KR20130123624A - Rack coupling damper system for vibration control of lightweight-framed storage racking structure - Google Patents

Abstract

A rack connected damping system for controlling vibration of a light weight frame structure for goods storage according to the present invention comprises: a base plate, crossly arranged between two adjacent facing racks in a rack system consisting of multiple racks having shelves for goods storage, having both ends combined to the upper surfaces of each rack; a mass unit, installed in the upper surface of the base plate to be able to move, having predetermined mass; a pair of spring members which are arranged in both sides of the mass unit on the upper surface of the base plate and are installed between the mass unit and a side wall respectively formed in one end of the base plate; and a vibration control unit which is arranged in both sides of the mass unit on the upper surface of the base plate and is composed of a pair of dampers installed between the mass unit and the side wall respectively formed in one end of the base plate; wherein the vibration control unit is aligned with two adjacent racks of the multiple racks and is arranged in the upper side of each shelf column of the racks.

Description

Rack coupling damper system for vibration control of lightweight-framed storage racking structure

The present invention relates to a rack-linked damping system for vibration control of a lightweight frame structure for logistics storage.

Generally, a large number of racks are stacked in order to store articles in a warehouse or the like of a large-sized logistics system, and a plurality of racks in which racks are arranged in the longitudinal direction are installed and used. In such a rack system, when the article is stored on the shelf of the rack or when the article is taken out of the shelf, the article is bulky and heavy, or in an automated system, the use of a forklift or other transportation vehicle is increasing. However, in the case of such a logistics system, there is an advantage that the goods can be quickly moved and stored by using the transportation vehicle. However, when the transportation vehicle hits the rack due to carelessness, There is a problem that it is broken.

Thus, a rack system has been developed with elastic members made of rubber on the legs of the rack to prevent the article from falling off the shelf in the event of an impact or vibration. Although there is a function to damp the vibration, there is a problem that it is difficult to suppress a large shock or vibration more than a certain level without guaranteeing the stability and reliability of the vibration of the entire rack system.

Accordingly, the present invention has been made to solve the problems of the prior art, to provide a rack-linked damping system for the vibration control of the light weight frame structure for logistics storage, which improves the structural stability of the rack itself and the vibration control function is improved. For the purpose of

Rack-linked damping system for the vibration control of the lightweight frame structure for logistics storage according to the present invention is disposed across the two racks facing each other in a rack system consisting of a plurality of racks having shelf for storing goods, each end is A base plate coupled to an upper surface of the rack, a mass portion movably installed on an upper surface of the base plate, and having a predetermined mass, and disposed on both sides of the mass portion on an upper surface of the base plate, and formed at one end of the base plate, respectively. A pair of spring members disposed between the side wall and the mass portion, and a pair of spring members disposed on both sides of the mass portion at an upper surface of the base plate and respectively disposed between the side wall formed at one end of the base plate and the mass portion. It comprises a vibration control unit consisting of a damper, the vibration control unit The plurality is arranged side by side between two adjacent racks and each vibration control unit is characterized in that arranged on the upper side of each shelf column of the rack.

In addition, a side wall formed at one end of the base plate, and between the spring member and the damper is formed a side wall support member, and a connection member having one end fitted to the side wall support member, and one end of the connection member by a spring An elastic support protrusion is formed, and the sidewall support member formed on the sidewall is formed with guide holes through which the protrusion of the connection member is inserted and moved, and coupling holes are formed on both sides of the guide hole.

In addition, each mass portion of the plurality of vibration control unit is characterized by having a different mass.

In addition, it is preferable that a coupling protrusion is formed on a side wall formed at one end of the base plate, and a coupling groove to which the coupling protrusion is coupled is formed at an upper side wall of the rack to be detachably coupled to the rack.

In addition, a side wall formed at one end of the base plate, and between the spring member and the damper is formed a side wall support member, and one end is fitted to the side wall support member and the other end is connected to the spring member and the damper,

One end of the connection member is provided with a moving pad fitted inside the sidewall support member, and the sidewall support member formed on the sidewall is provided with a movement limiting jaw that restricts the movement of the movement pad. Characterized in that the movable side between the one side of the side wall support member and the movement limiting jaw.

According to the present invention, there is provided a rack-linked damping system for vibration control of a lightweight frame structure for logistics storage that improves structural stability of the rack itself and improves vibration control.

In addition, since the rack system to which the present invention is applied is a method of storing weight logistics by using a lightweight frame member, the vibration control unit as shown in the present invention consists of a plurality of small mass stability due to the increase in load in the overall structural system The degradation is minimized. In addition, when the single vibration control unit is applied as the vibration characteristics of the entire structural system are constantly changed according to frequent movement of the storage logistics, the control performance may be drastically deteriorated. Excellent adaptability is ensured even with a change in characteristics.

1 is a perspective view of an apparatus according to a first embodiment of the present invention,
Figure 2 is a plan view of the vibration control unit in Figure 1 of the present invention,
3 is a partial cross-sectional view of FIG.
4 is a partial view of an apparatus according to a second embodiment of the present invention.

Hereinafter, a device according to a preferred embodiment of the present invention will be described in detail with reference to the drawings.

1 is a perspective view of a device according to a first embodiment of the present invention, FIG. 2 is a plan view of the vibration control unit in FIG. 1 of the present invention, FIG. 3 is a partial sectional view in FIG. 1, and FIG. 4 is a second embodiment of the present invention. A partial view of the apparatus according to the embodiment.

As shown in Fig. 1, the apparatus according to the preferred embodiment of the present invention is provided between two adjacent racks 10 facing each other in a rack system composed of a plurality of racks 10 having shelf 11 for storing goods. It comprises a plurality of vibration control unit 20 for controlling the vibration in conjunction with, each vibration control unit 20 is a base plate 21 and a base plate (cross) disposed between the two racks (10) A mass unit 23 movably mounted on the upper surface of the 21 and having a predetermined mass, a pair of spring members 24a and 24b, and a pair of dampers 25a and 25b. It is arranged on the upper side of each shelf column of the rack (10).

The base plate 21 is disposed across two adjacent racks 10, and both ends of the base plate 21 are coupled to the top surfaces of the two adjacent racks 10, respectively. In general, the rack 10 is configured by repeating the shelf column in which the shelves 11 are stacked in the longitudinal direction of the rack 10, and both ends of the base plate 21 are disposed above each shelf column.

The mass part 23 has a predetermined mass so as to be movable on the upper surface of the base plate 21, and the front and rear wheels 23a are coupled to the lower part of the mass part 23 on the front and rear sides. The mass unit 23 has a function of suppressing vibration of the rack 10 by having a certain displacement when shock or vibration occurs in the rack 10. In addition, the mass portion 23 of each vibration control unit 20 is formed to have a different mass, the configuration of the vibration control unit having a plurality of different mass is dynamic of the entire rack system according to the storage amount of the logistics stored in the rack system Characteristics (frequency characteristics due to mass change) can greatly change, which can significantly reduce the vibration damping performance of the vibration control unit by affecting the vibration characteristics of the rack system. For sake.

The pair of spring members 24a and 24b are disposed on both sides of the mass part 23 on the upper surface of the base plate 21, and each spring member 24a and 24b is connected to one end of the base plate 21. It is provided between the side wall 22 formed and the mass part 23.

The pair of dampers 25a and 25b (dampers) are also arranged in the same manner as the spring members 24a and 24b, which are disposed on both sides of the mass portion 23 on the upper surface of the base plate 21, and each of the dampers 25a and 25b are provided between the side wall 22 formed at one end of the base plate 21 and the mass 23.

As shown in Fig. 2, the side wall support member 22a and the side wall support are formed between the side wall 22 formed at one end of the base plate 21, the spring members 24a and 24b, and the dampers 25a and 25b. A connecting member 26 is fitted to the member 22a.

The side wall support member 22a is formed to protrude horizontally from the side wall 22, and has a hollow shape in which the connection member 26 is fitted. The sidewall support member 22a is formed with guide holes 22b for guiding the projections 26a of the connecting member 26, and coupling holes 22c are formed at both sides of the guide hole 22b. At one end of the connecting member 26 fitted to the side wall support member 22a, a projection 26a elastically supported by the spring 26b is formed and inserted into the guide hole 22b of the side wall support member 22a. The other end of the member 26 is coupled with the spring members 24a and 24b and the dampers 25a and 25b. Coupling protrusions 22d are formed on both sidewalls 22 formed at one end of the base plate 21, and the coupling protrusions 22d are coupled to the upper side walls 12 of the two racks 10. The groove 12a is formed and detachably coupled to the rack 10.

The rack-linked damping system of the present invention having such a configuration firstly has a structure in which two adjacent racks 10 are connected to each other when vibration occurs in the rack 10 due to an impact caused by a forklift or a transport vehicle. This vibration or shock is attenuated, and the shock and vibration are secondaryly suppressed by the displacement movement of the mass part 23 and the spring members 24a and 24b and the dampers 25a and 25b coupled thereto.

In addition, in the case of fine vibration, the projection 26a of the connecting member 26 is freely moved in the guide hole 22b of the side wall support member 22a, so that the vibration of the connection member does not perform the vibration control. The projection part 26a of (26) is pressed at one end of the guide hole 22b so that the projection part 26a is compressed toward the spring 26b, is separated from the guide hole 22b, and then coupled to the coupling hole 22c to vibrate control. It will perform the function. This gives the advantage that the vibration displacement level required for vibration control can be adjusted according to the characteristics of each rack 10.

Therefore, the rack-linked damping system according to the present invention has an advantage of improving the structural stability of the rack 10 itself by having a structure that interconnects two adjacent adjacent racks 10, as described above, such a structure The primary damping of the vibration generated due to the impact on the rack 10, etc. and the secondary part by the mass portion 23, the spring member (24a, 24b) and the dampers (25a, 25b) to suppress the shock and vibration This has the advantage of quickly damping shock and vibration.

Moreover, due to the structural characteristics of the rack 10 that are formed long in the longitudinal direction when an impact or vibration occurs in the rack 10, its vibration width varies along the longitudinal direction, and this vibration width is also the load of the article loaded on each shelf column. According to the present invention, each vibration control unit 20 is disposed on the upper side of each shelf column to correspond to the shelf column having a different vibration width, displacement of the mass 23 of each vibration control unit 20 coupled thereto The width is also corresponding to that has the advantage of suppressing the vibration more quickly and effectively. And, the system is installed between two racks 10, but may be formed over three racks 10 as another embodiment.

Next, the rack-linked damping system according to a second embodiment of the present invention will be described with reference to FIG. The rack-linked damping system according to the second embodiment of the present invention differs from the first embodiment in that the guide hole 22b and the coupling hole 22c are not formed in the sidewall support member 22a, and the sidewall support member 22a is not formed. That is, the movement limiting jaw 22f is formed to limit the movement of one end of the connecting member 26 to be fitted inside the.

In the second embodiment, a moving pad 26c coupled to the inside of the sidewall support member 22a and movably installed is formed at one end of the connection member 26, and the movable pad 26c is provided at the sidewall support member 22a. The movement limiting jaw 22f is formed to restrict the movement of the movement. Thus, the movement pad 26c of the connection member 26 moves between the one side surface 22e and the movement limiting jaw 22f inside the sidewall support member 22a. It is possibly installed.

In the second embodiment, the micro-vibration allows the movement pad 26c to move freely between the one side surface 22e of the side wall support member 22a and the movement limiting jaw 22f in the micro-vibration so as not to perform the vibration control function. When the vibration occurs, the movement pad 26c is supported on one side 22e or the movement limiting jaw 22f of the side wall support member 22a to perform the vibration control function. Therefore, the distance between one side 22e of the side wall support member 22a and the movement limiting jaw 22f in which the movement pad 26c moves inside the side wall support member 22a can be appropriately designed according to the allowable vibration standard. For example, in the case of setting a large vibration reference to perform the control function is formed by increasing the distance. One side 22e of the side wall support member 22a is provided with a spring 22g to mitigate the impact of the moving pad 26c.

Other constitutions and effects are the same as in the first embodiment, and detailed descriptions thereof are omitted here. However, in the first embodiment, the protrusions 26a of the connecting member 26 are coupled to the coupling holes 22c to control vibration. After performing the function it is necessary to press the projection (26a) again to the original position into the guide hole (22b), in the second embodiment there is an advantage that such an in-situ operation is unnecessary.

The present invention has been described above with reference to preferred embodiments, but the present invention is not limited thereto, and various modifications may be made by those skilled in the art without departing from the scope of the present invention as set forth in the claims below. There will be.

Description of the Related Art
10: rack 20: vibration control unit
21 base plate 22 side wall
22a: side wall support member 22b: guide hole
22c: coupling hole 22d: coupling protrusion
23: mass part 24a, 24b: spring member
25a, 25b: damper 26: connecting member
26a: protrusion

Claims (6)

A base plate disposed across two racks facing each other in a rack system comprising a plurality of racks having shelf for storing goods, and having both ends coupled to the top of each rack;
A mass portion movably installed on an upper surface of the base plate and having a predetermined mass;
A pair of spring members disposed on both sides of the mass portion on an upper surface of the base plate and installed between the side wall formed at one end of the base plate and the mass portion,
And a vibration control unit which is disposed on both sides of the mass portion on the upper surface of the base plate, and includes a vibration control unit including a side wall formed at one end of the base plate and a pair of dampers disposed between the mass portions. A rack-linked damping system for vibration control of lightweight frame structures for storage in which dogs are arranged side by side between two racks. The method of claim 1,
A side wall formed at one end of the base plate, and between the spring member and the damper, a side wall support member, and one end is fitted to the side wall support member and the other end is connected to the spring member and the damper, One end of the connecting member is formed with a projection that is elastically supported by a spring,
The side wall support member formed on the side wall is formed with a guide hole for moving the projection of the connection member is inserted, both sides of the guide hole rack-linked damping system for the vibration control of the lightweight frame structure for the distribution storage is formed a coupling hole . The method of claim 1,
Each mass portion of the plurality of vibration control unit rack-associated damping system for the vibration control of the light weight frame structure for storage having a different mass. The method of claim 1,
Coupling protrusions are formed on both sidewalls formed at one end of the base plate, and an upper side wall of the rack is provided with a coupling groove to which the coupling protrusion is coupled to control vibration of the lightweight frame structure for logistics storage that is detachably coupled to the rack. Rack-linked damping system The method of claim 1,
Rack-linked damping system for the vibration control of the light weight frame structure for logistics storage, the front and rear wheels are formed in the lower portion of the mass. The method of claim 1,
A side wall formed at one end of the base plate, and between the spring member and the damper is formed with a side wall support member, one end is fitted to the side wall support member and the other end is connected to the spring member and the damper,
One end of the connection member is provided with a moving pad fitted inside the sidewall support member, and the sidewall support member formed on the sidewall is provided with a movement limiting jaw that restricts the movement of the movement pad. Rack-linked damping system for the vibration control of the lightweight frame structure for distribution, characterized in that the movable side between the side of the support member and the movement limiting jaw.

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