EP2913159A1 - Hand-held electric tool having a spindle-locking device - Google Patents

Abstract

In a hand-held power tool (100) with a tool housing (105) in which a gear (170) for transmitting a torque generated by a drive motor (180) is arranged on a drive spindle (120), which is associated with a Spindellockvorrichtung (250), wherein the drive spindle (120) is rotatably mounted in the tool housing (105) at at least two bearing points (132, 134), a braking device (520) is provided in the spindle locking device (250) on the drive spindle (120) to prevent rattling during operation of the power tool (100) in the event of an outlet of the drive spindle (120).

Description

State of the art

The present invention relates to a hand-held power tool with a tool housing, in which a transmission for transmitting a torque generated by a drive motor is arranged on a drive spindle, which is associated with a Spindellockvorrichtung, wherein the drive spindle is rotatably mounted in the tool housing at least two bearing points.

Such hand-held power tools are known from the prior art, in which a drive spindle provided with a spindle locking device is mounted in a tool housing at two bearing points. Here, the spindle locking device is arranged either in one of the two bearings in the axial direction of the drive spindle downstream area or in a plane with a on or in the transmission, the first of the two bearings.

A disadvantage of the prior art is that power tools in which the spindle locking device is arranged in a region downstream of the two bearing points in the axial direction of the drive spindle, have a comparatively large length in the axial direction of the drive spindle. In power tools, in which the spindle locking device is arranged in a plane with a arranged on or in the transmission, the first bearing point, the drive spindle, however, a comparatively large Kippspiel on.

Disclosure of the invention

An object of the invention is therefore to provide a new hand-held power tool with a Spindellockvorrichtung that a shortened Length of the power tool with a simultaneous reduction of Kippspiels of its drive spindle allows. In addition, it is an object of the invention to provide a new hand-held power tool with a drive spindle and a Spindellockvorrichtung, in whose operation occurring at a spout of the drive spindle, undesirable noise can be at least reduced.

This problem is solved by a hand-held power tool with a tool housing, in which a transmission for transmitting a torque generated by a drive motor is arranged on a drive spindle, which is associated with a Spindellockvorrichtung. The drive spindle is rotatably mounted in the tool housing at least two bearing points. The at least two bearing points are provided in the tool housing in a region downstream of the transmission. The spindle locking device is arranged in the axial direction of the drive spindle between the two bearing points.

The invention thus enables the provision of a hand-held power tool, in which a shortening of the overall length in the axial direction of the drive spindle is made possible by an arrangement of the spindle locking device between the two bearing points.

According to one embodiment, the spindle locking device has a carrier element mounted on the drive spindle with a predetermined radial clearance, on which at least one spindle roller is arranged.

Thus, a stable and reliable storage of the spindle rollers can be made possible on the drive spindle.

The at least one spindle roller preferably lies in the axial direction of the drive spindle directly between the two bearing points against the drive spindle.

Thus, a reduction of the tilting clearance of the drive spindle can be achieved in a simple manner.

According to one embodiment, the carrier element is mounted by a bearing ring formed on its outer circumference at a first of the at least two bearing points in a plain bearing.

The invention thus enables an effective and cost-effective storage of the carrier element in the power tool.

The slide bearing is preferably mounted in a blocking member which is designed to prevent slippage of the at least one spindle roller from the carrier element in the radial direction of the drive spindle.

Thus, the spindle rollers can be securely and reliably fixed in the support member.

According to one embodiment, the drive spindle is mounted on a first of the at least two bearing points in a rolling bearing.

The invention thus enables a stable and comparatively wear-free mounting of the drive spindle in the power tool.

The rolling bearing is preferably mounted in a blocking member which is designed to prevent slippage of the at least one spindle roller from the carrier element in the radial direction of the drive spindle.

Thus, the spindle rollers can be securely and reliably fixed in the support member.

The blocking member is preferably annular and rotatably connected to the tool housing.

Thus, the blocking member can be fixed in a simple manner in the tool housing.

The drive spindle is preferably mounted on a second of the at least two bearing points in a roller bearing, which is mounted in the tool housing. Thus, the drive spindle can be stored stable and relatively wear-free in the power tool.

According to one embodiment, the carrier element is sleeve-shaped and surrounds the drive spindle at least in sections, wherein on the carrier element at least one recess for receiving the at least one spindle roller is formed.

The invention thus enables the provision of a simple and cost-effective support element, on which the spindle rollers can be stored safely and reliably.

The carrier element is preferably non-rotatably connected to a drive member of the transmission.

Thus, a shortening of the overall length in the axial direction of the drive spindle can be made possible in a simple manner.

According to one embodiment, the transmission is designed as a planetary gear and the drive member is a planet carrier.

The invention thus enables the provision of a safe and reliable transmission.

The drive spindle is preferably drivable directly from the drive member, wherein between the drive member and the drive spindle, a predetermined radial clearance is formed.

Thus, the drive spindle can be driven in a simple manner.

According to one embodiment, the drive spindle can be driven directly by the carrier element.

The invention thus enables an improvement of the interaction of carrier element, drive spindle and drive member.

According to one embodiment, a raceway is rotatably mounted on the drive spindle in the region of a first of the at least two bearing points, which is mounted in an associated sliding bearing.

Thus, the use of a sliding bearing at the first bearing point can be made possible in a simple manner.

The above-mentioned problem is also solved by a hand-held power tool having a tool housing in which a transmission for transmitting a torque generated by a drive motor is arranged on a drive spindle, which is associated with a Spindellockvorrichtung, the drive spindle in the tool housing at least two bearing points rotatable is stored. In the field of spindle locking device, a braking device is provided on the drive spindle, which is designed to prevent chattering during operation of the power tool at an outlet of the drive spindle.

The invention thus makes it possible to provide a hand-held power tool in which, by providing a braking device arranged in the region of the spindle locking device, undesired noise development of the drive spindle at the outlet can be reliably and reliably at least reduced.

The brake device preferably has an O-ring for realizing a braking function.

Thus, a simple and inexpensive braking device can be provided.

On the drive spindle, an annular groove is preferably formed in the region of the spindle locking device, in which the O-ring is arranged.

Thus, an uncomplicated and robust braking device can be provided.

According to one embodiment, the spindle locking device has a support element mounted on the drive spindle with a predetermined radial clearance. The braking device is arranged in the region of the carrier element.

The invention thus enables the provision of a hand-held power tool with a simple and stable Spindellockvorrichtung.

The carrier element is preferably non-rotatably connected to a drive member of the transmission.

Thus, a shortening of the overall length in the axial direction of the drive spindle can be made possible in a simple manner.

The drive spindle is preferably drivable directly from the carrier element.

The invention thus enables an improvement of the interaction of carrier element, drive spindle and drive member.

According to one embodiment, at least one spindle roller is arranged on the carrier element.

The invention thus enables the provision of a spindle locking device in which a stable and reliable mounting of the spindle rollers on the drive spindle can be made possible.

The at least one spindle roller preferably lies in the axial direction of the drive spindle directly between the two bearing points against the drive spindle.

Thus, a reduction of the tilting clearance of the drive spindle can be achieved in a simple manner.

The carrier element is preferably mounted by a formed on its outer circumference bearing ring at a first of the at least two bearing points in a sliding bearing.

Thus, an effective and inexpensive storage of the support member in the power tool can be made possible.

The slide bearing is preferably mounted in a blocking member which is designed to prevent slippage of the at least one spindle roller from the carrier element in the radial direction of the drive spindle.

Thus, the spindle rollers can be securely and reliably fixed in the support member.

Preferably, the at least two bearing points are provided in the tool housing in a downstream region of the transmission and the spindle locking device is arranged in the axial direction of the drive spindle between the two bearing points.

Thus, a shortening of the overall length in the axial direction of the drive spindle can be achieved by an arrangement of the spindle locking device between the two bearings.

Brief description of the drawings

• Fig. 1 eine schematische Ansicht eines handgeführten Elektrowerkzeugs gemäß der Erfindung,
• Fig. 2 eine vergrößerte Schnittansicht eines Ausschnitts des Elektrowerkzeugs von Fig. 1 gemäß einer ersten Ausführungsform,
• Fig. 3 eine perspektivische Explosionsdarstellung der Antriebsspindel, des Antriebsglieds, des Sinterlagers, des Kugellagers und der Spindellockvorrichtung von Fig. 2,
• Fig. 4 die perspektivische Explosionsdarstellung von Fig. 3, gesehen aus einem anderen Blickwinkel,
• Fig. 5 die Schnittansicht von Fig. 2 mit einer modifizierten Antriebsspindel,
• Fig. 6 eine vergrößerte Schnittansicht des Ausschnitts des Elektrowerkzeugs von Fig. 1 gemäß einer zweiten Ausführungsform,
• Fig. 7 eine perspektivische Explosionsdarstellung der Antriebsspindel, des Antriebsglieds, des Sinterlagers, des Laufrings, des Kugellagers und der Spindellockvorrichtung von Fig. 6,
• Fig. 8 eine vergrößerte Schnittansicht des Ausschnitts des Elektrowerkzeugs von Fig. 1 gemäß einer dritten Ausführungsform,
• Fig. 9 eine perspektivische Explosionsdarstellung der Antriebsspindel, des Antriebsglieds, der Kugellager und der Spindellockvorrichtung von Fig. 8,
• Fig. 10 eine perspektivische Ansicht der Antriebsspindel von Fig. 9,
• Fig. 11 eine perspektivische Rückansicht der Bauteile von Fig. 9 nach der Montage,
• Fig. 12 eine vergrößerte Schnittansicht des Ausschnitts des Elektrowerkzeugs von Fig. 1 gemäß einer vierten Ausführungsform,
• Fig. 13 eine perspektivische Rückansicht der Antriebsspindel, des Antriebsglieds und der Spindellockvorrichtung von Fig. 12 nach der Montage,
• Fig. 14 eine perspektivische Explosionsdarstellung der Antriebsspindel, des Antriebsglieds, der Kugellager und der Spindellockvorrichtung von Fig. 12, und
• Fig. 15 eine vergrößerte Schnittansicht des Ausschnitts des Elektrowerkzeugs von Fig. 1 gemäß einer fünften Ausführungsform.

The invention is explained in more detail in the following description with reference to exemplary embodiments illustrated in the drawings. Show it:

• Fig. 1 a schematic view of a hand-held power tool according to the invention,
• Fig. 2 an enlarged sectional view of a section of the power tool of Fig. 1 according to a first embodiment,
• Fig. 3 an exploded perspective view of the drive spindle, the drive member, the sintered bearing, the ball bearing and the Spindellockvorrichtung of Fig. 2 .
• Fig. 4 the perspective exploded view of Fig. 3 , seen from a different angle,
• Fig. 5 the sectional view of Fig. 2 with a modified drive spindle,
• Fig. 6 an enlarged sectional view of the section of the power tool of Fig. 1 according to a second embodiment,
• Fig. 7 an exploded perspective view of the drive spindle, the drive member, the sintered bearing, the race, the ball bearing and the Spindellockvorrichtung of Fig. 6 .
• Fig. 8 an enlarged sectional view of the section of the power tool of Fig. 1 according to a third embodiment,
• Fig. 9 an exploded perspective view of the drive spindle, the drive member, the ball bearing and the Spindellockvorrichtung of Fig. 8 .
• Fig. 10 a perspective view of the drive spindle of Fig. 9 .
• Fig. 11 a perspective rear view of the components of Fig. 9 after assembly,
• Fig. 12 an enlarged sectional view of the section of the power tool of Fig. 1 according to a fourth embodiment,
• Fig. 13 a rear perspective view of the drive spindle, the drive member and the spindle locking device of Fig. 12 after assembly,
• Fig. 14 an exploded perspective view of the drive spindle, the drive member, the ball bearing and the Spindellockvorrichtung of Fig. 12 , and
• Fig. 15 an enlarged sectional view of the section of the power tool of Fig. 1 according to a fifth embodiment.

Description of the embodiments

Fig. 1 shows a hand-held power tool 100 having a tool housing 105 with a handle 115. According to one embodiment, the power tool 100 for mains-independent power supply is mechanically and electrically connectable to a battery pack 190. In Fig. 1 is the power tool 100 exemplified trained as a cordless drill. It should be noted, however, that the present invention is not limited to cordless drill, but can be found in different, especially battery-powered power tools application in which a tool is rotated, for. B. in a cordless screwdriver, a cordless hammer drill, etc.

In the housing 105, one of the battery pack 190 supplied with power, electric drive motor 180 and a transmission 170 are arranged. The drive motor 180 is connected via the gear 170 with a drive shaft 120, z. B. a drive spindle connected. The drive motor 180 is illustratively disposed in a motor housing 185 and the transmission 170 is disposed in a transmission housing 110, with the transmission housing 110 and the motor housing 185 being arranged in the housing 105 by way of example.

The transmission 170 is designed to transmit a torque generated by the drive motor 180 to the drive spindle 120 and, according to one embodiment, a planetary gear formed with different gear or planetary stages, which is rotationally driven by the drive motor 180 during operation of the power tool 100. The planetary gear 170 will be described below with respect to a in Fig. 2 enlarged illustrated sectional view of a section 200 described.

The drive motor 180 is z. B. via a manual switch 195 actuated d. H. on and off, and may be any type of engine, e.g. As an electronically commutated motor or a DC motor. Preferably, the drive motor 180 can be electronically controlled or regulated in such a way that both a reversing operation and specifications with respect to a desired rotational speed can be realized. The mode of operation and the design of a suitable drive motor are sufficiently known from the prior art, so that a detailed description of the description is omitted here for the purpose of conciseness of the description.

The drive spindle 120 is rotatably supported by a bearing assembly 130 in the housing 105 and provided with a tool holder 140, which is arranged in the region of an end face 112 of the housing 105 and exemplarily has a drill chuck 145. The bearing assembly 130 according to one embodiment at least two bearing points 132, 134, which are provided in the tool housing 105 in a gear 170 downstream region 299. At the bearings 132, 134 are associated bearings (eg 232, 234 in Fig. 2 ), which serve as spindle bearings and in which the drive spindle 120 is mounted. The tool holder 140 serves to receive a tool 150 and may be formed on the drive spindle 120 or be connected in a tower-shaped manner with this. In Fig. 1 is the tool holder 140 exemplified tower-like and attached to a provided on the drive spindle 120 mounting device 122 thereto.

According to one embodiment, the drive spindle 120 is assigned a spindle locking device 250. This is arranged in the axial direction of the drive spindle 120 between the two bearing points 132, 134, preferably directly, and serves to center the drive spindle 120 when the drive motor 180 is turned off. The operation of spindle locking devices is sufficiently known from the prior art, so that here for the sake of scarcity of Description will be omitted to a detailed description of the operation of the Spindellockvorrichtung 250.

Fig. 2 shows the cutout 200 of the hand-held power tool 100 of Fig. 1 in which for the sake of clarity and simplicity of the drawing to a representation of the tool 150 and the tool holder 140 of Fig. 1 was waived. The cutout 200 illustrates an exemplary embodiment of the planetary gear 170, the drive spindle 120, the bearing assembly 130, as well as the Spindellockvorrichtung 250 according to a first embodiment.

The planetary gear 170 has, by way of example, three gear or planetary stages: a front stage 270, a middle stage 271 and a rear stage 272. The front planetary stage 270 has for example a sun gear 203 with a toothing 269, at least one planetary gear 205 with a toothing 263 , a planet carrier 204 with a rotational drive contour 267, and a ring gear 206. The torque of the drive motor 180 of Fig. 1 is transmitted via the planetary stages 272, 271, 270 by means of the rotary driving contour 267 of the planet carrier 204 to the drive spindle 120. Here, the planet carrier 204 serves as a drive member to drive the drive spindle 120 rotationally. Since the construction of a planetary gear is well known to those skilled in the art, here for the sake of brevity of the description on a further description of the planetary stages 271, 272 omitted.

The planetary stages 270, 271, 272 are illustratively arranged in the transmission housing 110, which is designed as an example in three parts and has a front part 210, a middle part 212 and a rear part 214. The front part 210 illustratively has an external thread 282 on which by way of example an adjusting ring 295 is rotatably mounted. On the inner periphery of the front part 210, an annular shoulder 201 is exemplified.

The drive spindle 120 has the illustrative formed as an external thread fastening device 122 on which the chuck 145 of the tool holder 140 of Fig. 1 is fastened, wherein the external thread 122 z. B. can be brought into threaded engagement with a provided on the drill chuck 145 internal thread. In addition, a support flange 255 is provided on the drive spindle 120 by way of example.

The bearing assembly 130 illustratively includes a plain bearing 232, e.g. B. a sintered bearing, and a rolling bearing 234, z. B. a ball bearing on. The sintered bearing 232 is arranged by way of example at the bearing point 132, which is also referred to below as the first bearing point, and which points in the direction of the tool holder 140 of FIG Fig. 1 seen the planet carrier 204 and thus the transmission 170 is preferably immediately downstream. The ball bearing 234 is arranged by way of example at the bearing point 134, which is also referred to below as the second bearing point, and which points in the direction of the tool holder 140 of FIG Fig. 1 Seen from the planet carrier 204 and thus spaced from the gear 170, and is supported on the support flange 255 from.

According to one embodiment, the spindle locking device 250 has a carrier element 252 mounted on the drive spindle 120 with a predetermined radial play, on which at least one spindle roller 254 is arranged. This is seen in the axial direction of the drive spindle 120 between the two bearings 132, 134 against the drive spindle 120, preferably directly between the sintered bearing 232 and the ball bearing 234. Alternatively, the spindle roller 254 z. B. abut against an inner ring of the ball bearing 234. The sintered bearing 232 and the at least one spindle roller 254 are mounted in a blocking member 256, which is also associated with the spindle locking device 250 and designed to prevent the at least one spindle roller from slipping 254 from the support member 252 in the radial direction of the drive spindle 120 to prevent.

The blocking member 256 is z. B. annular and at least indirectly rotatably connected to the tool housing 105. Illustratively, the blocking member 256 is pressed against rotation in the front part 210 of the gear housing 110, wherein both in the axial and in the radial direction within predetermined tolerances, a corresponding clearance may be present. Alternatively, the blocking member 256 may be connected to the transmission housing 110 without play. For example, the blocking member 256 formed integrally with the gear housing 110 or z. B. be molded by plastic injection to this.

Fig. 3 shows the planet carrier 204, the sintered bearing 232, the blocking member 256, the support member 252, the spindle roller 254, the ball bearing 234 and the drive spindle 120 of Fig. 2 , As described above, the blocking member 256, the support member 252 and the spindle roller 254 form the spindle lock device 250 connected to the drive spindle 120 of FIG Fig. 2 out.

According to one embodiment, the drive spindle 120, on a side of the support flange 255 facing away from the external thread 122, has an annular bearing structure 378, which illustratively terminates with an annular shoulder 388. Starting from the annular shoulder 388 in the direction of the axial end of the drive spindle 120 opposite the external thread 122, this has one or more flattened side surfaces 364, which in number preferably correspond to the number of spindle rollers 254. In addition, on the external thread 122 opposite axial end of the drive spindle 120 groove-like recesses 382, 384 are formed.

The carrier element 252 is illustratively sleeve-shaped and has on its outer circumference a bearing ring 340, which is preferably formed integrally with the carrier element 252 or at least formed on this. At an axial end of the bearing ring 340 axial extensions 322, 324, 326 are provided, which also extend radially outwardly over an outer circumference formed by the bearing ring. At the other axial end of the bearing ring 340, bolt-like holding members 312, 314, 316 are provided for fixing the carrier element 252 to the planet carrier 204.

The axial and radial extensions 322, 324, 326 form recesses 352, 354, 356 for receiving associated spindle rollers. Illustratively, the spindle roller 254 is provided for receiving in the recess 354. It should be noted, however, that any number of recesses may be provided to accommodate any number of spindle rolls.

The blocking member 256 illustratively has a plurality of radially outwardly directed projections 302, 304, 306, 308. These serve for the rotationally fixed fixing of the blocking member 256 in the front part 210 of the gear housing 110 of Fig. 2 as below Fig. 6 described.

The planet carrier 204 has, for example, a holding and driving device 450 formed on an approximately central opening. This realized by way of example the rotational engagement contour 267 of Fig. 2 and will be down below Fig. 4 described in detail.

In the following, an exemplary assembly of the sintered bearing 232, the blocking member 256, the carrier element 252, the spindle roller 254, the ball bearing 234 and the drive spindle 120 on the planet carrier 204 and in the front part 210 of the transmission housing 110 of Fig. 2 described. Here, first, the ball bearing 234 is pressed onto the annular bearing structure 378 on the drive spindle 120 and then with this in an in Fig. 2 the external thread 122 facing opening of the front part 210 pressed until the ball bearing 234 against the annular shoulder 201 of Fig. 2 is applied. Then, the blocking member 256 is pushed from the external thread 122 opposite the axial end of the drive spindle 120 in the axial direction on this and pressed into the front part 210, via its radial projections 302, 304, 306, 308 a rotationally fixed connection with the front part 210th is produced.

Subsequently, the carrier element 252 with the arranged in its recesses 352, 354, 356 spindle rollers 254 on the drive spindle 120 and thus inserted into the blocking member 256, so that the support member 252 surrounds the drive spindle 120 at least partially and the spindle roller 254 against the ball bearing 234 facing away from the annular shoulder 201 of Fig. 2 is applied. In order to minimize the play of the drive spindle To reach 120, a possible between spindle 120 and support member 252, radial clearance is preferably very low. Preferably, the connection between the spindle 120 and the carrier element 252 is free of play. In addition, the spindle roller 254 abuts against the flattened side surface 364 of the drive spindle 120.

Subsequently, the sintered bearing 232 is pushed onto the bearing ring 340 of the carrier element 252 and its bolt-like holding members 312, 314, 316 and the drive spindle 120 are anchored in the holding and driving device 450 of the planet carrier 204 such that at least the drive spindle 120 via a radial clearance-prone positive connection is mounted on the planet carrier 204. Here, the spindle roller 254 is preferably arranged directly between the sintered bearing 232 and the ball bearing 234 as described above.

Fig. 4 shows the planet carrier 204, the sintered bearing 232, the blocking member 256, the support member 252, the spindle roller 254, the ball bearing 234 and the drive spindle 120 of Fig. 3 , In Fig. 4 For example, an exemplary second flattened side surface 462 on the drive spindle 120 and another radial projection 402 on the blocking member 256 are illustrated.

According to one embodiment, the holding and driving device 450 of the planet carrier 204 has retaining grooves 412, 414, 416 and driving webs 482, 484, 486. The retaining grooves 412, 414, 416 are used in the in Fig. 3 described assembly for preferably play-free recording of the bolt-like holding members 312, 314 and 316 of the support member 252. The driving webs 482, 484, 486 are adapted to the in Fig. 3 assembly described in the groove-like recesses 382, 384 of the drive spindle 120 with a predetermined within appropriate tolerances, radial play to intervene, thus allowing a rotary drive of the drive spindle 120 directly through the planet carrier 204.

It is noted, however, that the in Fig. 2 to 4 illustrated embodiment is merely exemplary in nature and should not be construed as limiting the invention. Rather, multiple variations of one or more components in the context of the present invention are possible, as long as the inventive functionality of the spindle locking device 250 of Fig. 2 to 4 is guaranteed. For example, the carrier element 252 has a bearing function to the blocking member 256 at the first bearing 132 exercise, so that can be dispensed with the sintered bearing 232. In an alternative solution, the carrier element 252 may be made shorter than shown, so that the sintered bearing 232 can be pressed directly into the front part 210 of the transmission housing 110. In addition, the blocking member 256 in the front part 210 z. B. are positively molded with plastic, so that the overmolded blocking member 256 instead of the annular shoulder 201 serves as a bearing surface for the ball bearing 234. Furthermore, for example, the planet carrier 204 and the support member 252 may be made in one piece or the support member 252 may be integrally formed on the planet carrier 204 or z. B. by welding or gluing to this be attached, as exemplified in Fig. 15 shown.

Fig. 5 shows the arrangement of Fig. 3 and 4 after the at Fig. 3 described assembly. In Fig. 5 the drive spindle 120 illustratively in the region of the support member 252 has an annular groove 510, in the z. B. an O-ring 520 is arranged. This realizes a braking function between the carrier element 252 and the drive spindle 120, in order thus during operation of the power tool 100 of Fig. 1 to prevent rattling at an outlet of the drive spindle 120.

Fig. 6 shows the planet carrier 204, the sintered bearing 232, the ball bearing 234 of Fig. 2 to 4 and a drive spindle 620, as well as the blocking member 256 of FIG Fig. 2 to 4 , a support member 650, a race 632 and the spindle roller 254 of FIG Fig. 2 to 4 , which form a spindle locking device 610 according to another embodiment and in the front part 210 of Fig. 2 are arranged. The carrier element 650 illustratively has an annular collar 664 on which a bolt-like holding member 616 is formed in an axial direction and at least one recess 652 for receiving the spindle roller 254 and an axial extension 662 are formed in the opposite axial direction.

The drive spindle 620 is compared to the drive spindle 120 of Fig. 2 to 5 shortened and has at least one flattened side surface 654, which merges in a direction away from the support flange 255 axial direction in a groove-like recess 622. This serves to receive the bolt-like holding member 616 of the carrier element 650. In the area of this bolt-like holding member 616, a race 632 is arranged on the drive spindle 620, preferably pressed on. This is stored in the sintered bearing 232.

Fig. 7 shows the arrangement of Fig. 6 without the front part 210 before a corresponding mounting, similar to the above at Fig. 3 described. According to one embodiment, the bolt-like holding member 616 and two further bolt-like holding members 712, 714, and the axial extension 662 and two further axial extensions 764, 766 are formed on the annular collar 664 of the support member 650, the recess 652 and two further recesses for receiving the Form spindle roller 254 and two other spindle rollers.

The drive spindle 620 illustratively has a spindle body 790 facing away from the support flange 255, on which an annular bearing structure 378 for supporting the ball bearing 234 is provided, which illustratively ends with an annular shoulder 788. The at least one flattened side surface 654, which merges into the groove-like recess 622, adjoins this. In addition, illustratively, two side surfaces 782, 784 of arcuate cross-section connect to the annular shoulder 788, which at another shoulder 786 illustratively transition into at least one, preferably three, webs, of which FIG Fig. 7 two webs 794, 796 are visible.

The planet carrier 204 points in Fig. 7 a holding and entraining device 720, are provided on the preferably play-free recording of the bolt-like holding members 616, 712, 714 of the support member 650 retaining grooves. These essentially correspond to the retaining grooves 412, 414, 416 of FIG Fig. 4 and are for the sake of simplicity and clarity of the drawing in Fig. 7 not marked. In addition, the holding and entraining device 720 driving grooves 724, 726, 728 for receiving the webs 794, 796 of the drive spindle 620, so that it can be mounted on the planet carrier 204 via a radial play-affected form fit.

Fig. 8 shows the arrangement of Fig. 7 after assembly, in which instead of the race 632 and the sintered bearing 232, a rolling bearing 832, z. As a ball bearing, application finds. This is like the race 632 of Fig. 6 pressed onto the drive spindle 620 and the carrier element 650. In addition, the ball bearing 832 is pressed into the blocking member 256.

Fig. 9 shows the arrangement of Fig. 8 before assembly. Fig. 9 illustrates the use of the ball bearing 832 instead of the race 632 and the sintered bearing 232 of Fig. 6 and 7 ,

Figure 10 shows the drive spindle 620 of Fig. 6 to 9 , In Fig. 10 a further web 1094 and a further recess 1022 are visible.

Fig. 11 shows a rear view of the arrangement of Fig. 8 with the mounted on the planet carrier 204 at least substantially backlash-free support member 650 and also mounted on the planet carrier 204 drive spindle 620. This is as described above via a radially play-form fit on the planet carrier 204 mounted so that between the webs 794, 796, 1094 of the drive spindle 620 and the driving grooves 724, 728 and 726, respectively, a given within suitable tolerances game 1120 is formed, the sake of simplicity and clarity of illustration in Fig. 11 only once is marked.

During operation of the power tool 100 of Fig. 1 the drive of the drive spindle 620 according to the in Fig. 2 to 11 shown embodiments by acting as a drive member planet carrier 204. Although this can rotate relative to the drive spindle 620, but preferably not relative to the support member 650.

Fig. 12 shows the planet carrier 204, the ball bearings 832, 234 of Fig. 8 and a drive spindle 1220, and a blocking member 1256, a support member 1252 and the spindle roller 254 of Fig. 2 to 11 in the front part 210 of Fig. 2 are arranged and form a spindle locking device 1210 according to another embodiment, in which the support member 1252 serves as a drive member, as below Fig. 13 described. The blocking member 1256 is compared to the blocking member 256 of Fig. 2 to 11 Preferably designed shortened such that this substantially encompasses only a portion of the support member 1252 and the drive spindle 1220, in which the at least one spindle roller 254 is arranged.

The drive spindle 1220 has compared to the drive spindle 620 of Fig. 6 to 11 an annular shoulder 1222 at which the drive spindle 1220 extends from the at least one flattened side surface 654 in one of the support flange 255 directional axial direction tapers in an axial end portion 1242 on which at least one catch groove 1278 is formed. This serves to receive an associated, provided on the illustratively sleeve-shaped support member 1252, radially inwardly directed driving bar 1292, as below Fig. 13 described.

On the support member 1252 is illustratively the bearing ring 340 of Fig. 3 intended. On this is in the front part 210 z. B. pressed or injected by plastic injection ball bearing 832 pressed.

Fig. 13 shows the arrangement of Fig. 12 without the front part 210. Fig. 13 illustrates a plurality of radial projections 1302, 1304, 1306, 1308, which are provided on the blocking member 1256 by way of example.

According to one embodiment, an axial end region 1242 of the drive spindle 1220 is arranged in the carrier element 1252 in order to form a radially play-connected positive connection between the drive spindle 1220 and the carrier element 1252. For this purpose, illustratively, the radially inwardly directed carrier web 1292 and two further radially inwardly directed driving webs 1364, 1366 of the carrier element 1252 engage the receiving groove 1278 or two further driving grooves 1354, 1356 of the drive spindle 1220 with a radial clearance predetermined within suitable tolerances.

Between the carrier element 1252 and the planetary carrier 204, an at least substantially play-free positive connection is formed by way of example so that the carrier element 1252 driven by the planet carrier 204 during operation serves as a drive member and directly drives the drive spindle 1220. For this purpose, engage on the support member 1252 exemplarily formed, radially outwardly directed driving webs 1392, 1394, 1396 in associated driving grooves 1374, 1378 and 1376, which are assigned to a planet carrier 204 formed holding and driving device 1305.

Fig. 14 shows the arrangement of Fig. 13 before an appropriate installation. Fig. 14 illustrates an exemplary embodiment of the support member 1252.

Fig. 15 shows the arrangement of Fig. 2 according to an embodiment in which the planet carrier 204 and the carrier element 252 of Fig. 2 as an example in one piece are formed and form an illustrative drive member 1550.

Claims (26)

A handheld power tool (100) having a tool housing (105) in which a gear (170) for transmitting a torque generated by a drive motor (180) is disposed on a drive spindle (120) associated with a spindle lock device (250) Drive spindle (120) in the tool housing (105) is rotatably mounted on at least two bearing points (132, 134), characterized in that in the region of the spindle locking device (250) on the drive spindle (120) a braking device (520) is provided to the is formed during operation of the power tool (100) at a spout of the drive spindle (120) to prevent rattling. Power tool according to claim 1, characterized in that the braking device (520) has an O-ring (520) for realizing a braking function. Power tool according to claim 2, characterized in that on the drive spindle (120) in the region of the spindle locking device (250) an annular groove (510) is formed, in which the O-ring (520) is arranged. Power tool according to one of Claims 1 to 3, characterized in that the spindle locking device (250) has a carrier element (252) mounted on the drive spindle (120) with a predetermined radial clearance, the brake device (520) being located in the region of the carrier element (252). is arranged. Power tool according to claim 4, characterized in that the carrier element (252) is non-rotatably connected to a drive member (204) of the transmission (170). Power tool according to Claim 5, characterized in that the drive spindle (120) can be driven directly by the carrier element (252). Power tool according to one of claims 4 to 6, characterized in that on the carrier element (252) at least one spindle roller (254) is arranged. Power tool according to claim 7, characterized in that the at least one spindle roller (254) rests in the axial direction of the drive spindle (120) directly between the two bearing points (132, 134) against the drive spindle (120). Power tool according to claim 7 or 8, characterized in that the carrier element (252) is mounted by a formed on its outer circumference bearing ring (340) on a first (132) of the at least two bearing points (132, 134) in a sliding bearing (232). Power tool according to Claim 9, characterized in that the slide bearing (232) is mounted in a blocking member (256) which is designed to prevent the at least one spindle roller (254) from slipping out of the carrier element (252) in the radial direction of the drive spindle (120) ) to prevent. Power tool according to one of claims 1 to 10, characterized in that the at least two bearing points (132, 134) in the tool housing (105) in a transmission (170) downstream region (299) are provided and the spindle locking device (250) in the axial Direction of the drive spindle (120) between the two bearing points (132, 134) is arranged. Electric tool (100) according to one of the preceding claims, characterized in that the at least two bearing points (132, 134) in the tool housing (105) in a transmission (170) downstream region (299) are provided and the spindle locking device (250) in axial Direction of the drive spindle (120) between the two bearing points (132, 134) is arranged. Power tool according to Claim 12, characterized in that the spindle locking device (250) has a carrier element (252) mounted on the drive spindle (120) with a predetermined radial play, on which at least one spindle roller (254) is arranged. Power tool according to claim 13, characterized in that the at least one spindle roller (254) rests in the axial direction of the drive spindle (120) directly between the two bearing points (132, 134) against the drive spindle (120). Power tool according to claim 13 or 14, characterized in that the carrier element (252) is mounted by a formed on its outer circumference bearing ring (340) on a first (132) of the at least two bearing points (132, 134) in a sliding bearing (232). Power tool according to Claim 15, characterized in that the slide bearing (232) is mounted in a blocking member (256) which is designed to prevent the at least one spindle roller (254) from slipping out of the carrier element (252) in the radial direction of the drive spindle (120) ) to prevent. Power tool according to claim 13 or 14, characterized in that the drive spindle (120) is mounted on a first (132) of the at least two bearing points (132, 134) in a roller bearing (832). Power tool according to claim 17, characterized in that the roller bearing (832) is mounted in a blocking member (856) which is designed to prevent the at least one spindle roller (254) from slipping out of the carrier element (252) in the radial direction of the drive spindle (120) ) to prevent. Power tool according to one of claims 16 to 18, characterized in that the blocking member (256; 856) is annular and rotationally fixed to the tool housing (105) is connected. Power tool according to one of claims 13 to 19, characterized in that the drive spindle (120) is mounted on a second (134) of the at least two bearing points (132, 134) in a roller bearing (234) mounted in the tool housing (105) is. Power tool according to one of claims 13 to 20, characterized in that the carrier element (252) is sleeve-shaped and at least partially surrounds the drive spindle (120), wherein on the carrier element (252) at least one recess (354) for receiving the at least one spindle roller (254) is formed. Electric tool is connected to one of claims 13 to 21, characterized in that the carrier element (252) rotationally fixed to a drive member (204) of the transmission (170). Power tool according to claim 22, characterized in that the transmission (170) is designed as a planetary gear and the drive member (204) is a planet carrier. Power tool according to claim 22 or 23, characterized in that the drive spindle (120) directly from the drive member (204) is drivable, wherein between the drive member (204) and the drive spindle (120) is formed a predetermined radial clearance. Power tool according to claim 22 or 23, characterized in that the drive spindle (120) can be driven directly by the carrier element (252). Power tool according to claim 12, characterized in that on the drive spindle (120) in the region of a first (132) of the at least two bearing points (132, 134) a raceway (632) is rotatably mounted, which is mounted in an associated sliding bearing (232).

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