JP2002284161A - Connecting rack - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a nesting type rack which has high stability when it is stacked, lightweight and excellent durability. SOLUTION: When used as a rack, a connecting rack can be vertically stacked and when it is unused, two or more nesting type racks (X, X) in which another rack having the same structure can be housed inside part thereof are connected by one or more connecting floors (X1) in which connection supporting members 6-1, 6-2, 7-1 and 7-2 are provided having hooking tools, furthermore it can be stacked in a connected state.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a so-called nest, which can be stacked vertically when used as a rack (shelf) for storing articles, and can accommodate another rack of the same structure inside when not used. The present invention relates to a rack in which a nesting type rack is connected to the left and right or front and rear and left and right, and has a small number of members, has excellent stability when stacked, and can secure a large effective frontage.

[0002]

2. Description of the Related Art The safe and economical storage of various industrial products and commodities (hereinafter collectively referred to as "articles")
This is a major challenge for all industries. In recent years, nesting racks, which have been increasingly used, meet such demands for streamlining the storage of articles.

When nested racks are used as storage shelves, they can be stacked in multiple stages.
That is, when the racks themselves are moved or stored, they can be housed (nested) in a so-called nesting manner, which is extremely rational in that space can be saved and transportation costs can be reduced.

[0004] Nested racks have numerous inventions,
The invention is already known, but one of them is Jiko 61-6816.
There is a rack shown in Japanese Patent Publication No. In this, as shown in FIG. 21, a loading floor 1 on which articles are placed is provided on the upper surface of a rack. The rack having this structure has an advantage that articles can be placed not only on the loading floor 1 but also in a space thereunder (a floor surface of a warehouse or the like). Of course, as shown in FIGS. 7 and 17, it is also possible to stack in multiple stages, and when not in use, nesting can be performed by covering a rack having the same structure from above as shown in FIGS.

However, the rack shown in FIG. 21 has the following disadvantages.

(1) When a plurality of racks of this type are stacked up and down, the inverted V-shaped lower rail (4-9, 4-10) becomes the inverted V-shaped upper rail (1- 17,1-18). The stacking by fitting the upper rail and the lower rail has appropriate stability, but if a large vibration is applied due to an earthquake or the like, the fitting between the rails may be disengaged, and the upper rack may fall off or fall.

(2) The effective frontage of one rack is defined by the narrowest part (minimum interval) of the frontage. For this type of rack, the minimum distance is the inner distance between the lower rails (4-9, 4-10).
W _3. When the clear width distance between the right and left front pillars (2-9,2-10) and W _1, in order to lower rail (4-9,4-10) is present inside the left and right front pillars, W ₁ and W difference ₃ (W ₁ -W ₃₎ only valid frontage is narrowed. In addition, the load on the upper rack when stacked and the load on the loading floor when not stacked are transmitted eccentrically from the loading floor to the front column by the difference. Therefore, a bending moment is generated in the front column.

(3) The total height when a plurality of racks are stacked is an integral multiple of the height of one rack. That is,
When a large number of racks are used in conjunction with (2), a large space is required both in the horizontal direction (horizontal direction) and in the vertical direction (vertical direction).

The present inventors have previously proposed a new rack that eliminates the above-mentioned disadvantages (see Japanese Patent No. 2856696). The rack (hereinafter referred to as the rack of the prior invention)
As shown in FIG. 22, it has the following features.

[0010] The clear width interval _{W 1} of the left and right front pillars (2-11 and 2-12)
There greater than external dimensions spacing W ₂ of the pillar (3-9,3-10) after the left and right, inner size interval W _3-1 of the left and right lower longitudinal beams (4-11,4-12) before the right and left equal to clear width interval W ₁ of the pillars, that external dimensions width W ₄ of the loading floor 1 is smaller than the clear width interval W ₁ of the right and left front pillars (2-11 and 2-12), left and right front pillars ( The upper end of 2-11, 2-12) is lower than the lower surface of the loading floor 1, and V-shaped engaging tools (17-3, 17-4) are located just above these left and right front columns. -3, 12-4), and the V-shaped engaging tool (17-3, 17-4) immediately below the left and right front pillars (2-11, 2-12) The same V-shaped engaging tool (18
-5, 18-6).

The rack of the prior invention has not only the drawbacks (1) to (3) of the conventional rack but also the rails (1-17, 1-18 and 4- 9,4-10) is light because there is no, and when multiple units are stacked up and down, the load of the upper rack is reduced by the lower rack column via the engaging tools (17-3, 17-4). Since it is transmitted vertically to the rack, no bending moment is generated in the column, and the load bearing capacity is superior to that of the conventional rack. In addition, when stacked, the lower vertical beams of the upper rack sandwich the vertical beams of the lower rack loading floor from the side surfaces, and are so-called horse-riding types, which restrain left and right movement, so that the stability is excellent.

[0012]

The rack of the prior invention has been improved in terms of weight reduction and stability, but has a large number of members.
In particular, the structure of the engagement device is complicated.

An object of the present invention is to provide a connection rack which has high stability when stacked, has excellent earthquake resistance, has a small number of members, and can be connected to the front, rear, left and right.

[0014]

A rack according to the present invention is shown in FIG.
FIG. 14 shows a connection rack of the first invention connected to the left and right as illustrated in FIG. 14 and a connection rack of the second invention connected to the front, rear, left and right as illustrated in FIG. Each of these can be stacked up and down, and when not in use, a nesting rack capable of storing another rack of the same structure inside is connected by a connecting floor.

According to a first aspect of the present invention, two or more nesting racks (X, X) having the structure shown in FIG. 1 shown in (1) below are connected to the connecting floor (X) having the structure shown in FIG. It is a connection rack connected to the left and right as shown in FIG. 5 by one or more of ₁ ). This can be further stacked in a connected state as shown in FIG.

(1) The nesting rack X has the following configuration as shown in FIG.

The loading floor 1 is on the upper part, and four pillars (left and right front pillars 2-1 and 2-2 and left and right rear pillars 3-1 and 3-) supporting the loading floor 1 are provided.
2) having. Greater than external dimensions spacing W ₂ of clear width interval W _1-1 of left and right front pillars (21, 22) of the left and right rear pillars (3-1, 3-2), the left and right lower longitudinal beams (4-1, 4-2) Inner width interval W _1-2 is outer width W of loading floor
Greater than ₄ . Loading floor 1 consists of front and rear cross beams (1-1, 1-2) and intermediate cross beams (1-a,
1-b) and the upper surfaces of the intermediate longitudinal beams (1-c, 1-d) are on the same horizontal plane, and their lower surfaces are the left and right vertical beams (1-3, 1-d).
It is on the same horizontal plane as the upper surface of 4). The front cross beam (1-1) of the loading floor is between the lower surface of the lower longitudinal beam (4-1, 4-2) and the floor surface and between the lower surface of the lower cross beam 5 and the floor surface.
A space having a height higher than the height of the space is formed.

(2) The connecting bed (X ₁ ) has the following configuration as shown in FIG.

The loading floor 1 has front and rear horizontal beams (1-5, 1-6), left and right vertical beams (1-7, 1-8), and lattice-shaped intermediate beams (1-e, 1-f, 1-).
g, 1-h). On the outer surface of the vertical beam (1-7,1-8) near the front horizontal beam (1-5),
Arm (6-1) with hooks (6-12, 6-22) at the tip
1, 6-21) are provided. The rear cross beam (1-6) is longer than the front cross beam (1-5) and has a connecting support (7) with hooks (7-12, 7-22) at both ends.
-1,7-2).

According to a second aspect of the present invention, a nesting rack (X ₂ , X ₂ , X ₂ ) having a diagonal member having the structure shown in FIG.
Three or more are connection racks which are connected to the front, rear, left and right as shown in FIG. 15 by one or more connection floors (X ₃ ) having the structure shown in FIG. this is,
Further, as shown in FIG. 17, they can be stacked in a connected state.

The nesting rack (X
₂ ) has the following configuration as shown in FIG.

The loading floor 1 is located on the upper part, and four pillars (left and right front pillars (2-5, 2-6) and left and right rear pillars (3
-5,3-6)). Clear width interval W _1-1 of the previous column left is larger than the external dimensions spacing W ₂ of the dorsal column of the left and right, inner size interval of the lower longitudinal beam of the left and right W _1-2
Is larger than the outer width W _1-4 of the loading floor. The loading floor 1 has the upper surface of the front cross beam (1-9), the middle cross beam (1-a, 1-b) and the middle vertical beam (1-c, 1-d) on the same horizontal plane. Are on the same horizontal plane as the upper surfaces of the vertical beams (1-11, 1-12) and the rear horizontal beams (1-10). The front cross beam (1-9) of the loading floor is between the lower surface of the lower vertical beam (4-5, 4-6) and the floor surface and between the lower surface of the lower horizontal beam (5-2) and the floor surface. A space having a height higher than the height is formed. Diagonal members (8-1, 8-2) are inserted from the upper part of the left and right front columns (2-5, 2-6) to the lower cross beam (5-2).

The connecting bed (X ₃ ) which can be connected in three directions in the above (2) has the following structure as shown in FIG.

The loading floor 1 has front and rear horizontal beams (1-13, 1-14), left and right vertical beams (1-15, 1-16) and a grid-like intermediate beam (1-e, 1--1).
f, 1-g, 1-h). Arms (6-11,6-) with hooks (6-12,6-22) at the tip are on the outer surface of the vertical beams (1-15,1-16) near the front cross beam.
A connection support member (6-1, 6-2) constituted by 21) is provided. The rear cross beam (1-14) is longer than the front cross beam (1-13), and the connecting support parts (7-1,7-2) composed of hooks (7-21,7-22) at both ends. ), And an arm (6-31,6-41) having a hook (6-32,6-42) at the tip on the back.
(6-3, 6-4).

[0025]

BEST MODE FOR CARRYING OUT THE INVENTION Hereinafter, each connecting rack of the present invention will be described in detail with reference to preferred embodiments. A. Regarding the connecting rack of the first invention: FIG. 5 shows a first rack in which two nesting racks are laterally connected by a connecting floor.
FIG. 6 is a view showing a connection rack of the invention of FIG.

FIG. 1 is a perspective view showing an example of a nesting rack.

FIG. 3 is a perspective view showing an example of the connecting floor.

In the connecting rack of the first invention, two or more of the nesting racks (X, X) shown in FIG. 1 are connected to the left and right by the connecting floor (X ₁ ) shown in FIG. 3 as shown in FIG. It is a rack. The connection racks can be stacked in a connected state as shown in FIG.

A1. About the nesting rack: As shown in FIG. 1, the nesting rack (X) is composed of a loading floor 1 and columns (front columns 2-1 and 2-2 and rear columns 3-1 and 3-) extending downward from four corners thereof. 2)
And left and right lower vertical beams (4-1, 4-2) connecting the front and rear columns,
The lower cross beam 5 connecting the left and right rear columns (3-1, 3-2) is the main component.

The load floor 1, the external dimensions width W ₄ is narrower than the inner size interval W _1-2 of the left and right lower longitudinal beams (4-1, 4-2). Thus, the external dimensions spacing W ₂ of dorsal column (3-1, 3-2) left and right front pillars (2-1,
Smaller than the clear width interval _{W 1-1} 2-2). In the figure, it was equal to external dimensions width W ₄ of the loading floor external dimensions spacing W ₂ of dorsal column,
Do not mind the people of outside law interval W ₂ of the rear pillar is small. These relationships can be expressed as follows. The _{W 1-2> W 4 W 1-1>} W 2 satisfying these relationships, the rack 10
It can be nested in a nesting manner by placing it on a rack of the same structure as shown in FIG.

The nesting rack will be described in more detail with reference to an enlarged view.

FIGS. 2A and 2B are partially enlarged perspective views of the nesting rack. FIG. 2A is an upper portion of the front column shown as A in FIG. 1, FIG. 2B is a lower portion of the front column shown as B in FIG. FIG. 2C is a diagram showing the upper part of the rear pillar shown as C in FIG. 1 and FIG. Although this figure shows only one side of the rack, the rack is symmetrical.

The loading floor 1 of the rack (X) is shown in FIGS.
As shown in the figure, the front and rear cross beams (1-1,1-2) and middle cross beams (1-a, 1
-b) and the middle longitudinal beams (1-c, 1-d) are in the same horizontal plane, and the lower surfaces of both ends are left and right vertical beams (1-3,1-4)
Are connected to the same horizontal plane as the upper surface. The vertical beams (1-3, 1-4) on the loading floor have the front ends of the support members (9-1, 9-2) provided at the upper ends of the front columns (2-1, 2-2). Joined to the back,
The rear end is joined to the upper front of the left and right rear columns (3-1, 3-2).

At the corner formed by the back of the front cross beam (1-1) of the loading floor and the upper surface of the vertical beam (1-3, 1-4) of the loading floor, reinforcement and stacking of racks are performed. Guide members (10-1, 10-2) acting as guides are provided. Stoppers (11-1, 11-2) are provided on the rear surface of the rear cross beam (1-2). The stopper abuts the back surface of the lower cross beam of the upper rack when stacking the racks, and serves for positioning in the front-rear direction.

A support member (9-1, 9-2) is connected to the upper end of the front pillar (2-1, 2-2) as shown in FIGS. The left and right support members (9-1, 9-2) are connected to the front horizontal beam (1-1) of the loading floor on the inner upper surface in the longitudinal direction, and the vertical beams (1-3, 1-4) are connected, and a flat stopper (12-1, 12-2) is provided on the front surface.
Both ends of the front cross beam (1-1) are joined together including one end of the stopper at a position inside the position where the inner surface of the front column (2-1, 2-2) extends vertically to the upper surface of the support member. Have been.

As shown in FIGS. 1 and 2 (b), lower longitudinal beams (4-, 4) are provided at the lower ends of the front columns (2-1, 2-2).
1, 4-2) are connected with their lower surfaces being the same, and the mounting members (13-1, 13-2) are connected to their lower surfaces.

As shown in FIGS. 1 and 2 (c), the lower surfaces of both ends of the rear cross beam (1-2) of the loading floor are connected to the upper end of the rear pillar (3-1, 3-2). , Vertical beams on the loading floor in front (1-3,1-4)
Are combined. The vertical beams on the loading floor (1-3, 1-4)
May penetrate to the back of the rear pillar (3-1, 3-2).

As shown in FIG. 1 and FIG. 2 (d), the lower cross beam 5 supports the rear pillars (3-1, 3-2) on the upper surface, and the front side surfaces at both ends are left and right lower vertical beams ( 4-1, 4-2), and the mounting member (14-1, 14-2) is connected to the lower surface.

The mounting members (13-1, 13-2) of the front column and the mounting members (14-1, 14-2) of the rear column have the same height, and the rack is mounted on the floor. To secure the pressure receiving area. Further, a space portion is formed between the lower vertical beam and the lower horizontal beam and the floor surface to facilitate insertion of a fork of a forklift when stacking or nesting.

A2. Regarding the connecting floor (X ₁ ): The connecting floor (X ₁ ) has front cross beams (1-5), rear cross beams (1-6), and right and left vertical beams (1-7, 1-8) as shown in FIG. ), Middle cross beam (1-e, 1-
This is a loading floor configured in a lattice shape with the upper surfaces of f) and the intermediate longitudinal beams (1-g, 1-h) being on the same plane.

Connection support members (6-1, 6-2) are provided on the front outer side surfaces of the left and right vertical beams (1-7, 1-8), and the connection support members are provided at both ends of the rear cross beam (1-6). (7-1,7-2) are provided.

FIG. 4 is a partially enlarged perspective view of the connecting floor.
FIG. 4A is a view showing a state of attachment of a front connection support member shown as A in FIG. 3, and FIG. 4B is a view showing a rear connection support part shown as B in FIG. Since the connecting floor is symmetrical, only one side is shown in these figures.

Next, the connecting floor will be described in more detail with reference to FIGS.

The front connecting support members (6-1, 6-2) are shown in FIG.
And as shown in FIG. 4 (a), arms (6-11, 6-21) are provided on the side surfaces of the left and right vertical beams (1-7, 1-8), and the ends of the arms are hooks made of flat plates. Tools (6-12, 6-22) are attached. Spaces (6-13, 6-23) formed by the inner surface of the hook and the lower surface of the arm are spaces for hanging and connecting to the vertical beams on the loading floor of the nesting rack.

As shown in FIGS. 3 and 4 (b), the rear connecting support portions (7-1, 7-2) are formed by extending both ends of the rear cross beam (1-6). A hook (7-12, 7-22) made of a flat plate is attached to the tip, and a distance piece (7-14, 7-24) is attached to the back. The spaces (7-13, 7-23) formed by the inner surface of the hook and the lower surface of the arm are for hanging and connecting to the left and right vertical beams of the nesting rack. The distance pieces (7-14, 7-24) are in contact with the front side of the rear pillars (3-5, 3-6) of the nesting rack, and serve to restrict the positioning of the connecting floor and the backward movement. do.

A3. Regarding the first invention connecting rack in which two or more nesting racks are laterally connected by one or more connecting floors: A major feature of the first invention connecting rack is shown in FIG. 5 by adopting the above structure. In a structure that can be connected horizontally. Hereinafter, the structure will be described in detail.

FIG. 6 is an enlarged perspective view showing connecting portions at four corners of the connecting floor when the nesting racks are connected sideways.
(a) is a diagram showing a connecting portion on the front left side of the connecting floor shown as A in FIG. 5, (b) is a diagram showing a connecting portion also shown as B, (c) is a diagram showing a connecting portion shown as C, ( d) is a diagram illustrating a connecting portion indicated as D. FIG. In the figure, the dashed line indicates the connecting floor (X ₁ ), and the solid line indicates the nesting rack (X).

The connecting floor (X ₁ ) is hooked and connected to a vertical beam on one side of the loading floor of the left and right nesting racks (X). Are attached.

As shown in FIGS. 5, 6 (a) and 6 (b), the connecting portions on the front left and right of the connecting floor (X ₁ )
1,6-2) hooks (6-12,6-22) are hooked from above onto the inner surface of vertical beams (1-3,1-4) on the loading floor of the nesting rack (X), and the arm (6-11, 6-21) are mounted on the upper surface of the vertical beams (1-3, 1-4) and connected. In addition, the front cross beam (1-
5) is mounted on the upper surface of the support member (9-1, 9-2) of the telescopic rack. The guide members (10-1, 10-2) serve to position the arms (6-11, 6-21) of the connection support member at the leading end of the slope, and to restrict the forward movement.

As shown in FIGS. 5, 6 (c) and 6 (d), the connecting portions at the right and left rear portions of the connecting floor (X ₁ ) are connected to the connecting support provided on the extension of the rear cross beam (1-6). The hooks (7-12, 7-22) of the section (7-1, 7-2) are connected to the vertical beams (1-
3,1-4) is hooked from above, and the rear cross beam (1-6) is placed on the upper surface of the vertical beam (1-3,1-4) and connected. The distance pieces (7-14, 7-24) of the connecting floor abut against the rear beams (1-2) of the loading floor of the nesting rack, and serve to restrain backward movement of the connecting floor.

As shown in FIGS. 5 and 6, the connecting floor (X
₁ ) The front cross beam (1-5) is the stopper (1
2-1, 12-2), and the arm (6-11, 6-21) abuts on the tip of the slope of the guide member (10-1, 10-2). Also,
By distance pieces (7-14,7-24) abuts against the rear transverse beam (1-2), before moving direction of the connection floor (X ₁₎ it is restrained. Further, left and right movements are restricted by the hooks.

In the rack of the first invention, as shown in FIG. 5, two or more nesting racks are laterally connected to each other by one or more connecting floors, so that the stability is improved. The load is evenly applied to the left and right sides of the support member, which has the effect of reducing the bending stress generated in the front column. further,
Other racks can be stacked on top of the laterally connected racks.

A4. Regarding the stacking of the racks of the first invention connected in the lateral direction: A great feature of the connection rack of the first invention is that the above-described structure allows the racks to be connected horizontally and then stacked as shown in FIG. There is a structure that can be. Hereinafter, the structure will be described in detail.

FIG. 7 is a perspective view showing a state in which another rack is stacked on a connecting rack connected horizontally.

FIG. 8 is an enlarged perspective view showing the situation near the front column when another rack is stacked on the connecting rack connected horizontally, and FIGS. 8A and 8B show A in FIG. 7A and FIG. 7B show a state (a) and a state (b) just before stacking of the portion shown, and (c) and (d) show a state (c) and a state after stacking of the portion shown as B in FIG. 7. It is a figure showing (d).

FIG. 9 is an enlarged perspective view showing the situation near the rear pillar when another rack is stacked on a horizontally connected rack, and (a) and (b) are shown as C in FIG. A diagram showing a state (a) just before stacking of parts and a state (b) after stacking,
(c) and (d) are views showing a state (c) just before stacking and a state (d) after stacking of a portion shown as D in FIG. 7.

8 and 9, the dashed line indicates the lower connecting floor (X ₁ ), the solid line indicates the lower nesting rack (X), and the broken line indicates the stacked rack. The upper nesting rack (X). In the following description,
The “lower nesting rack” is simply called “lower rack”, and the “upper nesting rack” is simply called “upper rack”.

As shown in FIGS. 8A and 8C, the front pillars (2-3, 2-4) of the upper rack are stacked on the left and right mounting members (13-3, 13- space portion 4) is formed by a member of the lower connecting floor (X ₁₎ and a lower rack (X) (15-1 and 15-2)
8c, and further lowered and placed on the upper surface of the support member (9-1, 9-2) of the lower rack as shown in FIGS. 3,2-4) is the front pillar (2-
Stacked directly above 1,2-2).

The above-mentioned space (15-1, 15-2) is formed on the back side of the stopper (12-1, 12-2) of the lower rack (X) and the end face of the front cross beam (1-1) of the loading floor. , The side of the guide member (10-1, 10-2),
Arm of the connecting support member of the lower connecting floor (X _{1) (6-11,6-21)}
It is a space formed by the front side of the building and the side of the vertical beams (1-7, 1-8) on the connecting floor.

As shown in FIGS. 9 (a) and 9 (c), the rear pillars (3-3, 3-4) of the upper rack are stacked so that the lower side beam (5-1) of the upper rack has a lower rack. Stopper (11-1,11-2)
9 (b) and 9 (d), it is mounted on the upper surface of the horizontal beam (1-2) behind the loading floor of the lower rack.
At this time, the left and right mounting members of the upper rack (14-3, 14-4)
Is inserted into the corner space (16-1, 16-2) to restrain the upper rack from moving left, right, front and back.

The above-mentioned corner space (16-1, 16-2)
It is formed surrounded by the end face of the rear cross beam (1-2) of the loading floor of the lower rack, the inner surface of the distance piece (7-14,7-24) of the lower connecting floor, and the back surface of the rear cross beam (1-6). Space.

When the upper rack is stacked, the front column of the upper rack is placed on the upper surface of the support member of the lower rack via the mounting member, and the rear column is connected to the rear horizontal beam of the loading floor of the lower rack via the lower horizontal beam. Is placed. The lower part of the upper rack longitudinal beams (4-3 and 4-4) is above the arm (6-11,6-21) and Koyokohari (1-6) of the connecting support member of the lower connecting floor (X ₁₎ To position. Here, “located above” means that the load may be transmitted upon contact,
It means that it may have space.

The racks are connected in the horizontal direction, and can be connected in a stacked manner. In the stacking, since all the columns are placed directly on the columns, the load on the loading floor is transmitted vertically to all the columns, and the occurrence of bending stress can be reduced. Further, since the mounting member of the upper rack is inserted into the space formed in the upper part of the lower rack, it is possible to restrain the front and rear and left and right movements of the upper rack.

B. About the second invention connection rack: FIG.
FIG. 3 is a diagram showing an example of a connection rack in which three nesting racks having diagonal members are connected by one of connection floors that can be connected in three directions.

FIG. 11 is a perspective view showing an example of a nesting rack having diagonal members.

FIG. 13 is a perspective view showing an example of a connecting floor which can be connected in three directions.

As shown in FIG. 11, the second invention connecting rack alternately changes the front and rear directions of three or more nesting racks (X ₂ ) having a diagonal member between the front pillar and the rear pillar. The connecting floor (X
_The connection racks are connected in two rows as shown in FIG. 15 by ₃ ). The connection racks can be further stacked in a connected state as shown in FIG. In addition,
FIG. 15 shows an example in which only one nesting rack (X ₂ ) having diagonal members turned in the front and rear directions is mounted. X ₃ ) can be applied and linked.

B1. Regarding the nesting rack having diagonal members: As shown in FIG. 11, the nesting rack having diagonal members (X ₂ ) is composed of a loading floor 1 and columns (front columns 2-5, 2-) extending downward from four corners thereof. 6 and rear pillars 3-5, 3-6), left and right lower vertical beams (4-5, 4-6) connecting the front and rear pillars, and left and right rear pillars (3-5, 3-
The main structural members are the lower cross beam (5-2) connecting 6) and the diagonal members (8-1, 8-2) connecting the upper front column and lower rear column.
Hereinafter, in this specification, "nested racks having diagonal members"
Is simply called “rack with diagonal material”.

The rack with diagonal material (X₂) Loading floor 1
Outer width W₄Is the inner width of the lower vertical beams (4-5, 4-6)
_1-2 Narrower than). Therefore, the back pillar (3-5,3-6)
Outer spacing W of₂Is the inner width W of the left and right front columns (2-5, 2-6)
_1-1 Less than. In the figure, the outer width W of the loading floor₄ 
The posterior column spacing W₂, But the extraordinary spacing W of the rear pillar
₂It doesn't matter if is smaller. Express these relationships in equations
It is as follows. W_1-2> W₄ W_1-1> W₂ By satisfying these relationships, this diagonal rack
Can be put on a rack of the same structure as shown in Fig. 20
You can nest it in a nested way
Wear.

The rack with diagonal members will be described in more detail with reference to an enlarged view.

FIG. 12 is a partially enlarged perspective view of a rack with diagonal members, and FIG. 12 (a) is a view showing an upper part of a front column shown as A in FIG.
(b) is a view of FIG. (a) viewed from the back (the upper part of the front column shown as E in FIG. 15), (c) is a view showing the lower part of the front column shown as B in FIG. 11, (d) is a figure Diagram showing the upper part of the back pillar, shown as C at 11, (e)
FIG. 12 is a view showing the lower part of the rear pillar shown as D in FIG. These figures show only one side of the rack, which is symmetric.

As shown in FIG. 11, the loading floor 1 of the rack with diagonal material (X ₂ ) has a front cross beam (1-9) and an intermediate cross beam (1-a, 1).
-b) and the upper surfaces of the intermediate vertical beams (1-c, 1-d) are in the same horizontal plane, and the lower surfaces of both ends are connected to the upper surface of the rear horizontal beam (1-10) and the left and right vertical beams (1-11, It is connected to the same horizontal plane as the upper surface of 1-12).

The vertical beams (1-11, 1-12) of the loading floor are shown in FIGS.
As shown in 2 (a) and (b), the front end is the front pillar (2-5,2
-6) is connected to the back of the support members (9-3, 9-4) provided at the upper end of the rear pillars (3, 9-4) as shown in FIGS. 11 and 12 (d). -5,3-6). In addition, both ends of the rear cross beam (1-10) of the loading floor are joined to the upper inner surfaces of the left and right rear columns (3-5, 3-6).

The corners formed by the back surfaces of both ends of the front cross beam (1-9) of the loading floor and the upper surfaces of the vertical beams (1-11, 1-12) of the loading floor are shown in FIGS. As shown in (a) and (b), guide members (10-3, 10-4) having inclined surfaces that act as guides for reinforcing and stacking racks are provided. Also,
Diagonal members (8-1, 8-2) are connected to the lower surface of the guide member to increase the rigidity of the rack.

Each of the left and right support members (9-3, 9-4) is provided with an engaging member (17-1, 17-2) immediately above the front column, and next to the engaging member (17-1, 17-2). 1-9) are connected, and the vertical beams (1-111, 1-12) of the loading floor are connected to the inner back surface. The engaging member (17-1, 17-2) engages with the engaging member (18-1, 18-2) provided at the lower end of the front pillar of another rack when stacking racks, and Position and right / left movement of the object.

As shown in FIGS. 11 and 12 (c), the front pillar (2
-5, 2-6) has an engaging member (18-1, 17-2) which engages with an engaging member (17-1, 17-2) provided on an upper part of a front column of another rack.
18-2), and the lower vertical beam (4-5, 4-6) on the back
And the mounting members (13-5, 13-6) are connected.

As shown in FIGS. 11 and 12 (d), the left and right rear pillars (3-5, 3-6) have their upper ends located on the same horizontal plane as the upper surface of the loading floor, and have the loading floor on their side surfaces. The vertical beams (1-11, 1-12) and the rear horizontal beams (1-10) are connected.

As shown in FIG. 11 and FIG. 12 (e), the lower horizontal beam (5-2) has front left and right lower lateral beams (4-5, 4).
-6), and the lower surface has mounting members (14-5, 14-6) of the same height as the mounting members (13-5, 13-6) below the front column. .

As shown in FIG. 11, the lower longitudinal beams (4-5, 4-6) are provided with mounting members (13-5, 13-6) at the front and mounted at the rear. 14-5, 14-6), and a space is formed between the lower surface and the floor surface. In addition, since the placing members (14-5, 14-6) are provided on the lower surfaces of both ends of the lower horizontal beam (5-2), a space is formed between the lower horizontal beam and the floor surface. These spaces serve as spaces for inserting connecting arms of a connecting floor, which will be described later, and for inserting a fork of a forklift for stacking or nesting.

The features of this rack are shown in FIGS. 11 and 12 (b).
As shown in (1), diagonal members (8-1, 8-2) are provided from the lower surface of the guide member (10-3, 10-4) of the loading floor to the lower cross beam (5-2). The diagonal members serve to increase the rigidity of the rack and increase the stability when articles are placed. In addition, since this diagonal material is provided between the external method of the vertical beam (1-11,1-12) of the loading floor and the internal method of the lower vertical beam (4-5,4-6), Nesting can be performed as shown in FIG.
If these diagonal members are provided between the external method of the vertical beams on the loading floor and the internal method of the lower vertical beams, the support members (9-3, 9-
It may be provided from the back of 4) to the front or top of the lower cross beam (5-2).

B2. Regarding a connecting floor (X ₃ ) that can be connected in three directions: A connecting floor that can be connected in three directions (hereinafter referred to as a “three-way connecting floor (X ₃ )”) has a front cross beam (1- ₃ ) as shown in FIG. 13), rear horizontal beam (1-14), left and right vertical beams (1-15,1-1)
6), middle cross beam (1-e, 1-f) and middle vertical beam (1-g, 1-h)
Are loading floors formed in a lattice shape having the same upper surface as each other.

FIG. 14 is a partially enlarged perspective view of the three-way connecting floor, in which (a) is a partial view shown as A in FIG. 13, and (b) is a partial view shown as B in FIG.

As shown in FIGS. 13, 14 (a) and (b),
Direction connection floor (X₃) On the left and right vertical beams (1-15, 1-16)
Connection support members (6-1, 6-2) are provided on the outer side
The beam (1-14) has connecting support parts (7-1,7-2) at both ends and
The connection support members (6-3, 6-4) are provided on the back surface.
This three-way connecting floor (X₃) Is connected to the floor (X
₁), But with the following differences.

The connection support members (6-3, 6-4) are attached to the rear part of the rear cross beam (1-14). 11,6-22)
And the length of the rear cross beam (1-14) is longer.

The features of the three-way connecting floor (X ₃ ) will be described below because the connecting support members (6-3, 6-4) are attached to the back of the rear cross beam (1-14). Thus, the racks with diagonal members can be alternately connected by changing the front and rear directions, and can be stacked in that state.

B3. Regarding the second invention rack in which three or more racks with diagonal materials are connected in two horizontal rows by one or more three-way connecting floors: A major feature of the second invention rack is that the above structure makes the FIG. As shown in Fig. 7, racks with diagonal members can be connected in two horizontal rows by a three-way connecting floor.
Hereinafter, the structure will be described in detail.

FIG. 16 is a partially enlarged perspective view showing connecting portions at the four corners of the three-way connecting floor when the racks with diagonal members are connected in two horizontal rows. FIG. Figure showing the part,
(b) is a diagram showing a connecting portion also shown as B, (c) is a diagram showing a connecting portion shown as C, and (d) is a diagram showing a connecting portion shown as D. In the figure, the one-dot chain line indicates the three-way connecting floor (X ₃ ), and the solid line indicates the rack with diagonal material (X ₂ ).
It is. The three-way connecting floor is hooked and connected to a vertical beam on one side of the loading floor of the _two racks with diagonal material (X ₂ ). Are given.

As shown in FIGS. 15, 16 (a) and 16 (b), the front left and right connecting portions of the three-way connecting floor (X ₃ ) are connected to the connecting support members (6-1, 6-2). hooking member (the 6-12,6-22) hooked to the vertical beam (1-11,1-12) the loading floor of the diagonal members with the rack (X _2),
It is connected to the left and right diagonal racks (X ₂ , X ₂ ).
At this time, the front cross beam (1-13) of the three-way connecting floor (X ₃ )
It is placed on the upper surface of the support member (9-3,9-4) of the left and right slant members with the rack (X _2). The left and right guide members (10-3, 10-4) of the rack with diagonal material are connected to the arms (6
-11, 6-21) and the three-way connecting floor (X
₃ ) Restrict forward movement.

As shown in FIGS. 15, 16 (c) and 16 (d), the left and right connecting portions at the rear of the three-way connecting floor (X ₃ ) are connected to the rear cross beams (1-1).
The hooks (7-12, 7-22) provided on the extension of 4) are hooked on the side of the vertical beams (1-11, 1-12) on the loading floor of the rack with diagonal material, and the distance pieces (7 -14, 7-24) against the front of the rear columns (3-5, 3-6) of the rack with diagonal material,
It is placed on the upper surface of the vertical beam and connected. The connecting support member which is provided on the back of the crossbeam (1-14) after the three-way connecting floor (X ₃₎ (6-3 and 6-4), the front and rear faces by changing mounting the diagonal member with rack After the loading floor of (X ₂ ), it is hung on the cross beam (1-10) to connect the rack with diagonal members (X ₂ ).

As described above, the three-way connecting floors can be connected in two rows by alternately connecting three or more racks with diagonal materials by changing the front and rear directions. In addition, the load on the loading floor is evenly applied to the left and right front columns via the support members, and the bending stress generated in the front columns can be reduced. Further, other racks can be stacked on racks connected in two horizontal rows. B4. Regarding the stacking of the second invention connecting racks connected in two horizontal rows: A great feature of the connecting racks of the second invention is that, after being connected in two horizontal rows as shown in FIG. Figure
It has a stackable structure as shown in FIG.
Hereinafter, the structure will be described in detail.

FIG. 17 is a perspective view showing a state where another rack row is stacked on the connecting racks connected in two horizontal rows.

FIG. 18 is an enlarged perspective view showing a situation where the front pillars of another rack are stacked on the connecting racks connected in two horizontal rows, and (a) and (b) are A in FIG. 17A and 17B show the state immediately before stacking of the part shown as (b) and the state after stacking, and (c) and (d) show the state immediately before stacking of the part shown as B in FIG. 17 (c) and the state after stacking. It is a figure showing a state (d).

FIGS. 19A and 19B are enlarged perspective views showing the situation when the rear pillars of the other two racks are stacked on the racks connected in two horizontal rows. FIGS. FIG. 17 shows a state (a) immediately before stacking of a part shown as C and a state (b) after stacking, and (c) and (d) show a state (c) just before stacking of a part shown as D in FIG. 17 and after stacking It is a figure which shows the state (d) of FIG. In (a) and (c) of FIG. 19, the stacking of the racks is performed by stacking on the rack placed on the front side and then on the rack placed on the rear side. Is shown at a position above the upper rack.

18 and 19, the one-dot chain line shows the lower three-way connecting floor (X ₃ ), the solid line shows the lower rack with diagonal material (X ₂ ), and the broken line shows it. This is a stacked upper diagonal rack (X ₂ ). The reference numerals used in FIG. 11 indicate the lower racks.

The front pillars (2-7, 2-8) of the rack with upper diagonal
As shown in FIGS. 18A and 18C, the engagement members (18-3, 18-
4) is inserted from above into the engaging members (17-1, 17-2) of the rack with the lower diagonal material, and the respective engaging members are engaged as shown in FIGS. 18 (b) and (d). Stacked ,. At the same time, the mounting member of the upper diagonal member with the rack (13-7,13-8) includes a space portion formed between the lower diagonal members with the rack (X ₂₎ and the lower three-way connecting floor (X ₃₎ (15-3, 15-4) is inserted from above.

The space portions (15-3, 15-4) are provided with the engaging members (17-1, 17-2) and the guide members (10-3, 10-2) of the rack with lower oblique material.
-4), it is formed by each side of the arm (6-11,6-21) under three longitudinal beams (1-15,1-16 direction connecting the floor (X ₃₎₎ and the connection support member.

As shown in FIGS. 19 (a) and (c), the rear pillars (3-7, 3-8) of the rack with the upper slant are stacked at the rear of the rack with the upper slant. The lower cross beam (3-5) so that it is perpendicular to the rear pillars (3-5, 3-6) of the rack with lower diagonals (3-5, 3-6). ) And the lower cross beam (3-5) as shown in Fig. 19 (b) and (d).
Are placed on the upper surface of the rear pillars (3-5, 3-6) and stacked. At the same time, the mounting member (14-
7,14-8) are inserted into the corner-shaped spaces (16-3, 16-4) formed by the rack with lower oblique material and the lower three-way connecting floor.

As shown in FIGS. 19 (a) and 19 (c), the racks with upper diagonal members are stacked at the rear columns (3-7, 3-8) of the rack with upper diagonal members. Rear pillar of rack with diagonal material (3-5,3
The lower cross beam (3-5) is lowered to the upper surface of the rear column (3-5, 3-6) of the rack with lower diagonal back so that it is perpendicular to -6).
As shown in 9 (b) and (d), the lower cross beam (3-5) is placed on the upper surface of the rear pillars (3-5, 3-6) and stacked. At the same time, the mounting member of the rack with the upper oblique material at the rear (14-7, 14-8)
Is inserted into a corner-shaped space (not shown) with the front mounting member in contact with the back surface.

The corner-shaped spaces (16-3, 16-4) are provided on the outer slopes of the rear pillars (3-5, 3-6) of the rack with lower diagonal material and the lower three-way connecting floor (X). ₃ ) It is formed by the inner slope of the distance piece (7-14, 7-24) and the back of the rear beam (1-14).

Lower three-way connecting floor when stacked (X ₃ )
Arm (6-11, 6-21) and rear beam (1-1)
4) is located below the lower longitudinal beams (4-7, 4-8) of the rack with upper diagonal members.

The racks of the second invention can be connected in two horizontal rows, and can be further stacked and connected. The stacking is performed by connecting the upper and lower engaging members and placing the lower cross beam on the upper surface of the rear pillar. Thereby, all the columns are stacked directly on top of each other, and the columns can be reduced in bending stress due to the loaded load. Further, since the placing members are provided below both ends of the lower vertical beam and the lower horizontal beam, a space is provided between the lower surface of the lower vertical beam and the floor surface and between the lower surface of the lower horizontal beam and the floor surface. Are formed to facilitate insertion of a forklift fork when stacking or nesting racks. Further, since these mounting portions are inserted into the space formed by the rack with the lower diagonal material and the lower three-way connecting floor, the upper rack can be restrained from moving forward, backward, left and right, and can be stabilized.

[0102]

The rack of the present invention has the following advantages.

Advantage 1 (reduction of the number of members) In the first invention connecting rack, two or more nesting racks are connected by one or more connecting floors, so that four columns are reduced. The second invention connecting rack can reduce the number of members because three or more nesting racks having diagonal members can be alternately turned back and forth and placed on one or more three-way connecting floors in two horizontal rows. And the area of the storage can be saved.

Advantage 2 (Stability at the time of stacking) When stacking racks, FIGS.
As shown in the above, the mounting members (13-3, 13-4, 14-
3,14-4 and 13-7,13-8,14-7,14-8) formed in the upper part of the lower rack (15-1 to 15-4 and 16-1 to 16-4) Is inserted into. This restricts the movement of the upper rack,
Much more stable against vibration. Further, since the diagonal member is inserted into the second invention rack, the rigidity of the rack can be increased.

Advantage 3 (Rationalization of Load Distribution) When the racks of the present invention are stacked, as is clear from FIGS. 7 and 17, the load of the upper rack is transmitted perpendicularly to the columns of the lower rack, and the bending moment is applied to each column. Does not work. In addition, the loading floor is connected to the front pillar via the support member, so that the load on the loading floor is evenly applied to the front pillar, and the bending stress generated in the front pillar can be reduced.

As described above, the connecting rack of the present invention has been frequently demanded recently in order to improve stability when stacking racks, for example, to prepare for an unexpected situation such as an earthquake. It is.

The present invention is an invention having extremely large industrial applicability that contributes to rationalization of article storage and improvement of safety.

[Brief description of the drawings]

FIG. 1 is a perspective view showing an example of a nesting rack.

FIG. 2 is a partially enlarged perspective view of a nesting rack, and FIG.
1 is the upper part of the front pillar shown as A in FIG. 1, (b) is the lower part of the front pillar shown as B in FIG. 1, (c) is the upper part of the rear pillar shown as C in FIG.
(d) is a diagram showing the lower portion of the rear pillar shown as D in FIG. 1.

FIG. 3 is a perspective view showing an example of a connecting floor.

FIG. 4 is a partially enlarged perspective view of a connecting floor, and FIG.
FIG. 4B is a view showing a rear connecting portion shown as B in FIG.

FIG. 5 is a view showing a connection rack of the first invention in which two nesting racks are connected in a lateral direction by a connection floor.

6A and 6B are enlarged perspective views showing connecting portions at four corners of a connecting floor of a connecting rack; FIG. 6A is a diagram showing a connecting portion on the front left side of the connecting floor shown as A in FIG. 5; FIG. 3C is a diagram showing a connecting portion shown as C, FIG. 3C is a diagram showing a connecting portion shown as C, and FIG.

FIG. 7 is a perspective view showing a state in which another rack is stacked on a connection rack connected horizontally.

FIG. 8 is an enlarged perspective view showing a situation where a front pillar of another rack is stacked on a connection rack connected sideways;
(a) and (b) are diagrams showing the state (a) just before stacking and the state (b) after stacking of the portion shown as A in FIG. 7, (c) and
(d) is the state immediately before stacking of the portion shown as B in FIG. 7 (c)
It is a figure which shows the state (d) after stacking.

FIG. 9 is an enlarged perspective view showing a situation where a rear pillar of another rack is stacked on a connecting rack connected sideways;
(a) and (b) are diagrams showing a state (a) just before stacking and a state (b) after stacking of a portion shown as C in FIG. 7, (c) and
(d) is the state immediately before stacking of the portion shown as D in FIG. 7 (c)
It is a figure which shows the state (d) after stacking.

FIG. 10 is a perspective view showing a nesting state of the nesting rack shown in FIG. 1;

FIG. 11 is a perspective view showing an example of a nesting rack having diagonal members.

12 is a partially enlarged perspective view of a nesting rack having diagonal members, where (a) is a view showing an upper part of a front column shown as A in FIG. 11, and (b) is a view of FIG. (The upper part of the front pillar shown as E in FIG. 15), (c) shows the lower part of the front pillar shown as B in FIG. 11, and (d) shows the upper part of the rear pillar shown as C in FIG. ,
FIG. 12 (e) is a view showing the lower part of the rear pillar shown as D in FIG.

FIG. 13 is a perspective view showing an example of a three-way connecting floor.

FIG. 14 is a partially enlarged perspective view of the three-way connecting floor, and (a).
13 is a partial view shown as A in FIG. 13, and (b) is a partial view shown as B in FIG.

FIG. 15 is a diagram illustrating an example of a connection rack in which three nesting racks having diagonal members are connected by one of three-way connection floors.

16 is a partially enlarged perspective view showing connecting portions at four corners of a three-way connecting floor when nesting racks having diagonal members are connected in two horizontal rows, and (a) is a connecting portion shown as A in FIG. FIG. 3B is a diagram showing a connecting portion also shown as B, FIG. 3C is a diagram showing a connecting portion shown as C, and FIG.

FIG. 17 is a perspective view showing a state where another rack row is stacked on the connection racks connected in two horizontal rows.

18 is an enlarged perspective view showing a situation where a front pillar of another rack is stacked on a connecting rack connected in two horizontal rows, and (a) and (b) are portions shown as A in FIG. 17; FIGS. 17A and 17B show a state (a) just before stacking and a state (b) after stacking, and (c) and (d) show a state immediately before stacking of a portion shown as B in FIG.
It is a figure which shows (c) and the state (d) after stacking.

FIG. 19 is an enlarged perspective view showing a situation where the rear pillars of the other two racks are stacked on the connecting racks connected in two horizontal rows, and (a) and (b) are C in FIG. 17; A diagram showing a state (a) just before stacking of the part shown and a state (b) after stacking,
(c) and (d) are views showing a state (c) just before stacking and a state (d) after stacking of a portion indicated by D in FIG.

20 is a perspective view showing a nesting state of the nesting rack having diagonal members shown in FIG. 11;

FIG. 21 is a perspective view showing an example of a conventional nesting rack.

FIG. 22 is a perspective view showing an example of a conventional nesting rack made of Λ-shaped steel.

[Explanation of symbols]

1． Loading floor 2. Front pillar 3. Back pillar 4. Lower vertical beam 5． Lower cross beam 6. Connection support member 7. Connection support 8. Diagonal material 9. Supporting members 10. Guide members 11,12. Stoppers 13,14. Mounting member 15,16. Space parts 17,18. Engaging member X. Nested rack X ₁ . Consolidated floor X _2. Telescopic rack X ₃ having a diagonal member. Three-way connecting floor

 ──────────────────────────────────────────────────続 き Continued on the front page F term (reference) 3B060 BA02 BB03 BC01 BD01 BD02 BD03 BE04 BF03 BG07 3B067 AB02 DA01 EA04 3E063 AA02 CA04 CA05 CA06 CB04 CC04 CD09 FF04 3F022 FF01 MM01 MM02 MM11 MM51

Claims (2)

[Claims] 1. A linked rack wherein two or more nested racks shown in (1) below are connected by one or more connecting floors shown in (2) below. (1) When used as a rack, it can be stacked up and down, and when not in use, can house another rack of the same structure inside. The loading floor is supported by four pillars (left and right front pillars and left and right rear pillars). The inner spacing between the left and right front pillars is larger than the outer spacing between the left and right rear pillars, and the lower left and right sides The inner spacing of the beams is greater than the outer width of the loading floor.The loading floor is composed of front and rear cross beams and grid-like intermediate beams, their upper surfaces are on the same horizontal plane, and their lower surfaces are Be on the same horizontal plane as the upper surface of the left and right vertical beams. The height between the lower surface of the lower vertical beam and the floor surface and between the lower surface of the lower horizontal beam and the floor surface is greater than the height of the front horizontal beam of the loading floor. Space is formed. (2) A connecting floor characterized by the following. The loading floor is composed of front and rear cross beams, left and right vertical beams, and a grid-like intermediate beam, and a connecting support member including an arm having a hook at a tip portion on an outer surface near the front horizontal beam of the vertical beams. The rear cross beam is configured to be longer than the front cross beam, and both ends thereof are provided with connection support portions having hooks. 2. A linked rack wherein three or more nested racks shown in (1) below are connected by one or more connecting floors which can be connected in three directions as shown in (2) below. (1) When used as a rack, it can be stacked up and down, and when not in use, can house another rack of the same structure inside. The loading floor is supported by four pillars (left and right front pillars and left and right rear pillars). The inner spacing of the left and right front pillars is larger than the outer spacing of the left and right rear pillars, and the lower left and right sides The inner spacing of the beams is larger than the outer width of the loading floor.The loading floor is such that the upper surface of each of the front horizontal beams and the grid-like intermediate beams is on the same horizontal plane, and the lower surfaces are the left and right vertical beams and the rear horizontal beams. A space with a height greater than the height of the horizontal beam in front of the loading floor is formed between the lower surface of the lower vertical beam and the floor surface and between the lower surface of the lower horizontal beam and the floor surface. Diagonal material is inserted from the upper part of the front pillar to the lower cross beam; The loading floor is composed of front and rear cross beams, left and right vertical beams, and a grid-like intermediate beam. On the outer surface near the front horizontal beam of the vertical beams, a connecting support composed of an arm with a hook at the tip is provided. The member is provided, the rear cross beam is longer than the front cross beam, hooks are provided at both ends thereof, and a connection support member comprising an arm having a hook at the front end portion is provided on the back surface. That