DE3124227A1 - VIBRATION-DAMPING HANDLE DEVICE - Google Patents

Description

DESCRIPTION

The present invention relates to a vibration-damping handle device which is used for a hand-operated vibration tool, such as an electromotive or electromotive tool or a pneumatic tool, suitable is.

It has become a common practice to prevent transmission a vibration from a vibration tool to a handle or an elastic material as a damper use which is provided between the vibration source and the handle. Even if by means of such an elastic Material a significant vibration dampening effect can be achieved there is a tendency for the operation of the handle to increase due to the presence of the elastic material is flexible, and in the actual operation of a vibratory tool such as an electromotive tool, the tool has a tendency to wobble and twist and it is difficult to find a correct one Perform centering.

In brief summary, the present invention seeks to provide a vibration dampening handle device which is essentially rigid, stable and firmly connected to a vibration source, and which is nevertheless capable is to effectively dampen dangerous vibrations that come from the vibrating body. It should be noted here that im In the context of the invention, the terms "vibration" and "oscillation" in their various word and compound forms are synonymous be used.

In this way, the present invention is a vibration dampening Handle device provided that a vibration receiving part, which via a connecting part

fixed to a vibrating body, such as a housing of a vibrating tool or a vibrating tool, can be connected, and which is suitable, an initial oscillation from the oscillating body or from the latter emanating To absorb vibrations. A pair of first vibrating mass bodies is attached to the respective ends of the vibration receiving part; and a pair of second vibrating mass bodies is on the outside of the respective first vibration mass bodies provided as well as a damping part or one each Damping part, such as a spring or rubber or Rubber, with the respective first vibration mass bodies tied together. A pair of third vibration mass bodies is on the inside of the respective first vibration mass bodies intended; and a handle part is on the third vibrating mass body attached. A rod or rod part is concentric to the first, second and third vibration mass bodies provided and on the second and third vibration mass bodies attached.

The invention is hereinafter based on one in Figures 1 and 2 of the drawing shown in principle, particularly preferred Embodiment explained in more detail; show it:

Figure 1 is an exploded schematic view of a Embodiment of a handle device according to the present invention Invention; and

FIG. 2 is a schematic longitudinal sectional side view of the FIG Figure 1 shown handle device according to the present Invention in assembled form.

Reference is now made in more detail to FIGS. 1 and 2, in which 1 with a vibration receiving part is designated, which is designed so that it 2 vibrations via a connecting part from a source (not shown) of dangerous vibrations, such as the housing of an electric motor!

see tool, a pneumatic tool or a small one
Internal combustion system or a small explosion engine, such as a motorcycle engine, is. In the embodiment shown, the vibration absorbing part is constructed so that it has a channel shape. However, it may have any other shape so long as it is constructed so that it can absorb the vibrations separately depending on the right and left ends 1a
and 1b distributed towards a handle part 3.

At each of the two ends 1a and 1b, a first mass body 4 or 5 is attached, and these first mass bodies 4,
5 are preferably provided symmetrically to one another and preferably have the same mass. According to the illustration, welding or soldering, in particular hard soldering, is provided as the fastening means, which is simple and secure. However
Other fasteners, such as screw-and-nut or riveting, may also be used.

The first vibration mass body 4 and 5 are each with a
Hole 4a or 5a provided. In the most preferred embodiment, the holes are circular in cross section. However, they can optionally also have other cross-sections, such as, for example, a square or hexagonal or rectangular cross-section.

Each of the first vibration mass bodies 4 and 5 can most simply have the shape of a block, as shown in FIG
is, but can also be in the shape of a mug or a deep one
Have shell whose hollow parts 4b and / or 5b are loaded or packed full with a rubber or rubber or with other semi-rigid hard plastic, as shown in FIG.
The main part of the vibration mass body should of course preferably be made of a metal. This structure also applies to the second and third described below
Vibration mass body.

With the reference numerals 4c and 5c is a spring receiving part or projection, which is formed integrally or in one piece with the respective first vibration mass body 4 and 5 and is directed outwards from this. The spring receiving parts have the shape of a raised projection, as shown, but they can also be in the form of a recessed circular groove (not shown). Continue to extend the aforementioned holes 4a and 5a straight through the respective spring receiving part 4c and 5c.

Damping springs are denoted by the reference numerals 6 and 7, which are preferably formed to form a pair and which are preferably made of the same material in the same Form are made. They are arranged symmetrically to one another. In the embodiment shown, they have the shape of coil springs, which is a case in point. However, they can be replaced by any other suitable damping springs be replaced, such as by leaf springs, an arrangement of conical disc springs, bellows, etc., which are a modification within the present invention.

The reference numerals 8 and 9 are second vibration mass bodies assigned, which should preferably be made of a metal. With 8a and 9a holes are designated, which in the longitudinal direction pass through the middle of the respective second vibration mass body, and with 8b and 9b are spring receiving parts designated.

The reference numerals 8c and 9c are assigned to threaded holes, the provided at right angles to the axial center line of the respective second vibration mass body 8 or 9 and formed in this way are that they are fastening screws 10 and 11, respectively, in the present case Case grub screws, through which the second vibration mass body 8 and 9 at the respective ends of a Rod or rod part 20 are attached. In order to reinforce the attachment and make it more secure, it is possible in addition to the fastening screws that are attached to the

Upper side are provided, corresponding fastening screws with threaded holes on the lower side of the vibration mass body 8 and 9 to be provided.

The reference numerals 12 and 13 are third vibration mass bodies assigned, which are provided with central holes 12a and 13a, and with a threaded hole 12b and 13b, which are at right angles runs to the respective central hole. Fastening screws 14 and 15, in this case grub screws, are inserted into the threaded holes screwed in. Their structures and basic functions are the same as those referring to the second Vibration mass bodies 8 and 9 described. The vibration mass bodies 12 and 13 are attached via adhesive layers 16 and 17 attached to the inner wall of a handle part 3, which is a pipe or Has sleeve shape. The fastening means is not limited to such adhesive layers ". Rather, other known Types of fasteners, such as a pair of screws, or rivets, instead of the Adhesive layers are used. The handle part 3 and the rod part 20 are not shown in FIG.

After the structure of a handle device according to above of the present invention has been described, its mode of operation will now be explained.

A dangerous vibration from a vibration source, for example a housing of an electromotive tool, is via the connecting part 2 to the first vibration mass bodies 4 and 5 essentially with the initial amplitude and frequency and essentially with the output amplitude and frequency transmitted. If, however, the ends 1a and 1b in the form of an arm have a certain elasticity, this can already be done here a certain degree of vibration damping effect can be achieved.

In the vibration system on the left side of the center reference line C, the vibration from the mass body 4 becomes mean

the spring 6 damped and then on the second vibration mass body 8 transferred. Then the vibration is from the mass body 8 via the left-hand half of the rod part 20 to the third th vibrating mass body 12 transmitted, due to which the mass body 12 to an extraordinarily reduced degree swings. In a common hand-operated tool, the diameter of the rod part 10 can be from 5 to 8 mm.

In a corresponding way in the oscillation system, which is located on the right side of the reference line C, the oscillation of the first oscillating mass body 5 by means of the spring 7 damped and transmitted to the second vibration mass body 9, and then it is on the right half of the rod part 20 the third vibration mass body 13 transmitted, due to which the mass body 13 in an extraordinarily reduced Degree swings. The part of the rod part 20 which is present between the third mass bodies 12 and 13 can optionally be omitted or it can be continuous or continuously connect the two halves of the rod part 20 to one another, as illustrated in FIG.

By correct setting of the mass of each vibrating mass body and each spring as well as by correct setting of the spring constants of each spring it is possible to tune the system so that a node A (i.e. a point at which the oscillation is minimal) is arranged in the central point or close to this along the rod part 20. It is believed or assumed that in this state the oscillation phase of the left and right oscillation system along the rod part 20, especially the oscillation phase of each of the third Vibration mass bodies 12 and 13 are reversed relative to one another.

The handle part 3 is only with the third vibration mass body 12 and 13, and accordingly it is physically resp.

physically and mechanically isolated from other points in the vibration system, especially at both ends. The central one Part of the handle part 3 corresponds to a vibration node A in which the vibration is theoretically zero, and accordingly the handle part only absorbs a very limited oscillation. According to an experiment, it was found that the initial Vibration or the output vibration can be damped to a level that is from 1/10 to 1/30.

If excessive force is applied to the handle part, then it can happen that the rod part 20 is in direct contact with the inner walls of the central holes of the first vibrating mass body 4 and 5 comes, whereby the dangerous vibration is partially transmitted directly to the rod part 20. However Even in such a case, the vibration can be dampened to a level that is 1/10 of the initial or output vibration amounts to.

After a simple embodiment of a vibration model above has been described in which the oscillation systems on the left and right of the center line C are symmetrical with respect to each other, it should be noted that the left and right vibration system depending on the type of via the connecting part 2 of the vibration source The vibration to be transmitted can also be built up so that they are asymmetrical to one another, which is a matter of fact of particular design is within the scope of the present invention.

Furthermore, the initial oscillation can be quite be complicated, in particular include different types of vibrations that vary in amplitude and / or the Differentiate frequency and / or in the direction of the vibration levels. According to the results obtained on the basis of experi-

ments resulted, which carried out in the context of the present invention it has been found that even such complicated vibrations are effective by means of the device according to the present invention Invention, in which the left and right oscillation systems are exactly or substantially symmetrical, effectively damped t can be; accordingly, with such a structure, for practical reasons, the object of the present invention can be achieved particularly advantageously in an adequate manner. In addition, the springs can be tightened by some other elastic means. Devices are replaced, such as by Gummibzw. Rubber parts.

ι - ^ "· ♦ Blank page

Claims (7)

PATENT ADVERTISER DIPL,: RH.YS. WIDENMAYERSTRASSE 48 8000 MUNICH 22 TELEPHONE: (089) 22 6917 TELEGRAM SHORT ADDRESS: PATOMIC MUNICH FP / 55-87,578WG-D T) MAKGTO MINAMIDATE 2) KAZUTO SETO 24-7, Mito, Hatsuse-cho, 1727-3, Shimo-Yamaguchi, Miura-shi, Kanagawa; Japan Hayama-machi, Miura-gun, Kanagawa; Japan Vibration dampening handle device PATENT CLAIMS AJ vibration-damping handle device, characterized in that it comprises the following: a vibration receiving part (1) which via a connecting part (2) can be firmly connected to a vibrating body and is suitable for an initial vibration from the vibrating body or vibrations generated by the vibrating body go out, take in; and a pair of first vibration mass bodies (4, 5) which are attached to the respective ends of the vibration receiving part (1); a pair of second vibration mass bodies (8,9) which are provided on the outside of the respective first vibration mass bodies (4,5) or each of which is provided on the outside of one of the first vibration mass bodies (4,5) and which are provided via a damping part ( 6,7) are connected to the respective first vibration mass bodies (4,5) or of which one each via a damping part (6,7) with the first vibration mass body (4,5) assigned to it is connected; a pair of third vibration mass bodies (12,13), the are provided on the inside of the respective first vibration mass bodies (4, 5) or one of each of which is provided on the inside of one of the first vibration mass bodies (4, 5) is provided; a handle part (3), which is attached to the third Söhwingungsmassenkodies (12,13) is attached; and a rod part (20) concentric with the first, second and third vibrating mass bodies (4,5; 8,9; 12,13) is provided and attached to the second and third vibration mass bodies (8,9; 12,13). 2. Vibration-damping handle device according to claim 1, characterized in that the first, second and third vibration mass bodies (4,5; 8,9; 12,13) are each symmetrical are in equilibrium, and that the respective damping parts (6,7) have the same spring constant. 3. Vibration-damping handle device according to claim 1 or 2, characterized in that the damping part (6,7) a spring or rubber or rubber, in particular a rubber or rubber part, or a resilient plastic part is. 4. Vibration-damping handle device according to claim 1, 2 or 3, characterized in that the first, second and third vibration mass bodies (4,5; 8,9; 12,13) from consist of a rigid mass body which has a cup shape and its hollow part (4b, 5b) with a semi-rigid or elastic Material is loaded or completely or partially filled. 5. Vibration-damping handle device according to one of the Claims 1 to 4, characterized in that the handle part (3) is tubular and that the third vibration mass body (12,13) are attached to the inner wall of the tubular handle part (3). 6. Vibration-damping handle device according to one of claims 1 to 5, characterized in that the rod or rod part (20) is a metal rod, the one
Has a diameter of 5 to 8 mm. 7. Vibration-damping handle device according to one of claims 1 to 6, characterized geke η η ζ eich η et that the part of the rod or rod part (20) which is between
the third vibration mass bodies (12, 13) is omitted or that the rod or rod part (20) consists of a first and second rod or rod part, one of which is one of the first, second and third mass bodies (4,5; 8,9; 12,13) and on the other the respective other of the first, second and third mass bodies (4,5; 8,9; 12,13) is arranged.