Composite gearwheel for an electropneumatic hammer drill

Abstract

Composite gearwheel for an electropneumatic hammer drill, wherein the composite gearwheel has a basic body, consisting of a first material, and an encircling toothing, and wherein the encircling toothing is formed, along a first circular arc, by a toothed body of the composite gearwheel, and is formed, along the remaining second circular arc, by the basic body itself, wherein the toothed body consists of a second material that is different than the first material.

Claims

1. An electropneumatic hammer drill comprising: a composite gearwheel for an electropneumatic hammer drill, the composite gearwheel including: a basic body consisting of a first material; and a toothed body consisting of a second material different from the first material; the composite gearwheel having an encircling toothing formed, along a first circular arc, by the toothed body, and formed, along a remaining second circular arc by the basic body; wherein the composite gearwheel is installed in a transmission unit of the hammer drill in such a way that only the part of the encircling toothing formed by the toothed body is exposed to an increased torque of an impact mechanism of the hammer drill.

2. The electropneumatic hammer drill as recited in claim 1 wherein the first circular arc has a center angle of less than 90 degrees.

3. The electropneumatic hammer drill as recited in claim 2 wherein the center angle is less than 45 degrees.

4. The electropneumatic hammer drill as recited in claim 3 wherein the center angle is 40 degrees.

5. The electropneumatic hammer drill as recited in claim 1 wherein the basic body has a slot, the toothed body being at least partially introduced into and located in the slot.

6. The electropneumatic hammer drill as recited in claim 1 further comprising a balancing weight compensating for an imbalance caused by the toothed body.

7. The electropneumatic hammer drill as recited in claim 1 wherein the first material is a plastic.

8. The electropneumatic hammer drill as recited in claim 7 wherein the second material is a steel material.

9. The electropneumatic hammer drill as recited in claim 1 wherein the second material is a steel material.

10. The electropneumatic hammer drill as recited in claim 1 wherein exactly one toothed body having a plurality of teeth of the encircling toothing is provided.

11. The electropneumatic hammer drill as recited in claim 1 further comprising a central hub defining a timing of the composite gearwheel.

12. The electropneumatic hammer drill as recited in claim 11 wherein the central hub is form fitting in the basic body.

13. The electropneumatic hammer drill as recited in claim 11 wherein the central hub is in the form of an insert.

14. The electropneumatic hammer drill as recited in claim 11 wherein the central hub has an internal toothing with eight teeth.

15. The electropneumatic hammer drill as recited in claim 1 further comprising a brushless electric motor operatively connected to the impact mechanism via the transmission unit.

16. The electropneumatic hammer drill as recited in claim 1 wherein the impact mechanism has a piston acting on a pneumatic spring.

17. The electropneumatic hammer drill as recited in claim 1 wherein a peak range of a torque angle is from 280 degrees to 320 degrees.

18. A composite gearwheel for an electropneumatic hammer drill, the composite gearwheel comprising: a basic body consisting of a first material; and a toothed body consisting of a second material different from the first material; the composite gearwheel having an encircling toothing formed, along a first circular arc, by the toothed body, and formed, along a remaining second circular arc by the basic body; and a balancing weight compensating for an imbalance caused by the toothed body.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) In the figures, identical and similar components are denoted by the same reference signs. In the figures:

(2) FIGS. 1 A, 1 B and 1 C show a first preferred exemplary embodiment of a composite gearwheel according to the invention;

(3) FIG. 2 A shows an electropneumatic hammer drill having the composite gearwheel in FIG. 1; and

(4) FIG. 2 B shows the torque in the transmission unit plotted versus the crank angle KW.

DETAILED DESCRIPTION

(5) A preferred exemplary embodiment of a composite gearwheel 10 according to the invention is illustrated in FIGS. 1 A, 1 B and 1 C. The composite gearwheel 10 can be used in a transmission unit 30 of an electropneumatic hammer drill 100 (cf. FIG. 2).

(6) The composite gearwheel 10 has a basic body 1 consisting of a first material M1, in the present case for example a thermoplastic, and an encircling toothing 3. The encircling toothing 3 is formed, along a first circular arc K1, only by a toothed body 5 of the composite gearwheel 10. Exactly one toothed body 5 is provided, which has a plurality of teeth 3 of the encircling toothing 3. The second toothed body 5 is formed from a second material M2, which is different than the first material M1. In the presented here, the second material M2 is a steel material.

(7) As can be gathered from FIG. 1 A, the encircling toothing 3 is formed, along the remaining second circular arc K2, by the basic body 1 itself. The first circular arc K1 and the second circular arc K2 are each in relation to an axis of rotation D of the composite gearwheel 10 and add together to form a full circle.

(8) In the exemplary embodiment illustrated in FIG. 1 A, the first circular arc K1 has a center angle ZW of less than 45 degrees, in this case for example about 40 degrees. This corresponds to a sector with comparatively high torque loading (cf. FIG. 2 B).

(9) The composite gearwheel 10 in FIG. 1 A also has a central hub 2 for defining a timing of the composite gearwheel 10.

(10) FIG. 1 B shows the composite gearwheel 10 from FIG. 1 A in an exploded illustration. It is readily apparent that the toothed body 5 is in the form of a separate component, different than the basic body 1. In order to hold the toothed body 5 in the basic body 1, the basic body 1 has a slot 7, into which the toothed body 5 has been at least partially introduced (FIG. 1A shows the toothed body 5 introduced into the slot 7). As can be gathered from FIG. 1 B, the toothed body 5 has a cutout 6. This serves for one part for saving weight. For the other part, the toothed body 5 can be fastened in a radial direction R via this cutout 6 and a corresponding cutout 6, which is formed in the basic body 1. This can take place for example by plugging in a pin, which is not illustrated here, or by joint casting of the cutouts 6, 6.

(11) As can be gathered from FIG. 1 B, the composite gearwheel 10 has a balancing weight 9, in order to compensate for an imbalance caused by the toothed body 5. The balancing weight 9 is in the form of a separate body, in the present case made of steel, which is located entirely within the basic body 1 with the composite gearwheel 10 assembled (cf. FIG. 1 A). For example, the balancing weight 9 can be held in the basic body 1 in a radial direction R by means of a pin, which is not illustrated here and is intended to be introduced through a pin hole 9 formed in the basic body 1.

(12) As already mentioned, the composite gearwheel 10 has a central hub 2 for defining a timing of the composite gearwheel 10. In the present case, the central hub 2 is in the form of an insert, which is held in the basic body in a form-fitting manner (by means of the external teeth 8).

(13) FIG. 1 C shows, finally, a central hub 2 in detail. The hub 2 has for example an internal toothing 4 with eight teeth 4, which are distributed uniformly along an inner circumference IU of the hub. The teeth 4 are arranged at a spacing of 45 degrees, this corresponding approximately to the center angle ZW of the first circular arc K1 of the toothed body 5. As a result, the gearwheel can be installed in a transmission unit 30 of the hammer drill 100 in such a way that only that part of the encircling toothing 3 that is formed by the toothed body 5 is exposed to an increased torque of an impact mechanism 20 of the hammer drill 100.

(14) FIG. 2 A now shows such an electropneumatic hammer drill 100. The latter has a preferably brushless electric motor 40, which is operatively connected to an impact mechanism 20 via a transmission unit 30. For its part, the impact mechanism has a piston 21, which acts on a pneumatic spring 23. The transmission unit 30 has the composite gearwheel 10, which is driven about the axis of rotation D. In FIG. 2 B, the torque in the transmission unit 30 (to be more precise at the measurement point 35) is plotted versus the crank angle KW. The crank angle KW is defined about the axis of rotation D. It is readily apparent that the torque M is comparatively low (Mmin) in the range from 0 degrees to 180 degrees and a peak torque (Mmax) arises in the range between 280 degrees and 320 degrees. This is absorbed by the toothed body 5 having an exemplary center angle ZW of 40 degrees.

LIST OF REFERENCE SIGNS

(15) 1 Basic body 2 Hub insert 3 Encircling toothing 4 Internal toothing 4 Tooth 5 Toothed body 6, 6 Cutout 7 Slot 8 External tooth 9 Balancing weight 9 Pin hole 10 Composite gearwheel 20 Impact mechanism 21 Piston 23 Pneumatic spring 30 Transmission unit 35 Measurement point 40 Electric motor 100 Hammer drill D Axis of rotation K1 First circular arc K2 Second circular arc KW Crank angle M Torque M1 First material M2 Second material R Radial direction IU Inner circumference ZW Center angle