JP2012236719A - Anti-skid implement for fork - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an anti-skid implement for a fork which can stably retain a pallet to a fork even if a pallet formed of steel or plastic is used.SOLUTION: The anti-skid implement 21 for a fork has such a structure that a magnet sheet 31 and an urethane rubber sheet 41 are stacked on each other and are bonded with an adhesive. The magnet sheet 31 and the urethane rubber sheet 41 have, for example, lengths L of 1, 000 mm, widths W of 100 mm and thicknesses of 2 mm. The urethane rubber sheet 41 preferably has a hardness of 90 Hs and a tensile strength of 32 MPa. As the adhesive, a solvent-free resilient adhesive which is an epoxy type adhesive and has certain resilience after curing is used.

Description

  The present invention relates to an anti-skid tool for a fork attached to a fork of a forklift.

A forklift is provided with a fork that can move up and down in front of a vehicle body. The fork is inserted into a pallet on which a transported object is placed and lifted upward to transport the transported object integrally with the pallet.
Many of these pallets are made of wood, but in recent years, the use of lightweight and reusable steel and plastic pallets is increasing year by year.

Japanese Utility Model Publication 1-180498

By the way, iron is used for the fork because of the strength required for it.
However, when a steel or plastic pallet is transported with such a steel fork, the frictional force between the fork and the pallet cannot be obtained sufficiently, and the pallet slips on the fork when the vehicle is stopped. There is a possibility.

The present invention has been made in view of such circumstances, and an object of the present invention is to provide an anti-slip for a fork that enables the pallet to be stably held on the fork even when a steel or plastic pallet is used. It is in providing tools.
Another object of the present invention is to provide an anti-skid tool for a fork that can be easily attached to and detached from the fork and has high wear resistance.

  The inventor chooses a material that has a non-slip effect on plastic pallets in addition to wood, and uses a magnet that can be easily attached to and detached from the fork, and adheres the magnet and the anti-slip part stably. The above problems were solved by selecting the agent.

In order to solve the above-described problems of the prior art and achieve the above-described object, the anti-skid device for forks of the present invention is an anti-slip material for forks attached to a fork made of a ferromagnetic material of a forklift. And a magnet that is directly attached to and fixed by a magnetic force in a detachable manner on the loading surface of the fork, and an anti-slip portion that is fixed to the magnet via an adhesive and formed of urethane rubber.
In the anti-skid tool for a fork according to the present invention, the magnet portion is detachably fixed to the fork of the forklift. And a slip prevention part is inserted and conveyed in the pallet on which the load was mounted.
Since the non-slip portion is urethane rubber, it generates a frictional force that exceeds a predetermined level with a steel or plastic pallet, and the pallet is stably held by the anti-slip portion.

Preferably, the urethane rubber of the anti-slip device for forks of the present invention has a hardness of 70 to 100 Hs.
Suitably, the said urethane rubber of the anti-slip | skid tool for forks of this invention is a polyether type | system | group.
Preferably, the magnet of the anti-slip device for forks of the present invention is a ferrite type, and the adhesive is an epoxy resin type, and has elasticity capable of absorbing expansion and contraction of the magnet with the magnet. It has no solvent.
Preferably, the thickness of the thin urethane rubber of the anti-slip device for forks of the present invention is about 1 to about 3 mm, and the thickness of the magnet is about 1 to about 3 mm.

According to the present invention, even when a pallet made of steel or plastic is used, it is possible to provide a non-slip tool for a fork that makes it possible to hold the pallet on the fork in a stable state.
Furthermore, according to the present invention, it is possible to provide a fork anti-skid device that is easy to attach to and detach from the fork and has high wear resistance.

FIG. 1 is an external view of a forklift according to an embodiment of the present invention. FIG. 2 is a view for explaining the structure of the anti-skid tool for fork according to the embodiment of the present invention. FIG. 3 is an external view of the forklift shown in FIG. 1 with a fork slipper attached to the fork.

Hereinafter, a forklift according to an embodiment of the present invention and an anti-skid fork used therein will be described.
FIG. 1 is an external view of a forklift 1 according to an embodiment of the present invention.
FIG. 2 is a view for explaining the structure of the anti-skid tool 11 for fork according to the embodiment of the present invention.
FIG. 3 is an external view of the forklift 1 shown in FIG. 1 with a fork slip stopper 11 attached to the fork.

As shown in FIG. 1, in the forklift 1, a pair of inner masts 9 are arranged on a pair of outer masts 8 so as to be movable up and down.
A pair of forks 13 is attached to a lift bracket that can be moved up and down along the inner mast 9.
The forklift 1 is provided with a tilt cylinder for tilting the masts 8 and 9.
A lift cylinder for raising and lowering the inner mast 9 and the lift bracket is provided. A backrest 11 is also provided.

In the forklift 1, when the load is transported to a predetermined position, the operator operates the operation unit of the forklift 1 to insert the fork 13 into the pallet on which the load is placed.
Then, the tilt cylinder is driven to reduce and the masts 8 and 9 are tilted to the forklift 1 side. Further, the lift cylinder is driven to extend to lift the load, and the lifted load is conveyed to a predetermined place.

FIG. 2 is a view for explaining a fork antiskid 21 fixed to the fork 13 of the forklift 1 shown in FIG.
2A is a front view, and FIG. 2B is a side view.
As shown in FIG. 2 (A), the anti-skid tool 21 for fork has a longitudinal length L of 1000 mm, a width W of 100 mm, and a thickness of 4 mm, for example.
The size of the anti-slip device 21 for fork is defined so that the entire region is located inside the loading surface of the fork 5 or an area of the same size.
The anti-skid tool 21 for fork has a structure in which a magnet sheet 31 and a urethane rubber sheet 41 are overlapped and joined with an adhesive.
Here, the magnet sheet 31 is an example of the magnet of the present invention, and the urethane rubber sheet 41 is an example of the anti-slip portion of the present invention.

  For example, the magnet sheet 31 and the urethane rubber sheet 41 have a length L of 1000 mm, a width W of 100 mm, and a thickness of 2 mm, respectively.

  As the magnet sheet 31, for example, an isotropic sheet having an attractive force of 6.86 kPa or more and a surface magnetic flux density of 53 or more is used.

Thus, the urethane rubber sheet 41 can be attached to and detached from the fork 5 by using the magnet sheet 31. The fork 5 can be mounted simply by placing the anti-skid tool 21 on the nail, and can be easily removed by tapping from the end.
There are two types of magnet sheets 31: isotropic ferrite magnet sheets and anisotropic ferrite magnet sheets.
The anti-skid tool 21 for fork has a two-layer structure of a urethane rubber layer (front surface) and a magnet layer (back surface). The thickness of the anti-slip tool 21 for the fork is set so that the mat does not get caught (5 mm or less) when inserting the pawl of the fork lift into the pallet so as not to disturb the handling of the load. For example, urethane rubber is 2 to 3 mm and magnet 2 mm.
Moreover, the anti-slip | skid tool 21 for forks can be made into a shape without a sense of incongruity for an operator after mounting | wearing by making it flat shape without a groove | channel and an unevenness | corrugation, and thickness being 5 mm or less.

Hereinafter, the reason why the urethane rubber sheet 41 is employed will be described.
The load sliding test was performed using the following (1) to (3) as the moving side and the following (a), (b), (c), and (d) as the pressing side.
(1)
Steel pallet (2) made of the same material (steel SCM435) as the forklift claws
Resin palette (3)
Assumes a wooden pallet hits.

(A) Steel (b) Urethane rubber sheet (c) Synthetic rubber sheet (d) Felt sheet

The results are shown in Table 1 below.
In Table 1, μs represents a static friction coefficient, μk represents a dynamic friction coefficient, μs takes a peak value immediately after the start of the test, and μk is an average value in a stable section. n1, n2, and n3 each indicate the number of times.

  As shown in Table 1 above, it was found that the frictional force of urethane rubber was very high, and several times as much frictional force as that of felt or synthetic rubber was exhibited.

In addition, several types of “rubbers” that are expected to have an anti-slip effect were picked up, and their resistance to slipping (frictional force) and durability (tensile strength, tear strength, and abrasion) were verified based on the data shown in Table 2 below. did.
In addition, since rubber has a grade (hardness 30 to 110) in hardness, all of them were compared with those having a hardness Hs of about 70.

From the data in Table 2 above, it can be seen that urethane rubber is superior in terms of durability and resistance to slipping.
Urethane rubber is a little inferior in tear strength to butadiene rubber, but has excellent wear resistance.
Since there are types of urethane rubbers, it was verified to what degree of hardness (general hardness, 30 to 110 exists).

In the range of hardness 30 to 110, urethane rubber was tied to the surface of the forklift claw, a load of about 500 kg was placed on a metal pallet, and about 30 sudden brakes / starts were repeated every day for a month. As shown in Table 3 below, when the hardness was less than 70, the surface of the urethane rubber was scratched at a plurality of locations. On the other hand, when the hardness was 70 or more, neither abrasion nor tearing was observed. Therefore, “urethane rubber having a hardness of 70 or more” was adopted.
Moreover, as a result of conducting a test from the viewpoint of frictional force, as shown in Table 3 below, it was found that when the hardness exceeded 100, the frictional force dropped sharply.
In addition, the frictional force shown in Table 3 below is an example of the frictional force with the polypropylene pallet.
In Table 3 below, the unit of hardness is Hs, the number of scratches is the number of scratches within 5 cm × 5 cm, and the unit of friction force (static friction coefficient) is μs.

For this reason, urethane rubber having a hardness of 70 to 100 Hs is adopted. Here, it was found that a hardness of 90 Hs is optimal.
In other words, the hardness in this range was selected because of the balance between durability and frictional force. That is, if the hardness is less than 70, scratches and irregularities are likely to be generated on the surface, and if the hardness exceeds 100 Hs, the frictional force is lowered and the anti-slip effect is reduced. This range is derived from experiments. It was confirmed that 90Hs was optimum from the viewpoint of both durability and frictional force.

Since the urethane rubber itself is a material that easily repels water, the compatibility of adhesives is limited. In general, it is known that adhesives that are compatible with urethane rubber systems are epoxy resin adhesives, but there is no special adhesive for bonding urethane rubber and ferrite magnets in a plate shape. So developed independently.
It has been found that the specifications required for the adhesive are as follows in order to make urethane rubber and a ferrite magnet stick together in a plate shape and make it difficult to peel even if a heavy object is handled many times.

(1) It is an epoxy resin-based adhesive that is compatible with urethane rubber because urethane rubber is easy to play the adhesive.
(2) Since the elasticity of the urethane rubber and the magnet are different from each other, it is necessary to have “elasticity” that allows the adhesive layer to expand and contract to some extent so that it can withstand even when a large load is applied.
(3) If a solvent is contained in the adhesive, it will react with the components of the urethane rubber, and even if the adhesive force is sufficient, the product itself will bend and bend. It needs to be an agent.
Therefore, from the viewpoints of usage and adhesive strength, the most suitable adhesive to be used in this product is “epoxy adhesive and solvent-free elastic adhesive with a certain degree of elasticity after curing”. .

The anti-skid tool 21 for forks is manufactured as follows.
That is, a thin plate-like magnet plate having a thickness of 2 mm is prepared, and this is cut into a length L = 1000 mm and a width W = 100 mm to form the magnet sheet 31.
A thin plate-like urethane rubber having a thickness of 2 mm is prepared and cut into a length L = 1000 mm and a width W = 100 mm to form a urethane rubber sheet 41.

  Then, for example, an adhesive is applied to the entire surface of the magnet sheet 31 and the magnet sheet 31 and the urethane rubber sheet 41 are bonded together. Thereby, the anti-skid tool 21 for forks is obtained.

Hereinafter, a method for attaching the fork slip stopper 21 to the fork 13 of the forklift 1 will be described.
The magnet sheet 31 side of the forklift 1 is brought close to the fork 5 of the forklift 1. At this time, since the fork 5 is made of iron, the magnet sheet 31 is strongly attracted to the fork 5 by a magnetic force, and the magnet sheet 31 is bonded and fixed to the loading surface of the fork 5.

The forklift 1 has a fork 13 in which the anti-skid tool 21 is fixed to the pallet on which the load is loaded by operating the operation unit of the fork lift 1 while the fork anti-skid tool 21 is fixed to the fork 13. Insert.
Then, the tilt cylinder is driven to reduce and the masts 8 and 9 are tilted to the forklift 1 side. Further, the lift cylinder is driven to extend to lift the load, and the lifted load is conveyed to a predetermined place.
At this time, the urethane rubber sheet 41 of the anti-slip tool 21 for fork is joined to the pallet. The urethane rubber sheet 41 generates a sufficient frictional force for stable conveyance even if the pallet is made of steel or plastic. Therefore, even when the forklift 1 stops, the pallet does not slip and become unstable.

  Further, when the load is transported by a wooden pallet, the operator applies a force against the magnetic force to separate the magnetic sheet 31 of the fork slip stopper 21 from the fork 13 and attach the fork slip stopper 21. The wooden pallet is conveyed by the fork 13 which is not used.

As described above, by attaching the fork anti-skid tool 21 to the fork 13 of the forklift 1, it is effective that the pallet slides on the fork 13 even when transporting using a steel or plastic pallet. Can be suppressed.
Further, since the fork slip stopper 21 can be detachably attached to the fork 13 by the magnetic force of the magnet sheet 31, the pallet slides on the fork 13 even when transporting using a wooden pallet. There is no.
Moreover, since the anti-slip tool 21 for forks has a simple structure in which the magnet sheet 31 and the urethane rubber sheet 41 are bonded together with an adhesive, the manufacturing cost can be reduced.
In addition, unlike a ready-made product, which has irregularities and protrusions on the contact part with the pallet, it has a flat shape and is excellent in wear resistance and workability.

The present invention is not limited to the embodiment described above.
That is, those skilled in the art may make various modifications, combinations, subcombinations, and alternatives regarding the components of the above-described embodiments within the technical scope of the present invention or an equivalent scope thereof.
For example, in the above-described embodiment, as illustrated in FIG. 3, the case where the fork anti-skid tool 21 is attached to substantially the entire area of the loading surface of the fork 13 is illustrated. The anti-skid tool 21 for fork may be attached.
Moreover, the size of the anti-skid tool 21 described above is an example, and can be appropriately changed according to the size of the fork 13 or the like.

  The present invention is applicable to a forklift.

DESCRIPTION OF SYMBOLS 1 ... Forklift 8 ... Outer mast 9 ... Inner mast 13 ... Fork 21 ... Anti-slip tool 31 for fork ... Magnet sheet 41 ... Urethane rubber sheet

Claims (2)

A fork anti-skid device attached to a fork made of ferromagnetic material of a forklift,
A magnet that is directly attached and fixed by magnetic force in a detachable manner on the loading surface of the fork;
An anti-skid tool for a fork comprising: an anti-slip portion fixed to the magnet via an adhesive. The anti-slip portion is formed of urethane rubber,
The magnet has a planar thin plate shape whose entire region is located inside the loading surface,
The anti-skid tool for a fork according to claim 1, wherein the anti-slip portion has the same planar shape as the magnet plate, and has a thin plate shape that is attached to the magnet plate via an adhesive.