EP0152564A2 - Tool mounting - Google Patents

Abstract

The invention relates to a device for fastening a tool (23) in portable angle grinders, which allows the fastening to be released without an auxiliary tool. The device consists essentially of a hollow drive shaft (16), a spindle (20) slidably mounted therein, a displacement device (6) and a clamping point which is formed from the counter flange (22) and nut (21). To loosen the nut (21), the spindle (20) is moved in the direction of the clamping point by actuating the displacement device (6), so that the nut (21) connected to the spindle (21) via the threaded pin (19) is removed from the tool (23) is lifted off. The nut (21) can then be unscrewed by turning it by hand.

Description

The invention relates to a device for fastening a tool in portable angle grinders, which allows the attachment to be released without an auxiliary tool.

In order to be able to change the grinding wheel in the currently known angle grinders, the fastening flange, which is firmly connected to the grinding spindle, must be held with an auxiliary tool. Then the counter flange, which is screwed onto the grinding spindle, can be loosened with a second auxiliary tool. This procedure is extremely cumbersome, involves great risk of injury and is also very time-consuming.

For this reason, z. B. proposed in DE-PS 29 26 469, the grinding spindle over a fixed ins Lock gearbox integrated device. The advantage of this solution is that only one auxiliary tool is required to loosen the counter flange. However, the user of such an angle grinder will often look for the auxiliary tool for loosening the counter flange, which is just not at hand. A number of cases are known from practice in which the tool attachment was then forcibly released. The tool was damaged in many cases. Furthermore, the user is not spared the hand holding the auxiliary tool to make a movement relative to the cutting edge of the tool, which keeps the risk of injury the same as compared to the old method. An additional disadvantage is the design effort that must be made to secure the angle grinder against unintentional switching on.

The invention is therefore based on the object of providing a fastening for the tool of a hand-held angle grinder or similar power tool, in which no auxiliary tool is required for loosening or tightening the tool fastening. At the same time, the effort to protect against unintentional switching on should be kept to a minimum.

This object is achieved in that the bevel gear flange-mounted on the motor of the angle grinder, which essentially consists of a pinion, a bevel gear and a drive shaft, has a device by means of which a spindle guided in the hollow drive shaft is directed in the direction of can move the clamping point of the tool.

This axial movement of the spindle lifts the nut, which presses the tool onto the counter flange, from the tool. Then you can easily loosen the knurled nut from the spindle by turning it. An auxiliary tool for loosening the nut is not necessary with this arrangement. In addition, the effort to manufacture the displacement device is roughly equivalent to what it has to be done to integrate a spindle lock in the gear housing. By touching the nut directly with the hand during assembly and loosening and not screwing it on or off with an auxiliary tool, the hand no longer comes into contact with the cutting edge. This reduces the risk of injury from the tool.

In the above description, a tool attachment is shown in which, after actuation of a displacement device, a spindle is displaced in the axial direction in a hollow drive shaft. The displacement device is located at one end of the spindle, and the spindle is threaded at the other end. The thread is used to screw on a nut. With this nut, the tool is pressed onto a counter flange, which is firmly connected to the drive shaft. The drive movement of the drive shaft can thus be transferred to the tool.

This type of fastening thus allows much easier handling when changing tools than was previously possible. In order to be able to carry out the tool change even faster and above all to facilitate the tool change when handling by robots, the task was further designed to design the tool attachment in such a way that the tool change should no longer be carried out by turning a nut.

This object was achieved in that the screw fastening was replaced by a plug fastening. In order to be able to insert a fastening bolt into the spindle, a bore is machined on the end face of the spindle, which has a cross section similar to that of a pin facing it on the end face of the fastening bolt. The spindle has slots in the area of the bore, in the manner of a collet, so that the jaws of this clamping device can move in the radial direction. This radial movement is achieved in that the spindle is displaced axially in a hollow drive shaft by the displacement device and an outer cone provided in the slotted area of the spindle can slide onto an inner cone provided at a corresponding point on the drive shaft. So that a secure positive connection between pin and bore is achieved, the outer surface of the pin and the wall the transverse grooves on the bore so that they can engage in radial pressure on the slotted spindle.

In order to determine whether the fastening bolt has been pressed sufficiently far into the clamping point, a groove with a resilient locking element attached to it is provided on the outer surface of the fastening bolt. The resilient locking element snaps into a corresponding groove in the hollow drive shaft as soon as it has reached it. The fastening bolt is designed so that when this locking point is not reached, the fastening bolt is only loosely seated in the drive shaft, which makes it easy to see that it must be pressed in even deeper.

However, so that, for example in the case of an angle grinder with a braking device, the attachment of the tool does not come loose automatically after braking the rotation, a solution was also sought for this.

• Fig. 1 einen Längsschnitt durch einen Winkelschleifer, wobei der Motor nur angedeutet ist;
• Fig. 2 einen Schnitt nach der Linie II-II in Fig. 1, der eine Variante darstellt;
• Fig. 3 eine Variante nach Fig. 2;
• Fig. 4 einen Schnitt nach der Linie IV-IV in Fig. 3,
• Fig. 5 einen Längsschnitt durch ein Winkelschleifergetriebe, mit Spannhülse
• Fig. 6 einen Schnitt durch ein Getriebegehäuse eines Winkelschleifers, wobei die bekannten Getriebeelemente weggelassen wurden.

This object was achieved in that a bolt is screwed onto the end of the axially displaceably mounted spindle in the hollow drive shaft, which is provided with a flange on its end facing away from the spindle, with which it has an intermediate sleeve which is also provided with a flange Press the tool onto the counter flange of the drive shaft. The sleeve is provided on the outer surface of its cylindrical part with teeth in the axial direction, This axial movement of the spindle lifts the nut, which presses the tool onto the counter flange, from the tool. Then you can easily loosen the knurled nut from the spindle by turning it. An auxiliary tool for loosening the nut is not necessary with this arrangement. In addition, the effort to manufacture the displacement device is roughly equivalent to what it has to be done to integrate a spindle lock in the gear housing. By touching the nut directly with the hand during assembly and loosening and not screwing it on or off with an auxiliary tool, the hand no longer comes into contact with the cutting edge. This reduces the risk of injury from the tool. The invention is explained in more detail with reference to drawings. Show it:

• Figure 1 shows a longitudinal section through an angle grinder, the motor is only indicated.
• FIG. 2 shows a section along the line II-II in FIG. 1, which represents a variant;
• 3 shows a variant according to FIG. 2;
• 4 shows a section along the line IV-IV in FIG. 3,
• Fig. 5 shows a longitudinal section through an angle grinder gear, with adapter sleeve
• Fig. 6 shows a section through a gear housing of an angle grinder, wherein the known gear elements have been omitted.

The angle grinder shown in Fig. 1 essentially shows a motor 14 shown broken off, an adjoining gear 1 and a tool 23. Via a pinion 13, the rotational movement of the motor is transmitted to a bevel gear 15, which is rotationally fixed with a Drive shaft 16 is connected. The drive shaft 16 is supported by two bearings 3 and 17 on opposite sides in the transmission housing 2. At one end of the drive shaft 16 there is a displacement device 6 to be actuated from outside the transmission housing 2. At the other end, the drive shaft 16 projects so far out of the transmission housing 2 out that on its periphery a counter flange 22, which serves to fasten the tool 23, can be rigidly connected to it. The drive shaft 16 is hollow for receiving a spindle 20. The spindle 20 protrudes over the end faces of the drive shaft 16. On the one hand, in order to work together with the displacement device 6, on the other with a threaded pin 19, onto which a nut 21 can be screwed. Counter flange 22 and nut 21 form the clamping point for the tool 23. Thus drive shaft 16 and spindle 20 run synchronously, the spindle is 16. over a certain range z. B. provided with teeth 18. The teeth 18 find their correspondence in the inner bore of the drive shaft 16. This positive connection ensures that the spindle 20 rotates synchronously with the drive shaft 16. The possibility that the spindle 20 can be moved in the axial direction relative to the drive shaft 16 remains.

This displacement is achieved by the displacement device 6. A lever 12 arranged outside the transmission housing 2 is screwed into the transmission housing 2 with its cylindrical extension 9. The axis of the threaded bore in the gear housing 2 and that of the cylindrical extension 9 lies in the extension of the axis of the spindle 20. The drive shaft 16, which is rotatably supported by the two bearings 3 and 17, is on her the bearing 3 protruding end with a sleeve-shaped cover 11 which has a circular opening for the spindle 20 in its bottom part 10. In the remaining distance between the end face of the drive shaft 16 and the bottom part 10 of the sleeve-shaped cover 11, a spring 4 is arranged, which presses a concentric extension 5 of the spindle 20 against the bottom part 10. An end piece 7 of the spindle 20, which projects through the opening in the base part 10, extends into a recess 8 of the cylindrical extension 9.

If the lever 12 is pivoted about the axis of the cylindrical extension 9, the cylindrical extension 9 is screwed further into or out of the gear housing 2. When screwing in, the end piece 7 and thus the entire spindle 20 are axially displaced against the force of the spring 4 . This axial displacement causes the nut 21 to be lifted off the side surface of the tool 23. Since you no longer have to overcome the contact pressure between the nut 21 and the tool 23 to loosen the nut 21, it is entirely sufficient if the z. B. provided with a knurled nut 21 by hand from the threaded pin 19.

In order to assemble the tool 23, it is plugged onto the counter flange 22. Thereafter, the nut 21 is screwed onto the threaded pin 19, it being irrelevant whether the nut 21 is tight against the tool 23 or only loosely. After the motor has started, the nut 21 tightens itself on the threaded pin 19.

In the event that the lever 12 has not been pivoted back into its "closed position", the mutually facing surfaces are on the end piece 7 and the recess fung 8 designed so that when starting the machine, the frictional force between the two surfaces is sufficient to bring the lever 12 into the "closed position".

It is also conceivable that instead of the lever 12, with a corresponding choice of the thread pitch on the cylindrical extension 9, another rotary element is used, for. B. a rotary knob with the locking points "close" and "open".

The designs shown in FIGS. 2, 3 and 4 are variants of the displacement device 6 according to FIG. 1, which have the effect that the dimensions of the gear housing can be kept smaller.

2, the spindle 20 is axially displaced via a displacement device 25. The displacement device 25 consists of a slide button 27, which can slide on rails 29 in the gear housing 2. The sliding button 27 projects with a grip surface 26 through an opening 28 and beyond the outer contour of the gear housing 2. To prevent the penetration of z. B. To prevent dust in the gear housing 2, the slide button 27 is provided with two cover strips 24 each extending over the opening 28. The sliding button 27 has an inclined surface 30 on its side facing the spindle 20. When sliding the push button 27 from one end position "close" to the other end position "open", the inclined surface 30 is pushed over the end piece 31 so that the spindle 20 moves in the direction of the clamping point.

In the embodiment of FIGS. 3 and 4, the displacement device 33 is arranged so that it z. B. is not inadvertently adjusted when putting down the angle grinder. For this purpose, 2 troughs 32 are provided in the gear housing in each case in the area of the meeting of the two side surfaces and the side of the gear housing 2 facing away from the tool 23. These troughs 32 have openings for a push rod 35 which can be moved transversely to the axis of the drive shaft 16. The push rod 35 is guided laterally past the end piece 34. When the push rod 35 is displaced, a spring element 36 mounted obliquely on the push rod 35 presses a bead on the end piece 34 in the direction of the clamping point. The inclined spring element 36 thus has the same effect as the inclined surface 30 according to the embodiment in Fig. 2. As shown in Fig. 4, the end piece 34 can rotate even if the user has forgotten the push rod 35 before switching on of the motor in the "close" position.

With these arrangements it is possible to achieve an extremely simple change of the tool on the angle grinder. Due to the compact design, the dimensions of the gearbox housing are hardly larger. Functional safety is increased because the motor can be switched on without any part being blocked in the gearbox.

The angle grinder shown in FIG. 5 essentially has a motor 7 ', a gear 1' and a tool 21 '. The rotational movement of the motor 7 'is transmitted to a bevel gear 20' via a pinion 6 '. The bevel gear 20 'is non-rotatably and axially immovably connected to a drive shaft 5'. The drive shaft 5 'is supported in two bearings which are fixed in the housing 2' of the transmission 1 '.

With a displacement device 4 ', a spindle 3' guided in the hollow drive shaft 5 'can be displaced in the axial direction, as is described for FIG. 1.

On the end of the drive shaft 5 'facing away from the displacement device 4' there is a counter flange 19 'protruding from the gear housing 2'. The tool 21 'is placed on this counter flange 19'. When the tool 21 'abuts the counter flange 19', a fastening bolt 12 'can be inserted into the hollow drive shaft 5' through a receiving hole in the tool 21 '. The fastening bolt 12' has a pin 11 'on its end face. This pin 11 'passes simultaneously with the insertion of the fastening bolt 12' in the drive shaft _5. ¹ in a corresponding bore 10 'of the spindle 3'. The spindle 3 'is provided with slots 18' in the region of the bore 10 '. The slots 18 'allow the end of the spindle 3' to be pressed in the radial direction can be. This pressure should arise when the fastening bolt 12 'has been inserted into the drive shaft 5' and the pin 11 'is in the bore 10'. Then the displacement device is brought into the "closing" position and thus the spindle 3 'is moved away from the tool 21'. The pin 11 'is then clamped in the bore 10' of the spindle 3 'by an outer cone 9' of the spindle 3 'in the region of the slots 18' and a corresponding inner cone 8 'on the drive shaft 5'. In order to achieve a positive connection, the pin 11 'is provided on its lateral surface and the bore 10' on its wall with transverse grooves. After the pin 11 'has been tightened, the entire fastening bolt 12' is pulled in the direction of the displacement device 4 'and the tool 21' is thus firmly clamped. So that there is no relative movement between the drive shaft 5 'and the fastening bolt 12' during rotation, both parts have a corresponding toothing 13 '.

A resilient locking element 16 'is inserted in a circumferential groove 14' of the fastening bolt 12 '. Only when the resilient locking element 16 'engages in a groove 17' of the hollow drive shaft 5 'is the point reached at which a positive connection between the pin 11' and the spindle 3 'can be established. Otherwise, the tolerances between the fastening bolts 12 'and the drive shaft 5 'chosen so that the fastening bolt 12' is only loosely guided in the drive shaft 5 '.

The gear head 1 "has a displacement device 6" protruding from the transmission housing 2 "on one side. The displacement device 6" consists essentially of an actuating element 12 "and a lifting element 9". By turning the actuating element 12 ", the lifting element 9" firmly connected to the actuating element 12 "is screwed in or out of the thread provided in the gear housing 2". The screwing or unscrewing takes place in the axial direction of a drive shaft 16 "mounted in the transmission housing 2". A spindle 20 "is axially displaceably mounted in the hollow drive shaft 16" and, as shown in the first-mentioned exemplary embodiment, can be displaced in the axial direction by the displacement device 6 "against the force of spring elements 4". The drive shaft 16 "is provided at one end with a sleeve-shaped cover 11", which has a circular opening for the spindle 20 "in its bottom part 10". The spring elements 4 "are arranged in the remaining distance between the end face of the drive shaft 16" and the base part 10 "of the sleeve-shaped cover 11", which presses a concentric shoulder 5 "of the spindle 20" against the base part 10 ". An end piece 7" of the spindle 20 "by the breakthrough protrudes in the bottom part 10 ", extends into a recess 8" of the cylindrical extension 9 ". On the end of the drive shaft 16" facing away from the displacement device 6 ", a counter flange 22" is provided on the drive shaft 16 ". A tool is located on this counter flange 22" The tool 23 "is centered by a shoulder on the counter flange 22". The tool 23 "is pressed against the counter flange 22" by a flange 57 "of a bolt 56" indirectly through the flange 53 "of a sleeve 54". The contact pressure is generated by inserting the bolt 56 "through the cylindrical part 55" of the sleeve 54 "and screwing it with its threaded front part into a corresponding internal thread of the spindle 20" and, after screwing in the bolt 56 ", the actuating element 12" of the displacement device 6 "is brought into the" closing "position. This achieves a sufficient contact force for the use of the tool 23 ".

The hollow drive shaft 16 ″ has an enlarged bore in the area of the counter flange 22 ″. The wall of the enlarged bore is provided with longitudinal grooves 51 ". The corresponding toothing 52" on the lateral surface of the cylindrical part 55 "of the sleeve 54" can be inserted into the longitudinal grooves 51 ". This ensures a positive transmission of the rotary movement of the drive shaft 16" the sleeve 54 ".

So that when the drive shaft 16 "is braked, the bolt 56" is not unscrewed from the thread of the spindle 20 ", the flanges 53" and 57 "are provided on the mutually facing surfaces with teeth 58" and 50 "arranged in the radial direction this toothing 58 "and 50" is achieved that the bolt 56 "also carries out the rotary movement of the drive shaft 16" as long as the actuating element 12 "remains in the" closing "position. A ring-shaped arrangement of the teeth 58 "and 50" on the mutually facing surfaces of the flanges 53 "and 57" ensures that the contact pressure can also spring back through the flange 57 ".

So that the bolt 56 "can be easily unscrewed from the spindle 20", it is advisable to design the edge regions of the flange 57 "in such a way that they are easy to grip by hand. This can be achieved, for example, by using them knurled and / or covered with a soft elastic material.

To remove the tool 23 ", the actuating element 12" must be brought into the "open" position, as a result of which the displacement device 6 "displaces the spindle 20" against the force of the spring elements 4 ". This stroke movement is sufficient to achieve the force on the flange 57" of the Bolt 56 "arranged teeth 50" with teeth 58 "of flange 53" the sleeve 54 ". Then the bolt 56" can be screwed out of the spindle 20 ", the sleeve 54" can be pulled out of the drive shaft 16 "and the tool 23" can be changed.

Claims (22)

1. Device for fastening a tool in portable angle grinders, consisting of a motor, an angle gear and a clamping point for the tool, the angle gear essentially consisting of a motor pinion, a bevel gear and a drive shaft, characterized in that in the hollow Drive shaft (16), a spindle (20) is arranged in a rotationally fixed and axially displaceable manner, the displacement of which is achieved by a displacement device (6, 25, 33) from outside the transmission housing (2), in which an actuating element (12, 27, 35) a lifting element (9, 30, 36) transversely to the axial direction of the drive shaft (16) on an end piece (7, 31, 34) against the force of spring elements (4) which are located between the end face of the drive shaft (16) and a shoulder (5 ) the spindle (20) are arranged and the stroke of which is limited by a bush-shaped cover (11) fastened to the drive shaft (16), so that one acts on the threaded pin (19) of the spindle (20) screwed nut (21) is moved away from the tool (23). -2. Tool attachment according to claim 1, characterized in that the spindle (20) is provided with a toothing (18) which is matched in the hollow drive shaft (16). 3. Tool attachment according to claims 1 to 2, characterized in that a cylindrical extension (9) of the displacement device (6) acts on an end piece (7) of the spindle (20) in that it is in a threaded bore of the gear housing ( 2) is screwed in or out. 4. Tool attachment according to claim 1, characterized in that the displacement device (25) consists of a slide button (27) which can be moved in a guide (29) of the gear housing (2) and that the slide button (27) on it in Gear housing (2) extending into the side has an inclined surface (30). 5. Tool attachment according to claim 1, characterized in that in the edges between side surfaces and the tool (23) opposite surface of the gear housing (2) troughs (32) are provided which have an opening for receiving a push rod (35) and that the push rod (35) has in its center on the side facing the end piece (34) a spring (36) which is arranged obliquely to the direction of displacement of the push rod (35). 6. Tool attachment according to the preamble of claim 1, characterized in that the spindle (3 ') arranged in the hollow drive shaft (5') is provided on its end facing away from the displacement device (4 ') with a tensioning device (15'). 7. Tool attachment according to claim 6, characterized in that the clamping device (15 ') is designed such that the spindle (3') is slotted in the manner of a collet and in the slotted area on the lateral surface with a cone (9 ¹ ) is provided. 8. Tool attachment according to claim 7, characterized in that the drive shaft (5 ') in the region of the cone (9') of the spindle (3 ') has a corresponding inner cone (8 ¹ ). 9. Tool attachment according to claim 8, characterized in that the spindle (3 ') is provided on the end face of its slotted end with a bore (10'). 10. Tool attachment according to claim 9, characterized in that the bore (10 ') on its wall form-fitting design, such as. B. transverse grooves. 11. Tool attachment according to claim 6, characterized in that a fastening bolt (12 ') is releasably connected to the spindle (3') via the clamping device (15 '). 12. Tool attachment according to claim 11, characterized in that the fastening bolt (12 ') on its side facing the clamping device (15') has a pin (11 ') which is designed on its outer surface in a form-fitting manner. e.g. B. provided with transverse grooves corresponding to those arranged in the wall of the bore (10 '). 13. Tool attachment according to claim 11, characterized in that the fastening bolt (12 ') is provided with a circumferential groove (14') which serves to receive a resilient locking element (16 '). 14. Tool attachment according to the preamble of claim 1, characterized in that in the hollow drive shaft (16 ") a spindle (20") is arranged in a rotationally fixed and axially displaceable manner, the displacement of which by a displacement device (6 ") from outside the gear housing (2 ") is achieved in which an actuating element (12") via a lifting element (9 ") transversely to the axial direction of the drive shaft (16") on an end piece (7 ") against the force of spring elements (4") between the end face the drive shaft (16 ") and an extension (5") of the spindle (20 ") are arranged and the stroke of which is limited by a bush-shaped cover (11") fastened on the drive shaft (16 "), so that one into the other end of the spindle (20 ") screwed-in bolt (56"), with its flange (57 ") over a flange (53") of a sleeve (54 ") with which the flange (57" of the bolt (56 ") is in positive connection, acts on the tool (23 "), from the tool (23") and thus from the flange (53 ") of the sleeve (54") is moved away. 15. Tool attachment according to claim 14, characterized in that the sleeve (54 ") in the cylindrical region (55") on its lateral surface has a positive configuration, preferably a toothing (52 ") in the axial direction. 16. Tool attachment according to claim 15, characterized in that the depth of the toothing (50 ", 58") between the flanges (57 ", 53") is less than the stroke which is caused by the displacement device (6 "). 17. Tool attachment according to claim 14, characterized in that the bolt (56 ") on the edge of the flange (57") is provided with a structure which increases the grip. 18. Tool attachment according to claim 16, characterized in that the toothing (58 ", 50") between the flanges (57 ", 53") extends over a portion of the radial extent. 19. Tool fastening according to claim 14, characterized in that the bolt (56 ") on the end facing away from the flange (57") is provided with a thread. 20. Tool attachment according to claim 14, characterized in that the spindle (20 ") is provided on the end face with a threaded bore. 21. Tool attachment according to claim 19, characterized in that the length of the thread on the bolt (56 ") and in the spindle (20") is long enough to clamp tools (23 ") with different thicknesses. 22. Tool attachment according to claim 14, characterized in that the tool (23 ") on the shoulders of the counter flange (22") and the flange (53 ") of the sleeve (54") is centered.

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