KR20090070667A - Rubber mounting structure with adjustable vibration constant - Google Patents

Abstract

The present invention discloses a rubber mounting structure capable of adjusting vibration constants. The rubber mounting structure includes a bracket 12 provided in the lower body 10 of the vehicle and having a through hole 12a; A column 16a having a threaded portion at one side thereof and a head portion 16b provided at the other side thereof, and a bolt 16 fitted into the through hole 12a of the bracket 12; And a through hole 17a fitted into the column 16a of the bolt and a recess 17b formed by recessing one side thereof to support the upper body 11 of the vehicle when the bracket 12 is fixed to the bracket 12. Rubber 17; And is seated in the recessed portion 17b of the rubber 17 and fastened to the column 16a of the bolt 16, and the upper and lower ends of the recessed portion 17b are interacted with the bolt 16. And a first nut 20 to compress. When the first nut 20 and the bolt 16 are fastened to each other, the upper body (b) is formed at an outer edge of the recess 17b of the rubber 17. 11) and the bracket 12 is compressed to form a vibration constant k1, the concave portion 17b is compressed by the fastening force of the first nut 20 and the bolt 16 to form a vibration constant k2. The vibration constants k1 and k2 may be formed differently from each other. The present invention provides two rubbers with one rubber to easily solve the resonance phenomenon of the cabin.

Description

Rubber mounting structure with adjustable vibration constant {RUBBER MOUNTING STRUCTURE CAPABLE OF ADJUSTING VIBRATION CONSTANT}

The present invention relates to a rubber mounting structure capable of adjusting vibration constants, and in particular, a rubber mounting structure capable of adjusting vibration constants to prevent resonance of equipment or a vehicle by providing two elastic forces by using one rubber. It is about.

In general, a forklift is a kind of industrial vehicle that allows lifting or unloading a relatively heavy load, and is used to move a heavy load at a short distance or to load or unload the load into various transport vehicles. .

As shown in FIG. 1, the forklift 1 is composed of a main body 2 including an engine and a mast assembly 3 provided on the front side of the main body. In addition, the main body 2 is composed of a lower body 10 including the engine and a cabin 11 that can be rotated with respect to the lower body 10 so as to conveniently maintain the engine.

Four places of the lower body 10 are provided on the bracket 12 and the bracket so as to appropriately absorb the physical shock transmitted to the cabin 11 through the lower body 10 from the ground when the vehicle is running. The rubber 15 is attached via the flat plate 14 fixed by the screw 13.

Here, the rubber 15 has a flange (not shown) is formed around the lower edge. The flat plate 14 has a coupling hole 14a formed at the center portion thereof to detachably receive the rubber 15. Accordingly, the rubber 15 may be fixed by the screw 13 after the flange is fixed by the flat plate 14 in the state positioned above the bracket 12.

However, the conventional rubber fixing structure as described above has only one natural frequency because only one rubber 15 having a uniform vibration constant is applied to each installation position. For this reason, the cabin 11 did not properly absorb shaking due to external force, and thus the resonance phenomenon was very severe. Such a resonance phenomenon of the cabin 11 interferes with the operator's detailed device operation, smooth operation, and the like, which ultimately lowers work efficiency and increases the risk of safety accidents.

Accordingly, the present invention has been made to solve the problems described above, the object is to provide two elastic forces in one rubber to facilitate the vibration (or spring) constant to solve the resonance phenomenon of the cabin It provides an adjustable rubber mounting structure.

Another object of the present invention is to provide a rubber mounting structure capable of adjusting the vibration constant to effectively adjust the vibration constant of the rubber providing two elastic forces to effectively eliminate the resonance of the cabin of various models.

In order to achieve the above object, the present invention is a bracket provided on the lower body of the vehicle having a through hole; A column having a threaded portion at one side thereof and a head portion at the other side thereof, the bolt being fitted into the through hole of the bracket; A rubber having a through hole fitted into the column of the bolt and a recess formed by recessing one side thereof and supporting the upper body of the vehicle when the bracket is fixed to the bracket; And a first nut seated in the recess of the rubber and fastened to the column of the bolt, the first nut compressing the upper and lower ends of the recess in interaction with the bolt. When the coupling is completed, the outer edge of the concave portion of the rubber is compressed by the upper body and the bracket to form a vibration constant k1, the concave portion is compressed by the tightening force of the first nut and the bolt to vibrate constant k2 Is formed, the vibration constants k1 and k2 provide a rubber mounting structure capable of adjusting the vibration constants, characterized in that they are formed differently from each other.

In addition, the present invention further provides the following specific embodiments of the above-described embodiment of the present invention.

According to one embodiment of the present invention, a through hole is formed in the center portion so that the column of the bolt can be fitted in the upper portion of the bracket and both ends are further provided with a flat plate fixed to the bracket via a fastener, The through hole of the bracket is characterized in that formed larger than the first washer.

According to one embodiment of the invention, it further comprises a second nut fitted in the column of the bolt between the head of the bolt and the first washer ring.

The present invention provides two rubbers with one rubber to easily solve the resonance phenomenon of the cabin.

In addition, the present invention makes it possible to conveniently adjust the vibration constant of the rubber that provides two elastic forces to effectively eliminate the resonance of the cabin of various models.

Hereinafter, each embodiment of the rubber mounting structure capable of adjusting the vibration constant according to the present invention will be described with reference to FIGS. 2 to 5.

2 is a schematic partial enlarged side view showing a rubber mounting structure capable of adjusting vibration constants according to an embodiment of the present invention, and FIG. 3 is a schematic partial enlargement of a rubber mounting structure capable of adjusting vibration constants according to an embodiment of the present invention. Perspective view.

As shown in FIGS. 2 and 3, the rubber mounting structure capable of adjusting the vibration constant according to the exemplary embodiment of the present invention includes a bracket 12 provided in the lower body 10 of the equipment or the vehicle and having a through hole 12a. ); A column 16a having a threaded portion at one side thereof and a head portion 16b provided at the other side thereof, and a bolt 16 fitted into the through hole 12a of the bracket 12; A rubber (17) having a through hole (17a) formed in a central portion thereof to be fitted into the column (16a) of the bolt, and having a recessed portion (17b) in a central portion of one side thereof; A first washer (18) fitted to the column (16a) of the bolt (16) between the bracket (12) and the head portion (16b) of the bolt (16); And a second washer 19 and a first nut 20 fitted into the column 16a of the bolt 16 to be seated in the recess 17b of the rubber 17.

Meanwhile, the rubber mounting structure capable of adjusting the vibration constant according to the embodiment of the present invention further includes the following components in the basic configuration of the embodiment as described above, as shown in FIGS. 4 and 5. Can be done. A through hole 21a is formed in the center portion of the bracket 12 so that the column 16a of the bolt 16 can be fitted, and both ends thereof are fastened through fasteners 22 such as screws and rivets. A flat plate 21 fixed to the bracket 12 may be further provided.

On the other hand, the rubber mounting structure capable of adjusting the vibration constant according to an embodiment of the present invention and this embodiment is the bolt 16 between the head portion 16b of the bolt 16 and the first washer 18. It may be made in the form of further comprising a second nut 23 fitted to the column (16a) of () (see Figs. 2 to 5). In this case, the through hole 12a of the bracket 12 is preferably formed larger than the first washer ring 18. The reason is that the head washer 16b and the lower body of the bolt 16 were at least partially accommodated by the first washer 18 and the second nut 23 through the through hole 12a of the bracket 12. This is because it is possible to conveniently adjust the bolt 16 by sufficiently securing the gap gap between the parts (10).

On the other hand, the rubber 17 may be made of a variety of conventional rubber material, the upper ring-shaped portion (17A) and the bolt 16 and the first nut 20 or the first nut 20 forming the recess 17b. ) And the lower support part 17B compressed by the second nut 23. That is, the rubber 17 in the state mounted on the bracket 12 has the upper ring-shaped portion 17A pressed by the upper body or the cabin 11 in its original state, the bolt 16 and the first nut 20. Or it is divided into a lower support portion 17B which is compressed by the first nut 20 and the second nut 23. When the mounting is completed as described above, even if the rubber 17 is formed of a single body of the same material as a whole, the upper ring-shaped portion 17A is compressed by the load of the upper body or the cabin 11 to form a vibration constant k1. The lower support portion 17B is compressed by the first nut 20 and the bolt 16 or the first nut 20 and the second nut 23 to form a vibration constant k2. The vibration constant k2 may be varied by adjusting the fastening amount of the bolt 16 and the first nut 20 or the first nut 20 and the second nut 23 as mentioned above. Accordingly, the rubber 17 is formed with a plurality of natural frequencies capable of effectively absorbing vibrations caused by an external force (for example, a physical shock applied from the cabin). In this embodiment, the through hole 17a is formed to penetrate the recess 17b coaxially so that the rubber 17 is fixed to the bracket 12 by a nut seated on the recess 17b. have. However, the present invention is not necessarily limited thereto, and may be formed by differently fixing a portion of the rubber 17 to the bracket 12 and a portion at which the nut and the bolt are fastened to adjust the vibration constant.

The assembly and operation of each embodiment of the rubber mounting structure capable of adjusting the vibration constant according to the present invention configured as described above will be described with reference to FIGS. 2 to 5.

In the case of the rubber mounting structure according to one embodiment, the first washer (1) to the head portion 16b through the column 16a of the bolt 16 in a state in which the cabin 11 of the forklift 1 is first removed to one side ( 18), the column 16a of the bolt 16 is inserted from the lower part of the bracket to the upper part of the through hole 12a of the bracket 12 provided in each part of the lower body 10 of the forklift. .

Then, the rubber 17 is inserted into the column 16a of the bolt 16 through the front end of the column, and then the second washer 19 and the second washer until it is seated at the bottom of the recess 17b of the rubber 16. The first nut 20 is screwed into the column 16a of the bolt 16.

Then, in consideration of the vibration characteristics of the cabin 11 of the forklift truck identified by the design or experiment in advance of the lower support portion 17B of the rubber 17, using a conventional adjusting tool (not shown) Adjust the bolt 16 and the first nut 20 appropriately.

Then, the cabin 11 is returned to its original position, and then the cabin may be fixed to the lower body 10. If the shaking of the cabin 11 is not stable due to the difference in weight of the operator even after the adjustment is completed as described above, the cabin is lowered to the outside of the bracket 12 by using the adjusting tool without having to re-extract the cabin to one side. What is necessary is just to adjust the head part 16b of the said protruding bolt 16 suitably.

Then, the vibration (or shaking) of the cabin 11 is appropriately adjusted and absorbed through the combination of the vibration constant k1 of the upper ring-shaped portion 17A of the rubber 17 and the vibration constant k2 of the lower support portion 17B. It becomes possible.

On the other hand, in the case of the rubber mounting structure according to this embodiment, the first washer toward the head portion 16b through the column 16a of the bolt 16 in a state in which the cabin 11 of the forklift 1 is first removed to one side. With the ring 18 and the second nut 23 fitted, the bracket 12 is provided in each of the through holes 21a of the bracket 12 and the flat plate 21 provided in a part of the lower body 10 of the forklift. Insert the column 16a of the bolt 16 from bottom to top.

Then, the rubber 17 is inserted into the column 16a of the bolt 16 through the front end of the column, and then the second washer 19 and the second washer until it is seated at the bottom of the recess 17b of the rubber 16. The first nut 20 is screwed into the column 16a of the bolt 16.

Then, in consideration of the vibration characteristics of the cabin 11 of the forklift truck identified by the design or experiment in advance of the lower support portion 17B of the rubber 17, using a conventional adjusting tool (not shown) The 1st nut 20 and the 2nd nut 23 are adjusted suitably.

Then, the cabin 11 is returned to its original position, and then the cabin may be fixed to the lower body 10. If the shaking of the cabin 11 is not stable due to the difference in weight of the operator even after the adjustment is completed as described above, the cabin is lowered to the outside of the bracket 12 by using the adjusting tool without having to re-extract the cabin to one side. What is necessary is just to adjust the protruding 2nd nut 23 and the head part 16b of the bolt 16 suitably.

Then, the vibration (or shaking) of the cabin 11 is appropriately adjusted and absorbed through the combination of the vibration constant k1 of the upper ring-shaped portion 17A of the rubber 17 and the vibration constant k2 of the lower support portion 17B. It becomes possible.

The present invention described above is not limited to the above-described embodiments and the accompanying drawings, and simple substitutions, modifications, and changes within the technical idea of the present invention will be apparent to those skilled in the art.

1 is a schematic partially enlarged side view showing a general rubber mounting structure of a forklift according to the prior art;

Figure 2 is a partially enlarged side view showing a rubber mounting structure capable of adjusting the vibration constant in accordance with an embodiment of the present invention.

Figure 3 is a partially enlarged perspective view of a rubber mounting structure capable of adjusting the vibration constant in accordance with an embodiment of the present invention.

Figure 4 is a partially enlarged side view showing a rubber mounting structure capable of adjusting the vibration constant according to this embodiment of the present invention.

Figure 5 is a schematic partially enlarged perspective view of a rubber mounting structure capable of adjusting the vibration constant according to this embodiment of the present invention.

<Description of the symbols for the main parts of the drawings>

10: lower body 11: upper body (or cabin)

12: bracket 12a, 17a, 21a: through hole

16a: column 16b: head portion

16: bolt 17b: recess

17: Rubber 17A: upper ring portion

17B: lower support 18: first washer

19: second washer 20: first nut

21: Reputation 22: Fastener

23: second nut

Claims (3)

A bracket 12 provided in the lower body 10 of the vehicle and having a through hole 12a; A column 16a having a threaded portion at one side thereof and a head portion 16b provided at the other side thereof, and a bolt 16 fitted into the through hole 12a of the bracket 12; And a through hole 17a fitted into the column 16a of the bolt and a recess 17b formed by recessing one side thereof to support the upper body 11 of the vehicle when the bracket 12 is fixed to the bracket 12. Rubber 17; And It is seated in the recessed portion 17b of the rubber 17 and is fastened to the column 16a of the bolt 16. During the fastening, the upper and lower ends of the recessed portion 17b are compressed by interaction with the bolt 16. To include; a first nut 20; When the fastening of the first nut 20 and the bolt 16 is completed, the outer edge of the recess 17b of the rubber 17 is compressed by the upper body 11 and the bracket 12 to vibrate. A constant k1 is formed, and the concave portion 17b is compressed by a fastening force between the first nut 20 and the bolt 16 to form a vibration constant k2. The vibration constant k1 and k2 is a rubber mounting structure capable of adjusting the vibration constant, characterized in that formed differently. The upper part of the bracket 12, the through hole 21a is formed in the center portion so that the column (16a) of the bolt 16 can be fitted, both ends via the fastener 22 A flat plate 21 fixed to the bracket 12 is further provided, and the through hole 12a of the bracket 12 is formed larger than the first washer 18, and the rubber mounting structure capable of adjusting the vibration constant. . The second nut (23) according to claim 1 or 2, which is fitted in the column (16a) of the bolt (16) between the head (16b) of the bolt (16) and the first washer ring (18). Rubber mounting structure capable of adjusting the vibration constant further comprising.

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