Portable planing machine

Abstract

A portable planing machine has a rotatably mounted planing shaft in a housing. The planing shaft is driven by a drive motor. Furthermore, a fan wheel is configured to generate a cooling airflow. At least one cooling duct is integrated into the planing shaft. An outflow opening of the cooling channel is at a greater radial spacing from the rotational axis than an inflow opening of the cooling duct.

Claims

1. A portable planing machine, comprising: a housing; a planing shaft rotatably mounted in the housing, the planing shaft including at least one cooling duct having an outflow opening and an inflow opening, the planing shaft further including at least one blade; and an electric drive motor connected to the planing shaft and configured to drive the planing shaft, the electric drive motor including a fan wheel configured to generate a cooling air flow, wherein the outflow opening of the at least one cooling duct is positioned at a greater radial spacing from a planing shaft rotational axis than the inflow opening of the at least one cooling duct in the planing shaft.

2. The portable planing machine according to claim 1, wherein: the planing shaft has a substantially hollow-cylindrical shape; and the inflow opening of the at least one cooling duct is located on a radial inner side of the planing shaft.

3. The portable planing machine according to claim 2, wherein: the electric drive motor is integrated into the planing shaft by a connecting part; and the cooling air flow is guided axially along the electric drive motor by a channel formed between the connecting part and a stator of the drive motor to the inflow opening of the at least one cooling duct.

4. The portable planing machine according to claim 3, wherein a rotor or a motor shaft of the electric drive motor is fixedly connected to the planing shaft.

5. The portable planing machine according to claim 1, wherein the outflow opening of the at least one cooling duct is located on an end side of the planing shaft.

6. The portable planing machine according to claim 1, wherein the at least one cooling duct is a plurality of cooling ducts and the plurality of cooling ducts is distributed over a circumference of the planing shaft.

7. The portable planing machine according to claim 1, further comprising: a cover fastened to the housing and defining at least one ventilation slot and an annular channel extending in a circumferential direction wherein the annular channel is located between an inner side of the cover and the fan wheel.

8. The portable planing machine according to claim 7, wherein the annular channel opens into a discharge channel which extends through the housing transversely with respect to a longitudinal axis of the portable planing machine.

9. The portable planing machine according to claim 7, wherein the annular channel has a variable cross section over a length of the annular channel.

10. The portable planing machine according to claim 9, further comprising a flow guide element formed as one piece with the cover, wherein the flow guide element protrudes into the annular channel.

11. The portable planing machine according to claim 10, wherein: the flow guide element has a ramp-shaped configuration; and the variable cross section of the annular channel has an axial taper.

12. The portable planing machine according to claim 10, wherein the fan wheel is configured to generate an air flow that enters the annular channel downstream of the flow guide element.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) FIG. 1 shows a perspective view of a portable planing machine;

(2) FIG. 2 shows a section transversely through the portable planing machine, into the planing shaft of which cooling ducts are integrated which extend at an angle with respect to the planing shaft rotational axis, with a fan wheel which is driven by the drive motor;

(3) FIG. 3 shows a view of the end side of the portable planing machine below the fan wheel, with a plurality of inflow openings, via which the air flow which is generated by the fan wheel is guided into the interior of the portable planing machine;

(4) FIG. 4 shows a view of the end side of the planing shaft on the side which faces away from the fan wheel, with a plurality of outflow openings of the cooling ducts which are made in the planing shaft;

(5) FIG. 5 shows a perspective view of a cover which can be placed onto the fan wheel and is to be connected to the housing of the portable planing machine;

(6) FIG. 6 shows the cover in a further perspective view;

(7) FIG. 7 shows the fan wheel in the mounted position on the portable planing machine, without the cover placed onto it;

(8) FIG. 8 shows a detailed illustration of the air guidance of a chip discharge flow, via which chips are blown out of the portable planing machine; and

(9) FIG. 9 shows a further perspective illustration of a portable planing machine with an outflow opening in the lateral housing region for discharging the chip discharge flow.

DETAILED DESCRIPTION

(10) In the figures, identical components are provided with the same reference numerals.

(11) FIG. 1 shows a portable planing machine 1 which, in a housing 2, has an electric drive motor and a planing shaft which is mounted rotatably in the housing and is driven by the drive motor. On its circumference, the planing shaft has one or more knives with a blade which removes workpiece material during workpiece machining. A base plate 3 is situated on the underside of the housing 2, which base plate 3 rests on the workpiece upper side and has a recess, through which the knife of the planing shaft protrudes. Furthermore, a handle 4 for holding and guiding the portable planing machine is arranged on the housing 2. A cover 5 is arranged laterally on the housing and is connected to the latter; the cover 5 covers a fan wheel which is seated axially on the end side of the electric drive motor and is driven by the latter. The portable planing machine 1 can be equipped with a planing depth setting means.

(12) As can be gathered from the sectional illustration according to FIG. 2, the planing shaft 6 is of hollow-cylindrical configuration and accommodates the coaxially arranged electric drive motor 7 in its interior space. The motor shaft 8 of the drive motor 7 supports the fan wheel 9 which is connected fixedly to the motor shaft 8 so as to rotate with it and is arranged on the end side of the drive motor 7 or planing shaft 6. The fan wheel 9 is engaged over by the cover 5 which is connected to the housing 2.

(13) The drive motor 7 has a connecting part 10 which is connected to the motor shaft 8 and rotates jointly with the latter. The connecting part 10 is of hollow-cylindrical configuration and bears against the inner wall of the planing shaft 6 and is connected fixedly to the planing shaft 6, with the result that the planing shaft 6 is also driven when the drive motor 7 is running.

(14) The fan wheel 9 generates two air flows which are guided through the housing of the portable planing machine 1 and have different functions. A first air flow 11 is guided as a cooling air flow axially along the drive motor 7, in order to cool the latter. A second air flow 12 has the task of a chip discharge flow, via which chips which accumulate during workpiece machining are guided to the outside again out of the housing of the portable planing machine. Both air flows 11, 12 are introduced into the housing 2 via ventilation slots in the cover 5.

(15) The fan wheel 9 does not extend further to the outside in the radial direction than the planing shaft 6 which has a greater external diameter than the fan wheel 9. The cooling air flow 11 lies offset radially further to the inside than the chip discharge flow 12.

(16) The cooling air flow 11 is guided axially along the drive motor 7 along the inner side of the hollow-cylindrical connecting part 10. A cylindrical or annular channel, shown as a first cooling duct section 18 in FIG. 2, extends in the axial direction in relation to the rotational axis 14 of the planing shaft 6 and the motor shaft 8 is formed between the connecting part 10 and the radially inner stator 13 of the drive motor 7.

(17) On the outflow side of the first cooling duct section 18 between the stator 13 and the cylindrical connecting part 10, the cooling air flow 11 enters into cooling ducts 15 which are made in the planing shaft 6. The cooling ducts 15 are of rectilinear configuration and extend at an angle with respect to the rotational axis 14, which angle lies at approximately 30 in the exemplary embodiment. Each cooling duct 15 has an inflow opening 16 on the radially inner side of the planing shaft 6 and an outflow opening 17 on that end side of the planing shaft which faces away from the fan wheel 9. On account of the oblique course of the cooling duct 15, the inflow opening 16 is at a smaller radial spacing from the rotational axis 14 than the outflow opening 17. During a rotation of the planing shaft 6, this assists the flow course from the first cooling duct section 18 into the cooling ducts 15. Downstream of the outflow opening 17, the cooling air flow can pass into the surroundings via slots in the housing.

(18) A housing-side covering plate 19 is situated between the fan wheel 9 and the drive motor 7, in which covering plate 19 flow openings 20 are made, as can be gathered from FIG. 3. Via the flow openings 20, the cooling air flow 11 passes into the first cooling duct section 18 and, from there, further into the cooling ducts 15 in the planing shaft 6.

(19) FIG. 4 shows the end side 21 of the planing shaft 6. The cooling ducts 15 which are made in the planing shaft 6 open with their outflow openings 17 on the end side 21. Distributed over the circumference, a total of 12 cooling ducts with in each case one outflow opening 17 are made in the planing shaft 6. The cooling ducts with the outflow openings 17 are combined in each case in groups of three cooling ducts which are arranged in a closely adjacent manner and are situated in each case in a 90 angular segment.

(20) Moreover, the knife 22 can be gathered from FIG. 4, which knife 22 is arranged on the planing shaft 6 and, when the planing shaft is rotating, protrudes periodically through a recess in the base plate 3.

(21) FIGS. 5 and 6 in each case show the cover 5 which engages over the fan wheel in the mounted state. The cover 5 has fastening eyes 23 and 24, via which fastening to the housing of the portable planing machine is possible.

(22) An annular channel 25 which extends in the circumferential direction for the chip discharge channel 12 is formed in the cover 5 adjacently with respect to the annular outer wall. The cover 5 delimits the chip discharge channel in the axial direction and radially to the outside. In the mounted state, the annular channel 25 is delimited radially to the inside by the outer side of the fan wheel 9.

(23) In the flow direction, the cross section of the annular channel 25 widens in the radial direction. A flow guide element 26 which delimits the flow cross section of the annular channel 25 in the axial direction is configured in one piece with the outer wall of the cover 5. As can be gathered from the illustration according to FIG. 6, the flow guide element 26 is of ramp-shaped configuration and delimits the flow cross section in the flow direction axially in an increasing manner.

(24) FIG. 7 also shows the annular channel 25 on the housing side. It can be gathered in conjunction with the further FIGS. 8 and 9 that the chip discharge flow 12 opens into a discharge channel 27 in the housing, which discharge channel 27 extends through the housing 2 transversely with respect to the longitudinal axis of the portable planing machine 1 and guides the chip discharge flow 12 transversely through the housing, starting from the fan wheel 9, to the opposite side of the portable planing machine and discharges into the surroundings at this point.

(25) According to FIGS. 8 and 9, the chip discharge flow is divided into a first part flow 12 and a second part flow 12a, the first part flow 12 being guided, as described above, through the annular channel 25 in the circumferential direction between the outer side of the fan wheel 9 and the inner side of the cover 5. The second part flow 12a is situated within the fan wheel 9 and opens into the last section of the annular channel 25 (FIG. 8), which last section merges at a 90 angle into the discharge channel 27 which extends in the transverse direction. The ramp-shaped flow guide element 26 on the cover 5 deflects the first part flow 12 in the annular channel 25 axially, with the result that, as can be gathered from FIG. 8, the first and the second part flow 12 and 12a flow away in parallel and on different planes in the direction of the discharge channel 27 in the end section of the annular channel 25.