EP0168382A1 - Device for percussive and/or rotary drilling - Google Patents

Abstract

1. A device for percussive drilling, more particularly for opening tap holes of furnace, e.g. blast furnaces with a percussive mechanism (400) which is longitudinally displaceable on a carriage or the like, has a plug-in end (20) as a displaceable element drive energy transmission element in the percussion direction, and is connected to percussive rod as a tool, the plug-in end (20) having an enlargement (21), the side (212) of which facing the tool is provided with a stop (313) of a piston (31) longitudinally displaceable in a pressure chamber (30) surrounding the plug-in end (20) and which can be supplied with a pressure medium under pressure, the stressing of the piston acting with kinetic energy directed in an oscillating manner in the return direction (R3) as a counter percussive mechanism (300), the side (312) of the piston (31) facing the tool being able to be stressed, characterized in that the pressure chamber (30) is connected to a counter percussive compressed energy store (50) by the pressure medium, the device having a rotation gear (100) for percussive or rotary drilling, thus the counter percussion mechanism (300) has a stop ring (32) limiting the longitudinal movement of the piston (31) in the pressure chamber (30) in the direction away from the tool, resting on the housing (2) of the device (1) and held positionally rigidly, further characterized by a cap housing which is built over the counter percussion mechanism (300) containing a rinsing head, and comprises a sleeve (33) which limits the longitudinal movement of the piston (31) in the operating direction (R4) of the percussion rod, further characterized in that the longest distance (a) covered by the piston (31) when moving in the pressure chamber (30) is greather than the distance (b) between the point of impact (A) - nearest the percussion mechanism - of the percussive end (41) of the percussion mechanism piston (4) on the plug-in end (20) and the dead centre (T) - furthest from percussion mechanism during idling - of the percussion mechanism piston (4).

Description

The invention relates to a device for impact and / or rotating drilling, in particular a device for opening tap holes in melting furnaces for mineral, in particular metallic, materials, preferably blast furnaces. Such for rock, burned masses u. Certain drilling devices have a reciprocating impact impact mass, usually a pneumatically, hydraulically or the like. Operated, preferably double-acting piston, which on an impact energy transmission body, which with a work tool, such as a boring bar with a drill bit, or one Beater bar, optionally connected in one piece, beats. The kinetic energy contained in the impact mass at the moment of the impact is taken over by the transmission element and passed on to the point at which the energy is used to shred the material to be drilled. In normal operation, the free end of the work tool is kept in close contact with the material to be processed by the application of force, so that the impact energy transfer can take place with high efficiency. When opening tap holes, e.g. from blast furnaces, it can be done so that an opening is rotated into the stuffing material formed with refractory material up to about 50 cm before reaching the melt, after which the drill bit is pressed against one with impact-resistant but cheap steel or The like. Manufactured beater bar is replaced, the front part of which is driven through by the impact mass of the striking mechanism through the remaining stuffing mass, and the beater bar can remain in the tap hole like a plug until tapping takes place. To pull the bat from the tap hole, apply high, away from the tap hole directed forces on the carriage that carries the boring machine, oscillating impact energy applied to the beater bar. The forces required to pull out the beater bar can easily reach about 10 t, and the beating forces applied by the striking mechanism to the tool do not significantly reduce these pulling forces.

From AT-A 349.409 has become known for rock drilling rigs, when they are pulled back through the tool to guide shock and shock wave trains, and there is a construction specified which is to ensure that the pulling back supporting device parts are not fatigue or the like. be destroyed. There, a shock absorbing device is provided on the drilling device, in which the energy-transmitting tool end is held in the device with an annular piston penetrated by it, which piston can slide in an annular chamber arranged in the drilling device, which annular chamber with a source for incompressible, pressurized medium via a a check valve having line and is connected to a receiving container via a further line having an adjustable outlet valve, these lines having flow-restricting openings, that is to say flow restrictors. If this device can also make it easier to pull back, it cannot be overlooked that the shock wave trains are guided through the tool, but that their damaging effects are also reduced by strong damping by means of this ring piston. If the tool hits the ring piston with its collar, some of the energy is converted into heat. After a smaller amount of pressure medium has flowed off, pressure medium is again in the annular chamber during the Period between the blows introduced. This is to be achieved according to this AT-PS that the forces acting on the device and housing are reduced so much that they can be safely absorbed by the device.

It has now surprisingly been found that, if instead of such a damping element, in which only relatively little pressure medium can flow out of the annular chamber and be supplied later, and the piston therefore only travels extremely short distances, one essentially by means of the applied to the transmission element Impact energy essentially operated counter-impact mechanism with a higher piston travel, the load on the housing is kept low and there is no danger to the same, but the force for pulling a chisel out of a borehole, in particular a beater rod hammered into the tamping mass of a tap hole, is significantly reduced during tapping.

The invention thus relates to a device for percussive and / or rotating drilling, in particular for opening tap holes in melting furnaces for mineral, in particular metallic materials, preferably blast furnaces, or the like on a carriage. longitudinally movable percussion and slewing gear with drive energy transmission element, in particular push-in stub, which can be set in striking and / or rotating movement, and which is connectable or connected to a working tool, in particular a striking rod, wherein the energy transmission element has at least one thickening, a collar , Rotary wing or the like., Whose or the tool side facing with a stop along a pressure chamber in a pressurized pressure medium surrounding the energy transfer element surrounding the energy transfer element displaceable and on its work tool-facing side can be acted upon with pressure medium, which is characterized in that the one with the energy transmission element, preferably a plug-in stub, preferably formed integrally therewith, with a thickening, collar or the like and via one on its own arranged working surface facing away from the working tool, cooperating pistons which can preferably be pressurized with liquid, pressure medium, together with the energy transfer element, in particular insertion stub, during the application of which with oscillating directed kinetic energy by means of the striking mechanism as counter-impact mechanism which is effective in the direction facing away from the working tool Pressure chamber with a, preferably with counter-voltage, counter-impact energy pressure accumulator, preferably essentially directly, is connected to the pressure medium, and the longest of the pistons during its movement in the pressure chamber Distance traveled is greater than the distance between the impact point closest to the impact of the impacting end of the impact piston on the energy transmission element, in particular the plug-in stub, and when the dead center of the impact piston is most distant from the impact. It is essential, as has been found, that there is a pressure accumulator connected to the pressure chamber via a line, opening, or the like which is as wide as possible, from which, when impact energy is applied to the plug-in stub and from this to the piston of the counter-impact mechanism, from the pressure medium in the pressure chamber Energy is absorbed, which results in a slightly inhibited flow of the medium into the pressure accumulator, from where the energy between the strikes of the striking mechanism reacts quickly and unthrottled on the piston above the pressure chamber, thus creating a real counter-striking mechanism. which at the same time the extraction facilitating substantially between the blows of the hammer mechanism impact and shock waves delivered to the erkzeugfront present in the drilling or needle hole _W. Such a pressure accumulator has in its medium-filled interior a membrane-like wall, which is preferably acted upon from the other side by gas under adjustable pressure, possibly also by spring force, that is to say a counter-tension. There is thus a kind of "evasion" and "returning" this wall during the oscillating pressure energy storage process. It is also important that the path by which the piston of the counter-impact mechanism can be moved has the specified length, which means that if the tool is not pulled, but instead rotating and / or impact operation takes place, the counter-impact mechanism can be uncoupled, so that there is no hitting its piston on the collar of the stub.

It has proven to be particularly favorable in practical operation when tapping if the pressure chamber of the counter-impact mechanism, which has a supply for pressure medium and at least one discharge for pressure medium, which can preferably be circulated, via at least one supply and discharge, in particular line or opening the pressure accumulator is connected to the pressure medium, the cross-sectional or total cross-sectional area of which is at least as large as the cross-sectional or total cross-sectional area of the inlet opening of the counter-impact energy pressure accumulator at each point of its extension. If these conditions are observed, sufficient counter-impact force is applied to the stub exercised, by which the retraction of the striking mechanism is significantly supported with its traversing slide also become overlapping Shock waves are directed to the tool, eg to the bumper, whereby loosening in the drill hole or pothole is achieved; however, it has been found that the mechanical stress on the device and its housing is kept low.

According to a further preferred embodiment, it can be provided that the counterblow mechanism has a stop body, in particular stop ring, which is fixed in position in the housing of the device, in particular in its distal cap, which limits the longitudinal movement of the piston in the pressure chamber in the direction away from the work tool. This makes it easy to ensure that the stub is held at a defined distance from the striking mechanism even when the tool pressure is high, which means that there is no danger to the striking mechanism and housing.

If, as is furthermore conveniently provided, the pressure chamber of the counter-impact mechanism has a sleeve, in which the sleeve, in particular its cap, adjoins the inside, preferably rests against the pressure medium, preferably integrally formed with it and limiting the longitudinal movement of the piston in the direction toward the working tool the piston is slidingly movable, there are low-friction guidance of the piston of the counter-impact mechanism, special protection of the housing and easy interchangeability, e.g. given after wear. With the stop, the path of the insertion stub is also away from the striking mechanism, e.g. limited when pulling out the tool without counter impact.

If such a sleeve is provided, it is advantageous according to a further preferred variant if, in particular, at least the pressure medium connecting supply and discharge (s) Special line (s) or opening (s), between the pressure chamber and counter-impact energy pressure accumulator, preferably all such pressure medium guides, penetrate the sleeve of the pressure chamber. The advantage is that connection points, openings, lines or the like. For supply and discharge of pressure medium, which penetrate the housing, can each have mechanically favorable cross-sectional shape and size, while the guides, lines provided in the sleeve , Openings or the like. Can have cross-sections and ratios of the cross-sectional area that are matched to their respective task.

It has been found that particularly favorable counter-impact energy application for pulling out the tool, e.g. a shock rod, with optimal shock wave transmission to it, if the ratio between the area of the piston of the counter-impact mechanism that can be pressurized in the pressure chamber to the minimum cross-sectional or total cross-sectional area of the supply and discharge connecting the pressure medium ( s), in particular line (s) or opening (s) between pressure chamber and counter-impact energy pressure accumulator from 80: 1 to 20: 1, preferably from 50: 1 to 30: 1.

In order to keep the load on the inlets and outlets for the pressure medium low and in particular to utilize the energy for the counterblows in the pressure accumulator as far as possible, it has proven to be advantageous if the ratio of the minimum (total) cross-sectional area of the pressure medium Feed (s), preferably from their part passing through the pressure chamber sleeve, to the pressure chamber to the minimum (total) cross-sectional area of the circuit Pressure medium discharge, preferably from its part penetrating the sleeve, from 10: 1 to 2: 1, preferably from 5: 1 to 3: 1.

In a similar sense, a construction is advantageous, according to which it is provided that the ratio of the minimum (total) cross-sectional area of the pressure medium feed, preferably of its part passing through the pressure chamber sleeve, to the pressure chamber to the minimum (total) cross-sectional area of the pressure medium connecting supply and discharge (s), in particular line (s) or opening (s), between pressure chamber and pressure accumulator from 25: 1 to 5: 1, preferably 16: 1 to 8: 1.

In particular for drilling work in warmer rock layers, when tapping the furnace or the like, where additional heat stress occurs, it is advantageous if the number of main supply and disposal lines for pressure medium from a pressure medium source, e.g. a pump is kept as low as possible. Accordingly, an embodiment is favorable, in particular for tapping devices, which essentially consists in that the counterblow mechanism and the rotating mechanism of common main supply / disposal supplies, in particular lines, via at least one medium flow switching element, preferably 3 -Way 2-position valve can be supplied and disposed of with the exclusion of the other with pressure medium. As a result of this switchability between slewing gear and counterblowing mechanism, only 4 pressure medium supply and disposal lines are required instead of 6 in the case of individual striking, twisting and counterblowing mechanisms. The multi-position multi-way valves of the pressure medium supply system can be activated and switched over electrically, pneumatically or hydraulically.

In order to provide the above-mentioned reversal with a high level of operating safety, it is advantageous if at least one flow reversing switching element, preferably a 6 "position 3-position valve, the main supply / disposal guides, in particular lines, for rotary and counter-impact mechanism has electrical, pneumatic or hydraulic switching elements, which are each operatively connected via control lines to an actuating element of a medium flow switching element that feeds the rotating mechanism or the counter-impact mechanism with pressure medium.

The device according to the invention is explained in more detail with reference to the drawing.

In the drawings Fig. 1 and 2, the longitudinal and transverse section through an inventive tapping device, Fig. 3 is a diagram for a Bohrgeräts- control switching for the Druckme _d iumszuführung to turning or counter-striking mechanism by electrical means, and Fig. 4 shows such a hydraulic control for an inventive device.

In the tap hole opening device 1 shown in FIG. 1, a striking mechanism 400 is provided, a double-acting piston 4 being slidably mounted in the interior 3 of a housing 40 with an end cap 401 holding a guide body 402, the energy supply being provided by a, not shown here, hydraulic pressure medium supply system takes place, and the back and forth movement Rl, R2 of the piston 4 is controlled by a changeover slide 5. With its end 41, the piston 4 strikes during its oscillating movement on the plug-in stub 20 which is arranged in the direction of R2 towards the working tool and which is arranged in the two-part housing middle part 403 and in the front cap 39 and can also be moved back and forth in the direction R3, R4. which has radial drive wing 201 and can be connected distally, for example via a connecting body, to a boring bar with a frontal chisel, a beater bar or the like. By means of a, preferably hydraulic, drive motor 110 of a rotating mechanism 100, a pinion 14, which is detachably but non-rotatably connected and is supported by bearings 142, 143, is rotatably drivable via a shaft 12 mounted with bearings 102, the teeth 140 of which teeth 140 one with axial bearings 162, 163 rotatably mounted and with radial bearings 164, 165 against axial displacement secured hollow shaft 16, which hollow shaft 16 has radial force transmission wings 161 inside, which cooperate with the wings 201 of the stub 20. The wings 201 of the oscillating movable stub 20 are slidable on the wings 161 in the axial direction, so that even if the piston 4 of the striking mechanism 400 strikes the stub 20, its rotating movement can take place at the same time. Facing the tool, the stub 20 has, for example adjoining its rotary wing 201, a collar 21, which is connected here in one piece, preferably all-round, and subsequently passes through an approximately L-shaped profile with a radially outwardly directed leg 315 in the direction R4 and stub 20 surrounding leg 316, ring-shaped counter-impact piston 31 of the counter-impact mechanism 300, the impact face 313 of the impact mechanism facing the impact mechanism cooperating with a face 212 of the collar 21 of the stub 20 facing away from the impact mechanism. The piston 31 is in the pressure chamber 30, which can be supplied with pressure medium 60 via feed 35, 3 ₃₅ , in a sleeve 33 inserted in the front cap 39 of the tapping device so that it can be sealed against it. The sleeve 33 has a radially inward-pointing projection 331, which the movement of the piston 31 in tool - facing direction R 4 limited. The sleeve 33 is held axially immovable by means of an annular stop body 32, which at the same time limits the piston travel a in the direction R3 facing the striking mechanism. Via a feed 395 in the cap 39 and via radial feed channels 22 and an axial main channel 23 in the stub 20 which can be rotated in the sleeve 38, flushing medium, such as compressed air, can be introduced and conveyed to the tool front. The ring seals and lubricant feeds between moving and fixed parts are identified by 70 in FIG. 1. 1 also shows the impact point A of the striking piston end 41 on the stub 20, furthermore the dead center T of the piston 4 reached when the piston end 41 is idling with an oscillating movement, and the distance b between the points mentioned. Furthermore, the total distance a can be covered by the piston 31 of the counter-impact mechanism 300 between the pressure chamber wall 322 of the stop ring 32 and the inner surface 332 of the projection 331 of the sleeve 33 is visible. It can also be seen that the distance a is greater than the distance b.

The pressure reservoir 50, which is also essential and is shown in more detail in the cross-sectional illustration in FIG. The housing cap 39 of the counterblow mechanism 300 is penetrated by openings 35, 36 and 37 for the supply of fresh pressure medium 60 and the discharge of heated pressure medium 60 to be circulated and the oscillating supply / discharge of the pressure medium into a pressure accumulator 50. A guide sleeve 33, which fits snugly against the cap housing 39, is arranged toward the pressure chamber 30 and is penetrated by openings 335, 336 and a plurality of openings 337 adjoining the openings 35, 36 and 37 of the cap 39. Close Lich, the pressure chamber 30 filled with the medium 60 is limited to the stub 20 by the extension 316 of the piston 31. The compared to the opening 335 of the sleeve 33 for supplying the pressure medium 50 together having relatively large overall cross-section openings 337 of the sleeve 33 open into an inlet / outlet 37, to which the inlet opening 57 in the connecting flange 53 of a commercially available - shown partially cut Hydraulic medium pressure accumulator 50 with a diaphragm 51 indicated by dashed lines and supply opening 52 for compressed gas as a counter-voltage medium for acting on the diaphragm 51 connects.

Returning to FIG. 1, percussion pistons 4 of the percussion mechanism 400, insert stub 20 and counter-impact piston 31 are shown in two positions, with the piston 31 showing the impact and non-operating position, for example when rotating drilling. In the upper half, the insertion stub 20 has a position in which the counter-impact piston 31 is pressurized and the stub collar 21 rests with its surface 212 on the counter-impact surface 313 of the piston 31 when the striking piston 4 strikes the stub 20. As a result of the impact energy transferred from the stub 20 to the piston 31, the latter is suddenly displaced in the direction R4 toward the working tool, the medium 60 located in the pressure chamber 30, preferably incompressible, rapidly opening via the opening 337, 37, 57 into the pressure reservoir to which counterpressure is applied 50 is pressed. Now the impact energy slows down when the piston 4 of the striking mechanism 400 retreats, from the pressure accumulator 50 due to the large cross section of the connection 337, 37, 57 between the pressure accumulator 50 and the pressure chamber 30, practically unthrottled, immediate backflow of the medium, the energy releasing on the action surface 312 on the piston 31, which in turn acts in the opposite direction R3 on the collar 21 of the stub 20, so that a real, space-saving counter-impact mechanism 300 is provided, by which the extraction of the tool from a drilling or tap hole is significantly promoted is achieved by this impact, in addition to the pulling impact effect, also bringing shock wave impact energy to the tool front. In the lower part of the section of FIG. 1, it is shown how the piston 31 of the counter-impact mechanism 300, for example when the tool, the impact rod or the like is not being assisted by counter-impact support, is positioned out of the borehole, the collar 21 of the stub 20 bears directly against the piston 31 and this on the sleeve projection 331.

In the system of hydraulic pressure medium guidance and control of a hammer / drill device according to the invention, in particular a tapping device, which is advantageous because of its operational safety, shown schematically in FIG. 3, a pressure medium reservoir or a hydraulic pump 2 driven by a motor 1 'turns the tank 600 returned via line 41 via a 4! 3-way valve 442 in the circuit management position II shown, pressure medium via lines 45, 42, with filter 48 and medium cooler 49 into the tank 600. At position I of valve 442, the medium circuit is interrupted at all. In valve position III, pressure medium is introduced via line 41 with filter 48 into the cylinder chamber 3 with percussion piston 4 of the striking mechanism 400 of the tapping device 1 according to the invention, its energy is converted there into oscillation-directed impact energy, via return line 42 with the aforementioned filter 48 and oil cooler 49 circulated medium, such as hydraulic oil, returned to the main tank 600. The links Line ₄ 4 shown with controller 47 and filter 48 is by means of motor oil "driven compressor 2" with compressed air for oil mist lubrication of the drilling / impacting device 1, which is indicated schematically in FIG. 3 above the broken line, while below the energy supply and Control system 90 is indicated, supplied; the branch line 44a serves to supply the drill pipe and the front working tool with cooling and flushing medium.

By means of a pump 2 ', which in the present case is separate and driven by the same motor 1, hydraulic medium is conducted via line 20 to the 6/3-way valve 363, in the position II shown, a circulation of the pressure medium via line 22 in line 42 back to the medium tank 600 is done. In position I of the valve 363, the medium passes via line 21 to the 3/2-way valve 32 and _W -1-1 eg in the rotating mechanism 100 for rotating drilling or pre-drilling. The medium is returned via line 11a through a valve 32a in position I and lines 22, 42 to tank 600. If the 6/3-way valve 363 has position III, the rotating mechanism 100 is supplied with line ₃ via line 2la, IIIa / ₂ -way valve 32a, which reverses the direction of rotation in the rotating mechanism 100. If in position I or III of valve 363 the solenoids Ml, M2 of valves 32, 32a are actuated via control lines sl, s2 by means of switches el, e2, they are switched over to position II, whereby the supply of medium to rotating mechanism 100 is switched off and the medium is conveyed via line 21, 11 or 21a, lla via a double-acting non-return valve 311, eventually via line 310, the counter striking mechanism 300 with the pressure chamber 30, pressure accumulator 50 and counter-impact piston 31 is supplied with pressure medium and the pulling operation by applying counter-impact energy to the not shown Einstec _K stub with -

help of the impact energy of the piston 4 of the striking mechanism 400, the energy supply of which has already been described. Medium circulation, e.g. for cooling it takes place via line 36 with throttle 366 and check valve 367, which finally opens into line 42 to tank 600. In general, pressure reducers and pressure limiters in the system are designated 70 and 71. With the circuit shown schematically in the adjacent sketch to FIG. 3, the electrical switch is only made when the main switch 80 is closed when the "ON" position of one of the 6 / 3- Directional valve 363 actuated switches el, e2, in each case the attraction of a relay with magnet M1, M2 for actuating the 3/2-way valves 32, 32a, thus in their position II, and a clean switchover from the supply of the rotating mechanism 100 to a supply of the counter-impact mechanism 300. The main advantage of the supply and control system described is that only 4 main supply and disposal lines 41, 21, 42, 21a are required for the 3 functions turning, striking, counter-striking, which is particularly the case with tapping devices for blast furnaces with high Ambient temperatures is advantageous because there is a clear, mutually exclusive separation of the functions of the rotating mechanism 100 and the counter-impact mechanism 300 thus incorrect operation, which can damage the drilling or. Can lead tapping device is practically excluded.

In the supply / disposal and control system shown in FIG. 4, which relates only to the slewing gear and counterblow part of a tapping device 1, the same switching elements and analogous medium guidance are provided as in FIG. 3, only the control is carried out hydraulically, here one common supply pump 2 is provided for energy supply and control system; therefore they are the ones here individual elements of the medium supply are designated by the same reference symbols as in FIG. 3.

The hydraulic control is supplied with medium via line 81 with a 3/4-way valve 834 shown in the rest position II and performing the main on / off function, through which control medium can flow only in position I, for the switchover also shown here in rest position II -3 / 4-way valve 843 with control via lines 82, 83 opening into the inflow lines 21, 21a to the slewing gear 100. If the valve 834 is switched on in the I position, the control of the 4/2-way valve takes place. Valve 32 via line 84 for changing over to its II position, thus switching off the supply to the rotating mechanism 100 and switching to supplying the counter-impact mechanism 300 with pressure medium. In the III position of valve 843, valve 8a is activated via line 85 when valve 834 is switched on and this switches from supplying the rotating mechanism 100 for the reverse direction of rotation in the position I shown to exclusively supplying the counter-impact mechanism 300 in the position II. Pressure reducing valves and pressure limiting valves of the system are in the 4 generally designated 70 and 71.

Claims (10)

1.Device for percussive and / or rotating drilling, in particular for opening tap holes in melting furnaces for mineral, in particular metallic materials, preferably blast furnaces, with on a carriage or the like.Longitudinally movable impact (400) and slewing gear (100) with from this drive energy transmission element, in particular insert stub (20), which can be set in impact and / or rotary motion and which can be connected or connected to a work tool, in particular a striker rod, the energy transmission element having at least one thickened portion, a collar (21), Rotary wing or the like has the side (212) facing the work tool with a stop (312) of a pressure chamber (30) which can be supplied with a pressure medium (60) and which surrounds the energy transfer element and can be displaced longitudinally and on its side facing the work tool (312) with pressure medium (60) acted upon piston (31) cooperates, characterized in _{that the} ate with the energy transmission element, preferably insertion stub (20), over which, preferably integrally formed with it, thickening, collar (21) or the like. and, via a striking surface (313) facing away from the working tool, cooperating pistons (31) which can be pressurized with preferably liquid pressure medium (60) together with the energy transmission element, in particular insertion stub (20), during the application thereof with oscillating directed kinetic energy by means of the striking mechanism (400) as an effective counter in the direction away from the work tool (R3) can be cooperated, the pressure chamber (30) being connected to a pressure medium (50), preferably essentially directly, with a pressure medium, preferably with counter-voltage, which can be acted upon by counter-impact energy, and wherein the longest distance (a) which the piston (31) can move during its movement in the pressure chamber (30) is greater than the distance (b) between the impact point closest to the striking mechanism (A) of the striking end (41) of the striking mechanism piston (4) on the energy transmission element, in particular the plug-in stub (20), and when the dead center (T) of the hammer mechanism piston (4) is most distant from the hammer mechanism. 2. Device according to claim 1, characterized in that a feed (35, 335) for pressure medium (60) and at least one discharge (36, 336) for, preferably in the circuit, pressure medium (60) having pressure chamber (30) of Counter-impact mechanism (300) is connected to the pressure accumulator (50) via at least one inlet and outlet, in particular line or opening (37, 337), the cross-sectional or total cross-sectional area of which is at least the same size at each point of its extension like the cross-sectional or total cross-sectional area of the inlet opening (57) of the counter-impact energy pressure accumulator (50). 3. Device according to claim 1 or 2, characterized in that the counter-impact mechanism (300) one in the housing (2) of the device (1) limiting the longitudinal movement of the piston (31) in the pressure chamber (30) in the direction away from the work tool (R3) ), particularly in the distal cap (39) held in a fixed position _A nschlagskörper, in particular stop ring (32),. 4. Device according to one of claims 1 to 3, characterized in that the pressure chamber (30) of the counter-impact mechanism (300) on the housing (2), in particular its cap (39), internally adjacent, preferably tightly sealed against pressure medium, preferably in one piece with her out Formed sleeve (33), which limits the longitudinal movement of the piston (31) in the direction (R4) facing the work tool (R4) and in which the piston (31) is sealingly slidably movable. 5. Device according to one of claims 1 to 4, characterized in that at least the pressure medium connecting (s) supply and discharge (s), in particular line (s) or opening (s) (337), between the pressure chamber (30) and Counter-impact energy pressure accumulator (50), preferably all such pressure medium guides (335, 336, 337), pass through the sleeve (33) of the pressure chamber (30). 6. Device according to one of claims 1 to 5, characterized in that the ratio between the pressure medium (60) in the pressure chamber (30) pressurizable surface (312) of the piston (31) of the counter-impact mechanism (300) to the minimum cross-sectional or Total cross-sectional area of the inlet and outlet (s) connecting the pressure medium, in particular line (s) or opening (s) (37, 337) between pressure chamber (30) and counter-impact energy pressure accumulator (50) of 80: 1 to 20: 1, preferably from 50: 1 to 30: 1. 7. Device according to one of claims 1 to 6, characterized in that the ratio of the minimum (total) cross-sectional area of the pressure medium supply (s) (35, 335), preferably of which the pressure chamber sleeve (33) penetrating part (335) to the pressure chamber (30) to the minimum (total) cross-sectional area of the circuit pressure medium discharge (336, 36), preferably from its part (336) passing through the sleeve (33), from 10: 1 to 2: 1 , preferably from 5: 1 to 3: 1. 8. Device according to one of claims 1 to 7, characterized in that the ratio of the minimum (total) cross-sectional area of the pressure medium supply (35, 335), preferably of the part (335) penetrating the pressure chamber sleeve (33) , to the pressure chamber (30) to the minimum (total) cross-sectional area of the inlet and outlet (s) connecting the pressure medium, in particular line (s) or opening (s) (337, 37), between the pressure chamber (30) and the pressure accumulator (50 ) from 25: 1 to 5: 1, preferably 16: 1 to 8: 1. 9. Device according to one of claims 1 to 8, characterized in that the counterblow mechanism (300) and the rotating mechanism (100) of common main supply / disposal supplies, in particular lines (11, lla), via at least one medium flow - Switching device, preferably 3-way, 2-position valve (32, 32a), each with the exclusion of the other with pressure medium (60), can be supplied and disposed of. 10. Device according to one of claims 1 to 9, characterized in that a flow reversal switching element, preferably a 6-way 3-position valve (363), the main supply / disposal guides, in particular lines (11, 21, lla, 21a) for rotary (100) and counter-impact mechanism (300) has electrical, pneumatic or hydraulic switching elements (el, e2), each of which via control lines (sl, s2) with an actuator (M1, M2) of the rotating mechanism (100) or the counter-impact mechanism (300) with pressure medium (60) feeding medium flow switching element (32, 32a) are operatively connected.

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