SE469971B - Pressure medium driven impact mechanism - Google Patents

Description

469 97 "! Become too high for certain uses, whereby it can. Local points arise with very high temperatures of the work tool in question and thus its service life can be shortened considerably due to premature material fatigue. This applies in particular when using the percussion mechanism for sawing movements and the like, since only a very limited part of, for example, a saw blade is used and exposed to a high frequency.

BRIEF DESCRIPTION OF THE INVENTION The object of the present invention is to provide a percussion mechanism of the kind mentioned in the introduction, which enables both an accurate definition of the stroke length of the mechanism substantially independent of the pressure of the tool driven pressure medium and achieving long strokes relative to the dimensions of the sealing member. .

This object is achieved according to the invention in that in a percussion mechanism of the type mentioned in the introduction the sealing means is arranged to move axially relative between the working means and the abutment means relative to a pressure medium which, by means of the pressure medium entering the working chamber, moves from the said assembled position. of these means during sealing abutment against the circumferential wall of the working chamber and axial sealing between the working chamber and the other of the means, and that one of the working means and the abutment means has means arranged to at a predetermined distance from its position reached by the other means in said collapsed position allow the pressure medium to exit the working chamber.

Due to the axial movement of the sealing means relative to one of the working and abutment means and the arrangement of said pressure medium outlet means, on the one hand a very precisely defined stroke length is achieved and on the other hand that the stroke length can be given virtually any desired size by suitably placing the pressure medium outlet means. f! In the previously known percussion mechanisms, the distance between working and abutment means, at which the pressure medium is allowed to leave the working chamber, depends on the pressure of the pressure medium, since the axial extent of the sealing means and thus the sealing action depends on the prevailing pressure. axially relative to one of the working and abutment means during sealing abutment against the circumferential wall of the working chamber and axial sealing between the working chamber and the other of the means and obtained a shape much less dependent on the medium pressure when the other means reaches the position in which the pressure medium is allowed to exit the working chamber.

According to a preferred embodiment of the invention, the sealing means is arranged that, by the action of the pressure medium entering the working chamber from the said collapsed position caused by distinctive movement between the working means and the abutment means accompanying the other of these means while moving axially along the circumference of the working chamber. , and it is the circumferential wall of the working chamber which has said pressure medium outlet means arranged to allow at a predetermined distance reached by the sealing means from its position in said collapsed position to allow the pressure medium to exit the working chamber.

According to a further preferred embodiment of the invention, said pressure medium outlet means comprises at least one opening radially arranged in the circumferential wall of the working chamber, and preferably this opening is supplemented by an increase in the cross section of the working chamber, so that simultaneous radial as well as axial sealing of the working chamber is interrupted. distinct and well-defined.

Tools provided with the percussion mechanism according to the invention thus have a more even function and thus achieve a result of higher quality than tools provided with previously known percussion mechanisms when machining surfaces and the like. Due to the achievable increased stroke length, tools provided with this type of stroke mechanism gain new possible areas of use, where a larger stroke 469 971 is almost a prerequisite, such as, for example, sawing and the like.

Additional advantages and advantageous features of the invention will become apparent from the following description and other dependent claims.

BRIEF DESCRIPTION OF THE DRAWINGS Hereinafter, an exemplary preferred embodiment of the invention is described with reference to the accompanying drawings, in which: Fig. 1 is a side view of a tool provided with a pressure medium driven percussion mechanism according to the invention, Fig. 2 is a comparison with Fig. 1. enlarged longitudinal sectional view of the tool shown in Fig. 1, illustrating the construction of an impact mechanism according to a preferred embodiment of the invention; Fig. 3 is a partially enlarged partial sectional view illustrating the configuration of the working chamber and the sealing member of the percussion mechanism shown in Fig. 2 with working means and abutment means in the most assembled position, and Fig. 4 is a Fig. 3 substantially corresponding view, but with the working means and the abutment means moved apart to substantially the opposite end position.

DETAILED DESCRIPTION OF A PREFERRED EMBODIMENT OF THE INVENTION Fig. 1 shows a tool 1 which for exemplary, but by no means limiting purpose is provided with a saw 2 arranged to perform a reciprocating movement thanks to the casing 3 provided inside the tool. . The tool has 469 971 at one end a means 4 for connecting pressure medium, in this case air via a hose 5 cut off for reasons of space, and a line 6, preferably a flexible plastic hose, for discharging spent pressure medium. Thanks to all the consumed pressure medium. via the line 6 is led away from the workplace and does not, as is usual for this type of tool, flow out into the area of the opposite end of the tool, the working environment is significantly improved for the person handling the tool by reducing noise and swirling dust. Hereafter, for the sake of simplicity, reference will always be made to compressed air, although of course other types of pressure medium are also included.

With reference to Fig. 2, the construction of the percussion mechanism according to the invention, arranged inside the tool 1, will now be described. It consists in a conventional manner of an axially guided reciprocating working means 7 inside the housing 3, to one, free end 8 of which different types of working tools, such as small saws, chisels and the like, can be attached by inserting a small rod between them between the jaws. 9 of the working means and then tightening a nut 10. At its opposite end, the working means 7 comprises a plate 12 screwed to the elongate part 11 of the working means with a circular bottom 13 facing in the axial direction away from the end 8 and circumferential walls 14 extending substantially perpendicular thereto in the same direction. with cylinder shell shape. An abutment member or balance body 15 is arranged in the axial direction slidably guided along an elongate body 32 received at the pressure air supply end of the tool 16 and extends into the space inside the circumferential wall 14 of the plate while being axially guided also via guide means in the form of O-rings 17, 17 'which abuts' against both the inner wall of the housing and the circumferential wall 14 (ring 17'). The elongate body 32 is also controlled via an O-ring 17 relative to the housing 3.

The working means 7 and the stop means 5 are actuated in the direction of each other by respective compression springs 18 and 19, respectively, which are arranged to act between axially directed surfaces of the housing and respective means and in a rest position in the absence of compressed air in the connecting means 4 pour the stop means 15 'with their front axially directed surfaces 20 in prestressed abutment against a sealing member 21 abutting against said bottom 13, here in the form of a conventional elastic O-ring.

The percussion mechanism so far described, as well as on the actual design of the plate 12, is previously known, and now the new and peculiarity of the percussion mechanism according to the invention, namely the method of determining the stroke of the working means, will be described with reference also to Figs. 4.

Fig. 3 illustrates a position in which the working means 7 and the abutment means 15 are maximally brought together and which substantially corresponds to said rest position. In this position an outwardly sealed working chamber 22 is formed between said bottom 13 and the axial surfaces 20 of the abutment member facing this bottom. The sealing member 21 abuts radially close to the circumferential wall 14 and seals the working chamber 22 axially between the abutment member and the circumferential wall.

The sealing member 21 is in this position slightly deformed by the forces which seek to press the working member and the abutment member against each other.

The body 32 has an inner channel 23, which at one end opens towards the compressed air connection means 4 and continues in the opposite direction in the stop means 15 and at its other end 24 opens into the working chamber 22 (see also Fig. 2). When supplying compressed air via the duct 23 to the working space 22, this compressed air will press apart the working means 7 and the abutment means 15, so that the working means 7 moves forward against the action of the spring 18, while the abutment means 15 moves in the opposite direction against the action of the spring 19.

The sealing member 21 is arranged freely movable in the working chamber and during this disengaging movement will be pressed via the compressed air radially against the circumferential wall and at the same time axially against the axial surfaces 20 of the abutment member and thereby follow the working member in its movement while maintaining the working chamber 22 sealing outwards. The bottom 13 of the working chamber is preferably formed by a lubricated Teflon washer, so that the sealing member can easily release from the bottom during the disengaging movement of the working and abutment member.

The circumferential wall 14 of the working chamber 22 is provided at a distance from the bottom 13 of the working chamber with circumferentially evenly distributed through holes 25. When the sealing member (O-ring 21) during said disengaging movement of the working member 7 and the abutment member 15 with its radial abutment surface it reaches the bottom 13 facing the boundary 26, the radial seal of the sealing member will be interrupted via said hole 25 (see the position according to Fig. 4), and the compressed air present in the working chamber 22 can flow past the sealing member 21 and out of the holes 25. A free space 27 is arranged outside the circumferential wall 14. between the plate and the casing. The compressed air can then move to the outlet 6 via this free space and by the stop means being provided with a groove 28 on one side.

This means that now only the two compression springs 18 and 19 act on the working means 7 and the abutment means 15, respectively, so that the disjointed movement after a negligible continuation transitions to an opposite joining movement. Thereby the sealing member 21 will be pushed towards the bottom 13 of the working chamber and again seal it, whereupon compressed air is again supplied to the working chamber and presses apart the now position according to Fig. 3, with deformed sealing member 21, occupying the working and abutment means.

The circumferential wall 14 of the working chamber 22 has, at the height of said boundary 26 facing the bottom 13, a concentrically increased 469 971 diameter increase, so that the circumferential wall has a wall portion 29 extending from the boundary 26 away from the bottom 13 with a larger inner diameter than the closer bottom 13 located wall portion 30.

When the sealing member 21 during the disengaging movement with its radial abutment surface abutting against the circumferential wall reaches said limit 26, the diameter increase of the circumferential wall will cause an interruption of the axial seal. between the circumferential wall and the stop means, so that compressed air present in the working chamber can flow axially past the sealing means 21 and here out of the holes 25.

Thanks to the interaction of the holes 25 and the cross-sectional increase of the circumferential wall, a very sudden, distinct and strong or large opening of the previously sealed working chamber is obtained. This cooperation thus means that the end of the stroke of the working organ and thus the stroke of the tool is well defined. In this way, the stroke of the tool does not depend on the dimensions of the sealing member or the pressure of the compressed air as in prior art percussion mechanisms, but it is the position of the holes 25 and the cross-sectional increase of the circumferential wall 14 that determines the stroke, and thanks to this the stroke can be selected in advance. depending on the use the tool is intended to obtain by placing these compressed air outlet means at a suitable distance from the bottom of the working chamber 13.

It would then also be conceivable to provide a tool of this kind with a set of different discs 12 for changing the disc by operating the screw 31 for 'varying' the stroke length of the tool.

The invention thus not only achieves a stroke mechanism with a well-defined stroke, but this stroke can also be given any desired length by suitably dimensioning the working chamber and placing the compressed air outlet means. Due to the greater stroke length of the stroke mechanism achievable in this way compared to previously known ditto, a tool equipped therewith can be used in working situations where a relatively long stroke and a lower frequency are desired. To achieve this lower frequency, the compression springs 18 and 19 are not required to be made softer as with previously known percussion mechanisms, but this ensures the increased stroke length. An example of such a use V? of 469 971 is sawing of small contours, as in this way a larger part of the saw blade can be used and the generation of high temperatures for the saw blade material is avoided.

The well-defined stroke gives a clearly improved function and increased efficiency of the tool when using it, for example as a slag chopper to, for example, weld away welding slag or the like, but this well-defined stroke naturally has advantages in all conceivable applications of a percussion mechanism thereof. type provided tools.

Examples of dimensions of a tool of the type shown in the figures are: the inner diameter of the circumferential wall about 20 mm, the cross-section of the O-ring 2 mm, the distance between the bottom 13 and the border 26 3 mm, the diameter of the holes 2 2 mm, spaces between the holes 25 2 mm, increase in the diameter of the working chamber at the limit 26 0.3 mm. Such a tool has a stroke of 4 mm. The frequency of the tool is about 221 beats per second.

The invention is of course not in any way limited to the preferred embodiment described above, but a number of possibilities for modifications thereof should be obvious to a person skilled in the art, without this departing from the basic idea of the invention.

For example, it would be possible as a pressure medium outlet means to have only holes in the circumferential wall of the working chamber or a cross-sectional increase thereof, in the latter case it is necessary that the pressure medium is then allowed to pass the abutment means axially. The neck could have any desired number or be replaced with slits or the like. The increase in cross-section could also be partial, so that for instance the cross-section could be increased in intervals along the circumference of the circumferential wall, so that, for example, axially extending grooves beginning at said boundary 26 could be arranged in the circumferential wall. 469 971 10 It 'would be conceivable. that the working chamber has a different cross-sectional shape than circular, in which case the sealing member is to be designed in a corresponding manner. Likewise, the bottom and circumferential walls of the working chamber could be arranged on the abutment member and the opposite end of the working member could be designed in adaptation thereto.

The sealing means could be fixedly arranged on the means movable relative to the circumferential walls of the working chamber, in the case shown the abutment means, and it would then also be conceivable to arrange a separate spacer attached to the bottom of the working chamber to define the most collapsed position and a sealing means surrounding the member movable relative to the circumferential wall during radial abutment against the circumferential wall and axial sealing of the working chamber.

Thanks to the arrangement of the two compression springs, a practically complete balancing of the mechanism is achieved and it is also arranged resiliently in the tool housing, so that firstly no or insignificant vibrations are transmitted to the housing when the tool is idling, and secondly neither some harmful vibrations are transmitted to the housing when the tool is applied to a work surface for chiseling or the like. However, it would also be conceivable to refrain from this vibration and to arrange the stop means fixed relative to the housing, so that the relative movement between working means and stop means is achieved only by a movement of the working means.

Claims (13)

469 971 Patent claims 1. Pressure medium driven, reciprocating percussion mechanism having at least one working member (7) in the form of a piston or the like and at least one abutment member (15) arranged axially movable relative to each other, and in at least one, first of which is designed a working medium (22) for pressure medium open to the second member, a sealing means (21) being arranged inside the working chamber between the working means and the abutment means and in the most collapsed position of the relative movement of these means abutting radially against the circumferential wall (14) of the working chamber and sealing working chamber , characterized in that the sealing means is arranged to move axially relative to one of these means during sealing action against the circumferential wall of the working chamber (14) by actuating the pressure medium entering the working chamber from said position from said position. axial seal between the working chamber and the other of the organs, and that one of the working o and the abutment means have means (25, 29) arranged to allow at a predetermined distance reached from the position of the second from the position in said collapsed position to allow the pressure medium to exit the working chamber. Mechanism according to claim 1, characterized in that the sealing means (21) is arranged to, when the pressure medium entering the working chamber enters from the said collapsed position due to the brought together position, accompany the disengaging movement between the working means and the abutment means. to move axially along the circumferential wall (14) of the working chamber, and that the circumferential wall of the working chamber has means (25, 29) arranged to allow a predetermined distance from its position in said collapsed position in said collapsed position to allow the pressure medium to exit the working chamber. Mechanism according to claim 2, 469 971, characterized in that said pressure medium outlet means comprises at least one opening (25) arranged in the circumferential wall (14) of the working chamber (14) arranged at a predetermined distance from the substantially axially axial bottom of the working chamber towards the second member. ) arranged to interrupt the radial seal of the sealing member (21) against the circumferential wall (14) and connect to the working chamber (14) when the sealing means reaches the circumferential abutment of the working means and the abutment means with its radial abutment against said circumferential wall against said circumferential wall. 22) for releasing pressure medium therefrom. Mechanism according to claim 2 or 3, characterized in that said pressure medium outlet means comprises a bottom (13) in the circumferential wall (14) of the working chamber (14) directed at a predetermined distance from the substantially axial substantially axially, towards the second member (15) at least along a part of the circumference made an increase (29) of the cross-section of the working chamber arranged to reach the said boundary wall (14) of its boundary wall (14) facing its circumferential abutment with the radial abutment of the working means and abutment means. (26) interrupting the axial seal of the sealing member (21) between the circumferential wall (14) and the second member (15) and allowing pressure medium to leave the working chamber (22) by passing the sealing member. Mechanism according to any one of claims 2-4, characterized in that the sealing member (21) is arranged freely movable in the working chamber (22) and that the pressure medium present in the working chamber is pressed against substantially axially, towards the bottom (13) of the working chamber. surfaces (20) of the second (15) of the means for following this means in its movement relative to the circumferential wall (14) of the working chamber. 6. A mechanism according to any one of claims 2-5, characterized in that the second (15) of the means has substantially axial surfaces (20) directed towards the bottom of the working chamber, and that the sealing means (21) is arranged to function o! 469 971 13 as a spacer between these surfaces and the bottom (13) of the working chamber and define the most collapsed position of the working and abutment means by being axially pressed therefrom by 'said surfaces' against said bottom. Mechanism according to claims 3 and 4, characterized in that the boundary (26) of the opening (25) facing the bottom (13) of the working chamber and the cross-sectional increase (29) of the circumferential wall are arranged at substantially the same distance from said bottom ( 13) for substantially simultaneously interrupting the radial and axial sealing of the sealing member (21) against the circumferential wall (14) of the working chamber. Mechanism according to claim 3, characterized in that the pressure medium outlet means comprises a plurality of substantially equally large and radially directed openings (25) arranged around the circumferential wall substantially regularly and at substantially the same distance from the bottom (13) of the working chamber. Mechanism according to claim 8, characterized in that the openings (25) have a substantially circular cross-section. 10. A mechanism according to claim 4, characterized in that the circumferential wall (14) of the working chamber has the shape of substantially a cylinder shell and that said cross-sectional increase (29) is formed by a concentrically formed, substantially stepped diameter increase of the cylinder shell. Mechanism according to any one of claims 1-10, characterized in that the sealing member is a conventional O-ring (21) of elastic material and with 3. unloaded condition substantially the same outer diameter as the inner diameter of the working chamber (22) in connection with its bottom (13). A mechanism according to claim 8 or 9, characterized in that each of the openings (25) has substantially the same cross-sectional area as. the sealing member (21) has in an axially directed plane. 13. A mechanism according to claim 8, characterized in that the circumferential distance between two successive openings (25) substantially corresponds to the circumferential direction largest dimension of each of the openings. IN)