EP0144282B1 - Hydraulic hammer - Google Patents

Abstract

1. An hydraulic lift hammer with a steel casing (3, 103) which completely encloses the tool formed from the drill (10, 110') and its drive unit (1, 101), with the exception of an opening for the passage of the free end of the drill, characterised in that the drive unit (1, 101) almost completely enclosed by the casing (3, 103) is mounted ((guided)) and supported inside the casing with the aid of elastic and attenuating material (4, 4', 6, 104, 104a, 106, 106a, 109).

Description

The invention relates to a demolition hammer specified in the preamble of claim 1.

Such breakers (also called rock breakers or rock chisels or chisel hammers or hydraulic chisels and provided with a hydraulic drive) are guided by a holding device, in particular by earthworks or other carrier devices.

Such a breaker is known for example from US-A-3 827 507 or US-A-3 889 762.

The disadvantage here is that the operation is associated with considerable noise pollution, so that use is not possible in all cases, since certain sound levels may not be exceeded during construction work due to environmental protection regulations.

The noise generated by the pulsating drive at high speed and by the impact on the chisel or the workpiece and the vibrations produced reach the atmosphere unhindered and are transmitted through the holding devices to the carrier device.

The object of the invention, which is characterized by the measures specified in the characterizing part of claim 1, is to achieve a considerable reduction in the amount of sound emitted to the outside in such a breaker without reducing the general usability of the hammer. In particular, the holding device should be such that the noise radiation and the vibrations are considerably reduced.

It is particularly advantageous in the solution according to the invention that the accessibility and interchangeability of individual parts of the chisel drive is hardly impaired and there are no operational restrictions.

Known elastic means (e.g. US-A-3 827 507, Fig. 1) for breakers only serve as a pneumatic spring, but do not contribute to sound insulation.

A large number of measures for reducing noise in connection with other construction machines are generally known. For example, DE-A-2410 360 shows a device for driving piles in, which has a ram bear that is almost completely surrounded by a housing, which is guided inside the housing and is supported on the housing by means of shock-absorbing means. In the case of a ram bear of this type, the transmission of impact forces as an impact load occurs exclusively in the direction of advance of the pile. The housing surrounding the ramming bear is therefore exposed to almost no stress. Forces transverse to the driving direction do not occur. In addition, there is a fundamental difference between the solution according to the invention and the known ramming device, since in the latter the housing is constructed in two parts without a stable mutual connection and thus does not form a single part, which as an additional device without further external support measures, for example on the boom of an excavator, can be used.

From the magazine "Erzmetall", volume 31, (1978), H. 7/8, p. 319, it is also known to provide full length rigid casing with a hammer to reduce noise. The associated reduction in sound radiation is, however, only slight.

The solution according to the invention, however, is based on the knowledge that an effective control of disturbing sound radiation can be achieved even in highly stressed devices by the fact that the holding forces for the drive and the tool with almost complete encapsulation, despite the considerable forces and moment loads acting, only with elastic damping elements soundproofing properties are transferred.

In corresponding advantageous developments of the invention, care is taken to ensure that these damping elements are designed such that the transverse force loads which occur when the chisel is used in the manner of a crowbar when the limit load of the damping elements is reached, in particular by means of projecting metallic stops, are introduced directly into the housing. In this way, overloading of the damping elements can be avoided.

In the case of hammers designed for smaller loads, the non-linearity of the damping elements alone is sufficient to form a travel limitation for the drive unit within the housing.

Preferably, the damping elements forming the soundproofing means are preloaded in such a way that, even at maximum load on the opposite side as a result of the chisel-like use of the chisel, they are able to transmit a sufficient holding force that fixes the tool to the drive unit and with the opposite wall maintain a mechanical contact of the housing which is sufficient to prevent uncontrolled movements (displacement and the like) of the drive part.

A cellular polyurethane-based plastic is preferably used as the insulating material, which has the necessary resilience and high volume compressibility with low material fatigue. Furthermore, the aging, temperature and oil resistance are great. Due to the high compressibility - with a suitably selected prestressing of the material - also relatively large vibration amplitudes of the drive unit can be absorbed, which both a reduction in the sound radiation and a reduction in the shock loads to be borne by the suspension in normal operation results. The strong non-linearity caused by the strong progression of the spring constants is also favorable.

The insulating and insulating materials installed to reduce structure-borne noise transmission between the drive of the chisel and the carrier housing thus have a leading effect and give the arrangement a certain pretension. By interrupting the metallic contact between the rock chisel and the housing, the excitation of the housing by vibrations and sound is avoided and the prerequisite for an effective attenuation of the sound radiation is created.

For proper guidance and for the transfer of forces and moments, which are caused by correcting the chisel direction during work in the axial and radial direction, the pretension is necessary in order to initially avoid metallic contact between the housing and drive unit due to the preferably progressive spring action. This bias is achieved when the insulating and insulating material, fixed by guide parts, is pressed against the drive unit within the housing of the housing.

To i.a. not to overwhelm the insulating and insulating material, but the elastic area of the damping elements should be able to be overcome from a certain load, and should have rigid - or almost rigid - properties. As a result, the resilience of the damping elements in the elastic range need not be designed for the maximum load that occurs. By means of the «limiter effect of the suspension as a result of - preferably metallic - mechanical contact between the drive unit and the housing, the very large forces and moments which occur during levering, pressing and tamping and which are dependent on the size of the carrier device can be readily taken over. Experience has shown that these high stresses occur particularly when the break-open chisel is used in the manner of a crowbar.

It is also essential for the invention to recognize that during the aforementioned extraordinary moment loads, chiseling does not take place in the actual sense, since the drive is stopped and therefore no noise can arise. The reduction in the sound-absorbing effect of the damping elements as a result of leaving the approximately linear region of the suspension is therefore of no importance.

Even if the drive should be switched on in the event of strong transverse loads, the overall noise reduction achieved is so essential that a brief rise in the noise level can easily be accepted.

On the other hand, if the insulating and insulating materials were designed in such a way that they could absorb such a stress within the range of their elastic deformation, they would not be able to fulfill their task of reducing the transmission of structure-borne noise, since they are too rigid should have, if such a design is possible at all.

The closed design of the housing, which is favorable for the purpose of sound insulation, is also maintained in the area of the drive element. An elastic connection between housing, drive and chisel compensates for the movements occurring in the axial and radial directions. The elastic material is attached to the housing by means of a metallic frame. It is provided with an opening for the passage of the chisel and lies sealingly against the shaft of the housing in the region of this opening. At the points of contact, a sealing lip is preferably attached for better effectiveness. The frame is easy to disassemble, so that at this point particularly heavy use can be quickly replaced by easily changing the elastic material and the frame.

In order to ensure the previously described effectiveness of the elastic material in the area of the tool, the chisel shaft is provided with a fixed collar which is limited on the drive part by means of a thickening or device provided in the direction of the housing. The elastic material (disk made of fabric rubber) is pressed together between the collar on the drive part and the rock chisel in the operating state and thus provides the necessary sealing effect together with the housing at this point. (When pressure is applied to the chisel tip, this is usually in the area of its rear stop and is struck by the percussion piston in this position in rapid succession, which are transferred directly to the material to be broken open).

An axial displacement of the tool, for. B. when renewing or repairing the drive is possible without impairment. The size of the collar or the washer protects the elastic material from damage.

The greatest noise is generated when the "percussion piston" hits the back surface of the chisel. In order to bring about noise reduction at this point as well, noise-reducing plastic disks can be inserted into the tool or the percussion piston or an intermediate part, in order to reduce the noise at the point at which it occurs.

The measures described so far for reducing noise include the drive unit, but a not insignificant part of the noise is also emitted by the chisel itself. In order to reduce the noise radiation at this point, an elastic material is guided in the aforementioned frame, which encloses the chisel in its shank area - but allows free access at the point of contact with the workpiece. When the chisel penetrates the material, the elastic foam material compresses together because it changes its volume under pressure due to its properties. Due to its shape, the named frame absorbs part of the insulation material and protects it from destruction by protruding edges.

The supply openings for the working medium (compressed oil or compressed air), which must necessarily be fed through the housing by means of pipes or hoses to the drive part, are padded with elastic material at this point to ensure that the housing is closed. Sealing lips preferably provided in this area prevent leakage and penetration of dirt.

In order to take away the possibility of vibrations and noise to propagate in the holding arm of the carrier device, the articulation points for the attachment are separated from one another by means of damping buffers. This in particular prevents the arm of the carrier device from acting as a resonance body.

In another advantageous development of the breaker according to the invention, various measures ensure that the drive unit can be inserted from above into a pot-shaped or trough-shaped housing, the bottom of the pot or cup only having the passage for the chisel.

The preload of the damping elements in the radial direction, which has proven to be favorable, was applied in a first embodiment of the invention in that, in the event of radial oversize of the damping elements, they were compressed by tightening the cover parts which could be screwed onto the side of the housing. This version, which is particularly suitable for large hammers, is relatively complex. It has been found that the required compression can also be ensured in other ways:

For this purpose, either the drive unit is pressed with great force into the damping elements fitted inside the housing - which proves to be particularly advantageous if appropriate assembly tools are available.

By means of recesses in the area of the surface damping elements, which are directed towards the interior of the housing, the deformability can be increased locally, so that the drive unit can be inserted more easily into the housing with compression of the damping elements. Another advantageous way to produce the desirable compression is that the damping elements have an oversize in the axial direction, whereby compression of the elements to their nominal dimensions within the housing produces a compression effect in the axial direction, which produces the required bias to Introduce the appropriate forces of the drive unit into the housing while maintaining sound insulation when strong bending moments are exerted on the chisel. The compression of the sealing elements is applied in a favorable manner in that the cover for the mounting opening for receiving the drive unit compresses the insulating elements protruding from this opening with excess when closing.

The necessary sound insulation in the passage area for the chisel is generated in the "cup-shaped construction by an annular damping element in the area of the floor to which the drive element rests when the cover part is tightened and with the interposition of a circular disc-shaped damping element, the drive unit is locked in the axial direction.

The forces arising from the chisel side are introduced from below into the base part by an annular damping element, which is inserted into a corresponding recess. The collar of the chisel is supported on this damping element, so that overall there is a sandwich-like construction, which is given the necessary stability by the rigid intermediate bottom part, while the damping buffers provide the necessary sound absorption - seen from the inside out in two stages and thus particularly effectively - carry out.

• Figur 1 ein erstes vorteilhaftes Ausführungsbeispiel eines hydraulisch angetriebenen Aufbruchhammers gemäß der Erfindung in Schnittdarstellung und
• Figur 2 ein weiteres entsprechendes Ausführungsbeispiel in Schnittdarstellung.

Advantageous further developments of the invention are characterized in the subclaims or are described in more detail in the following illustration together with preferred embodiments of the invention. Show it :

• Figure 1 shows a first advantageous embodiment of a hydraulically driven breaker according to the invention in a sectional view and
• Figure 2 shows another corresponding embodiment in a sectional view.

In the exemplary embodiment of a hydraulic breaker with sound insulation device according to the invention shown in FIG. 1, the drive part 1, which generates a movement of the percussion piston 2, is almost completely surrounded by a housing 3. The housing 3 is lined with sound-absorbing material (insulating elements 4 or 4 'and 6). The sound-absorbing material preferably consists of a rubber-elastic material which, with good load-bearing capacity, has a sound absorption behavior which reduces the mechanical sound radiation. The soundproofing elements 4 and 4 'are circumferentially formed within the cylindrical housing as a hollow cylinder, the internal dimensions of the hollow cylinder being adapted to the external dimensions of the cylindrical drive element 1 in this area.

The illustration with regard to the sound insulation elements 4 in the right part of the drawing and the sound insulation elements 4 'in the left part represent two different embodiments, which for the sake of simplicity are shown in a single figure (separated by double lines). The cylindrical insulating element 4 can be inserted into the cylindrical housing 3 through the opening in the drawing (at the bottom) and at the same time forms the carrier element for the drive part 1 with regard to radially directed forces. Another insulation element 6 in the form of a block lies against the bottom of the housing 3, which is closed at the top, and absorbs forces originating from the drive part .1, which are directed axially. This block 6 can also be inserted in front of the drive part 1 in the housing 3 and fastened there. After the insulation elements 4 and 6 have been introduced, the drive part 1 is likewise pushed into the housing from below and lies against the inner surface of the insulation elements 4 and 6.

The cylindrical insulating element 4 is supported in the axial direction by metallic ring elements 5 and 5a. These ring elements 5 and 5a can be inserted into the cylindrical housing from the lower opening side and are screwed in place. In the axial direction they have such a dimensioning that the insulating element 4 is held. In the radial direction it is dimensioned such that it supports the drive element 1 when loaded in the radial direction when the insulation elements are compressed in such a way that their linearity range is exceeded. Since the drive part 1 is generally switched off when the tool is used as a crowbar, and since a pulsating drive of the chisel is not required in this case, no noise pollution is associated with this operating state, so that the direct metallic contact of the drive part 1 and housing 3 is harmless.

The insulation element 4 is inserted under radial prestress and the insulation block 6 under axial prestress, so that compression of the insulation element 4 is present even when the chisel and the central position of the drive part 1 are unloaded in the transverse direction. In this way it is achieved that with radial loading during operation - if the stop surfaces of the ring elements 5 and 5a have not yet been reached - contact between the insulating elements and the drive part 1 is guaranteed, so that on the one hand a stable contact due to the mechanical contact and the resulting frictional engagement Position of the drive part is achieved and on the other hand, even with radial deflection, the non-loaded side exerts a damping effect and thus helps to effectively reduce vibrations of the drive part, which can contribute to the disturbing sound radiation.

The lower opening of the housing 3 is surrounded by a flange part 7 ', which in operation is adjacent to an annular support frame 8, which carries a membrane-like disk 9 made of fabric rubber, which is designed in the form of a clamped elastic disk and with its outer edge in the annular frame part 8 is clamped. The elastic disk holds the chisel 10 in a relaxed central position, in which there is a distance from the percussion piston 2 with respect to the rear surface of the chisel 10, so that it only acts on the chisel when it is excited by the drive part 1 to pulsate vibration.

The chisel 10 is also provided with a collar 11, which presses against the elastic disk 9 by means of sealing lips 12 and thus prevents the escape of liquid (drive medium) from the housing 3. The disc 9 holds the chisel centering and at the same time forms an insulation measure against noise components emerging directly from the housing 3.

The collar 11 lies in the operating state on the disc 9, which consists of fabric rubber - or other corresponding elastic material - so that an optimal seal is given. However, the main force which is absorbed by the chisel 10 and transferred to the housing is not absorbed by the collar 11, but by stops 27 which limit the movement of the chisel end into the housing 3 in such a way that the disk 9 'through the Collar 11 is already under sufficient prestress for sufficient compression, so that the necessary sealing is ensured.

The insulating effect of the disc 9 is additionally supported by a block 13 made of soft elastic material (foam or the like), which surrounds the chisel 10 in its areas protruding from the housing 3 (with the exception of the chisel tip) and absorbs vibrations which are caused by the chisel itself radial vibrations are emitted. The block 13 is shown in the left part of the drawing in a relaxed position, while it is shown compressed under load in the right part, so that an enlarged part of the chisel 10 is released. The block 13 is pressed into an annular insert of the frame part 8 during compression, so that it is securely held and guided there and, in the compressed state, provides increased resistance to external loads.

In the alternative embodiment, separated from the left part by double lines, the insulating elements 4 'are inserted in the radial direction through openings provided within the housing 3. The steel parts 5 ', 5a' and 5b 'surrounding the elements 4' are adapted to the dimensions of the insulation elements 4 'with respect to their inner surfaces - which are adjacent to the insulation elements 4'. After the drive part 1 has been inserted, the parts are inserted into the housing 3 from the side with the chisel 10 and pressed by means of cover parts 5c 'and 5d'. The cover parts are tightened by means of screws, the oversize of the insulating elements 4 'being dimensioned in the radial direction in such a way that when the cover parts 5c' and 5d 'are tightened they receive the correct prestressing - as described above.

The insulation elements 4 'are preferably vulcanized onto the cover parts 5c' or 5d 'and face the opposite side of the cover parts each side also has a vulcanized metal plate 5c 'and 5d', which increases the resistance of the insulation elements on the inner surfaces. The structure of the insulation elements 4 and 4 'corresponds to elements such as are available as «metal-rubber elements or« silent blocks ».

The breaker is shown in the figure in the loaded state, the rear (top) of the drive part 1 exerting a compressive force on the insulating block 6. In the unloaded state, an extension 14 of the drive part 1 is supported on locking elements 15 and 16, which are introduced laterally into the housing and prevent the drive part 1 from falling out in the downward direction. If the drive part 1 together with the chisel are to be removed from the housing 3, the blocking elements 15 and 16 can be removed to the outside and release the drive part 1. Accordingly, the ring frame 8 can be removed so that the drive part 1 is accessible without difficulty. A feed opening 17 in the housing 3 allows the passage of a pressure hose 18 for the working medium driving the chisel. The housing carrying the drive part 1 can be screwed onto the carrier device (excavator or the like) via articulation points 19 and 20. In order to keep disturbing vibrations away from the boom of such a carrier device, additional damping elements 21 to 24 are provided at the articulation points 19 and 20, which are designed as buffers.

In order to avoid the emission of disturbing vibrations due to natural vibrations over surface areas of the housing 3, this is additionally provided on its inside with damping material 25, which consists of a corresponding foam or a sandwich system of rubber and outer metal layers and is capable of, on the one hand, the To reduce the transmission of disturbing vibrations to this housing and on the other hand to form a damping for natural vibrations of the housing.

A support made of plastic 26 reduces the noise when the impact piston 2 strikes the rear chisel surface. A fixed ring 27 limits the movement of the percussion piston by means of an edge provided thereon.

To prevent the ingress of dirt or the escape of liquids (hydraulic oil, etc.), the housing is additionally protected in the region of its openings by sealing lips, as is shown in the example of ring 9. Corresponding sealing lips 28 are also provided on the lead-through opening for the hydraulic line 18 or at corresponding other locations.

While the material of the element 13 is relatively soft in order to achieve a good seal and sound absorption of the vibrations emitted by the chisel, a plastic sleeve 29 surrounding the casing 13 is relatively rigid. The cuff is movable and, when the cuff is compressed as a result of being placed on the workpiece, is pushed back into the position denoted by 19 ', so that it forms protection and guidance at the same time.

A further exemplary embodiment of the invention is shown in section in FIG. 2, the overall arrangement being shown shortened in length for reasons of clarity. The reference numerals have been increased in each case by “100” in relation to the exemplary embodiment shown in FIG. 1 for corresponding components.

In the case of the “pot-shaped or trough-shaped construction, the drive unit 101 was inserted into the cylindrical housing — consisting of the side wall 103 and the bottom part 108 — from above. The annular damping elements 104 and 104a have an oversize in the radial direction, the required axial forces being overcome when the drive unit 101 is inserted by corresponding pressing tools. To facilitate insertion, the upper damping element 104a has recesses 104b which are machined into the inner surface and bring about a continuous compression of the damping material in the radial direction outwards, so that the resistance to compression in this direction - and thus the non-linearity - accordingly increases. Dodge in the axial direction is prevented by elements 105 and 105a.

In the case of the upper annular damping element 106a, which is held on the ring part 105b in the axial direction, there is an axial oversize, which is transformed into a radial pressure component by pressing the cover 107b. The oversize of the annular damping element 106a in the axial direction is larger than the corresponding oversize of the circular disk-shaped damping element 106, so that the lateral guidance due to compression of the elements 106a is particularly great when the drive unit is loaded by the chisel and is located in the housing axially pushes upward under compression of the disk 106. In this case, the annular element 106 can only move to a reduced extent into the space accommodated by the disk 106 under load, so that the resistance of the ring 106a to compression is now also increased and a particularly rigid guidance takes place in the radial direction, the sound-absorbing Effect is slightly reduced, but the drive element does not yet strike the metal limiting element 105b.

The base part of the “pot or” cup has a damping element 109 in the form of a circular disk, which is supported on the base part 108 and cushions the drive unit 101 toward the interior of the housing. The collar 111 'of the chisel 110' rests on the base part 108 against a further circular disk 109a which is inserted into a corresponding recess and forms a damping element, so that for the interior of the Sound-propagating parts of the housing through the elements 109, 108 and 109a result in a sandwich-like arrangement, which produces effective sound damping. In this way, a seal with great rigidity results at the same time, since the middle ring of the sandwich construction is rigid, so that uncontrolled movements of the drive unit and the chisel with respect to the housing are reliably prevented.

It can be seen that the embodiment of the invention is not limited to the examples shown and can have many other configurations. Thus, in the case of advantageous alternatives, it is particularly advantageous to insert the insulating elements in the longitudinal direction, which rails can be provided on the inside of the housing 3 or on the outside of the drive part 1. It is left to the respective practical embodiment to arrange the insulating elements 4 or 4 'or 6 such that they remain connected to the housing or to the drive part when the drive part 1 is removed from the housing 3. In the embodiment shown in FIG. 2, the stop rings 105 to 105b can be omitted in the case of smaller hammer designs, namely because the damping elements, because of their non-linearities, can all absorb the forces themselves.

Claims (21)

1. An hydraulic lift hammer with a steel casing (3, 103) which completely encloses the tool formed from the drill (10, 110') and its drive unit (1, 101), with the exception of an opening for the passage of the free end of the drill, characterised in that the drive unit (1, 101) almost completely enclosed by the casing (3, 103) is mounted ((guided)) and supported inside the casing with the aid of elastic and attenuating material (4, 4', 6, 104, 104a, 106, 106a, 109).

2. A lift hammer according to claim 1, characterised in that the elastic and attenuating material (4, 4', 104, 104a, 106, 106a, 109) is firmly arranged between the outer periphery of the drive unit and the casing inside on the casing or on the drive unit and/or is formed to be capable of insertion into the casing from outside through an assembly opening (7) which may be separate if necessary.

3. A lift hammer according to any one of the preceding claims, characterised in that the elastic and attenuating material (4, 4', 6, 104, 104a, 106, 106a, 109) is arranged inside a guide (5, 5a, directed transversely or longitudinally in the casing.

4. A lift hammer according to any one of the preceding claims, characterised in that the elastic and attenuating material (4, 4', 6, 104, 104a, 106, 106a, 109) is assembled under prestress.

5. A lift hammer according to claim 4, characterised in that the prestress is produced as a result of oversize of the elastic and attenuating material by pressure at least of one lid element (107b, 5c', 5d') which closes an assembly opening, on to the elastic and attenuating material (5c', 5d', 106), when said material takes up its end position abutting the face surrounding the relevant opening.

6. A lift hammer according to claim 4, characterised in that the prestress is produced as a result of oversize of the elastic and attenuating material by pressing in the drive unit (101) into the casing which is cladded with the elastic and attenuating material (104, 104a, 106a).

7. A lift hammer according to any one of the claims 4 to 6, characterised in that the prestress is produced by compression of the elastic and attenuating material when joining together the casing (103) while incorporating the drive unit or arranging the one lid element (107b) in a direction transverse to the desired prestress direction.

8. A lift hammer according to any one of claims 4 to 7, characterised in that the casing (3, 103) for housing the drive unit (1, 101) is formed in cup or pot or trough shape and the latter may be inserted into the casing from the side which is initially open.

9. A lift hammer according to any one of the preceding claims characterised in that the prestress between the casing (3, 103) and the drive unit (1, 101) is selected such that the latter is not released, even when the loading is occurring operationally, from the surface of the material which is placed rearwardly in the direction of loading.

10. A lift hammer according to any of the preceding claims, characterised in that the radially or axially elastic and attenuating material (4, 4', 6, 104, 104a, 106, 106a, 109) is made so yielding and is so shaped that a metallic contact is made with the outer casing (3) for the purpose of direct transmission of forces and moments, from a predetermined force loading onwards. Which corresponds to an operational limit value and which acts on the said loading, by corresponding compression.

11. A lift hammer according to any one of the preceding claims, characterised in that the elastic and attenuating material has a highly progressive spring constant.

12. A lift hammer according to any one of the preceding claims, characterised in that the elastic and attenuating material is reduced in its thickness from the casing towards the drive unit, more particularly as a result of recesses provided there, in its surface (104a) facing towards the inside of the casing.

13. A lift hammer according to any one of the preceding claims, characterised in that the elastic and attenuating material comprises a cellular polyurethane elastomer.

14. A lift hammer according to any one of the preceding claims, characterised in that the opening (7) for the passage of the drill is provided with an elastic cladding in the form of a disc (13) which in its centre position holds the drill impact face in a position which is close to the percussion piston (2).

15. A lift hammer according to any one of the preceding claims, characterised in that the drill (10) is provided with a flange (11) which comes into mutual action with the disc (9) such that, in the operating condition under load in the region of its central opening, it abuts the said opening.

16. A lift hammer according to claim 14 or 15, characterised in that the disc (9) is made from rubberised fabric.

17. A lift hammer according to any one of the preceding claims characterised in that the passage opening for the drill is provided a rigid disc (108) firmly connected to the casing and forming a closure for the casing, said disc being provided on both sides with the elastic and attenuating material (109, 109a), the inside of which forms the stop face for the drive unit.

18. A lift hammer according to any one of the preceding claims characterised in that the passage opening (7) for the drill is loosely enclosed with a jacket (13) made of elastic and attenuating material.

19. A lift hammer according to claim 18, characterised in that in order to guide the jacket (13) during its at least partial taking up upon compressing as the result of impact against a workpiece, a frame (8) enclosing this is provided on the drill-side end of the casing.

20. A lift hammer according to claim 19, characterised in that the frame (29, 29') is compressible in the drill direction, more particularly telescoped or formed like a bellows.

21. A lift hammer according to any one of the preceding claims, characterised in that the drill has on its rearward collision face for the percussion piston (2) at least one plastics element (26) placed on its end or placed into a corresponding recess.

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