EP3822036A1 - Impact device assembly - Google Patents

Abstract

Hammer drill and / or chisel hammer (100) with a drive motor (70), an impact mechanism (10) and a tool holder (50) for receiving a tool (110), the impact mechanism (10) axially ( AR) has displaceable anvil (30) acting on the tool (110), the hammer mechanism (10) having an idle impact absorber element (11) and a rebound impact absorber element (13), which are designed in one piece with one another and thus form a combination damper element (15) wherein the striker guide (20) is arranged outside, preferably exclusively outside of the combi-steamer element (15).

Description

The present invention relates to a hammer drill and / or chisel hammer with a drive motor, an impact mechanism and a tool holder for receiving a tool. The striking mechanism has a striker that is axially displaceable in a striker guide and that acts on the tool. The hammer mechanism is equipped with an idle shock absorber element and a rebound shock absorber element, which are designed in one piece with one another and form a combination damper element.

Rotary hammers of the type mentioned are basically known from the prior art and, for example, in US Pat EP 1 479 485 A1 described.

Idle shock absorber elements and rebound shock absorber elements, which are preferably designed as elastomer damping elements, are used to keep force peaks on downstream components and vibrations as low as possible. When the hammer mechanism is at the operating point, the striker hits a typically provided impact disc after each impact and is intercepted by the impact shock absorption element.

If the contact pressure is too low or if the concrete / stone to be processed breaks away, blank spaces can occur. This means that blows must be absorbed with full impact energy by the hammer and in particular the tool holder itself. A blank impact damping element is typically used to protect the downstream components from a peak force of the blank impact. for use. A blank impact damping of the idle impact absorber element influences the return speed of the anvil after a blank impact and thus also the shutdown behavior of the hammer.

It is the object of the present invention to provide a hammer drill and / or chisel hammer, the striking mechanism of which has a comparatively long service life and is easy to assemble.

The object is achieved in that the striker guide is arranged outside, preferably exclusively outside of the combi-steamer element. The invention includes the knowledge that a striker guide implemented within the combi-steamer element, in particular if the combi-steamer element itself forms part of this striker guide as in the known prior art, significantly reduces the service life of the Combi-steamer element and thus the entire striking mechanism favors. Because the striker guide is arranged according to the invention outside, preferably exclusively outside of the combi-steamer element, this disadvantage is avoided.

In a particularly preferred embodiment, the anvil is cylindrical. The otherwise preferably cylindrical striker can have a radial bead which is arranged to strike the idle impact damper element on the one hand and to strike the rebound shock absorber element on the other hand. The combi-steamer element can have a central recess which extends over the entire length of the combi-steamer element. The anvil is preferably received at least in sections within the central recess and / or passed through it.

It has been found to be advantageous if the combi-steamer element has a cylindrical inner surface which extends in the axial direction between a blank impact stop surface and a rebound impact stop surface. In a particularly preferred embodiment, a radial distance is provided between the cylindrical inner surface and the bead, preferably along the entire inner surface. The radial distance between the cylindrical inner surface and a thickest point of the bead, based on the radial direction, is preferably provided.

It has been found to be advantageous if the combi-steamer element has a planar end stop surface via which the combi-steamer element is supported on a shoulder of the tool holder. Preferably, the end stop surface is annular and / or the end stop surface runs perpendicular to the axial direction of the anvil.

In a particularly preferred embodiment, the combi-steamer element has a longitudinal slot. It has been found to be advantageous if the longitudinal slot extends axially along the combi-steamer element on the tool holder side. The longitudinal slot is preferably used for air exchange. In this way, vacuum suction of the striker at the blank impact stop surface or at the set-down point located on the blank impact stop surface can be avoided. It has been found to be advantageous if, when the empty shock absorber element is compressed, a residual opening remains from the longitudinal slot.

It has been found to be advantageous if the combi-steamer element consists of or has an elastomer material. This has the advantage that the combi-steamer element can be slipped comparatively easily over the anvil during assembly of the striking mechanism. In a particularly preferred embodiment, the Idle shock absorber element has a higher stop rigidity than the rebound shock absorber element. The higher stop stiffness is preferred

In a particularly preferred embodiment, the combi-steamer element is formed by two half-shells. A parting plane between the half-shells is preferably oriented parallel to the axial direction of the anvil.

It has been found to be advantageous if the striker guide has at least one slide bearing and / or at least one roller bearing. The striker is preferably guided or supported on both sides outside the combi-steamer element by a sliding bearing and / or at least one roller bearing.

Further advantages emerge from the following description of the figures. Various exemplary embodiments of the present invention are shown in the figures. The figures, the description and the claims contain numerous features in combination. The person skilled in the art will expediently also consider the features individually and combine them into meaningful further combinations.

Fig. 1

ein erstes bevorzugtes Ausführungsbeispiel eines Bohr- und/oder Meisselhammers;

Fig. 2

ein erstes bevorzugtes Ausführungsbeispiel eines Kombidämpferelements; und

Fig. 3

ein zweites bevorzugtes Ausführungsbeispiel eines Kombidämpferelements.

In the figures, the same and similar components are numbered with the same reference numerals. Show it:

Fig. 1

a first preferred embodiment of a hammer drill and / or chisel hammer;

Fig. 2

a first preferred embodiment of a combi-steamer element; and

Fig. 3

a second preferred embodiment of a combi-steamer element.

Embodiments:

A preferred embodiment of a hammer drill and / or chisel hammer 100 according to the invention is shown in FIG Fig. 1 shown. The hammer drill and / or chisel hammer 100 is equipped with an electric drive motor 70, an impact mechanism 10 and a tool holder 50 for receiving a tool 110. The impact mechanism 10, which is arranged in a housing 90, has an axial direction in an anvil guide 20 AR displaceable and acting on the tool 110 anvil 30.

The hammer mechanism 10 has an idle impact damper element 11 and a rebound impact damper element 13. The idle impact damper element 11 and the rebound impact damper element 13 are designed in one piece with one another and thus form a combination damper element 15. The combination damper element 15 has a central recess 40 which extends over the entire length L ( see. Figure 2B ) of the combi-steamer element 15 extends. The anvil 30 is received at least in sections within the central recess 40 and passed through it.

Again Fig. 1 can be removed, the striker guide 20 has two roller bearings 21, 23, which are completely outside of the combi-steamer element 15. The striker 30 is therefore not mounted inside the combi-steamer element 15 or by the combi-steamer element 15 itself.

The anvil 30 is cylindrical and has a radial bead 31 approximately in the middle. The radial bead 31 is to strike against the idle shock absorber element 11 on the one hand (left in Fig. 1 ) and for hitting against the impact shock absorber element 13 on the other hand (right in Fig. 1 ) is arranged.

The combination damper element 15 has a cylindrical inner surface 16 which extends in the axial direction AR between a blank impact stop surface 12 of the idle impact damper element 11 and a rebound impact stop surface 14 of the rebound impact damper element 13. In other words, the cylindrical inner surface 16 is delimited on the one hand by the beginning empty impact stop surface 12 and on the other hand by the beginning of a rebound impact stop surface 14, each seen in the axial direction AR. A radial distance 19 is provided between the cylindrical inner surface 16 and the bead 31, more precisely between the cylindrical inner surface 16 and the thickest point 32 of the bead 31 in the radial direction RR (can also be seen particularly well in FIG Figure 2B ). The radial distance 19 extends along the entire inner surface 16, ie at no point between the blank impact stop surface 12 and the rebound impact stop surface 14 does the thickest point 32 of the bead 31 touch cylindrical inner surface 16 of the combi-steamer element 15. Therefore, undesired abrasion of the combi-steamer element 15 is effectively avoided.

Fig. 2 now shows a first preferred embodiment of a combi-steamer element 15, as it is, for example, in the hammer drill and / or chisel hammer 100 of Fig. 1 can be used. Figure 2A shows the combi-steamer element 15 from the perspective of the tool holder 50. It can be clearly seen that the combi-steamer element 15 has a planar end stop surface 51, via which the combi-steamer element 15 is attached to a shoulder 52 (see also FIG Fig. 1 ) the tool holder 50 is supported.

The combi-steamer element 15 of the Fig. 2 consists, for example, of an elastomer material and is formed by two half-shells 15 ', 15 "which facilitate assembly. A parting plane 18 between the half-shells 15', 15" runs parallel to the axial direction AR.

Figure 2B shows a section through the combi-steamer element 15 along the parting plane 18. This can be seen in FIG Figure 2A is the central recess 40, which is delimited by the annular, planar end stop surface 51. The central recess 40 extends over the entire length L of the combi-steamer element 15. The anvil 30 (indicated schematically here) is received at least in sections within the central recess 40. The radial distance 19 already described is provided between the cylindrical inner surface 16 and the bead 31, more precisely between the cylindrical inner surface 16 and the thickest point 32 of the bead 31 in the radial direction RR.

When combi-steamer element 15 of the Figure 2B shows that the idle impact absorber element 11 has a higher stop stiffness than the rebound impact absorber element 13. This is achieved by structural design alone in such a way that - in relation to the axial direction AR - "more" of elastomer material is used in the idle shock absorber element 11 than in the rebound shock absorber element 13. If the idle shock absorber element 11 has a rather cylindrical cross-section Q11, it widens Cross-section Q12 of the impact shock absorber element 13 in the manner of a diffuser (to the right in Figure 2B ).

A second preferred embodiment of a combi-steamer element 15 is shown in FIG Fig. 3 shown. In addition to the in Fig. 2 illustrated embodiment is the combi-steamer element 15 Fig. 3 a longitudinal slot 17 is provided, which is located on the tool holder side (in Fig. 3 from the left) extends axially along the combi-steamer element 15. An exchange of air is ensured by the longitudinal slot 17, so that a vacuum suction of the anvil (not shown here) on the blank impact stop surface 12 is avoided. Figure 3A shows the combi-steamer element 15 in the relaxed state, ie Döpper is located, for example in Figure 2B can be seen in a central position. In Figure 3B the combination damper element 15, more precisely the idle impact damper element 11, is shown in the compressed state. A residual opening 17 ′ remains from the longitudinal slot 17, via which an exchange of air is possible even when the empty shock absorber element 11 is compressed.

List of reference symbols

10

Percussion

11

Idle shock absorber element

12th

Space stroke stop surface

13th

Shock absorber element

14th

Impact stop surface

15th

Combi-steamer element

15 ', 15 "

Half shells

16

cylindrical inner surface

17th

Longitudinal slot

17 '

Residual opening

18th

Parting plane

19th

radial distance

20th

Stopper guide

21, 23

roller bearing

30th

Döpper

31

radial bead

32

thickest point

40

central recess

50

Tool holder

51

flat face stop surface

52

shoulder

70

Drive motor

90

casing

100

Hammer drill and / or chisel hammer

110

Tool

AR

axial direction

RR

radial direction

Q11, Q12

Cross-sections

Claims (10)

Hammer drill and / or chisel hammer (100) with a drive motor (70), an impact mechanism (10) and a tool holder (50) for receiving a tool (110), the impact mechanism (10) having an axial ( AR) has displaceable anvil (30) which acts on the tool (110), the hammer mechanism (10) having an idle impact absorber element (11) and a rebound impact absorber element (13) which are designed in one piece with one another and thus form a combination damper element (15),
characterized in that the striker guide (20) is arranged outside, preferably exclusively outside of the combi-steamer element (15). Hammer drill and / or chisel hammer (100) according to Claim 1,
characterized in that the otherwise preferably cylindrical anvil (30) has a radial bead (31) which is arranged to strike against the idle shock absorber element (11) on the one hand and to strike the rebound shock absorber element (13) on the other hand. Hammer drill and / or chisel hammer (100) according to Claim 2,
characterized in that the combi-damper element (15) has a cylindrical inner surface (16) which extends in the axial direction (AR) between a blank impact stop surface (12) and a rebound impact stop surface (14), wherein between the cylindrical inner surface (16 ) and the bead (31), preferably along the entire inner surface (16), a radial distance (19) is provided. Hammer drill and / or chisel hammer (100) according to one of the preceding claims,
characterized in that the combi-steamer element (15) has a planar end stop surface (51) via which the combi-steamer element (15) is supported on a shoulder (52) of the tool holder (50) Hammer drill and / or chisel hammer (100) according to one of the preceding claims,
characterized in that the combi-steamer element (15) has a longitudinal slot (17) which extends axially along the combi-steamer element (15) on the tool-receiving side. Hammer drill and / or chisel hammer (100) according to Claim 6,
characterized in that , when the empty shock absorber element 11 is compressed, a residual opening 17 'remains from the longitudinal slot 17. Hammer drill and / or chisel hammer (100) according to one of the preceding claims,
characterized in that the combi-damper element (15) consists of or has an elastomer material. Hammer drill and / or chisel hammer (100) according to one of the preceding claims,
characterized in that the idle impact absorber element (11) has a higher stop stiffness than the rebound impact absorber element (13). Hammer drill and / or chisel hammer (100) according to one of the preceding claims,
characterized in that the combi-steamer element (15) is formed by two half-shells (15 ', 15 "), a parting plane (18) between the half-shells (15', 15") preferably parallel to the axial direction (AR) of the anvil (30 ) is oriented. Hammer drill and / or chisel hammer (100) according to one of the preceding claims,
characterized in that the anvil guide (20) has at least one slide bearing and / or at least one roller bearing (21, 23).

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