POWER TOOL, IN PARTICULAR HANDHELD POWER TOOL

Abstract

A power tool includes a guard hood to be fixed on a tightening neck via a securing device thereof. The securing device has a securing part, which is to be tightened via an actuation element, and a detent component which is adjustable between a detent or locked position and a nondetent or unlocked position. The actuation element acts upon both the securing part and the detent component.

Description

CROSS-REFERENCE TO RELATED APPLICATION

This application is based on German Patent Application 10 2008 002 468.6 filed Jun. 17, 2008.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The invention relates to a power tool, in particular a handheld power tool, such as a ring-angle sander, and to a guard hood for a power tool.

2. Background of the Invention

From German Patent Disclosure DE 102 59 520 A1, an electric handheld power tool with a disklike rotating tool is known over which a guard hood fits that is retained with the aid of a tightening ring on a tightening neck of the power tool. There is also a tool receptacle in the tightening ring for the rotating support of the tool. The tightening ring for fixing the guard hood to the tightening neck is tightened with the aid of a screw.

On the outside of the tightening ring, a detent component is also supported in articulated fashion. By means of a detent element, the detent component protrudes through a recess in the wall of the tightening ring and engages a set of teeth on the outer jacket of the tightening neck. In this way, a form lock in the circumferential direction between the tightening ring and the tightening neck can be created, which prevents twisting of the tightening ring and guard hood on the tightening neck. This increases safety, particularly in the event of breakage of the tool.

The detent element is disposed on a detent grip, which is supported in articulated fashion on the outside of the tightening ring and can be pivoted manually between the detent position, in which the detent element is in engagement with the set of teeth on the tightening neck, and a nondetent or unlocked position.

OBJECT AND SUMMARY OF THE INVENTION

The object of the invention is, with high functional safety, to simplify a power tool, in particular a handheld power tool, having a guard hood retained on a tightening neck via a securing device, in its handling and structural makeup, as well as to create a guard hood suitable as original equipment for such a power tool but also suitable as a conversion part or retrofitting part of power tools.

In the power tool of the invention, by means of the common actuation of the securing part and the detent component via an actuation element a common adjustment of the securing part and detent component is attained, and thus in one work step, not only is the securing part put in its securing position, but the detent component is also put in its detent position relative to the tightening neck.

Hence the actuation element is given a dual function: First, the securing part is tightened, and second, the detent component is adjusted into the detent position. A separate actuation of the detent component can thus be omitted. It suffices, via the actuation element, to put the securing part into the tightening position, and at the same time, via the actuation element, the detent component is adjusted into the detent position. The result is considerably simpler handling, achieved by structurally simple means. With the tightening of the securing part, this part exerts a radial clamping force, by way of which the guard hood is firmly clamped on the tightening neck. By way of the detent component which is in engagement with the tightening neck, additional securing is achieved, and this additional securing is embodied in particular as a form lock which is operative in the circumferential direction and/or the axial direction; for that purpose, the tightening neck has a circumferentially extending set of teeth on its jacket face that are engaged by the detent element in the detent position.

A circumferential groove can moreover be provided on the tightening neck and preferably extends over the entire circumference of the tightening neck. In combination with the set of teeth, this leads to an embodiment in which the toothlike indentations forming the set of teeth extend in the axial direction, originating at the circumferential groove.

The circumferential groove has the function of securing the guard hood axially on the tightening neck in form-locking fashion. This is preferably effected via the detent element of the detent component, which thus besides the securing in the circumferential direction is also given the function of securing in the axial direction. When the guard hood is adjusted in the circumferential direction, the detent element can be moved inside the circumferential groove. However, in principle, it is also possible for a further component, such as a pin or a peg on the guard hood or the tightening ring, to engage the circumferential groove.

In an alternative embodiment, the circumferential groove is embodied separately from the set of teeth; for instance, the circumferential groove is axially offset from the set of teeth on the jacket face of the tightening neck. In this embodiment, the securing in the axial direction is effected via a separate component, such as the aforementioned pin or peg.

The guard hood of the invention is preferentially used in handheld power tools, in particular electrically operated handheld power tools, with a rotating, preferably disklike tool, such as a ring-angle sander, in which the guard hood that surrounds the rotatingly supported tool of the power tool, is to be fastened via the securing device on a tightening neck of the power tool. The securing device of the guard hood has a securing part, which is to be tightened via an actuation element, and also has a detent component, which is to be adjusted by the tightening neck between a detent position and a nondetent or unlocked position.

In the guard hood of the invention and its securing device, it is provided that the actuation element acts upon both the securing part and the detent component, and with the fastening of the securing part via the actuation element, the detent component is to be put simultaneously into the detent position. Despite the dual function of the securing device, the result is a simple construction of the guard hood, which as a functional unit with its securing device also forms a spare part and retrofitting part that—at least without major requirement for adaptation—can also be used to replace guard hoods of different construction in many power tools.

The securing par is preferably embodied as a tightening ring, which is laid around the tightening neck and tightened via the actuation element. In principle, however, structurally different securing with which the guard hood is to be secured to a component of the power tool can also be considered.

In a preferred embodiment, the detent component is retained solely on the securing part, so that the securing part and the detent component form a common module which is to be adjusted by the actuation element. The actuation element too can be retained directly on the securing part, particularly when embodied as a screw that in the case of an embodiment as a tightening ring connects two radially upward-bent end portions of the tightening ring in a known manner. The free face end of the screw preferably acts as the contact face with which the screw is in contact with the detent component and adjusts the detent component from the nondetent position into the detent position.

In principle, however, it is also possible to retain the detent component on some other tool component, for instance directly on the guard hood or on a housing part of the power tool. It is furthermore possible for the actuation element to be embodied not as a screw but instead as a toggle fastener, and the toggle fastener acts on the detent component during the tightening process. Optionally, the actuation element is retained not on the tightening ring but on some other component, such as the guard hood or a housing part.

Various possibilities of movement for the detent component upon the transfer from the nondetent position to the detent position can be considered. Preferably, the detent component executes a pivoting or rotary motion then, but within the scope of the invention a translational adjusting motion or a mixed translational-rotary adjusting motion is possible.

In the case of articulated support, the engagement or contact point is located between the actuation element and the detent component, spaced apart from the joint axis of the detent component, so that it is assured that a resultant torque becomes operative about the joint axis, and by means of this torque the detent component is adjusted into the detent position.

It may furthermore be expedient to associate a spring element with the detent component, the spring element advantageously being braced on the same component as the detent component, in particular on the tightening ring, and subjecting the detent component to force in the direction of the nondetent position. It is thus assured that the detent component is automatically restored to the nondetent position by the action of the spring element as soon as the actuation element is adjusted into the release position, in which the tightening ring is also located in the relaxed state. Thus with a single adjusting motion of the actuation element, on the one hand the tightening ring is tightened and simultaneously the detent component is adjusted into the detent position, and on the other, upon an opposite motion of the actuation element, the tightening ring is relaxed and at the same time the detent component is adjusted into the detent position.

However, it may also be expedient, in addition or alternatively to the spring element, to provide mechanical coupling between the actuation element and the detent component, by way of which coupling the detent component, upon a releasing motion of the actuation element, is pulled by the actuation element into the nondetent position. The coupling can be effected via a slaving element, for instance.

In the case of articulated support, the pivot joint of the detent component can assume various positions relative to the detent element, which arrives in contact with the tightening neck, and to the actuation element, as long as a spacing both between the pivot joint and the detent element and between the pivot joint and the contact point between the actuation element and the detent component is assured. For instance, an arrangement in which the detent element is located between the pivot joint and the contact position with the actuation element can be considered. However, positioning the pivot joint between the detent element and the actuation element is also possible.

BRIEF DESCRIPTION OF THE DRAWINGS

The invention will be better understood and further objects and advantages thereof will become more apparent from the ensuing detailed description of preferred embodiments taken in conjunction with the drawings, in which:

FIG. 1 is a section through an electric handheld power tool in an embodiment of the invention, of a ring-angle sander, in the region of the tool over which a guard hood fits that is retained on a tightening neck of the power tool;

FIG. 2 shows the tightening neck and guard hood in a section perpendicular to the axis of the tool;

FIG. 3 shows the securing device of the guard hood according to the invention, by way of which the guard hood is secured to the tightening neck, with a tightening ring, a screw tightening the tightening ring, and a detent component that is to be adjusted by the screw into a detent position;

FIG. 4a shows a further securing device, in which the detent component has a modified embodiment;

FIG. 4b shows a spring element which exerts force on the detent component of FIG. 4a;

FIG. 5 shows a further securing device in an alternative embodiment;

FIG. 6 shows a bearing flange with a tightening neck, in which a bearing for the tool is received, and a circumferential groove, with a set of teeth with which the detent component is to be put into the detent position, is made in the outer jacket face of the tightening neck; and

FIG. 7, similarly to FIG. 6, shows a bearing flange, but with a separate, axially offset embodiment of the circumferential groove and of a set of teeth extending over the circumference.

DESCRIPTION OF THE PREFERRED EMBODIMENTS

In the drawings, identical components are identified by the same reference numerals.

The handheld power tool 1 shown in FIG. 1 is embodied as a right-angle or cutting sander, which in a tightening neck 2 has a bearing 3 for rotationally supported reception of a drive spindle 4 that is the carrier of a tool 5 embodied as a sanding wheel or cutting wheel. The tool 5 is partly surrounded by a guard hood 6, which has an integrally formed-on cylindrical collar 7 that is slipped onto the outside of the tightening neck 2. The collar 7 is firmly clamped to the tightening neck 2 via a tightening ring 8 of a securing device; an additional detent component for securing in the circumferential direction and/or the axial direction is provided, and the detent component 9 protrudes through a recess in the collar 7 and into a toothlike indentation 10 that is made in the jacket face of the tightening neck 2.

As can be seen from FIG. 2, the tightening ring 8, in a manner known per se, on its face ends has end portions 8a, 8b bent radially upward, in each of which a recess is made through which a screw 11 is passed that forms an actuation element. The screw is secured to the tightening ring via a nut, so that when the screw 11 is turned, the tightening ring 8 is tightened and presses against the tightening neck 2 with increasing, radially acting tightening force.

The free face end 12 of the screw 11 is in contact with a portion of the detent component 9 that is to be put into a detent position by the tightening neck 2. As can be seen from FIG. 2 in conjunction with FIG. 3, the detent component 9 is embodied as a lever, and a detent element 13 is embodied in one piece with the detent component 9 and, compared to the approximately circumferentially extending base body of the detent component 9, extends radially inward in the direction of the outer jacket face of the tightening neck 2. A recess 14 is made in the tightening ring 8 and the detent element 13 protrudes through this recess.

The base body of the detent component 9 is supported rotatably or pivotably via a pivot joint 15 on the side facing away from the screws 11 and at the same time is retained on the tightening ring 8. The pivot joint 15 is located on the outside of the tightening ring 8 and is connected to the tightening ring 8. A spring element can additionally be provided, which exerts force on the detent component 9 into the nondetent position, in which position the detent element 13 of the detent component 9 is at least partially raised out of the recess 14. The pivot joint 15 enables the detent component 9 to execute a rotary motion about an axis that is parallel to the axis of rotation of the tool.

On the side toward the actuation element, the base body of the detent component 9 has a contact portion 9a, which is bent in hooklike fashion and is contact with the fee face end 12 of the actuation element that is embodied as a screw 11. The hooklike contact portion 9a is embodied such that as the screw 11 is screwed increasingly in, the base body of the detent component 9 and thus the detent element 13 as well are adjusted into the detent position by way of the contact between the free face end 12 and the portion 9a. The detent position is shown in bow FIG. 2 and FIG. 3. If a spring element is provided that exerts force on the detent component 9 into the nondetent position, then a leg spring that is placed around the pivot joint 15 can for instance be employed.

In the exemplary embodiment of FIGS. 2 and 3, the pivot joint 15 is located on the side facing away from the screw 11. The detent element 13 on the detent component 9 is located between the pivot joint 15 and the contact point between the free face end 12 of the screw 11 and the hooklike contact portion 9a of the detent component 9.

Instead of a separately embodied spring element it is also possible to make the detent component 9 from a resilient material, such as spring steel, and to prestress it such that the detent component 9 in the mounted position is adjusted by its own tension into the nondetent position. This has the advantage that a spring element embodied as a separate component can be dispensed with.

The detent component 9 has an end stop 23, which originating at the pivot joint 15 is disposed on the side of the pivot joint remote from the actuation element embodied as a screw 11. The end stop 23 has the function of limiting the upward pivoting motion of the detent component 9 about the axis of rotation of the pivot joint 15. To that end, the end stop 23, preferably embodied in one piece with the detent component, protrudes at an angle from the outside of the tightening ring 8, and the angle with the outside of the tightening ring 8 defines the maximum upward pivoting angle of the detent component 9. In the maximally upward-pivoted position, the end stop 23 rests on the outside of the tightening ring 8.

In the exemplary embodiment of FIG. 4a, the detent component 9 is shown in an alternative embodiment. The pivot joint 15 of the detent component 9 is located between the detent element 13 and the contact point on the free face end 12 of the actuation element. The base body of the detent component 9 is constructed in angular form, and the free face end, facing away from the pivot joint 15, simultaneously forms the detent element 13, which is passed through the recess 14 in the tightening ring 8. Near the angular region in the base body, the free face end 12 of the screw 11 is in contact with the detent component 9.

In FIG. 4b, a spring element 16 embodied as a leg spring is shown in detail; it can be placed around the pivot joint 15 of FIG. 4a and in the mounted position it exerts force on the detent component 9 into the nondetent position.

In FIG. 5, a further exemplary embodiment is shown, in which it is fundamentally possible to dispense with a separate spring element that urges the detent component 9 into the nondetent position. The adjustment of the detent component 9 both from the nondetent position into the detent position and in the opposite direction, that is, from the detent position into the nondetent position, is effected via the adjusting motion of the actuation element embodied as a screw 11. For that purpose, the screw 11 is connected in the region of its face end to the base body of the detent component 9 via a slaving element 17. On the side opposite the slaving element 17, there is a spring element 18, which is embodied as a compression spring and presses the detent component 9 axially against the slaving element 17. It is thus assured first that upon a screwing-in motion of the actuation element 11, the detent component 9 is adjusted into the detent position, and second that with the aid of the spring element 18 and of the axial displacement motion of the detent component 9 on the actuation element, play and flexibility in the components can be compensated for. The detent element 13, which in the detent position is in engagement with the set of teeth on the jacket face of the tightening neck, is as in the preceding exemplary embodiment embodied in one piece with the base body of the detent component 9.

The axial displacement capability of the detent component 9 along the axis of the screw 11 offers the farther advantage that upon a relative rotation of the tightening ring 8 clockwise in terms of FIG. 5, self-locking occurs, and hence the form lock between the detent component and the set of teeth on the tightening neck increases. In the opposite direction, conversely, the detent component can execute a relative motion because of the free travel on the actuation element, and as a result a limited play is achieved.

In FIG. 6, a bearing flange 19 is shown, including a base plate 20 and the tightening neck 2 embodied in one piece with the base plate, the bearing 3 for the drive spindle 4 being received in this tightening neck. A set of teeth 21 is made in the outer jacket face of the tightening neck 2 and comprises a plurality of axially extending toothlike indentations, distributed over the circumference, which are associated with the detent element of the detent component; in the detent position, the detent element protrudes into a respective toothlike indentation. As a result, a form lock in both the circumferential direction and the axial direction is attained.

The toothlike indentations each extend axially from a circumferential groove 22 that extends over the entire circumference of the tightening neck 2. The detent element of the detent component can be displaced along the circumferential groove 22. However, optionally, a component embodied separately from the detent element, such as a pin or the like, protrudes into the circumferential groove and thereby secures both the tightening ring and the guard hood in the axial direction on the tightening neck.

In the exemplary embodiment of FIG. 7, which also shows a bearing flange 19 with a base plate 20 and a tightening neck 2, the set of teeth 21 is embodied separately from the circumferential groove 22. The set of teeth 21 is located adjacent to the top side of the base plate 20; conversely, the circumferential groove 22 is located adjacent the face end of the tightening neck 2. In this embodiment, it is absolutely necessary that a component embodied separately from the detent component protrude into the circumferential groove 22, this component for instance being a pin or the like.

The foregoing relates to preferred exemplary embodiments of the invention, it being understood that other variants and embodiments thereof are possible within the spirit and scope of the invention, the latter being defined by the appended claims.

Claims

1. A power tool, in particular a handheld power tool, such as a ring-angle sander, comprising:

a guard hood, to be fixed to a tightening neck via a securing part;

a detent component that is lockable in a detent position against the tightening neck; and

a actuation element which is common for the securing part and the detent component, by way of which the securing pan and the detent component are adjustable relative to the tightening neck.

2. The power tool as defined by claim 1,

wherein the tightening neck of the power tool has a set of teeth, extending in a circumferential direction, which is engaged by a detent element of the detent component in the detent position.

3. The power tool as defined by claim 1, wherein a circumferential groove is provided on the tightening neck.

4. The power tool as defined by claim 2, wherein a circumferential groove is provided on the tightening neck.

5. The power tool as defined by claim 3, wherein toothlike, axially extending indentations are made in a jacket face of the tightening neck, beginning at the circumferential groove on the tightening neck.

6. The power tool as defined by claim 4, wherein toothlike, axially extending indentations are made in a jacket face of the tightening neck, beginning at the circumferential groove on the tightening neck.

7. A guard hood for a power tool, in particular for a handheld power tool, such as a ring-angle sander as defined by claim 1, the guard hood is securable on the tightening neck of the power tool via the securing device, which tightening neck has both the securing part, to be adjusted via the actuation element, and the detent component, which is adjustable into the detent position and a nondetent position relative to the tightening neck,

wherein the actuation element acts upon both the securing part and the detent component, and with the fastening of the securing part via the actuation element, the detent component is to be put simultaneously into the detent position.

8. The guard hood as defined by claim 7, wherein the securing part of the securing device is a tightening ring, which is to be tightened via the actuation element.

9. The guard hood as defined by claim 7, wherein the detent component is retained on the securing part.

10. The guard hood as defined by claim 7, wherein the detent component is supported in articulated fashion and is pivotable between the detent position and the nondetent position.

11. The guard hood as defined by claim 10, wherein the actuation element acts upon the detent component with spacing from a pivot joint axis thereof.

12. The guard hood as defined by claim 10, wherein the pivot joint axis of the detent component is located between a detent element of the detent component which acts upon the securing part and a contact point for the actuation element.

13. The guard hood as defined by claim 10, wherein the detent element acting upon the securing part is located between a contact point for the actuation element and the pivot joint axis of the detent component.

14. The guard hood as defined by claim 7, wherein the detent component is disposed on an outside of the securing part, and that in the detent position, the detent element of the detent component protrudes through the securing part.

15. The guard hood as defined by claim 7, wherein the actuation element is retained translationally adjustably on the securing part and in particular is embodied as a screw.

16. The guard hood as defined by claim 7, wherein the detent component is subjected to force into the nondetent position via a spring element.

17. The guard hood as defined by claim 16, wherein the spring element is embodied in one piece with the detent component.

18. The guard hood as defined by claim 7, wherein the actuation element rests loosely on the detent component.

19. The guard hood as defined by claim 7, wherein the actuation element is connected to the detent component, in particular via a slaving element.

20. The guard hood as defined by claim 7, wherein the detent component, in the detent position, effects a form lock in the circumferential direction.