PL4467B1 - Drilling hammer, compressed air operated. - Google Patents

Description

The invention relates to a drill hammer with a valve that moves back and forth; zaiwón sitanowi ball, lapel or the like. A disadvantage of this type of drill hammer is the often inconsistent advancement of the piston because the leakage of the valve results in compressed air flowing in so that back pressure occurs prematurely. This causes the piston path to be too short, and the same percussive movement generated by it falls out too weak and the chisel stops in the stone.

The invention eliminates the above disadvantage in that the opening of the small channels leading towards the piston path and acting jointly with the annular channels is vented from the open chamber. The deaeration, as a result of the extended piston run, also increases the force of the impact on the stem and allows for a shock-free operation, since the air cushion generated for braking in front of the piston screw acts smoothly and follows a true adiabatic curve.

It is important to note that the channels for venting must be sized so that they do not cause too great a loss of fresh air. On the reverse stroke of the piston, they reconnect the cylinder spine with the exhaust and fresh air escapes. Although this opening is temporary, as the piston reverts to its fastest movement, the length of the channels must be truncated so that, after sufficient venting, the exhalation of fresh air does not reduce venting. An example of the invention is shown by the attachment of a mlofea / tricycle attached to a stone. As it is known, the hammer consists of a cylinder 1, in which a piston 2 operates, directed by a valve with a ball 3, which moves back and corresponds to the pressure drop. It opens the channel 5 / to the compressed air, and then it is the channel 4. As a result, the piston will be located alternately in the chamber 6, then in the chamber 7. For venting chambers 6 and 7, exhalation openings 8 are used and 9. The stem iO connected to the piston 2 has a spiked chisel, Czech, parallel to the axis. In this way, the threaded nut 12 underneath the cap, not shown in the drawing, becomes suitably flushed, until the shaft 10 and the insert (sleeve) 13 rotate, keeping it in place 14. For a proper test, the piston 2 should be running at full stroke, which does not happen if the pressure on the fly stroke, i.e. after the exhalation in the chamber of cylinder 6 or 7, occurs prematurely, because then the pressure on the valve 3 is such that it is actuated prematurely occupied location. To avoid this, the cylinder chamber has two channels 15 and 16 parallel to the cylinder axis.

Transformed into transverse openings 17 and 18 (or 19 and 20), having their outlets in the cylinder chamber, positioned so that their outlets 18 and 19 are at the same height with the exhalation openings 8 Jub 9; At the end of the slide, its end 21 or 22 at the same time reaches exits 18 and 19, when it encounters exhalation openings 8 and 9.

The piston has two annular grooves 25 and 26 and, for example, on the downward stroke, the edge 21 contacts the edge 23 of the exhalation 8 and simultaneously with the openings of the channels 18.

During the further stroke, as is clearly shown in the drawing, the exhalation canal is closed and the mouth 1 opens through the annular cavity 25, simultaneously connecting it to the exhalation 8, until the cavity 25 passes through the mouth 18. Then the opening 17 to the cylinder chamber 6 is also opened and the air filter closed in the chamber part 6 can escape through the duct 15, through the opening 25 and the exhaust opening 8. In this way, venting takes place. With the piston backstroke, the same ratio applies to the chamber 7, because the channel 16 connects it in the same way to the exhalation opening 9. It turns out, when checking the ratios of the inflow and operation of the channels 15 and 16, that these channels are let through with fresh air. wind, have a certain negative effect.

The small loss of the driving factor is not of great importance, however, if all channels 15 and 16 are correctly measured, i.e. if they are not longer than the width of the depths 25 or 26 together with the relative distances of these extrusions from the front surfaces of the piston 21 lulb 22. If If the chamber 7 is represented in the position of the piston as shown in the drawing, the outlet 20 will be omitted at the piston stroke. But since mouth 19, the bed where cavity 26 moves, at the same time (it is reached, an outflow of fresh air takes place only for a short moment of displacement of cavity 26 around mouth 19, the pressure loss for such a short time is slight), but is sufficient to bleed air during reverse stroke.

Of course, it would be possible to arrange the device in reverse, namely the channels 15 and 16, in the piston, and the channels defined in the cylinder.

Claimed by a patent, a drilling hammer, operating with air springs, with a start-up valve and venting of the cylinder chambers after the damaged exhalation of the annular soils (25, 26) and channels parallel to the axis (15, 16), characterized by - 2 - the arrangement of the channels so that their outlets (18 or 19) correspond to the exhalation openings (8 or 9), as long as the beginning of the piston stroke (2) around one (18) or around the second outlet (19) begins simultaneously with exhalation (9), while the distance of the mouths (17, 18 or 19, 20) adjacent to one canal (15 or 16) is so measured that it does not exceed the width of the annular cavity (25 lvb 26) with respect to to distance the face of the piston (21 or 22).

M] a schinenbau- Aktiengesellschaft H. Flottmann & C o m p.

Deputy: I, Myszczynski, patent attorney. To the patent description No. 4467.

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