阅读说明：本技术 便携式动力工具 (Portable power tool ) 是由 M·汉斯托塞尔 J·埃哈特 于 2019-10-29 设计创作，主要内容包括：便携式动力工具1具有用于将工具3固位的工具固持器2、手柄7、电动马达4和传动系10。该传动系将该电动马达4联接到该工具固持器2。该传动系10包含具有行星架13和多个行星齿轮14的行星传动装置11。这些行星齿轮14中的至少一个行星齿轮具有圆柱形切口30,并且该行星架13具有呈圆弧形式的突出到该切口30中的套环24。(The portable power tool 1 has a tool holder 2 for retaining a tool 3, a handle 7, an electric motor 4, and a drive train 10. The drive train couples the electric motor 4 to the tool holder 2. The drive train 10 comprises a planetary gear 11 with a planet carrier 13 and a plurality of planet gears 14. At least one of the planet gears 14 has a cylindrical cutout 30, and the planet carrier 13 has a collar 24 in the form of a circular arc that projects into the cutout 30.)

1. Portable power tool

A tool holder (2) for holding a tool (3),

a handle (7) for holding and guiding the portable power tool (1),

an electric motor (4) is provided,

a drive train (10) coupling the electric motor (4) to the tool holder (2), wherein the drive train (10) comprises a planetary transmission (11) having a planet carrier (13) and a plurality of planet gears (14), characterized in that at least one of the planet gears (14) has a cylindrical cutout (30) and the planet carrier (13) has a collar (24) in the form of a circular arc protruding into the cutout (30).

2. The portable power tool (1) as claimed in claim 1, characterized by a planet support (19) for the at least one planet gear (14), wherein the collar (24) is arranged at a radial distance (25) from the planet support (19).

3. The portable power tool (1) as claimed in claim 2, characterized in that the planetary transmission (11) has a ring gear (12) and the collar (24) is arranged between the ring gear (12) and the planet carrier (19).

4. A portable power tool (1) according to claim 3, characterized in that the collar (24) surrounds the planet support at least 120 degrees and surrounds the planet support (19) at most 240 degrees.

5. The portable power tool (1) as claimed in one of the preceding claims, wherein the planet carrier (13) is mounted so as to be rotatable about a main axis (16) and the at least one planet gear (14) is mounted so as to be rotatable about a bearing axis (18), characterized in that the planet carrier (13) has a passage (22) which extends from the main axis (16) to the bearing axis (18).

6. Portable power tool (1) according to claim 5, characterized in that the channel (22) has a void (23).

Technical Field

The present invention relates to a portable power tool having a planetary transmission.

The speed of the electric motor is stepped down by the planetary transmission to match the desired speed of the tool holder. To reduce friction and wear, the various moving parts of the planetary transmission are wetted with lubricant. The centrifugal forces generated by rotating the ring gear make it more difficult to reliably supply and meter lubricant in the region of the planet gears.

Disclosure of Invention

The portable power tool according to the present invention improves lubrication of the planetary gear.

The portable power tool has a tool holder for retaining a tool, a handle for holding and guiding the portable power tool, an electric motor and a drive train. The drive train couples the electric motor to the tool holder. The drive train comprises a planetary gear having a planet carrier and a plurality of planet gears. At least one of the planet gears has a cylindrical cutout, and the planet carrier has a collar in the form of a circular arc projecting into the cutout.

The cut-out on the planet gear and the collar engaging in the cut-out form an effective barrier for the lubricant, which counteracts the centrifugal force.

One configuration has a planet support for the at least one planet gear, wherein the collar is arranged at a radial distance from the planet support. Furthermore, the planetary transmission may have a ring gear, and the collar is arranged between the ring gear and the planet carrier.

In a preferred configuration, the collar surrounds the planet support at least 120 degrees and at most 240 degrees. The lubricant can enter through an open area like a door and be prevented from exiting by the collar.

In one configuration, the planet carrier is mounted so as to be rotatable about the main axis and the at least one planet gear is mounted so as to be rotatable about the bearing axis. The planet carrier has a passage extending from the main axis to the bearing axis. The lubricant can be supplied via the main axis and distributed in the planetary gear by centrifugal force. The channel may have a void.

Drawings

The following description explains the invention on the basis of exemplary embodiments and the drawings, in which:

FIG. 1 shows an electric screwdriver

FIG. 2 shows a planetary transmission

FIG. 3 shows a longitudinal section through a planetary transmission

Unless otherwise indicated, identical or functionally identical elements in the figures are denoted by the same reference numerals.

Detailed Description

Fig. 1 shows an electric screwdriver as an example of a portable power tool 1. The portable power tool 1 has a tool holder 2 for retaining a tool 3. The tool 3 is for example a screwdriver bit, a drill bit or a grinding bit. The user can insert the tool 3 into the tool holder 2 and preferably lock the tool manually. The tool holder 2 is driven by an electric motor 4. In the illustrated example, the tool holder 2 is driven in rotation about a working axis 5.

The portable power tool 1 has a machine housing 6 and a handle 7. The handle 7 is permanently connected to the machine housing 6. The user can hold the portable power tool 1 by the handle 7 and guide the portable power tool 1 during operation. The handle 7 preferably has an ergonomic shape to fit the hand. The handle 7 is connected to a machine housing 6 in which the electric motor 4 is arranged. A battery pack 8 for powering the electric motor 4 is releasably secured to the machine housing 6. Alternatively, the electric motor 4 may be powered via a grid connection. The portable power tool 1 has an operating switch 9, which is preferably arranged on the handle 7. The user can put the portable power tool 1 into operation by actuating the operating switch 9. Typically, the operating switch 9 is monostable and must remain depressed, otherwise the portable power tool 1 is turned off. The tool holder 2 is connected to an electric motor 4 via a drive train 10. The drive train 10 comprises a planetary gear 11. The planetary transmission 11 can adapt the speed and torque of the electric motor 4 to the desired speed and desired torque of the tool 3. The exemplary planetary transmission 11 supports this speed.

The planetary gear 11 has a gear stage which comprises a ring gear 12, a planet carrier 13, a plurality of planet gears 14 and a sun gear 15. Although the following description is limited to a planetary transmission 11 having only one gear stage, a plurality of these or other gear stages may be connected in series.

The planetary gear 11 has a main axis 16, with which the ring gear 12, the planet carrier 13 and the sun gear 15 are arranged coaxially. The planet carrier 13 is mounted to rotate about the main axis 16 independently of the ring gear 12 and the sun gear 15. The ring gear 12 and the sun gear 15 preferably lie in one plane. The ring gear 12 and the sun gear 15 are not directly engaged and are mounted so as to be rotatable relative to each other about a main axis 16. The planet carrier 13 is preferably arranged along the main axis 16 in an offset manner with respect to the ring gear 12 and the sun gear 15. The planet carrier 13 is mounted to be rotatable about the main axis 16 and is not in direct engagement with the ring gear 12 or with the sun gear 15. Accordingly, the carrier 13 is rotatable relative to the ring gear 12 and the sun gear 15. The coupling between the ring gear 12, the planet carrier 13 and the sun gear 15 takes place via three or more planet gears 14. Three or more planet gears 14 are arranged between and in the plane of the ring gear 12 and the sun gear 15. The planet gears 14 are both in engagement with the ring gear 12 and with the sun gear 15 and thus transfer torque from the ring gear 12 to the sun gear 15 and vice versa. The planet gears 14 are mounted on a (front) face 17 of the planet carrier 13. The planet gears 14 are mounted in a planet carrier 19 so as to be rotatable about their (planet) shafts 18. The planet carrier 19 is arranged on the planet carrier 13. The planet supports 19 are radially offset with respect to the main axis 16. In the illustrated example, the planet carrier 19 is arranged centrally between the ring gear 12 and the sun gear 15. Fixedly attaching the planet pins 18 to the planet carrier 13 has the effect that when the planet carrier 13 rotates around the main axis 16, they are carried eccentrically around the main axis 16. The planet carrier 13 can transmit torque to the ring gear 12 and the sun gear 15 in a coupled manner via the planet gears 14 and vice versa.

In the embodiment shown, the planetary transmission 11 is connected on the drive input side to the electric motor 4 through a sun gear 15 and on the drive output side to the tool holder 2 through a planet carrier 13. This arrangement is merely an example. The ring gear 12, the planet carrier 13 and the sun gear 15 may each serve as a drive output side or a drive input side, depending on the desired gear ratio, design and other considerations. Furthermore, respective third ones of these elements may be coupled to the machine housing 6 in a rotationally fixed manner, freely rotatable about the main axis 16, or coupled to the machine housing 6 via a brake or switching mechanism. The illustrated teeth and number thereof are for illustration only and do not necessarily correspond to actual gear ratios.

The illustrated planet carrier 19 includes a carrier neck 20 on the planet carrier 13 and a hub 21 in the planet gears 14. A bearing neck 20 projects from the front face 17 of the planet carrier 13 in the direction of the plane of the ring gear 12 and the sun gear 15. The bearing neck 20 is arranged in a manner offset from the main axis 16. In the example, the support neck 20 is centrally disposed between the ring gear 12 and the sun gear 15. The (bearing) axis 18 of the bearing neck 20 is parallel to the main axis 16. The bearing neck 20 may be rigidly connected to the planet carrier 13, or may be mounted in the planet carrier 13 so as to be rotatable about the bearing axis 18. The hub 21 of the planetary gear 14 is rotatably fitted on the bearing neck 20. In one configuration, the hub 21 may be rigidly connected to the bearing neck 20, wherein the bearing neck 20 is mounted in the planet carrier 13 so as to be rotatable about the bearing axis 18.

The planet carrier 13 has a radially extending passage 22 which extends from the main axis 16 to the planet support 19. The channel 22 has been introduced as a recess in the front face 17 of the planet carrier 13. The depth of the channels 22 is less than the width of the channels 22 so they can be produced using conventional sintering methods. The aspect ratio of depth to width is preferably less than 1: 3. Depth represents the dimension along the main axis 16 and width represents the dimension measured perpendicular to both the line of connection between the main axis 16 and the bearing axis 18 and the depth.

The planet carrier 19 is preferably located within the channel 22. One end of the channel 22 forms an annular space 23 around the support neck 20. The voids 23 may be formed in a circular manner. The void 23 is recessed relative to the front face 17.

For each planet carrier 19, the planet carrier 13 has a collar 24 in the form of a circular arc. Collar 24 projects along main axis 16 relative to front face 17. The collar 24 may directly abut the void 23. The collar 24 extends at a radial distance 25 from the support axis 18. The cylindrical axis of the collar 24 and the bearing axis 18 are correspondingly coincident. The collar 24 has an (outer) surface 26 facing away from the support axis 18 and an (inner) surface 27 facing the collar 24. In the case of the collar 24 shown by way of example, the outer surface 26 and the inner surface 27 are cylindrical. The thickness of the collar 24 (i.e., the distance 25 from the outer surface 26 to the inner surface 27) is constant. In another configuration, the outer surface 26 is still part of a cylinder having a radius 28 about the bearing axis 18, while the inner surface 27 has a different, preferably concave shape and is spaced from the bearing axis 18.

The collar 24 is arranged between the ring gear 12 and the planet carrier 19 in the radial direction. Accordingly, the average distance of the collar 24 from the main axis 16 is greater than the distance of the bearing axis 18 from the main axis 16. The collar 24 covers an angular sector of at least 120 degrees, such as at least 150 degrees, such as at least 175 degrees. Preferably, the collar covers an angular sector of less than 240 degrees (e.g. less than 210 degrees, e.g. less than 185 degrees). The collar may be arranged in mirror symmetry to the connecting line between the main axis 16 and the bearing axis 18. The collar 24 has an opening in the direction of the sun gear 15. The collar 24 has a height less than the radius 28, preferably having an aspect ratio less than 1: 3. The height represents a dimension along the major axis 16.

The planet gears 14 may be formed in the same manner. The description is limited to one of the planet gears 14 by way of example. The planet gears 14 have a (rear) face 29 facing the planet carrier 13. There is an air gap between the front face 17 of the planet carrier 13 and the rear face 29 of the planet gears 14. The two faces do not touch each other.

The planet gear 14 has a cylindrical cutout 30 in the rear face 29. The cylindrical cutout 30 has a radius 28 which corresponds to the radial distance 25 of the collar 24 from the bearing axis 18. The depth 31 of the cut 30 corresponds to the height of the collar 24. The collar 24 extends into the cutout 30 of the planet gear 14. The radial dimension has a play element, so the planet gears 14 do not contact the collar 24. The planet carrier 19 is preferably formed only by the carrier neck 20 and the hub 21.

The planet carrier 19 is wetted by the lubricant film. The lubricant is delivered from the main axis 16 to the bearing neck 20 by centrifugal force. The collar 24 and the cylindrical cutout 30 form an effective barrier for the lubricant, which prevents any discharge from the planet support 19 due to centrifugal forces. The wetting of the main axis 16 can take place by a reservoir of lubricant outside the planetary gear 11.

The illustrated planetary transmission 11 is shown with the sun gear 15 on the drive input side and the planet carrier 13 on the drive output side. In other configurations, one of the sun gear 15, the carrier 13, and the ring gear 12 may be coupled to the electric motor 4 at the drive input side. One of the remaining two elements of the sun gear 15, the planet carrier 13 and the ring gear 12 is coupled to the tool holder 2 on the drive output side. The planetary gear 11 shown comprises only one gear stage. In an alternative embodiment, a plurality of planetary gear stages may be interconnected. Each planetary gear stage may have a planet carrier 13 with said collar 24 and a corresponding planet gear 14 with a cylindrical cut-out 30.

The use of the planetary transmission 11 in the illustrated electric screwdriver is an example. Other portable power tools with planetary transmissions include drills, hammer drills, chisels, circular saws, jig saws, pendulum jigsaws, angle grinders, and the like. The drive train 10 may include other drive components 32 connected upstream or downstream of the planetary transmission 11. Examples of driving members are slip clutches, tangential impact mechanisms, electro-pneumatic impact mechanisms, pendulum stroke mechanisms, other gear stages, etc. Depending on the drive train 10, the tool holder 2 transmits a continuous rotary motion, a pulse-like rotary motion, an axial percussion motion, a pendulum motion or a superposition of these motions to the tool 3.