DE19825408A1 - Oscillating saw with rotarily driven holder and saw-blade container - Google Patents

Abstract

A pressure element is pressed towards the rotarily driven holder (8) and fixes the saw-blade on the holder towards the holder's pivot axis. A tie-rod (17) grips the pressure element. A clamping element (21) is supported on the holder and adjustably held on the tie-rod. A spacer piece (28) between the holder and clamping element is adjustable in length towards the tie-rod. The spacer piece has two relatively movable support bodies (29,30) supporting each other on facing support surfaces (31,35).

Description

The invention relates to an oscillating saw for me medical purposes with an oscillating rotary transmission level holder and a non-rotatable seat for a se blade on the holder, with one against the holder pushable, the saw blade on the holder towards the Axis of rotation of the holder defining pressure element which is attacked by a tie rod, and with one on the tie rod ker held, supported on the holder Spannele ment, its position on the tie rod so adjustable is that thereby the tie rod, the pressure element and so that the saw blade clamps against the holder.

Such a saw is for example from the company Zim mer Inc. under the name The Hall Series 4 Oscillator offered. The clamping element is on an external ge winch of the tie rod screwed on, the tensioning path must be like this be sized so that saw blades are different Thickness can be used, and accordingly with thin saw blades, the clamping element over a great way to be moved, so it may be a very high number of turns of the mother art gene clamping element necessary.

It is an object of the invention to provide a generic os training saw so that they ge on the one hand  is suitable for holding saw blades cher thickness and that on the other hand, nevertheless, the tension paths be kept small for the tie rod.

This task is the case of an oscillating saw type described above ge according to the invention triggers that a distance between the holder and clamping element piece is arranged, its length in the direction of the train anchor is changeable.

With such a solution, the length of the distance piece to the thickness of the saw blade used be fit, with a thin saw blade the length of the spacer enlarged, with a thick saw sheet reduced, so that the tension path of the tie rod in be kept essentially the same in all cases can.

The length of the distance can be changed by the user appropriate handling can be carried out according to a particularly preferred embodiment is, however, featured see that the clamping element and the spacer such are in operative connection that the clamping element at Be the length of the Spacer enlarged. This enlargement can tion preferably go so far that for the distance the maximum available length is taken, so that, conversely, the span mini is lubricated. The spacer is therefore automatically the same table the missing thickness of the inserted saw blade and thus ensures a high level of user-friendliness  speed because the clamping element only has a small clamping distance must travel, for example, the reverse down number of a screwed clamping element puts.

The length of the spacer can change continuously be derbar in a preferred embodiment however, provided that the spacer step in its length is changeable. The one for the clamping element necessary span is essentially on limits the amount of such a level, if necessary it can be even lower.

In a preferred embodiment, that the spacer two relative to each other across Has tie rod direction displaceable support body, the mutually facing support surfaces who support, and that at least on a support body the support surface on adjacent sections points, which are offset against each other in the tie rod direction are. Simply by shifting the two supports body is thus a change in length of the spacer possible.

In particular, the adjacent Ab cuts of the support surface may be designed like a staircase.

It is particularly favorable if the two supports body sleeve-shaped surround the tie rod and to the cross displacement around the tie rod axis against each other are rotatable. Just by relative rotation of the two  Support bodies come with different sections the opposite support surface to each other to plant, and this leads to a change in length of the Spacer.

The clamping element can basically in different Be slidably attached to the tie rod, esp it is advantageous if the clamping element on the Tie rods rotatably mounted around its longitudinal axis and is guided such that it is at a twist changes axial position along the tie rod. This can through a suitable guideway, for example wise by a cam track, but in particular can also be provided that the clamping element on an off the thread of the tie rod is screwed on.

When using a spacer with two against each other other rotatable support bodies and when using egg Nes rotatable clamping element can according to one before drafted embodiment of the invention may be provided that the clamping element and one of the two support bodies stand in a friction connection, so that at a Dre hung of the clamping element and the support body rotated becomes. This friction connection therefore leads to the fact that with egg ner rotation of the clamping element of the support body with is taken until its rotational movement through the contact the two support bodies is limited. With a wide one ren twist of this clamping element remain the two Support body in the angular position and once reached are caused by the displacement of the clamping element in Towards the tie rod approximated until their  Support surfaces are pressed firmly against each other. On this way the maximum possible length of the Spacer set as soon as the clamping element in Clamping position is rotated. The span of the Spannele This minimizes mentes.

It can also be provided that the two Support body have stops that the Relativverdre hung the support body when increasing their distance limit their support surfaces. So if the instep element is opened, it takes off by friction the support body until the support surfaces of the two support bodies a maximum distance from each other take in this position, the support body remain by then when turning the clamping element in the release position. This is a maximum ver sliding movement of the tie rod possible, so that very thick saw blades can be easily inserted nen.

It is favorable if to form the friction connection the support body resiliently against the tie rod the clamping element is pressed.

In particular, it can be provided that the support body pressing against the tensioning element Supports. Such an arrangement has the intent partly that the spring has a double effect, näm Lich puts it once by pressing the support body to the clamping element a friction connection between these parts, on the other hand moves the feet  which thereby increases the tensioning element and its size stood by the holder. This will make the tie rod Pressing element pressed against the holder, so that a provisional fixation of an inserted in the recording Saw blade is done, but only with a relative low force determined by the spring. A be drive-ready pressing of the saw blade then takes place only by the tension of the tensioning element.

Can be used to twist the tensioning element on the tie rod a handle may be provided.

It is beneficial if the handle and the Spannele ment to rotate with play and if this Game is greater than the rotation of the oscillating exaggerated holder. It is possible that the Handle stops when the oscillating saw is operating, although the holder, the saw blade held in it and of course also the tie rod, the one held on it Clamping element and the spacer oscillating be driven.

The twist grip can, for example, by the engagement of a non-round driver in a non-round driver acceptance, in particular the driver and the driving recess is in the form of a regular Polygon, the external dimensions of the driver are smaller than the internal dimensions of the take. These polygons can, for example, regularly be hexagons.  

It is also beneficial if the handle is in a certain Angular position is detachable. In operation be thus the handle does not move, even though the handle with it Rotating connection pedaling parts driven oscillating become. If these parts are twisted using the Handle is desired, the handle is released and then due to the playful rotary drive rotatably with the Clamping element connected.

In a preferred embodiment, that the handle is provided with a one-way clutch Twist in the direction of the tension of the tensioning element allows, but is releasably locked in the opposite direction. There through it is easy for the user to clamp Lich, in the clamping direction, the handle can be extended res twist, however, it is not possible to tighten the instep element if this is not desired. Around Allowing this solution must first block the Freewheel can be canceled.

A spring-loaded slide can be arranged in the handle be the resilient against angular fixation against the outside flats of a saw-resistant, surrounding the tie rod the sleeve is pressed, on which the handle is rotatable is stored. Such an angle fixation leads to that the handle is held in an angular position during operation will, however, against overcoming the feet derkraft the handle can be rotated, for example to increase the tension of the tensioning element.  

It is advantageous if the flats on one Wear a protruding step along the longitudinal edge their longitudinal edge, however, is not. This configuration leads to the fact that the spring-loaded slide simultaneously tig forms the freewheel described, since the shooting By rotating the handle on the longitudinal channel strikes and prevents further rotation, with one However, twisting in the other direction is not.

The slide can be activated by an actuator on the handle can be lifted off the flattening, so that then a Rotation against the blocking direction of the freewheel possible is.

The handle can be moved in the axial direction on the Be stored sleeve and the flattening can be on her upper and protruding steps on their lower edge carry. These steps act as a displacement limitation for the handle. Due to the axial displacement of the It is possible to attach the handle to the front of the handle Create tie rods and if the Grip the tie rod in the holder in the release position to move, so in a position in which the on pressure element is lifted from the holder. In this position It is easy to change the saw blade Lich.

It is convenient if the handle on the sleeve festge by a friction connection in the axial direction is placed, for example by inserting a seal ring between handle and sleeve.

The following description of preferred embodiment Forming serves in connection with the drawing of the nä here explanation. Show it:

Fig. 1 is a longitudinal sectional view through the front part of an oscillating saw blade in the region of the storage;

Fig. 2 is a sectional view taken along line 2-2 in Fig. 1;

Fig. 3 is a view similar to Figure 1 when inserting a saw blade.

FIG. 4 is a view similar to FIG. 3 with the saw blade inserted and tensioned;

Fig. 5 is a sectional view taken along line 5-5 in Figure 1 with effective freewheel.

Fig. 6 is a view similar to FIG. 5 with switched off freewheel and

Fig. 7 is a sectional view taken along line 7-7 in FIG. 1.

The oscillating saw 1 shown in the drawing comprises a housing 2 , inside which a drive is arranged, for example an electric motor. Its drive shaft 3 carries a pin 4 arranged eccentrically to the longitudinal axis of the drive shaft 3 , on which a ball bearing 5 is placed ( FIG. 2). On the outer ring of this ball bearing 5 , the arms 6 engage a rocker 7 which is connected to a holder 8 in a rotationally fixed manner.

This holder 8 is in a transverse to the drive shaft 3 through opening 9 of the housing 2 is inserted and rotatably mounted in this through opening 9 by two Ku gel bearings 10 , 11 so that the holder 8 is rotated oscillating about its longitudinal axis when the drive shaft 3 rotates , The angle of rotation is limited to a few degrees.

The holder 8 protrudes from the housing 2 at the upper end and forms a flat support surface 12 for a plate-shaped saw blade 13 , which can be placed on the support surface 12 in such a way that drivers on the support surface 12 , in the illustrated embodiment, for example in the form of pins 14 , dip into corresponding openings 15 of the saw blade 13 and connect it to the holder 8 in a rotationally fixed manner. This with participants can be designed differently, for example, star-shaped rotating body can be placed on the support surface 12 , which immerse in ent speaking openings of the saw blade.

To fix the saw blade 13 on the support surface 12 , a cover-shaped pressure element 16 is provided, which is placed on the saw blade 13 on the side opposite the support surface 12 of the holder 8 and which can be tensioned by a tie rod 17 against the support surface 12 . The tie rod 17 passes through the saw blade 13 , which has an opening 18 for this purpose, and a central bore 19 of the holder 8 . On the side opposite the support surface 12 , the tie rod 17 emerges from the holder 8 and has an external thread 20 at its free end.

A sleeve-shaped clamping element 21 is screwed onto this external thread 20 and has a corresponding internal threaded bore 23 in its base 22 . On the side opposite the floor 22 , the clamping element 21 is closed off by a hexagon 24 . In the interior 25 of the clamping element 21 ra end of the tie rod 17 a nut 27 is screwed up, which is permanently fixed in a suitable manner in its position. As a result, the displacement path of the tensioning element 21 on the external thread 20 is limited.

In the area between the holder 8 and the Spannele element 21 , the tie rod 17 is surrounded by a spacer 28 which comprises two support bodies 29 and 30 .

The support body 29 adjacent to the holder 8 is sleeve-shaped and is supported on the holder 8 in the axial direction, wherein the holder 8 engages in the support body 29 and also fixes it centrally in the radial direction to the tie rod 17 .

The holder 8 remote from the edge 31 of the support body 29 is formed like steps, that is, it forms in the circumferential direction adjacent portions 32 from taking the holder 8 at a different distance.

The support body 30 adjacent to the tensioning element 21 is supported by an inserted ring 33 in the axial direction on the bottom 22 of the tensioning element 21 and has a wall section 34 which extends over a limited circumferential area and which projects in the direction of the other support body 29 and on which forms a support surface 35 facing away from the clamping element 21 , which is laterally delimited by axially parallel edges 36 .

The support body 30 is pressed against the bottom 22 of the tensioning element 21 by a helical spring 37 which gives the tension spring 17 , which is supported on the one hand on the support body 30 and on the other hand on an annular shoulder 38 of the holder 8 . The ring 33 in the contact area of the support body 30 and the clamping element 21 be made of a material with high friction, for example, this ring is designed as an elastomer ring, so that by this axial pressing of the support body 30 against the bottom 22 of the clamping element 21 a Reibver connection arises, which leads to rotation of the tensioning element 21 that the support body 30 is also rotated about the longitudinal axis of the tie rod 17 .

The part of the tie rod 17 protruding from the holder 8 is surrounded by a sleeve 39 which is screwed into the housing 2 and which is permanently connected to the housing 2 by suitable means, for example by gluing.

This sleeve 39 serves as a pivot bearing for a handle 40 into which the sleeve 39 enters and which has a recess 41 which has the shape of a polygon in cross section, in the example shown the shape of a hexagon. The driving recess 41 is so arranged that the hexagon 24 dips of the clamping element 21 in this driving recess 41, with play, because of the hexagonal cross section of the Mitnahmeausneh mung is selected to be greater 41 than the cross section of the hexagon 24th The size differences are chosen so that the handle 40 can be rotated relative to the hexagon 24 by a certain angular amount, but that after this angular amount has been exceeded, a jamming and thus rotational driving occurs. The game is so large that the handle 40 and the hexagon 24 are freely rotatable against each other over an angular range that is greater than the angular range that is stroked by the holder 8 in its oscillating rotary movement.

The handle 40 is attached to the sleeve 39 and is fixed in the axial direction by an elastic ring 42 which is inserted into the sleeve 39 on the outside and which rests on the inside of the handle 40 and thus forms a connection.

The outside of the sleeve 39 carries a number of flats 43 , which are limited on the top and on the bottom by protruding shoulders 44 and 45 , respectively. In addition, these flattened areas 43 are delimited on one longitudinal edge by a shoulder 46 , but such a shoulder is missing on the opposite longitudinal edge.

In an outwardly open, transverse to the longitudinal direction of the tie rod 17 bore 47 of the handle 40 , a slide 48 is slidably supported by a compression spring 49 , which on the one hand rests on the slide 48 and on the other hand on a closure cap 50 of the bore 47 against the Sleeve 39 is pressed so that the end face 51 of the slider 48 comes from a flat 43 of the sleeve 39 to the plant.

In a transverse to the bore 47 bore 52 of the handle 40 , a further slide 53 is mounted bar, which passes through the slide 48 in the region of an opening 54 and there carries an inclined sliding surface 55 to its direction of displacement. The slider 53 protrudes from the handle 40 in the form of a push button 56 . When pushed out, the slider 53 sets the slider 48 in such a way that the slider 48 can move freely in the bore 47 , but if the slider 53 is pushed into the handle 40 , the slider 48 will be in contact with the sliding surface 55 moved against the action of the compression spring 49 so that the end face 51 is lifted off the sleeve 39 ( Fig. 6).

The slider 48 simultaneously forms a fixation for the position of the handle 40 and a freewheel for the handle. The fixation takes place in that the slide 48 is pressed under the action of the compression spring 49 against a flattening 43 of the sleeve. This fi xation can be overcome, however, when the handle 40 is subjected to a greater torque, namely the slide 48 is inserted against the action of the Druckfe the 49 in the bore 47 and allows rotation of the handle 40th This rotation is possible without limitation, however, only in one direction, since the slide 48 can slide over the longitudinal edge of the flattenings 43 in only one direction; on rotation, however, the slide 48 strikes the shoulder 46 of the flat 43 and prevents it another twisting. This gives us the effect of a freewheel. A rotation in the blocking direction is only possible if the slider 48 is lifted off the flattened area 43 by pushing the slider 53 in .

When operating the saw described, first insert a saw blade into it. For this purpose, the handle 40 is first rotated into the open position when the slide 53 is pressed in. This rotary movement leads to a corresponding rotation of the tensioning element 21 and since with the friction connection also to a rotational movement of the support body 30 relative to the support body 29 , which remains fixed relative to the holder 8 . By this rotation of the support body 30 relative to the support body 29 , the support surface 35 of the wall section 34 is rotated ver in an area of the support body 29 in which the distance to the sections 32 is particularly large. There is therefore no longer any contact between the support body 29 and 30 . This rotary movement is limited in that the edges 36 of the Wandab section 34 abut an axially parallel edge 57 of the support body 29 , this edge thus forms a stop for limiting the angle. Upon further rotation of the handle 40 and thus the clamping element 21, the two support bodies 29 and 30 remain ben in this relative position, in which the support surface 35 holds a maximum distance from the sections 32 of the support body 29 .

In this position, it is possible to move the tie rod 17 against the action of the helical spring 37 , so that the pressure element 16 is at a maximum distance from the support surface 12 . This displacement can be carried out simply by moving the handle 40 in the direction of the housing 2 . The handle 40 rests on the hexagon 24 and thereby pushes it together with the tie rod against the action of the coil spring 37 .

In this position of the pressure element 16 , a saw blade 13 can be placed on the support surface 12 .

The user then lets go of the handle 40 , the coil spring 37 moves the tie rod 17 in such a way that it presses the pressure element 16 against the bearing surface 12 and thus fixes the saw blade 13 provisionally in the switched-on position.

A final fixation takes place in that the user now turns the handle 40 in the opposite direction, that is, in the direction in which the freewheel allows the rotation. Due to this twisting, the tensioning element 21 is rotated in the corresponding manner, and this takes the support body 30 with it due to the frictional connection until the edge 36 of the support body 30 strikes sections 32 of the support body 29 from one of the step-like sections. Depending on the thickness of the saw blade used, the support body 30 can thus be rotated to different extents until such a stop occurs, since the tie rod 17 correspondingly protrudes from the holder 8 to the thickness of the saw blade.

The support bodies 29 and 30 remain in this position since the frictional connection between the tensioning element 21 and the support body 30 is overcome when the tensioning element 21 is rotated further. During this further rotation of the tensioning element 21 , only the two support members 29 and 30 in the direction of the tie rod are approached to one another, since the screw-in depth of the tensioning element 21 on the tie rod 17 is changed until the support surface 35 of the wall section 34 contacts one of the sections te 32 creates and thus defines a defined length of the spacer 28 formed from the support bodies 29 and 30 . Upon further rotation of the clamping element 21 , the pressure element 16 is then clamped vigorously against the bearing surface 12 , so that the saw blade 13 is clamped in place.

As soon as this clamping process has ended, the handle 40 remains in the angular position once reached, since the slide 48 rests on one of the flats 43 and opposes resistance to rotation of the handle.

If the saw is now switched on, the holder 8 is driven in an oscillating manner, this then also applies to the clamping element 21 and its hexagon 24 . Since its sen dimensions are smaller than the inner dimensions of the driving recess 41 of the handle 40 , the handle 40 is not carried oscillatingly, but it remains under the action of the slider 48 in a certain angular position. This reduces the moving masses, and the user of the saw is not disturbed by an oscillating movement of the handle 40 .

To release the saw blade is proceeded in the opposite direction, by means of the handle 40 , the Spannele element 21 is rotated into the open position, for this purpose it is necessary to push the slider 48 back over the slider 53 to release the freewheel lock.

When turning the tensioning element 21 in the opening position, the friction connection between the tensioning element 21 and the support body 30 moves it back into the position in which it is maximally removed from the support body 29 , so that the tie rod 17 with the Pressure element 16 can be removed from the support surface 12 .

In the construction described, the ef fective length of the spacer 28 formed by the two support bodies 29 and 30 sets itself automatically, in such a way that the maximum possible length is always assumed for a certain saw blade thickness. As a result of a minimal clamping distance, despite different thicknesses of the saw blades, the user needs only a few turns of the handle 40 in order to clamp the saw blade. Even when loosening 40 maximum displacements of the tie rod are possible with a few turns of the handle.

Claims (23)

1. Oscillating saw for medical purposes with an oscillating, rotationally driven holder and a non-rotatable receptacle for a saw blade on the holder, with a pressing element which can be pressed against the holder and which fixes the saw blade on the holder in the direction of the axis of rotation of the holder, to which a tie rod is attached attacks, and with an anchor held on the train, supported on the holder clamping element, the position of which is adjustable on the tie rod in such a way that the tie rod clamps the pressure element and thus the saw blade against the holder, characterized in that between the holder ( 8 ) and clamping element ( 21 ) a Di punch piece ( 28 ) is arranged, the length of which can be changed in the direction of the tie rod ( 17 ). 2. Saw according to claim 1, characterized in that the clamping element ( 21 ) and the spacer ( 28 ) are operatively connected such that the Spannele element ( 21 ) increases the length of the spacer ( 28 ) ver at the start of the position adjustment in the clamping direction . 3. Saw according to claim 1 or 2, characterized in that the spacer ( 28 ) is variable in length in its length. 4. Saw according to one of the preceding claims, characterized in that the spacer ( 28 ) has two mutually displaceable transverse to the tie rod support body ( 29 , 30 ), which are supported by mutually facing support surfaces ( 31 , 35 ), and that at least on one support body ( 30 ) the support surface ( 31 ) has adjacent sections ( 32 ) which are offset from one another in the tie rod direction. 5. Saw according to claim 4, characterized in that the adjacent sections ( 32 ) of the support surface ( 31 ) are designed like stairs. 6. Saw according to one of claims 4 or 5, characterized in that the two support bodies ( 29 , 30 ) sleeve-shaped surround the tie rod ( 17 ) and are rotatable against each other for transverse displacement about the tie rod axis. 7. Saw according to one of the preceding claims, characterized in that the clamping element ( 21 ) on the tie rod ( 17 ) about its longitudinal axis is rotatably mounted and guided such that it is at a rotation its axial position along the tie rod ( 17 ) changes. 8. Saw according to claim 7, characterized in that the clamping element ( 21 ) is screwed onto an external thread ( 20 ) of the tie rod ( 17 ). 9. Saw according to claim 6 and according to one of claims 7 or 8, characterized in that the clamping element ( 21 ) and one of the two support bodies ( 30 ) are in a frictional connection, so that when the clamping element ( 21 ) is rotated, the Support body ( 30 ) is rotated. 10. Saw according to claim 9, characterized in that the two support bodies ( 29 , 30 ) have stops ( 36 , 57 ) which by ( 29 , 30 ) the relative rotation of the support body in increasing the distance between their support surfaces ( 32 , 35 ) limit. 11. Saw according to one of claims 9 or 10, characterized in that to form the Reibverbin extension of the support body ( 30 ) in the direction of the Zugan core ( 17 ) is resiliently pressed against the clamping element ( 21 ). 12. Saw according to claim 11, characterized in that a support body ( 30 ) against the clamping element ( 21 ) pressing spring ( 37 ) is supported on the holder ( 8 ). 13. Saw according to one of claims 7 to 12, characterized in that a handle ( 40 ) is provided for the rotation of the Spannele element ( 21 ) on the tie rod ( 17 ). 14. Saw according to claim 13, characterized in that the handle ( 40 ) and the clamping element ( 21 ) are rotatably engaged with play and that this play is greater than the rotation of the oscillatingly driven holder ( 8 ). 15. Saw according to claim 14, characterized in that the rotary engagement is formed by the engagement of a non-circular driver ( 24 ) in a non-circular driver recess ( 41 ). 16. Saw according to claim 15, characterized in that the driver ( 24 ) and the driving recess ( 41 ) have the shape of a regular polygon and that the outer dimensions of the driver ( 24 ) are smaller than the inner dimensions of the driving recess ( 41 ). 17. Saw according to one of claims 14 to 16, characterized in that the handle ( 40 ) is releasably lockable in a certain angular position. 18. Saw according to claim 17, characterized in that the handle ( 40 ) is provided with a freewheel which allows rotation in the direction of the tension of the clamping element ( 21 ), but is releasably locked in the opposite direction. 19. Saw according to one of claims 17 or 18, characterized in that in the handle ( 40 ) a spring loaded slider ( 48 ) is arranged, the spring to Win kelfixierung resilient against outside flattening gene ( 43 ) of a saw-fixed, the tie rod ( 17 ) vice versa sleeve ( 39 ) is pressed, on which the handle ( 40 ) is rotatably mounted. 20. Saw according to claim 19, characterized in that the flats ( 43 ) carry a projecting step ( 46 ) on one longitudinal edge, but not on the other longitudinal edge. 21. Saw according to one of claims 19 or 20, characterized in that the slide ( 48 ) can be lifted off from the flattened portion ( 43 ) by an actuating member ( 53 , 55 ) on the handle ( 40 ). 22. Saw according to one of claims 19 to 21, characterized in that the flattened portion ( 43 ) carries projecting steps ( 44 , 45 ) on its upper and on its lower edge and that the handle ( 40 ) is displaceable in the axial direction on the sleeve ( 39 ) is stored. 23. Saw according to claim 22, characterized in that the handle ( 40 ) on the sleeve ( 39 ) is fixed by a frictional connection in the axial direction.