JPH09188325A - Pallet made of synthetic resin foam - Google Patents

Abstract

PROBLEM TO BE SOLVED: To obtain a light-weight pallet made of a synthetic resin foam, capable of being manufactured at low cost, and having a bending strength which sufficiently withstands pratical use. SOLUTION: A pallet 1 made of a synthetic resin foam, preferably, an EPS or the like, is plane as a whole, and channels 2, 2 for inserting forks of a fork lift, etc., thereinto are formed on the rear face of the pallet 1 so as to extend from the side of one side face of the pallet to the side of the other side face thereof. Further, reinforcing materials 3a, 3b are disposed in a partly or entirely embedded state in a direction only which is orthogonal to the channels.

Description

Detailed Description of the Invention

[0001]

TECHNICAL FIELD The present invention relates to a pallet using a synthetic resin foam.

[0002]

2. Description of the Related Art Conventionally, wooden pallets have been mainly used as pallets used for loading and transporting products produced in factories or the like when they are stored or shipped. In recent years, synthetic resin pallets, especially synthetic resin foam pallets, are often used because of their lighter weight, easier handling, and hygiene compared to wooden pallets. It has become.

However, the pallet using such a synthetic resin foam has the above-mentioned advantages, but has a problem that the pallet is weaker in bending strength and the like than the wooden pallet. On the other hand, this kind of pallet is formed with an insertion hole or a groove for inserting a fork such as a forklift, and a load such as a load placed on the pallet uses the fork inserted in the insertion hole or the groove as a fulcrum. Although supported, if the center of gravity of the load is located outside the fork insertion part, which is the fulcrum, depending on the state of the load placed on the pallet, the amount of deflection at the end of the pallet tends to increase, and this deflection If it is too large, a load placed during transportation may slip or fall sideways.

To solve this deflection only by increasing the thickness of the synthetic resin foam constituting the pallet increases the amount of the synthetic resin foam used as a material and the accompanying increase in weight, and further, the storage space. It causes an increase and is not preferable. Therefore, in the conventional pallet structure made of synthetic resin foam, as shown in FIG. X, a hole for fork insertion is formed in the pallet so that relatively high strength against bending can be obtained even with the same thickness. Most of them were formed as through holes. A reinforcing core material made of a metal material or a low-foaming or non-foaming synthetic resin material around the through hole so that the strength is further increased and the synthetic resin foam, which is a raw material, is not damaged when the fork is inserted. Was arranged in the direction along the fork insertion hole (see Japanese Utility Model Publication No. 6-24343).

As another example, instead of arranging a reinforcing core material which is a separate member around the through hole, the portion corresponding to the through hole of the molded body is melt-pressed by heating the thermoplastic resin foam. It has also been proposed to solidify and reinforce (see Japanese Utility Model Laid-Open No. 5-13937). However, in order to integrally mold a synthetic resin foam-molded product having a hollow through hole with a mold, a mold having a complicated shape is required, resulting in a high cost. In order to simplify the molding die, members each having a shape that is divided into two parts on the surface passing through the hollow through hole are integrally molded, and the molded product is integrated by an appropriate means such as heat fusion. However, the cost is still high because two sets of molds are required and the work of joining them together is required.

[0006] As a pallet using a flat-plate synthetic resin foam molded by a molding die having a simple structure, an actual flat plate 6
Japanese Patent Laid-Open No. 76052 discloses a deck board in which a reinforcing material layer is provided on both surfaces of a synthetic resin foam plate, and a pallet in which legs are joined and integrated by adhesion or heat fusion to the reinforcing material layer surface on the back surface of the deck board. Has been done. With this pallet, the molding cost can be reduced, and the load can be shared by the reinforcing material layers arranged on both sides, so that the thickness of the deck board can be reduced, and the storage space can be saved.

[0007]

However, in the pallet described in Japanese Utility Model Laid-Open No. 6-76052, reinforcing materials are laminated on both sides of a flat synthetic resin foam plate by a method such as adhesion or heat fusion. Therefore, the laminated reinforcing material may be separated or separated from the synthetic resin foam plate due to an impact generated during the use or transportation of the pallet.
Further, in addition to the work of integrally laminating the reinforcing material, a work of separately joining the separately manufactured legs to the deck plate side is required, which makes it difficult to avoid a complicated manufacturing process and a high manufacturing cost. . Further, even if the synthetic resin foam plate can be made thin, the weight of the pallet cannot be reduced because it has the reinforcing material layer and the leg portions.

In view of the above situation, the present invention aims to obtain a lightweight pallet which has a reduced weight, a reduced manufacturing cost, and an efficient arrangement of a smaller number of reinforcing members to improve bending strength. To aim. Further, it is an object of the present invention to obtain a lightweight pallet in which the arranged reinforcing material does not peel off or fall off due to impact or the like.

[0009]

The present invention has been made as a result of extensive studies to achieve the above-mentioned object, and is a pallet made of a synthetic resin foam having a flat plate shape as a whole. A concave groove for inserting a fork such as a forklift is formed from one side surface side to the other side surface side, and the reinforcing material is embedded in a state in which a part or the whole is buried only in the direction orthogonal to the concave groove. Preferably, a plurality of lines are arranged.

When an eccentric load is generated on the pallet, the forks themselves effectively function as load supporting members on both side edges of the pallet in the fork insertion direction, so that there is almost no bending, and reinforcement against bending in this direction occurs. Can be virtually ignored. However, as described above, the non-negligible bending occurs at both side edges of the fork which are orthogonal to the inserting direction. Therefore, in the present invention, the reinforcing member is arranged only in the direction orthogonal to the groove for inserting the fork. As a result, it is possible to obtain a lightweight pallet having a bending strength that does not hinder practical use with a small number of reinforcing materials.

Further, since the pallet according to the present invention does not have a hollow through hole, the entire pallet can be easily integrally molded by using an ordinary molding die, and the manufacturing cost can be reduced. The attachment of the reinforcing material may be performed by press-fitting a separately manufactured reinforcing material after molding the synthetic resin foam, and after arranging the reinforcing material at a predetermined position in the molding die,
A resin material such as beads may be inserted into the mold to be integrally foam-molded. When arranging the reinforcing material in a state where a part of the reinforcing material is exposed in the groove, the load is supported by the fork via the exposed surface of the reinforcing material, and deformation and damage of the synthetic resin foam are avoided. It

The reinforcing material used may be any resin material, metal material, etc., but is the same material as the synthetic resin material used for the pallet body and has a lower expansion ratio than the expansion ratio of the pallet body or a non-foamed synthetic resin molding. Is a preferred embodiment. In the case of this aspect, the labor for separating and collecting and reusing each material at the time of discarding the pallet is greatly reduced. Further, the reinforcing material may be arranged in one step or in a plurality of steps in the thickness direction of the pallet.

As the resin that can be used for the synthetic resin foam plate,
A styrene resin, a polyolefin resin, or a mixture thereof can be used. The styrene-based resin is a polymer containing styrene-based vinyl monomers such as styrene, methylstyrene, and dimethylstyrene as a main constituent unit, and the expanded styrene-based resin sheet used in the present invention contains 50% by weight or more of the styrene-based monomer. Examples of the monomer that can be copolymerized with the styrene-based monomer include acrylic acid, methacrylic acid or their esters, acrylonitrile, methacrylonitrile, and maleic anhydride.

As the polyolefin resin, high density polyethylene, low density polyethylene, ethylene-vinyl acetate copolymer, ethylene-carboxylic acid ester copolymer,
Ethylene-carboxylic acid metal salt copolymer, crystalline propylene homopolymer, crystalline propylene-ethylene copolymer, crystalline propylene-ethylene diene terpolymer and the like can be mentioned. Among the above resins, it is particularly preferable to use a styrene resin from the viewpoint of its strength.

The expansion ratio of the synthetic resin foam is preferably about 5 to 50 times, and if the expansion ratio is 5 times or less, the lightness of the pallet is impaired. Further, when it exceeds 50 times, the load holding force per unit area becomes insufficient, and the foamed body is easily damaged by placing a load. Preferably a styrene resin is used,
The magnification is about 45.

When a resin material is used as the reinforcing material,
In addition to the above resins, polyester-based resins such as polyethylene terephthalate, nylon-based resins, and resins such as polycarbonates may be mentioned, but the resins are not particularly limited to these resins. A resin in which a styrene resin is used as the resin and the expansion ratio is 1 to 10 is particularly excellent in terms of lightness and strength. The cross-sectional shape and size of the reinforcing material, the number of pieces to be arranged, and the like are appropriately selected in consideration of the maximum mounting load expected on the pallet. Further, the reinforcing material may be made of a single material, or may be a stack of different materials or materials of the same kind.

[0017]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT A preferred embodiment of a pallet according to the present invention will be described below with reference to the drawings. FIG. 1 is a perspective view showing an embodiment of a pallet according to the present invention.
In this example, the pallet 1 is formed as an integral molded product of synthetic resin foam as a whole, and has a width of 1100 mm.
It has dimensions of length 1100 mm x thickness 140 mm.
Two concave grooves 2 having a depth of 70 mm are formed in parallel on the back surface from one side surface side to the other side surface side in the length direction. Further, at a position slightly inward from both end surfaces (end surfaces in the front-rear direction) on the opening side of the two recessed grooves 2, two upper and lower reinforcing members 3a and 3b are orthogonal to the recessed grooves 2. It is buried.

As shown, in this example, the reinforcing material 3
a and 3b are both flat plates having a rectangular cross section and have a width of 40 mm.
The length is 1100 mm and the thickness is 8 mm. As well shown in the front view of FIG. 2, the reinforcing material 3b located in the lower position
Are arranged so that the back surface side thereof is at the same position as the bottom surface of the concave groove 2 (upper side in FIG. 2), whereby the reinforcing material 3a is embedded in the synthetic resin foam with only that portion exposed. Has been done. The upper reinforcing material 3a is located directly above the lower reinforcing material 3b and is 10 mm from the surface of the pallet 1.
Is placed in a state where the whole is embedded in a synthetic resin foam.

In this example, EPS was used as the resin material for the pallet and the reinforcing material, and the expansion ratio was 30 times for the pallet body and 2.5 times for the reinforcing material. At the time of molding, the mold is clamped in a state where two reinforcing materials 3a and 3b are arranged at predetermined positions in the mold, and pre-expanded resin particles of EPS are supplied into the mold together with steam, and then foamed and integrally molded. (Hereinafter, this pallet is referred to as pallet A).

The same as the pallet A, except that only the upper reinforcing material 3a is arranged as a reinforcing material, which is integrally molded (hereinafter, this pallet is referred to as a pallet B). further,
Similar to pallet A and pallet B, a pallet body having a foaming ratio of 40 was molded (hereinafter, pallet C and pallet D). With respect to the pallets A to D according to the present invention molded as described above, the amount of deflection was measured as shown in FIG. For comparison, the amount of deflection was measured in the same manner for a pallet having the same shape and the same expansion ratio but no reinforcing material arranged (hereinafter, this pallet will be referred to as pallet ₃₀ and pallet _40).
).

As shown in FIG. 3, a length 1100 is placed on the floor.
mm wood x 150 mm wide x 200 mm high wooden timber 1
0, 11 are fixed, and one side y of the pallet is pressed to the above-mentioned timber 1
The pallet 1 was placed on the square members 10 and 11 so that the distance x to the one side of 0 was 200 mm. Next, a weight 15 was placed on the center of the pallet 1 and two weights W of 20 kg were placed on the weight 15 to prevent the pallet 1 from moving. In that state, a weight Wa of 20 kg was sequentially placed on the end of the pallet 1 on the side y side, and the average distance H to the pallet surface position on the side y side and the floor was measured as the amount of deflection.

FIG. 4 shows the experimental results of pallet A, pallet B and pallet ₃₀ which is a comparative example, and FIG. 5 shows the experimental results of pallet C, pallet D and pallet ₄₀ which is a comparative example. As shown in FIG. 4, a pallet made of a synthetic resin foam having a foaming ratio of 30 times and having no reinforcing material (pallet ₃₀ ) has reached a deflection of 15 mm under a load of about 250 kg. Although it cannot be said to be a satisfactory pallet, the pallet A according to the present invention has a deflection amount H of 9 mm or less even at a load of 360 kg, and the pallet B also has a deflection amount H of 13 mm or less at a load of 340 kg, which is sufficiently practical. It is shown to be a palette.

Further, as shown in FIG. 5, when the expansion ratio is 40 times, the amount of deflection H is higher than that of 30 times.
The size of the pallet is large, and the one without the reinforcing material (pallet ₄₀ ) reaches a deflection of 15 mm under a load of around 190 kg, which is not a pallet that is practically satisfactory. However, the pallet C according to the present invention has a deflection of up to 340 kg. The amount H is 11 mm or less, and even in the pallet D and the load of 300 kg, the amount of deflection H is still 15 mm or less, which indicates that the pallet can withstand practical use.

It should be noted that the shapes and specific dimensions relating to the pallet and the reinforcing material in the above description are merely examples showing preferred embodiments, and it is obvious that the present invention is not limited thereto. For example, although the reinforcing material is shown as being arranged at two locations near the side, it may be arranged such that it is further arranged near the central portion. Further, the position and depth of the concave groove may be appropriately changed according to the interval and shape of the fork to be inserted.

[0025]

Since the pallet made of synthetic resin foam according to the present invention has a flat plate shape as a whole and a concave groove on the back surface thereof, it can be easily integrally molded with a usual molding die and the manufacturing cost can be reduced. Does not soar. Further, as shown in the above experimental results, by only disposing the reinforcing material only in the direction orthogonal to the groove for inserting a fork such as a forklift, it is possible to obtain a bending strength sufficient for practical use,
From this point as well, the manufacturing is easy, the cost does not soar, and the weight can be reduced as a whole. Further, since the reinforcing material is substantially embedded in the synthetic resin foam, it does not separate due to impact or the like, and there is no inconvenience in use.

[Brief description of the drawings]

FIG. 1 is a perspective view showing an embodiment of a pallet made of synthetic resin foam according to the present invention.

FIG. 2 is a front view of the pallet shown in FIG.

FIG. 3 is a diagram illustrating a measurement state of a deflection amount.

FIG. 4 is a graph showing the results of a pallet deflection test.

FIG. 5 is a graph showing the results of a pallet deflection test.

[Explanation of symbols]

1 ... Pallet made of synthetic resin foam according to the present invention, 2 ... Recessed groove for inserting fork such as forklift, 3
a, 3b ... Reinforcing material

Claims (2)

[Claims] 1. A pallet made of a synthetic resin foam having a flat plate shape as a whole, wherein a recessed groove for inserting a fork such as a forklift is formed on a back surface thereof from one side surface side to the other side surface side. A pallet made of a synthetic resin foam, characterized in that the reinforcing material is arranged such that a part or all of the reinforcing material is embedded only in a direction orthogonal to the groove. 2. The reinforcing material is made of the same material as the synthetic resin used for the pallet body and is formed of a synthetic resin molded product having a lower expansion ratio than the expansion ratio of the pallet main body or a non-foaming synthetic resin. The synthetic resin foam pallet according to claim 1.