WO2024149530A1 - Percussion mechanism for a hammer drill or chisel hammer - Google Patents

Abstract

The invention relates to a percussion mechanism (1) for a hammer drill or chisel hammer, comprising a tubular tool receiving area (4) for a tool (6), said tool receiving area being received in a guide housing (2) and having a proximal end which is provided with a percussion ram (8) arranged coaxially rearward. An assembly consisting of an idle-impact and a rebound-impact damping element (24, 26) is positioned between the tool receiving area (4) and the guide housing (2), said assembly interacting with the tool receiving area (4) in order to provide an idle-impact and rebound-impact damping function, wherein the tool receiving area (4) is supported relative to the guide housing (2) via at least two plain bearings (28, 34) which are provided on axial outer faces of the assembly consisting of the idle-impact and rebound-impact damping element (24, 26). In order to radially damp the tool receiving area (4), elastic material (32, 36) is arranged between the plain bearings (28, 34) and the guide housing (2) in the region of at least one plain bearing (28, 34).

Description

IMPACT MECHANISM FOR A DRILL OR CHISEL HAMMER

DESCRIPTION

The present invention relates to a percussion mechanism for a drill or chisel hammer, comprising a tubular tool holder for a tool, which is accommodated in a guide housing and at the proximal end of which a coaxially arranged impact ram is provided. Between the tool holder and the guide housing there is positioned an arrangement of an idle impact damping element and a rebound impact damping element, which interact with the tool holder to achieve idle impact and rebound impact damping. The tool holder is mounted to the guide housing via at least two plain bearings, which are provided on the axial outer sides of the arrangement of idle impact damping element and rebound impact damping element. The invention also relates to a drill or chisel hammer for processing a mineral material, in particular concrete or stone, with such a percussion mechanism.

The field of application of the invention extends primarily to hand-held drilling or chisel hammers which are equipped with an electric motor drive. Such electric hand-held power tools generate a linear alternating working movement via a mechanical impact mechanism, i.e. a back and forth movement to act on the tool, which in the case of a chisel hammer is designed as a chisel and in the case of a hammer drill as an impact drill for machining preferably mineral materials - such as stone, concrete and the like. An electric hand-held power tool which can be driven by impact usually has a complex vibration behavior as a result of an interaction with the workpiece and the hand-arm system of the operator as well as the internal mass and stiffness distribution, which must be suppressed as far as possible. In the context of the electric hand-held machine tools of interest here, tool holders are primarily used to fix and guide the drilling or chiseling tools in these machines. In the case of hammer drills, the tool holder transfers torque to the tool, ensures that impact pulses are transmitted from the impact mechanism to the workpiece by allowing limited axial movements, and prevents the tool from accidentally falling out of the machine. The tool holder device according to the invention is particularly exposed to so-called idle blows and bounce blows in the context of the impact mechanism pulses. Idle blows occur when tools are accelerated by impact pulses from the impact mechanism, but this impact energy cannot be transmitted to the workpiece because the tool is not in contact with the workpiece. Bounce blows occur when the tool is in contact with too much force and/or a workpiece that is too hard, so that the impact pulses from the impact mechanism essentially have a feedback effect on the machine.

State of the art

WO 2021/094214 A1 discloses a percussion mechanism with a tool holder for holding a tool. The percussion mechanism has an anvil that can be moved in the axial direction and acts on the tool. The anvil is mounted to the tool holder via two bearings. The percussion mechanism also has an idle impact damper element, which is arranged between the anvil and the tool holder to dampen idle impacts of the anvil. In addition, an additional idle impact damping element is arranged between the tool holder and a guide housing to achieve further damping. In the same way, the percussion mechanism has both a rebound impact damper element, which is arranged between the anvil and the tool holder, and an additional rebound impact damping element, which is provided between the guide housing and the tool holder. Both damping elements serve to dampen a rebound impact. The tool holder is mounted opposite the guide housing via a guide bearing. I

The object underlying the invention is to provide an impact mechanism for a drilling or chisel hammer with which mechanical loads and vibrations on the housing can be effectively reduced using simple technical means.

Disclosure of the invention

The object is achieved on the basis of a percussion mechanism for a drilling or chisel hammer according to the preamble of claim 1 in conjunction with its characterizing features. The following dependent claims reflect advantageous developments of the invention. With regard to a drilling or chisel hammer having a percussion mechanism according to the invention, reference is made to claim 10.

The invention includes the technical teaching that an elastic material is arranged between the plain bearing and the guide housing in an area of at least one plain bearing for radial damping of the tool holder. The plain bearings are therefore not directly in contact with the guide housing. The tool holder is thus dampened in the radial direction to the guide housing via the elastic material. Since radial bending vibrations or bending shocks also act on the guide housing during operation of the drilling or chisel hammer, these can be effectively reduced by simple technical means. The mechanical load on the structure due to shock-like bending and transverse force can thus be significantly reduced, so that the service life of the structure is improved.

According to a preferred embodiment, the elastic material is applied to the guide housing. The elastic material is thus firmly connected to the guide housing. This avoids the need to introduce the elastic material separately. A firm connection between the guide housing and the elastic material also prevents the elastic material from slipping between the plain bearing and the guide housing during operation of the device. This ensures that permanent vibration damping is possible between the guide housing and the plain bearing. According to a further preferred embodiment, the elastic material is applied to the plain bearing. The plain bearing is coated with the elastic material. The elastic material can thus be applied in a simple manner before the plain bearing is inserted into the guide housing. The assembly of such a plain bearing coated with elastic material is therefore easier than if both components were assembled separately. Accordingly, bending stress on the guide housing can be reduced in an economical manner.

The elastic material is advantageously formed by means of a vulcanization step. The vulcanization step makes the elastic material more resistant to external influences. The elastic material is also more resistant to aging after a vulcanization step. The service life of such an elastic material can thus be increased.

The plain bearing is preferably formed as an L-shaped component, which forms a radial region against which the elastic material rests. The radial region is a part of the plain bearing which extends in the radial direction, in contrast to the remaining axially extending part. The elastic material can be held in the axial direction by the radial part so that it does not slip. The radial region is advantageously arranged on one side of the rebound impact damping element or idle impact damping element. This creates a larger support surface for the corresponding damping element. This prevents the damping element from being damaged by the plain bearing in the event of a corresponding rebound impact or idle impact.

Preferably, the elastic material is additionally sealingly applied to the tool holder at least on one axial outer side, between the plain bearing and the arrangement of the idle impact damping and rebound impact damping elements. The elastic material thus seals the plain bearing to the arrangement of the idle impact damping and rebound impact damping elements. This prevents lubricant from the plain bearing from penetrating into the arrangement of the idle impact damping and rebound impact damping elements. I

This eliminates the need for a separate seal between the plain bearing and the arrangement of the idle impact damping and the rebound impact damping element, so that several functions can be integrated into the elastic material in a single component.

In an advantageous embodiment, the elastic material is additionally in contact with the tool holder on at least one axial outer side, on a side of the plain bearing that is axially opposite to the arrangement of the idle impact damping and rebound impact damping elements. The plain bearing is thus sealed to the outside by the elastic material. This prevents dust and dirt from reaching the plain bearing. Dirt usually leads to greater wear on the plain bearing and therefore to a shorter service life. The service life of the plain bearing can therefore be increased in a simple manner using such a seal. A suitably designed elastic material means that a separate seal in front of the plain bearing is not necessary.

The elastic material is preferably an elastomer. By using elastomers as a damping material, peak loads that occur during operation due to impacts can be reduced in such a way that loads passed on to downstream components are reduced. Elastomers are also available in different versions with different properties, so that a suitable elastomer material can be selected that optimally meets the requirements. In addition, such elastomers are inexpensive and easy to process, or can be easily incorporated into an automated manufacturing process.

The elastomer is particularly preferably made from a hydrogenated acrylonitrile butadiene rubber material. An elastomer made from a hydrogenated acrylonitrile butadiene rubber material (HNBR) has a higher resistance to mineral oils than other elastomers. This makes it particularly suitable for use directly on the plain bearing. The abrasion resistance and mechanical properties of such an elastomer are also improved. In particular, with the high mechanical loads in such an impact mechanism, such an elastomer can Material ensures high damping of bending vibrations over a longer service life.

The plain bearing is advantageously made of steel and/or bronze. Using a steel material or steel alloy material ensures that the plain bearings can withstand high mechanical loads. Using bronze enables favorable friction values to be achieved.

Detailed description based on drawing

Further measures improving the invention are described in more detail below together with the description of a preferred embodiment. It shows:

Fig. 1 is a partial longitudinal section of a percussion mechanism for a drilling or chisel hammer according to a first embodiment of the invention, and

Fig. 2 is a schematic representation of a partial longitudinal section of a percussion mechanism for a drill or chisel hammer according to a second embodiment of the invention.

Figure 1 shows a partial longitudinal section of an impact mechanism 1 for a drilling or chisel hammer according to a first embodiment of the invention. The impact mechanism 1 comprises a guide housing 2, which can be arranged in a housing of a drilling or chisel hammer (not shown here). A tubular tool holder 4 is arranged in the guide housing 2, in the distal end of which a tool 6 is accommodated, which is held axially displaceably in the tool holder 4. At a proximal end, an impact ram 8, also called a striker, is arranged in the tool holder 4. The impact ram 8 is arranged axially displaceably in order to transfer an impact pulse introduced onto the impact ram 8 to the tool 6. The impact ram 8 is guided via a distal and a proximal impact ram bearing 10, 12. In a central area, the impact ram 8 has a radial extension 14, which interacts with an impact ram idle impact damping element 16 on the distal impact ram bearing 10 side during an idle impact, so that the impact energy of the impact ram 8 is dampened. An impact ram rebound impact damping element 18 is arranged on the proximal impact ram bearing 12 side, with which the impact energy of the impact ram 8 is absorbed during a rebound impact. This prevents the impact energy from being passed on to the structure without being dampened.

The tool holder 4 forms a radial extension 20, on which stop elements 22 are arranged in the embodiment shown. On a distal side to the radial extension 22, an idle impact damping element 24 is arranged between the guide housing 2 and the tool holder 4. In the case of an idle impact, in which the tool holder 4 is displaced in the direction of the idle impact damping element 24, the radial extension 20 interacts with the idle impact damping element 24 so that an idle impact is dampened. A rebound impact damping element 26 is arranged on a proximal side of the radial extension 20. In the case of a rebound impact, the radial extension 20 is displaced in the direction of the rebound impact damping element 26 so that the rebound impact is dampened.

On a side of the idle impact damping element 24 facing away from the radial extension 20, a first plain bearing 28 is arranged, via which the tool holder 4 is mounted in the guide housing 2 in an axially movable manner. The first plain bearing 28 is designed as an L-shaped component in the embodiment shown. A radial region 28a of the plain bearing 28 is arranged on the side of the idle impact damping element 24. As a result, the idle impact damping element 24 is better supported by the plain bearing 28. A first elastic material 32 is arranged between the plain bearing 28 and the guide housing 2, via which the plain bearing 28 is supported on the guide housing 2. This The first elastic material 32 dampens bending shocks and vibrations to the guide housing 2.

A second plain bearing 34 is arranged on a side of the impact damping element 26 facing away from the radial extension 20, which also supports an axial movement of the tool holder 4 to the guide housing 2. The second plain bearing 34 is also L-shaped. A radial region 34a of the second plain bearing 34 is arranged on the side of the impact damping element 26. A second elastic material 36 is also arranged between the second plain bearing 34 and the guide housing 2, via which the second plain bearing 34 is supported on the guide housing. This second elastic material 36 dampens bending impacts and vibrations to the guide housing 2.

Figure 2 shows a schematic representation of a partial longitudinal section of a percussion mechanism 1 for a drilling or chisel hammer according to a second embodiment of the invention. In the figure shown, the impact ram 8, the tool 6, the bearings 10, 12 of the impact ram 8 and the impact ram idle impact damping element 16 as well as the impact ram rebound impact damping element 18 have been omitted for the sake of clarity. In comparison to the first embodiment, the first elastic material 32 of the first plain bearing 28 is also arranged axially between the plain bearing 28 and the idle impact damping element 24. In this area, the first elastic material 32 bridges a gap 38 between the guide housing 2 and the tool holder 4, so that this is sealed to the first plain bearing 28. The first elastic material 32 also projects beyond the first plain bearing 28 in the distal direction on a side of the first plain bearing 28 facing away from the idle impact damping element 24. On this side too, the first elastic material 32 lies sealingly against the guide housing 2 and the tool holder 4, so that the first plain bearing 28 is protected against external environmental influences, such as dirt.

In the embodiment shown, the second elastic material 36 of the second sliding bearing 34 is designed to be equivalent to the first elastic material 32 of the first sliding bearing 28. Accordingly, the second elastic material 36 is located between the second plain bearing 34 and the impact damping element 26 form a seal both on the guide housing 2 and on the tool holder 4. This also prevents lubricants from the second plain bearing 34 from reaching the impact damping element 26. On a side of the second plain bearing 34 facing away from the impact damping element 26, the second elastic material 36 projects beyond the second plain bearing 34 in the proximal direction. On this side too, the elastic material forms a seal on the guide housing 2 and on the tool holder 4.

List of reference symbols

1 percussion

2 guide housing

4 Tool holder

6 Tools

8 impact rams

10 distal impact ram bearing

12 proximal impact ram bearing

14 radial expansion

16 Impact ram idle impact damping element

18 Impact ram impact damping element

20 radial process

22 stop elements

24 Idle stroke damping element

26 Impact damping element

28 first plain bearing

28a radial area

32 first elastic material

34 second plain bearing

34a radial area

36 second elastic material

38 gap

Claims

EXPECTATIONS

1. Impact mechanism (1) for a drilling or chisel hammer, comprising a tubular tool holder (4) for a tool (6), which is accommodated in a guide housing (2) and at the proximal end of which a coaxially rearwardly arranged impact ram (8) is provided, wherein an arrangement of an idle impact damping element and a rebound impact damping element (24, 26) is positioned between the tool holder (4) and the guide housing (2), which interact with the tool holder (4) in order to realize idle impact and rebound impact damping, wherein the tool holder (4) is mounted to the guide housing (2) via at least two sliding bearings (28, 34), which are provided on axial outer sides of the arrangement of idle impact damping element and rebound impact damping element (24, 26), characterized in that for radially damping the tool holder (4), in an area of at least one sliding bearing (28, 34), an elastic material (32, 36) is arranged between the plain bearing (28, 34) and the guide housing (2).

2. Impact mechanism (1) according to claim 1, characterized in that the elastic material (32, 36) is applied to the guide housing (2).

3. Impact mechanism (1) according to claim 1, characterized in that the elastic material (32, 36) is applied to the sliding bearing (28, 34).

4. Percussion mechanism (1) according to one of the preceding claims, characterized in that the elastic material (32, 36) is formed by means of a vulcanization step.

5. Impact mechanism (1) according to one of the preceding claims, characterized in that the sliding bearing (28, 34) is formed as an L-shaped component which forms a radial region (28a, 34a) against which the elastic material (32, 36) rests.

6. Impact mechanism (1) according to one of the preceding claims, characterized in that the elastic material (32, 36) additionally rests sealingly on the tool holder (4) at least on one axial outer side, between the sliding bearing (28, 34) and the arrangement of the idle impact damping and rebound impact damping element (24, 26).

7. Impact mechanism (1) according to one of the preceding claims, characterized in that the elastic material (32, 36) additionally rests sealingly on the tool holder (4) at least on one axial outer side, on a side of the sliding bearing (28, 34) axially remote from the arrangement of the idle impact damping and rebound impact damping element (24, 26).

8. Percussion mechanism (1) according to one of the preceding claims, characterized in that the elastic material (32, 36) is an elastomer.

9. Impact mechanism (1) according to claim 8, characterized in that the elastomer is made of a hydrogenated acrylonitrile butadiene rubber material.

10. Drill or chisel hammer for processing a mineral material, in particular concrete or stone, with a striking mechanism (1) according to one of the preceding claims.