EP2069109A1

EP2069109A1 - Electric machine tool with vibration-decoupled gripping element

Info

Publication number: EP2069109A1
Application number: EP07788117A
Authority: EP
Inventors: Holger Frank
Original assignee: Robert Bosch GmbH
Current assignee: Robert Bosch GmbH
Priority date: 2006-09-21
Filing date: 2007-08-01
Publication date: 2009-06-17
Also published as: WO2008034668A1; DE102006044433A1; RU2466855C2; CN101516578A; RU2009114755A

Abstract

The invention relates to an electric machine tool (1), in particular a hand-operated hammer drill, comprising a basic body (2) and a gripping element (3), wherein the basic body (2) and the gripping element (3) are connected to each other by means of a pivot mounting (4) and at least one decoupling unit (7), which lies at a distance from a pivot axis (8) of the pivot mounting (4) and acts with a vibration-decoupling effect, and at least one linear guide (10) is assigned to the decoupling unit (7). It is provided that the linear guide (10) has at least one linear guiding element (18) displaceably guided in a flexible vibration decoupling element (25).

Description

description

Title Electric machine tool with vibration-decoupled handle element

State of the art

The invention relates to a power tool, in particular a hand-held rotary hammer, with a base body and a handle element, wherein the base body and the handle member via a pivot bearing and at least one, spaced from a pivot axis of the pivot bearing, vibration decoupling acting decoupling unit are interconnected and the decoupling at least one Linear guide is assigned.

In a known power tool of the type mentioned, which is designed as a hammer drill, a handle member is pivotally mounted on the main body of the hammer drill. The required for this

Swivel bearing is located at one end of the approximately U-shaped grip element. At the other end of the handle member is a decoupling unit for reducing vibrations that occur during operation of the hammer drill arranged. The decoupling unit has a helical compression spring, which at one end on the base body and with the other end on

Gripping element supported. The bias caused by the helical compression spring is intercepted by means of a linear guide, on the one hand firmly engages the handle member and slidably on the body, wherein at rest, so if a user of the hammer transfers no manual forces on the handle body, the linear guide in a guide direction rigidly on Body abuts. This embodiment has basically proven in practice, but should be further improved in terms of a reduction or isolation of vibrations.

Disclosure of the invention The electric machine tool according to the invention is characterized in that the linear guide has at least one linear guide element displaceably guided in an elastic vibration decoupling element. As a result, the linear guide no longer forms a relatively rigid bridge between the base body and the grip element, since a vibration-related decoupling is provided due to the elastic vibration decoupling element. As a result of the design according to the invention, the user can precisely transfer executive forces to the power tool, at the same time reducing unwanted vibrations to a very considerable extent.

According to a development of the invention can be provided that the linear guide element is fixed to the handle element or the base body. As a result, the elastic decoupling element is located on the base body or on the grip element.

According to a development of the invention, it is provided that the linear guide element engages displaceably in a receptacle of the vibration decoupling element. This receptacle is preferably formed as a passageway. Accordingly, the linear guide element passes through the passage, wherein it is preferably provided that it has a head which can be supported on the vibration decoupling / support. If the electric machine tool is pressed in the direction of a processing point, the head of the linear guide element lifts off from the vibration decoupling element; laterally, however, the linear guide element is guided in the passage of the elastic vibration decoupling element.

The linear guide element is preferably designed as a screw whose screw head forms the aforementioned head.

It is advantageous if the base body and grip element are acted upon in the region of the decoupling unit by at least one spring element. The spring element acts in such a way that the grip element has the tendency to move around the Swivel pivot axis of the pivot bearing away from the body. In this case, however, the head of the linear guide element is supported on the vibration decoupling element, so that the pivoting movement is limited. During operation of the electric machine tool, when this is detected on the grip element and pressed in the direction of a processing point, the grip element pivots while compressing the spring element a little way in the direction of the base body, wherein the head of the linear guide element can lift or lift off the base body. Laterally, however, the linear guide element is guided vibration damping in the passage of the vibration decoupling element.

The spring element is formed here by way of example as a helical compression spring.

Preferably, two linear guide elements may be provided between which the spring element is located.

It is advantageous if the pivot bearing is designed to decouple oscillation, so that no excessive vibrations are transmitted via the connection of the grip element to the base body performing pivot bearing.

It is preferably provided that the pivot bearing has a first bearing part with a bearing channel in which a holding part is mounted with the interposition of at least one elastic vibration decoupling component. The storage channel preferably belongs to the main body. The

Vibration decoupling component is in particular designed as a decoupling ring, which is located in the bearing channel and supports the holding part vibration-damped.

At least one end of the holding part, a fastening means is preferably releasably attached in particular, which passes through a bearing opening of a second bearing part of the pivot bearing. The second bearing part preferably belongs to the grip element, while the first bearing part preferably belongs to the base body. The vibration-decoupled held in the bearing channel holding part is therefore used to hold a fastener on which the second bearing part, in particular, therefore, the Ghffelement is attached. As a result, the grip element is decoupled with respect to the vibration of the main body in the region of the pivot bearing.

Finally, it is advantageous if a portion of the vibration decoupling element lies between the first and the second bearing part. This has the consequence that even under harsh operating conditions is prevented that vibrations of the body thereby reach the handle member that the body strikes the handle member. This striking is prevented due to the interposition of the portion of the vibration decoupling element.

Brief description of the drawings

The drawings illustrate the invention with reference to an embodiment, in which:

1 shows a side view in section through a power tool, which is designed as a hammer drill,

Figure 2 shows a longitudinal section through a decoupling unit, with a handle element of the hammer drill is held on a base body of the hammer drill and

Figure 3 decoupled pivot bearing, here by way of example at the lower end of the handle, with the handle member is also held on the main body of the hammer drill.

Embodiment (s) of the invention

1 shows a power tool 1, which has a base 2, to which a handle element 3 is attached. The attachment takes place via a pivot bearing 4, which is located in an end region 5, preferably the U-shaped grip element 3. In the other end region 6 of the gripping element 3, the latter is via a decoupling unit 7 that decouples vibration connected to the main body 2. The pivot bearing 4 is also designed vibration damping, so that vibrations that occur when working with the power tool designed as a hammer drill on the base body 2 are only slightly or even no longer feel on the handle element 3. The pivot bearing 4 has a pivot axis 8 which extends at right angles to the machining direction of the power tool 1 marked 9. The decoupling unit 7 is associated with a linear guide 10 (Figure 2), which allows a movement of the end portion 6 of the handle member 3 about the pivot axis 8 in the direction of the resulting from the figure 1 double arrow 11.

FIG. 2 illustrates the embodiment of the decoupling unit 7 and the linear guide 10, wherein two linear guides 10 are provided, which have the decoupling unit 7 between them. Hereinafter, only one of the linear guides 10 will be described, because the other is formed accordingly.

The decoupling unit 7 has two mutually concentric spring elements 12, which are each formed as a helical compression spring 13 with different large diameter, both helical compression springs 13 concentric umwendein each other and supported with their one end portions 14 on the handle member 3 and with its other end portions 15 on the base body 2 and consequently act on the handle element 3 in the direction of the arrow 16, so that it is pushed away from the base body 2. If a workpiece machining takes place with the power tool 1, then the user touches the grip element 3 and thereby guides the power tool, wherein he will exert pressure forces against the direction of the arrow 3 in the case of a hammer drill. As a result, the helical compression springs 13 are more strongly biased, since the grip element 3 continues to approach the base body 2. Bridging joints between the base body 2 and handle element 3 are bridged by means of elastic bellows 17. To the

Restricting movement possibility for an exact guidance of the power tool 1, the linear guide 10 is provided which allows movement in the direction of the double arrow 11 (Figure 1) within certain limits. For this purpose, the linear guide 10 has a linear guide element 18 which is fixed rigidly on the grip element 3. The linear guide element 18 is as Screw 19 is formed, which is screwed with its thread 20 in a blind bore 21 of the handle member 3. The shank 22 of the screw 19 extends in the direction of the main body 2 and thereby engages through a passage 23 forming a passage 24 of an elastic vibration decoupling element 25 which is fixed in a receiving channel 26 of the base body 1. The vibration decoupling element 25 is formed in particular bush-shaped. The screw 19 has a screw head 27 which forms a head 28 of the linear guide element 18 and rests with its inner side 29 on a wall 45 of the base body 2 (housing) in front of the vibration decoupling element 25 in the position resulting from FIG. The shaft 22 is guided longitudinally displaceable in the passageway 24.

If, during use of the electric machine tool 1, the grip element 3 is acted upon counter to the direction of the arrow 16 in FIG. 2, this takes place against the forces of the helical compression springs 13, wherein the screw head 27 protrudes from the wall 45 of the base body 2 in front of

Vibration decoupling element 25 can lift slightly. Laterally, ie transversely to the direction of the arrow 16, there is a guide of the linear guide element 18 within the through-channel 24, so that lateral stabilization is present.

The vibration decoupling in the fulcrum of the handle, the pivot bearing 4 will be explained in more detail with reference to FIG 3. It has a first bearing part 30 with a bearing channel 31, wherein the first bearing part is connected to the base body 2 or formed thereon. A vibration decoupling component 32 in the form of a decoupling ring 33 is arranged in the bearing channel 31. According to FIG. 3, two vibration decoupling components 32 are provided at the end regions of the first bearing part 30. However, the following is only on the formation of a page, ie in the field of

Decoupling ring 33 received, since the other side is formed accordingly. A holding part 34, which forms a bearing axis, passes through the interior of the decoupling ring 33 and is therefore kept vibration-decoupled. About a bearing body 37 by means of a screw 38, the handle member 3 (handle) attached to the holding part 34 so that through the Decoupling element 33, a decoupling gap a between the first bearing part 30, which belongs to the base body 2, and a second bearing part 40 results, wherein the second bearing part 40 belongs to the grip element 3.

Overall, it is clear that in vibration, small

Pivoting movements of the grip element 3 about the pivot axis 8 due to the elastic vibration decoupling component 32 grip element 3 and body 2 are vibration-damping decoupled from each other.

From the above, it becomes clear that through the

Vibration decoupling element 25 and the vibration decoupling member 32 takes place a vibration decoupling. Both components may for example consist of rubber or of a foam material (for example PUR = polyurethane). By the end stop (screw head 27) and the wall 45 in front of the vibration decoupling component is that the handle, even at

Failure of the mentioned vibration decoupling components firmly on the device, so remains on the body. The power tool can be operated on with emergency with limited vibration decoupling. The above embodiments also show a simple structure and the ability to easily tune the vibration decoupling on the device, ie on the respective power tool. The relevant decoupling components can be easily manufactured, in particular as cylindrical bushings and exchanged for parts with different density and / or altered vibration properties. When using sprayable material for the vibration decoupling elements, it is possible to direct a sprayed on the grip element rubber over preferably cleverly arranged holes in the interior of the handle member and the elastic vibration decoupling guide elements, so the vibration decoupling element 25 and the vibration decoupling member 32, in the course of gumming with. Due to the bush-shaped vibration decoupling element 25, which is penetrated by the linear guide element 18, takes place after reaching a certain lateral deflection, a relatively hard side stop. Thus, with a good vibration isolation, the power tool can be very well captured and performed well while working. It is possible the Accommodate vibration isolation in a small space. They can even be incorporated in the contour of existing power tools, so that after retrofit solutions exist for a given space. Instead of or in addition to the handle element, which represents a main handle, additional handles of electric machine tools can be equipped accordingly with the vibration decoupling according to the invention.

Claims

claims

1. electric power tool, in particular hand-guided hammer drill, with a base body and a handle element, wherein the base body and the

Gripping element via a pivot bearing and at least one, spaced from a pivot axis of the pivot bearing, vibration decoupling acting decoupling unit are interconnected and the decoupling at least one linear guide is assigned, characterized in that the linear guide (10) at least one in an elastic vibration decoupling element (25) displaceable guided linear guide element (18).

2. Electric machine tool according to claim 1, characterized in that the linear guide element (18) on the handle element (3) or base body (2) is fixed.

3. Electric machine tool according to one of the preceding claims, characterized in that the linear guide element (18) engages displaceably in a receptacle (23) of the vibration decoupling element (25).

4. Electric machine tool according to one of the preceding claims, characterized in that the receptacle (23) as a passageway (24) is formed.

5. Electric machine tool according to one of the preceding claims, characterized in that the linear guide element (18) has a head (28) which is supported on the vibration decoupling element (25) / support.

6. Electric machine tool according to one of the preceding claims, characterized in that the linear guide element (18) is designed as a screw (19) whose screw head (27) forms the head (28).

7. Electric machine tool according to one of the preceding claims, characterized in that the base body (2) and handle element (3) in the region of the decoupling unit (7) of at least one spring element (12) are acted upon.

8. Electric machine tool according to one of the preceding claims, characterized in that the spring element (12) is a helical compression spring (13).

9. Electric machine tool according to one of the preceding claims, characterized in that two linear guide elements (18) are provided, between which the spring element (12) is arranged.

10. Electric machine tool according to one of the preceding claims, characterized in that the pivot bearing (4) is designed vibration decoupling.

11. Electric machine tool according to one of the preceding claims, characterized in that the pivot bearing (4) has a first bearing part (30) with a bearing channel (31) in which a holding part (34) with the interposition of at least one elastic vibration decoupling component (32) is mounted ,

12. Electric machine tool according to one of the preceding claims, characterized in that the vibration decoupling component (32) a

Decoupling ring (33) is.

13. Electric machine tool according to one of the preceding claims, characterized in that at least one end of the holding part (34) a fastening means (37) is in particular releasably secured, which passes through a bearing opening (41) of a second bearing part (40) of the pivot bearing (4) ,

14. Power tool according to one of the preceding claims, characterized in that between the first and the second bearing part (30,40) is a portion of the vibration decoupling member (32).

15. Power tool according to one of the preceding claims, characterized in that between the first bearing part 30 (bearing block) and the handle element 3 (handle) a decoupling gap (a) is formed, which is bridged by the decoupling element (32) in the axial direction.