameters at the other end, which extends through to the larger bore. 447 666 The end of the first part of the piston has an inwardly displaced part 16, which is airtight slidable towards the outside of the widened part 8 of the chamber divider.

The drill steel part 3 comprises a pin 17, from which a projecting rod 18 projects into the chamber. The drill steel part 3 is slidable in the housing between certain boundaries. The slidability is achieved in any suitable way and the part is controlled in the housing. A part of the pin 17 extends into the interior of the housing from a shoulder in the housing and the slidability of the drill steel part allows it to move between an upper position, wherein the pin part is in the interior of the housing and a lower position, when drilling the end of the steel part corresponds to the shoulder of the house.

A channel 19 runs through the end of the rod 18 to the atmosphere through the bottom of the drill steel part. The channel 19 is divided into two separate channels 20 in the outer part of the drill steel part and the channels 20 are connected to the atmosphere on the side of the drill steel part.

Two concentric annular grooves 21 are provided in the housing, one near each end of the interior of the housing. The piston has in the middle an annular groove 22 with approximately the same width as the distance between the grooves 21 in the housing.

The piston is arranged to strike between two positions. The first position (Fig. 1) is with the piston against the drill steel part at its upper position, and with a drill. the steel rod 8 fully projecting into the second smaller part 15 of the drilling piston. In this position a first chamber 23 is formed around the drilling steel part and is delimited by the wall of the drilling steel part in this position, the housing wall opposite it, the shoulder on the drilling steel part and the overlapping part 25 on the piston.

In this position, further, the end portion of the groove 21 is closest to the drill steel portion communicating with the first chamber 23, while the second groove 21 communicates with the interior of the housing past the end of the first major portion of the bore of the piston. The constrictions on the piston and the chamber part lie opposite each other and seal the first larger part 14 of the piston bore and the annular groove 10 of the chamber from the interior of the housing.

In the second position of the piston (Fig. 3) the piston is displaced towards the cylinder head unit, the end of the second smaller part of the bore of the piston is 447 666 free from the projecting rod 18 on the drill part and the constriction 16 on the piston has now slid past the shoulders 8 on chamber parts clean as shown. In this position the guide rod 9 of the chamber divider is located within the second part 15 of the piston bore and the groove 21 of the cylinder head is sealed from the interior of the housing by means of the wall of the piston. At the other end of the piston bore, the projecting rod 18 is extended from the bore of the piston. A second chamber 26 is then formed with the piston in this position and is delimited by the first larger part 15 of the bore on the piston and the cavity 10 in the chamber divider.

A first flow path begins through the cylinder head past the chamber divider and the walls of the housing to the cavity 21 at the end of the cylinder head with the piston in its first position and then between the housing and the piston cavity 22 to the cavity 21 in the housing at the drill steel end and into the first chamber. 23. The first inflow path is clearly indicated by the arrows 27 in Fig. 1.

A second supply path from the second chamber 26 runs from the chamber 26 to the second part of the bore of the piston, from there to the passage 19 in the drill shaft part and out to the atmosphere. This flow path is denoted by arrows 28 in Fig. 1.

A second supply path with the piston in its second position (Fig. 3) runs through the cylinder head between the chamber divider and the wall of the housing and between the inner wall of the first part of the bore of the piston and the outer wall of the chamber divider to the second chamber 26. This path is clearly indicated by arrows 29 in Fig. 3.

A first outflow path runs from the first chamber with the piston in its second position, directly to the passage 19 in the drill shaft part and through this passage out to the atmosphere. This outflow path is indicated by arrows 30 in Fig. 3.

A radial opening 31 through the chamber of the chamber divider is located in its extension 8. the opening is located so as to communicate with the second chamber 26 and the passage between the chamber divider and the housing wall when the constriction 16 on the piston is in the drill steel side of the opening 31.

In operation, compressed air is supplied to the housing through the cylinder head and flows along the first supply path to the first chamber 447 666 where the pressure causes the piston to move towards the cylinder head and position 2. It is obvious that the pressure-exposed piston surface in the chamber 23 has a larger surface than the piston end surface at the end of the first major part of the borehole.

As the piston moves towards its second position, the rod 18 is pulled out of the second chamber 23 and air from the chamber flows along the first outflow path.

The piston moves towards its second position and the inlet to the latches at the end of the cylinder head is closed when the piston moves over it and the second inlet path is opened when the constriction 16 on the piston passes the expansion 8 on the chamber divider. Thus, a second outflow path is open and the air follows this path to the second chamber 26.

The pressure in this chamber causes the piston to begin to return to the drill steel part 3. When the piston has moved far enough for the projecting rod 9 on the chamber divider to be pulled out from the second smaller part 5 of the piston bore, the second outflow path becomes open and air from the chamber 26 flows along this path to the atmosphere.

It can be seen that the cavity 10 increases the volume of the chamber 26 and thereby reduces a build-up of pressure as the piston returns to its second position. This effect is achieved without increasing the total length of the hammer and thereby means a saving in material and provides easier operation of the hammer.

Furthermore, air flows along both outflow paths through the drill steel part and thereby helps to remove drill biscuits from the borehole that may be located there.

The control of the chamber divider by means of the split guide ring allows the use of a piston with a maximum diameter and thereby provides maximum impact power from the piston against the drill steel part. Suitably, the depth of the cavities 21 therefor is not greater than the depth of the internal thread at the end of the cylinder head.

If the housing is lifted from the drilled surface, the drill steel part will sink to its lower position and support the piston. In this position, the end of the widened part 16 of the piston opens the opening 31, which connects the chamber 26 and the passage between the wall of the housing and the chamber parts.

Air then flows along the road between the wall of the house and the chamber parts, through the opening 31 and into the chamber 26 and out along the outflow path 28 to the atmosphere through the drill steel part. This provides continuous cleaning of the borehole and the drill steel part and since all air supply to the machine flows out as described, the machine is inactive in this position.

The invention thus provides an effective pneumatic hammer, which eliminates difficulties with known hammers of the same kind.

Variations can be made in the above-mentioned embodiment without departing from the spirit of the invention. For example. For example, the first inlet path may pass through one passage or several passages which are located entirely in the wall of the housing and the piston need not have any grooves in its outer wall at all.

Claims (6)

10 15 20 25 30 35 447 666 Eëššßššššl 1. l. Control valveless pneumatic hammer. which comprises a hollow housing (1) with a cylinder head unit (2) and a drill steel part (3), a piston (13), which is movable back and forth in the housing (1) and which has an axial bore. wherein a first part (14) of the piston bore has a larger diameter than the second part (15) of the piston bore and the piston (13) has a first. front working chamber (23) and a second. rear working chamber (26). in which fluid supply and fluid discharge channels are limited. and a control rod (9). extending from the cylinder head (2) of the housing (1) in the forward direction. which rod can be sealingly inserted into the second part (15) of smaller diameter. characterized in that the guide rod (9) is centrally arranged and integrated combined with a sleeve-like chamber divider (S). the front end portion (8) of which has an enlarged outer diameter. which end portion can be inserted from behind into the first portion (14) of the piston bore, which first portion (14) is formed in the rear portion of the piston (13), and that the first portion (14) of the piston bore substantially forms the rear working chamber (26). which in turn has a sealing part (16) at its rear end. which has a smaller diameter than the rest of the rear chamber. the rear working chamber (26) being sealed to the rear of the guide rod (9) when it is led out of the second part (15) of the piston bore, and there is also a sealing connection between the guide rod (9) and the second part (15) of the piston bore when the sealing part (16) of the first part (14) of the piston bore has been moved backwards past the end part (8) with extended outer diameter of the sleeve-like chamber divider (5). 2. A hammer according to claim 1, characterized in that the chamber divider (5) is held in place inside the housing (1) by means of a split ring (6). annular recess in the housing (1) and with a part in a concentric which with a part fits into a concentric. risk. annular seam in an inner edge portion of the chamber divider adjacent the housing wall to retain the chamber divider against the cylinder head assembly. 10 15 20 CD 447 666 Hammer according to claim 1 or 2. characterized in that the fluid supply channel to the front working chamber (23) is provided by a concentric, annular recess (21) in the rear area of the housing wall, a concentric, annular recess (21) shaped recess (21) ) in the front area of the house wall. in the center area of the piston (13) and a concentric. ring- Hammer according to one of Claims 1, 2 or 3, characterized in that the end part (8) of the chamber divider has an opening (31) through the wall. surrounded by the first piston part (14). which opening is located so that when the hammer is raised to the inoperative position and the piston (13) is in such a position that it shuts off the fluid supply (27. 29) to both working chambers (23. 26), the fluid supply (27) to the drill can go through this opening into the first part (14) of the piston and out of the drill through the discharge line (28) from the first part (14) of the piston. . Hammer according to one of the preceding claims. feel that the guide rod (9) has a continuous passage (11). which is connected to a pressure valve (12) in the cylinder head unit. which valve is arranged to open when the operating fluid is below a predetermined minimum. Hammer according to claim 1, characterized in that a concentric part (10) of the chamber divider (5) is arranged at a distance from the rod (9) in order to increase the volume of the rear working chamber (26).