KR20250093934A - Pallet rack for logistics storage made of earthquake-resistant structural material - Google Patents

Abstract

The purpose of the present invention is to provide a pallet rack for logistics storage formed with earthquake-resistant structural material with enhanced safety performance by cutting and forming earthquake-resistant sheet piles to produce a steel rack that can be easily installed and removed.
The present invention comprises: a stabilizer fixedly installed to anchor bolts buried at a predetermined distance on the floor surface of a logistics warehouse; a rack post whose lower end is fixed to the stabilizer and which is installed to face each other at a predetermined distance in the vertical direction with respect to the floor surface of the logistics warehouse; a rack bracing installed to vertically or inclinedly connect rack posts which are close to each other and which face each other; a load beam installed to connect rack posts which are far apart from each other and which are connected to the rack bracing; and a tie beam installed with both ends fixed to the load beams which face each other so as to connect the load beams and which can place a pallet loaded with cargo on them; and is characterized in that the rack post, the rack bracing, the load beam, and the tie beam are formed by cutting and forming an earthquake-resistant sheet pile.

Description

Pallet rack for logistics storage made of earthquake-resistant structural material

The present invention relates to a pallet rack for logistics storage formed with earthquake-resistant structural material with enhanced safety performance, by manufacturing and using a steel rack that can be easily installed and removed by cutting and forming earthquake-resistant sheet piles.

In general, warehouse rack structures are designed to load or transport items in a small space, and more specifically, they are used to temporarily or long-term store all daily-use items such as various foods, beverages, clothing, home appliances, and miscellaneous goods mass-produced at factories or production sites.

In this regard, the following patent document discloses a pallet rack in which a plurality of intermediate upper vertical beams are provided between a plurality of outer vertical beams provided on the left and right sides respectively, extending downward a certain distance from a plurality of upper horizontal beams to form a space at the bottom, the lower portions of the intermediate upper vertical beams are connected to each other by a flat-plate-shaped pallet support member having a certain width in the horizontal direction, the plurality of intermediate upper vertical beams extend downward to 1/2 the height of the outer vertical beams, the pallet rack is formed in two stages, the pallet support member is provided as a unit in the horizontal direction on the inside of the outer vertical beams provided on the left and right sides respectively, and on the lower portions of the plurality of intermediate upper vertical beams, a plurality of through holes are formed at a certain interval in the flat-plate-shaped pallet support member, the plurality of intermediate upper vertical beams provided at the rearmost end are connected to each other by a horizontal cross beam, and a pallet support member is further provided on the horizontal cross beam, so that the pallet support member of each compartment is formed in a "ㄷ" shape overall, a plurality of rear vertical beams are further provided at the rear of the space portion through which a work vehicle can enter, and a vertical beam reinforcing member is further provided on the plurality of rear vertical beams. A pallet rack for loading goods is provided, characterized in that it allows a work vehicle to run freely in an open space on the ground formed at the bottom of a number of intermediate upper vertical beams, thereby allowing goods of various sizes to be stored and unloaded in the space on the ground inside the pallet rack.

However, currently, there is a need for a pallet rack tie beam that is different from the pallet support member of the patent document on which shelves loaded with various light and heavy objects are placed.

In addition, since tie beams were previously installed by welding them to the load beam, when additional light or heavy objects were loaded onto a shelf loaded with various light or heavy objects, tie beams had to be additionally welded and installed on the load beam.

Because of this, even if some of the light or heavy objects were moved to another location on the shelf loaded with various light or heavy objects, it was difficult to remove the tie beam installed on the load beam by welding.

Domestic patent registration number 10-1569312, pallet rack for loading goods.

The present invention has been made to solve the problems of the above-mentioned prior art, and the purpose of the present invention is to provide a pallet rack for logistics storage formed with earthquake-resistant structural material with enhanced safety performance by manufacturing and using a steel rack that can be easily installed and removed by cutting and forming an earthquake-resistant sheet pile.

In order to achieve the above object, the present invention comprises: a stabilizer fixedly installed to anchor bolts buried at a predetermined distance on the floor surface of a logistics warehouse; a rack post whose lower end is fixed to the stabilizer and which is installed to face each other at a predetermined distance in the vertical direction with respect to the floor surface of the logistics warehouse; a rack bracing installed to vertically or inclinedly connect rack posts that are close to each other and are connected to each other; a load beam installed to connect rack posts that are far apart from each other and to which the rack bracing is connected; and a tie beam installed with both ends fixed to the load beams that face each other so as to connect the load beams and on which a pallet loaded with cargo can be placed; and it is preferable that an earthquake-resistant sheet pile is cut and formed to form the rack post, the rack bracing, the load beam, and the tie beam.

The above rack post comprises: a post front portion formed by cutting and forming an earthquake-resistant sheet pile to have a predetermined length, and having a pair of first connecting holes formed at a predetermined interval along the longitudinal direction; a first post side surface portion formed by forming so as to be bent inwardly at a right angle at both ends of the post front portion, and having second connecting holes formed at a predetermined interval along the longitudinal direction; a post bend portion formed by forming so as to be bent inwardly at the ends of the first post side surface portion; a second post side surface portion formed by forming so as to be bent inwardly at the ends of the post bend portion parallel to the first post side surface portion, and having third connecting holes formed at a predetermined interval along the longitudinal direction; a post bend end portion formed by forming so as to be bent outward at the ends of the second post side surface portion; and a post front surface portion formed by forming so as to be bent inwardly at the center of the post front surface along the longitudinal direction. It is desirable that it be formed and made of a reinforcing part.

The above stabilizer is preferably formed of: a floor surface fixing plate having a horizontal plane so as to be installed in close contact with the floor surface of a water storage warehouse and having anchor fixing holes formed therein so as to be fixed to anchor bolts embedded in the floor surface of a logistics warehouse; a post fixing plate having a post fixing hole formed corresponding to a first joining hole formed on the front surface of the post so as to be able to fix the lower end of the front surface of the post constituting the rack post by being vertically bent at one side of the floor surface fixing plate to form a vertical plane; and a post support bending portion which is vertically bent upwards at a distance corresponding to both side surfaces of a second post constituting the rack post at a middle portion of the floor surface fixing plate to form a vertical plane and which can support the lower end of the both side surfaces of the second post.

The above rack bracing comprises: a bracing front portion formed by cutting and forming an earthquake-resistant sheet pile to have a predetermined length, and having bracing fixing holes formed at both ends thereof to be fixed to third connecting holes on the inside of second post side surfaces constituting the rack post; bracing upper and lower side portions formed by forming so as to be bent inwardly at a right angle from upper and lower ends of the bracing front portion; and bracing bent portions formed by forming so as to be bent inwardly at a right angle from the bracing upper and lower side portions; wherein a bracing reinforcing groove is formed by forming along the longitudinal direction of the bracing front portion; and it is preferable that the bracing reinforcing grooves are formed so as to have a predetermined gap therebetween.

It is preferable that the above load beam includes: a load beam body formed with earthquake-resistant structural steel to have a predetermined length, and a load beam bracket formed by combining two of the above load beam bodies to form a closed rectangular cross-section, and fixedly installed as an integral part at both ends of the closed rectangular cross-section to the front side of the post and both sides of the first post to form the rack post.

The above load beam body is formed by: a load beam front portion formed by cutting and forming an earthquake-resistant sheet pile to have a predetermined length; load beam upper and lower side portions formed by forming so as to be bent inwardly at right angles from upper and lower ends of the load beam front portion; and load beam bent portions formed by forming so as to be bent inwardly at right angles from the upper and lower side portions of the load beam; and it is preferable that a first load beam reinforcing groove is formed by forming along the longitudinal direction on the load beam front portion, wherein the first load beam reinforcing groove is formed to be located at the upper portion of the load beam front portion, and a second load beam reinforcing groove is formed by forming along the longitudinal direction on each of the load beam upper and lower side portions.

The above load beam bracket is: integrally fixedly installed at both ends of the load beam body, and comprises a first surface that is in close contact with both side surfaces of the first post constituting the rack post, and a second surface that is bent at a right angle from the first surface and is in close contact with the front surface of the lost constituting the rack post, wherein the first surface includes an extension surface formed to extend to the lower portion of the load beam body, and a load beam fixing hole that can be fixed to a second coupling hole formed on both sides of the first post is formed on the extension surface, and a fixing projection that can be fixed to the first coupling hole formed on the front surface of the post is protrudedly formed on the second surface, and a pin fixing hole that can be fixed to the first coupling hole using a fixing pin is preferably formed between the fixing projections.

It is preferable that the above tie beam includes: a tie beam body formed by cutting and forming an earthquake-resistant sheet pile to have a predetermined length, and a tie beam bracket integrally fixedly installed at both ends of the tie beam body and fixed to the load beam.

The above tie beam body is formed by: a tie beam upper surface portion formed by cutting and forming an earthquake-resistant sheet pile to have a predetermined length; a tie beam front and rear end portion formed by forming so as to be bent downward at a right angle from the front and rear end portions of the tie beam upper surface; and a tie beam bent portion formed by forming so as to be bent inward at a right angle from the tie beam front and rear end portions. It is preferable that a tie beam reinforcing groove portion be formed by forming along the longitudinal direction of the tie beam front and rear end portions.

The above tie beam bracket is preferably formed of a fitting member that is fixedly installed as an integral part at both ends of the tie beam body and is installed so as to be fitted and fixed in a manner that spans the load beam body.

In addition, the load beam: has a recessed portion formed along the longitudinal direction on the upper surface, and the tie beam: includes a tie beam body formed by forming earthquake-resistant structural steel to have a predetermined length, and a tie beam bracket integrally fixedly installed at both ends of the tie beam body and fitted to the load beam, and the tie beam bracket: comprises: a support end welded to the tie beam body and having an inner surface in close contact with one side surface of the load beam, a mounting end formed by protruding outwardly from the upper portion of the support end and having an inner surface in close contact with the upper surface of the load beam, and a catch end formed by bending downward from the mounting end and having an inner surface in close contact with one side surface of the opposite side of the load beam, so that an insertion space for the load beam to be inserted is formed between the support end, the mounting end, and the inner surface of the catch end, and a protruding groove portion is formed on the mounting end that protrudes downward along the longitudinal direction and protrudes inwardly of the insertion space, so that the protruding groove portion is preferably fitted into the recessed groove portion formed on the upper surface of the load beam.

According to the pallet rack for logistics storage formed with an earthquake-resistant structural material according to the present invention, the steel rack is manufactured by cutting and forming earthquake-resistant sheet piles, so that it can be easily assembled and installed. In other words, it has the effect of allowing the pallet rack to be assembled quickly.

In addition, the present invention has the effect of enhancing safety performance by cutting earthquake-resistant sheet piles and forming them to produce each part.

Figure 1 is a drawing showing a pallet rack for logistics storage formed with an earthquake-resistant structural material according to the present invention.
Figure 2 is a drawing showing a rack post provided in a pallet rack for logistics storage formed with an earthquake-resistant structural material according to the present invention.
Figure 3 is a drawing showing a stabilizer provided on a pallet rack for logistics storage formed with an earthquake-resistant structural material according to the present invention.
Fig. 4 is a drawing showing an example of a rack post as shown in Fig. 2 being installed on a stabilizer as shown in Fig. 3.
Figure 5 is a drawing showing a rack bracing provided on a pallet rack for logistics storage formed with an earthquake-resistant structural material according to the present invention.
Figure 6 is a drawing showing a load beam provided in a pallet rack for logistics storage formed with an earthquake-resistant structural material according to the present invention.
Figure 7 is a cross-sectional view along line II of Figure 6.
Figure 8 is a drawing showing a load beam body constituting the load beam shown in Figure 6.
Figure 9 is a drawing showing a load beam bracket constituting the load beam shown in Figure 6.
Figure 10 is a drawing of the load beam bracket shown in Figure 9 viewed from a different direction.
Figure 11 is a drawing showing an example of a fixing pin for attaching the load beam bracket of Figure 9 to the rack post.
Figure 12 is a drawing showing a tie beam provided in a pallet rack for logistics storage formed with an earthquake-resistant structural material according to the present invention.
Figure 13 is a drawing showing a tie beam body constituting the tie beam shown in Figure 12.
Figure 14 is a drawing showing a tie beam bracket constituting the tie beam shown in Figure 12.
Figure 15 is a drawing showing the state in which the load beam of Figure 6 and the tie beam of Figure 12 are separated.
Figure 16 is a drawing showing a state in which a tie beam is connected to a load beam as shown in Figure 15.
Fig. 17 is a drawing showing another embodiment of the display of Fig. 16,
Figure 18 is a drawing showing a state in which cargo is stacked on a pallet rack for logistics storage formed with an earthquake-resistant structural material according to the present invention.
Figure 19 is a drawing showing a state of loading cargo onto a pallet rack for logistics storage formed with an earthquake-resistant structural material according to the present invention.

Hereinafter, preferred embodiments of the present invention will be described in more detail with reference to the attached drawings.

Before describing the present invention, the following specific structural and functional descriptions are merely exemplified for the purpose of explaining embodiments according to the concept of the present invention, and the embodiments according to the concept of the present invention can be implemented in various forms and should not be construed as being limited to the embodiments described in this specification.

In addition, since the embodiments according to the concept of the present invention can have various changes and can have various forms, specific embodiments are illustrated in the drawings and described in detail in this specification. However, this is not intended to limit the embodiments according to the concept of the present invention to a specific disclosed form, but should be understood to include all modifications, equivalents, or substitutes included in the spirit and technical scope of the present invention.

In addition, the components of the present invention are to be interpreted in the same scope not only as direct contact or connection, but also as contact or connection through other components between components.

Attached Fig. 1 is a drawing showing a pallet rack for logistics storage formed with an earthquake-resistant structural material according to the present invention, Fig. 18 is a drawing showing a state in which cargo is stacked on a pallet rack for logistics storage formed with an earthquake-resistant structural material according to the present invention, and Fig. 19 is a drawing showing a state in which cargo is loaded on a pallet rack for logistics storage formed with an earthquake-resistant structural material according to the present invention.

As illustrated in these drawings, it is preferable that the pallet rack for logistics storage formed with earthquake-resistant structural material according to the present invention is configured to include a stabilizer (100), a rack post (200), a rack bracing (300), a load beam (400), and a tie beam (500).

The present invention is characterized in that the rack post (200), the rack bracing (300), the load beam (400), and the tie beam (500) are formed by cutting and forming an earthquake-resistant sheet pile.

The above stabilizer (100) has a structure that is fixedly installed on anchor bolts buried at a predetermined distance on the floor surface of a logistics warehouse.

The above rack posts (200) are fixed at their lower ends to the stabilizer (100) and are installed facing each other at a predetermined distance in the vertical direction with respect to the floor surface of the logistics warehouse. The rack bracing (300) is installed to vertically or slantwise connect rack posts (200) that are close to each other, and the load beam (400) is installed to connect rack posts (200) that are far from each other.

The above tie beam (500) is installed with both ends fitted and fixed to the load beams (400) facing each other to connect the load beams (400) and can place a pallet loaded with cargo on it. Each component is described in detail below.

Attached Figure 2 is a drawing showing a rack post provided in a pallet rack for logistics storage formed with an earthquake-resistant structural material according to the present invention.

The above rack post (200) is formed by cutting and forming an earthquake-resistant sheet pile to have a predetermined length, and includes a post front portion (210) in which a pair of first connecting holes (212) are formed at a predetermined interval along the longitudinal direction, a first post side surface portion (220) formed by forming so as to be bent inwardly at a right angle from the ends of both sides of the post front portion (210) and in which second connecting holes (222) are formed at a predetermined interval along the longitudinal direction, a post bend portion (230) formed by forming so as to be bent inwardly from the ends of the first post side surface portion (220), and a second post bend portion (230) formed by forming so as to be bent inwardly from the ends of the first post side surface portion (220) and in which third connecting holes (242) are formed at a predetermined interval along the longitudinal direction. It is preferable that the post side surface portions (240) and the post bend end portions (250) formed by forming so as to be bent outward from the ends of the second post side surface portions (240) and the post front surface portion (210) formed by forming so as to be bent inward along the length direction from the center are formed to form a reinforcing portion (260).

Accordingly, the above rack post (200) can be assembled and installed by cutting and forming an omega-shaped column using an earthquake-resistant sheet pile. At this time, the above rack post can be assembled and installed by fastening bolts and nuts without welding, and it is preferable to use a high-strength bolt.

Attached Fig. 3 is a drawing showing a stabilizer provided on a pallet rack for logistics storage formed with an earthquake-resistant structural material according to the present invention, and Fig. 4 is a drawing showing an example in which a rack post shown in Fig. 2 is installed on the stabilizer shown in Fig. 3.

The above stabilizer (100) is configured to form a horizontal plane so that it can be installed in close contact with the floor surface of a water storage warehouse, and has a floor surface fixing plate (110) formed with an anchor fixing hole (112) that can be fixed to an anchor bolt embedded in the floor surface of a logistics warehouse, a post fixing plate (120) formed with a post fixing hole (122) corresponding to a first joining hole (212) formed in the front surface of the post (210) so that the lower end of the front surface of the post (210) constituting the rack post (200) can be fixed, and a post support plate (110) that is vertically bent upward at a distance corresponding to the second post side surfaces (240) constituting the rack post (200) in the middle portion of the floor surface fixing plate (110) to form a vertical plane and can support the lower end of the second post side surfaces (240). It is preferable that it be formed of a bending portion (130).

Accordingly, it has a feature that can firmly fix the lower end of the rack post (200) by the stabilizer (100). That is, it is fixed to the front side (210) of the rack post (200) and supports the second post side surfaces (240) of the rack post (200), thereby maintaining a firm fixing force of the rack post (200).

Attached Figure 5 is a drawing showing a rack bracing provided on a pallet rack for logistics storage formed with an earthquake-resistant structural material according to the present invention.

The above rack bracing (300) is preferably formed by cutting and forming an earthquake-resistant sheet pile to have a predetermined length, and is formed with a bracing front portion (310) having bracing fixing holes (312) formed at both ends thereof that can be fixed to a third connecting hole (242) on the inside of the second post side surfaces (240) constituting the rack post (200), bracing upper and lower side surfaces (320) formed by forming so as to be bent inwardly at a right angle from the upper and lower ends of the bracing front portion (310), and bracing bending portions (330) formed by forming so as to be bent inwardly at a right angle from the bracing upper and lower side surfaces (320).

At this time, it is preferable to reinforce the front part of the bracing (310) by forming and forming a bracing reinforcing groove (340) along the longitudinal direction.

It is preferable that the above bracing reinforcement groove (340) be formed with a predetermined interval in the upper and lower directions.

The attached FIG. 6 is a drawing showing a load beam provided in a pallet rack for logistics storage formed with an earthquake-resistant structural material according to the present invention, FIG. 7 is a cross-sectional view taken along line I-I of FIG. 6, FIG. 8 is a drawing showing a load beam body constituting the load beam of FIG. 6, FIG. 9 is a drawing showing a load beam bracket constituting the load beam of FIG. 6, FIG. 10 is a drawing showing the load beam bracket of FIG. 9 as viewed from another direction, and FIG. 11 is a drawing showing an example of a fixing pin for connecting the load beam bracket of FIG. 9 to a rack post.

The above load beam (400) is preferably configured to include a load beam body (410) formed by cutting and forming an earthquake-resistant sheet pile to have a predetermined length, a load beam bracket (420) formed by combining two load beam bodies (410) to form a closed rectangular cross-section, and fixedly installed integrally at both ends of the closed rectangular cross-section to form the rack post (200) and fixed to the front side (210) of the post and the both side surfaces (220) of the first post.

The above load beam body (410) is preferably formed of a load beam front portion (412) formed by cutting and forming an earthquake-resistant sheet pile to have a predetermined length, load beam upper and lower side portions (414) formed by forming so as to be bent inwardly at a right angle from the upper and lower ends of the load beam front portion (412), and load beam bend portions (416) formed by forming so as to be bent inwardly at a right angle from the upper and lower side portions (414).

At this time, it is preferable to reinforce the front part (412) of the load beam by forming a first load beam reinforcing groove (413) along the longitudinal direction.

It is preferable that the first load beam reinforcing groove (413) is formed so as to be located at the upper portion of the front portion (412) of the load beam, and it is preferable that the second load beam reinforcing groove (415) is formed along the longitudinal direction on the upper and lower side portions (414) of the load beam.

The above load beam bracket (420) is preferably fixedly installed as an integral part at both ends of the load beam body (410), and is preferably composed of a first surface (422) that is in close contact with the first post side surfaces (220) that constitute the rack post (200), and a second surface (424) that is bent at a right angle from the first surface (422) and is in close contact with the lost front surface (210) that constitutes the rack post (200).

At this time, the first surface (422) includes an extension surface formed to extend to the lower portion of the load beam body (410), and a load beam fixing hole (423) that can be fixed to a second connecting hole (222) formed on both sides (220) of the first post is formed on the extension surface, and a fixing projection (425) that can be fixed to a first connecting hole (212) formed on the front surface (210) of the post is protrudingly formed on the second surface (424), and a pin fixing hole (426) that can be fixed to the first connecting hole (212) using a fixing pin (430) is preferably formed between the fixing projections (425).

The attached Fig. 12 is a drawing showing a tie beam provided in a pallet rack for logistics storage formed with an earthquake-resistant structural material according to the present invention, Fig. 13 is a drawing showing a tie beam body constituting the tie beam shown in Fig. 12, Fig. 14 is a drawing showing a tie beam bracket constituting the tie beam shown in Fig. 12, Fig. 15 is a drawing showing a state in which the load beam shown in Fig. 6 and the tie beam shown in Fig. 12 are separated, and Fig. 16 is a drawing showing a state in which the tie beam is connected to the load beam shown in Fig. 15.

It is preferable that the above tie beam (500) be configured to include a tie beam body (510) formed by cutting and forming an earthquake-resistant sheet pile to have a predetermined length, and a tie beam bracket (520) that is integrally fixedly installed at both ends of the tie beam body (510) and fixed to the load beam (400).

The above tie beam body (510) is preferably formed of a tie beam upper surface (512) formed by cutting and forming an earthquake-resistant sheet pile to have a predetermined length, a tie beam front and rear portions (514) formed by forming so as to be bent downward at a right angle from the front and rear ends of the tie beam upper surface (512), and a tie beam bent portion (516) formed by forming so as to be bent inward at a right angle from the tie beam front and rear portions (514).

At this time, it is preferable to reinforce the front and rear parts (512) of the tie beam by forming a tie beam reinforcing groove (518) along the longitudinal direction.

The above tie beam bracket (520) is preferably installed integrally at both ends of the tie beam body (510) and is formed of a fitting fixing part (521) that is installed so as to be fitted and fixed in a manner that spans the load beam body (510).

Attached Figure 17 is a drawing showing another embodiment of a tie beam.

FIG. 17 is another embodiment of a structure in which the load beam (400) and tie beam (500) are joined. The load beam (400) preferably has a recessed portion (402) formed along the longitudinal direction on the upper surface thereof, and the tie beam (500) comprises a tie beam body (510) formed by forming an earthquake-resistant structural steel material to have a predetermined length, and a tie beam bracket (520) integrally fixedly installed at both ends of the tie beam body (510) and fitted into the load beam.

At this time, it is preferable that the tie beam bracket (520) is configured to include a support member (522) welded to the tie beam body (510) and having an inner surface that is in close contact with one side of the load beam, a mounting member (524) that protrudes outwardly from the upper portion of the support member (522) and is mounted so that its inner surface is in close contact with the upper surface of the load beam (400), and a catch member (526) that is bent downward from the mounting member (524) and has its inner surface in close contact with one side of the opposite side of the load beam (400), so that an insertion space (528) in which the load beam (400) is fitted is formed between the inner surfaces of the support member (522), the mounting member (524), and the catch member (526).

In addition, it is preferable that the mounting member (524) is formed with a protruding groove portion (502) that protrudes downward along the length direction and protrudes into the inside of the fitting space, so that the protruding groove portion (502) is fitted into the recessed groove portion (402) formed on the upper surface of the load beam (400).

The present invention, configured in this manner, can be easily assembled and installed. That is, the assembly work of the pallet rack can be performed quickly.

In particular, the present invention enhances safety performance by cutting and forming earthquake-resistant sheet piles to produce each part. That is, the present invention can provide an earthquake-resistant pallet rack with enhanced safety performance by producing logistics storage rack parts using KS D 3864 building structure square (SNRT) or round (SRT) carbon steel pipe forming raw materials used as earthquake-resistant structural materials.

The technical task of the present invention is achieved by the technical configuration as described above, and although it has been described by limited examples and drawings, it is not limited thereto, and it is obvious that various modifications and variations are possible within the technical idea of the present invention and the equivalent scope of the patent claims to be described below by a person having ordinary knowledge in the technical field to which the present invention belongs.

100 - Stabilizer
200 - Rack Post
300 - Rack Bracing
400 - Load Beam
500 - Tie Beam

Claims (3)

Stabilizers that are fixedly installed on anchor bolts buried at a predetermined distance on the floor of a logistics warehouse;
Rack posts whose lower parts are fixed to the above stabilizers and which are installed facing each other at a predetermined distance in the vertical direction with respect to the floor of the logistics warehouse;
Rack bracing installed to connect rack posts that are close to each other vertically or inclined;
A load beam installed to connect the rack posts facing each other and having a distance between the rack bracings; and
Includes a tie beam, which is installed with both ends fixed to the load beams facing each other to connect the load beams and can place a pallet loaded with cargo on it;
A pallet rack for logistics storage formed with an earthquake-resistant structural material, characterized in that the rack post, the rack bracing, the load beam, and the tie beam are formed by cutting and forming earthquake-resistant sheet piles.
In the first paragraph,
The above rack posts:
A post front portion formed by cutting and forming an earthquake-resistant sheet pile to have a predetermined length and having a pair of first connecting holes formed on the left and right at regular intervals along the longitudinal direction, a first post side surface portion formed by forming so as to be bent inwardly at a right angle at both ends of the post front portion and having second connecting holes formed at regular intervals along the longitudinal direction, a post bent portion formed by forming so as to be bent inwardly at the ends of the first post side surface portion, a second post side surface portion formed by forming so as to be bent inwardly parallel to the first post side surface portion at the ends of the post bent portion and having third connecting holes formed at regular intervals along the longitudinal direction, a post bent end portion formed by forming so as to be bent outward at the ends of the second post side surface portion, and a reinforcing portion formed by forming so as to be bent inwardly at the center of the post front portion along the longitudinal direction. It is done,
The above stabilizer:
A floor fixing plate having a horizontal plane so that it can be installed in close contact with the floor surface of a water storage warehouse and having anchor fixing holes formed therein so that it can be fixed to anchor bolts embedded in the floor surface of a logistics warehouse, a post fixing plate that is vertically bent at one side of the floor fixing plate to form a vertical plane and has a post fixing hole formed corresponding to a first joining hole formed on the front side of the post so that the lower end of the front side of the post constituting the rack post can be fixed, and a post support bending portion that is vertically bent upward at a distance corresponding to both side surfaces of a second post constituting the rack post at a middle portion of the floor fixing plate to form a vertical plane and can support the lower end of the both side surfaces of the second post,
The above rack bracing is:
A bracing front portion formed by cutting and forming an earthquake-resistant sheet pile to have a predetermined length, and having a bracing fixing hole formed at both ends thereof, which can be fixed to a third connecting hole on the inside of the second post side surfaces constituting the rack post, a bracing upper and lower side portions formed by forming so as to be bent inwardly at a right angle from the upper and lower ends of the bracing front portion, and a bracing bend portion formed by forming so as to be bent inwardly at a right angle from the upper and lower side portions of the bracing, wherein a bracing reinforcing groove is formed by forming along the longitudinal direction of the bracing front portion, and the bracing reinforcing groove is formed so as to have a predetermined gap vertically,
The above load beam:
It includes a load beam body formed by cutting and forming an earthquake-resistant sheet pile to have a predetermined length, and a load beam bracket formed by combining two load beam bodies to form a closed rectangular cross-section, and fixedly installed as an integral part at both ends of the closed rectangular cross-section to the front side of the post forming the rack post and the side surfaces of the first post;
The above load beam body:
It consists of a front portion of a load beam formed by cutting and forming an earthquake-resistant sheet pile to have a predetermined length, upper and lower side portions of the load beam formed by forming so as to be bent inwardly at a right angle from the upper and lower ends of the front portion of the load beam, and a bent portion of the load beam formed by forming so as to be bent inwardly at a right angle from the upper and lower side portions of the load beam.
The front portion of the above load beam is formed by forming a first load beam reinforcing groove along the longitudinal direction, and the first load beam reinforcing groove is formed to be located at the upper portion of the front portion of the load beam, and the upper and lower side portions of the load beam are formed by forming a second load beam reinforcing groove along the longitudinal direction,
The above load beam bracket:
It is integrally fixedly installed at both ends of the above load beam body, and is composed of a first surface that is in close contact with both sides of the first post constituting the above rack post, and a second surface that is bent at a right angle from the first surface and is in close contact with the front surface of the lost constituting the above rack post.
The first surface includes an extension surface formed to extend to the lower portion of the load beam body, and a load beam fixing hole that can be fixed to a second coupling hole formed on both sides of the first post is formed on the extension surface, and a fixing projection that can be fixed to a first coupling hole formed on the front surface of the post is protrudingly formed on the second surface, and a pin fixing hole that can be fixed to the first coupling hole using a fixing pin is formed between the fixing projections.
The above tie beam:
It includes a tie beam body formed by cutting and forming an earthquake-resistant sheet pile to have a predetermined length, and a tie beam bracket integrally fixedly installed at both ends of the tie beam body and fixed to the load beam;
The above tie beam body:
It is composed of a tie beam upper surface formed by cutting and forming an earthquake-resistant sheet pile to have a predetermined length, a tie beam front and rear end portions formed by forming so as to be bent downward at a right angle from the front and rear end portions of the tie beam upper surface, and a tie beam bent portion formed by forming so as to be bent inward at a right angle from the front and rear end portions of the tie beam, wherein a tie beam reinforcing groove is formed by forming along the longitudinal direction of the tie beam front and rear end portions,
The above tie beam bracket:
A pallet rack for logistics storage formed of an earthquake-resistant structural material, characterized in that it is integrally fixedly installed at both ends of the tie beam body and is formed with a fitting fixing part that is installed so as to be fitted and fixed in a manner that spans the load beam body.
In the first paragraph,
The above load beam:
A recessed portion is formed along the longitudinal direction on the upper surface,
The above tie beam:
It includes a tie beam body formed by cutting and forming an earthquake-resistant sheet pile to have a predetermined length, and a tie beam bracket integrally fixedly installed at both ends of the tie beam body and fitted to the load beam.
The above tie beam bracket:
It is composed of a support member welded to the above tie beam body and having an inner surface that is in close contact with one side of the load beam, a mounting member that is formed to protrude outwardly from the upper portion of the support member and is mounted so that its inner surface is in close contact with the upper surface of the load beam, and a catch member that is formed to be bent downward from the mounting member and has its inner surface in close contact with one side of the opposite side of the load beam.
An insertion space is formed between the inner surface of the support member, the anchor member, and the hanging member, into which the load beam is inserted.
A pallet rack for logistics storage formed with an earthquake-resistant structural material, characterized in that the above-mentioned fixing member has a protruding groove formed that protrudes downward along the longitudinal direction and protrudes inwardly into the fitting space, and the protruding groove is fitted into the recessed groove formed on the upper surface of the load beam.