JPH0223654B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention uses a cushion effect to reduce the impact force when a person falls, to prevent a serious accident, and to prevent loss of walking ability and mobility under normal conditions. The present invention relates to shock-absorbing flooring materials.

BACKGROUND ART Conventionally, flooring materials such as cushion floors, soft rubber tiles, ordinary rubber tiles, and artificial turf have been laid on building floors, sports fields, and the like to cushion the impact of falls. Therefore, it is essential for such a flooring material to have, in addition to the above-mentioned shock-absorbing function, at least a function that allows sufficient walking and maneuverability. However, the above two functions are in a contradictory relationship. If priority is given to the shock-absorbing function, the hardness of the floor material will be lost and the functions of walking and mobility will be reduced, and in the opposite case, the hardness of the floor material will become too high and the shock-buffering function will deteriorate. There was a problem that functionality deteriorated. For this reason, in the past, priority was given to the functions of walkability and maneuverability, at the expense of the shock-absorbing function.

For reference, we measured the impact buffering function of each of the conventional flooring materials mentioned above using a human head model (weighing 3.85 kg). The results below were as follows. In other words, as shown in Fig. 1, the cushion floor test pieces A, B, and C are 113 to 162G;
Test pieces D, E, F of soft rubber tiles with a thickness of 20 mm
is 70 to 95G, rubber tile test pieces H and J with a thickness of around 10 mm are 165 to 172G, and artificial grass test piece K is 109G.
It was hot. Note that the unit G is a unit of acceleration in all cases. From these test results, it is clear that the above-mentioned conventional flooring materials have insufficient impact impact functions because they give priority to the functions of walkability and mobility.

In view of the above-mentioned drawbacks of conventional flooring materials, the present invention has been developed to improve and eliminate them.A surface material is attached to a base material made of a sponge material such as rubber sponge or polyethylene sponge, and the hardness and thickness of the base material are improved. By limiting the number of materials, the purpose is to provide a seed bed material that harmoniously combines a shock-absorbing function and a function that allows sufficient walking and maneuverability.

The configuration of the present invention will be described below with reference to the drawings based on an embodiment in which tiles are sized 200 to 600 mm on a side.

FIG. 2 is a longitudinal sectional view showing a tile 1 as a flooring material according to the present invention. As shown in the figure, this tile 1 includes a base material 2 made of a sponge material such as rubber, polyethylene, vinyl chloride, urethane, etc.
A sheet-like surface material 3 made of rubber, vinyl chloride, or the like is attached using rubber glue, acrylic adhesive, or the like. The surface material 3 is used to improve durability, abrasion resistance, weather resistance, and anti-slip properties, and does not need to contribute significantly to the direct impact buffering function. Therefore,
A thickness of 2 to 8 mm is sufficient. however,
Regarding walking and mobility functions, because humans come into direct contact with it, it is necessary to treat the surface to make it sufficiently rough and to have an anti-slip effect.

The base material 2 is preferably a rubber or polyethylene sponge in terms of rigidity, durability, etc. Therefore, it is necessary that the base material 2 has both a shock-absorbing function and a walking and maneuverability function. Therefore, in the present invention, the intended purpose is achieved by limiting the hardness and thickness that most affect both of the above functions. The suitable hardness range is 35 to 75 as measured by a C type spring type hardness tester specified in Japanese Industrial Standard K-6301, and the thickness range is 10 to 40 mm.
is appropriate. The reason for limiting the thickness is that if it is less than 10 mm, the desired shock-absorbing effect cannot be achieved due to the elasticity of the sponge material itself, and if it exceeds 40 mm, it may become too soft depending on the hardness of the sponge material, making it difficult to walk. This is because there are problems with ease of movement and movement, and it becomes too thick, making construction work difficult. The reason for limiting the hardness is that the measured value of hardness is
If the hardness is less than 35, it becomes too soft as a flooring material and becomes difficult to walk or exercise on.
This is because if it exceeds 75, the impact when a person falls becomes too large, which is dangerous, and the existing problems cannot be improved in any way. Moreover, the present invention harmonizes the contradictory requirements of ease of walking and movement and impact buffering effect by organically combining the limited hardness range and the measured thickness range. However, if either the hardness or the thickness deviates from the above-mentioned limited range, it is impossible to satisfy these requirements.

By the way, the size of tile 1 in the above example is
Although one side was set to be within 200 to 600 mm, this was done in consideration of ease of work during construction and ease of transportation, and there is no need to limit it within the above range.

Next, a test was conducted in which the impact buffering function was investigated by changing the material, hardness, and thickness of the base material 2 in two forms: the case of only the base material 2, and the case of the tile 1 with the surface material 3 attached to the base material 2. Explain the results.
The test results were obtained by creating a human head model weighing 3.85 kg, as in the case of the conventional product shown in Figure 1.
This was dropped from a height at which the impact velocity was 2 m/sec, and the acceleration generated in the head model at the time of collision was measured. In any case, the surface material 3 is
It is a rubber sheet with a hardness of 70 and a thickness of 3 mm.

Figure 3 shows the test results when a rubber sponge with a hardness of 38 is used as the material for the base material 2 and its thickness is varied, and Figure 4 shows the test results when a rubber sponge with a hardness of 70 is used as the material for the base material 2. These are the test results when the thickness was changed. In addition, Figure 5 shows the material of base material 2, which has a hardness of 46 (apparent density 0.075 g/cm ³ ).
Figure 6 shows the test results when using a polyethylene sponge with a hardness of 66 (apparent density: 0.125 g/cm ³ ) and changing its thickness. It is.

From these test results, it was found that tile 1 with only base material 2 and tile 1 with base material 2 and surface material 3 attached.
There is no big difference between the two cases, and it is clear that the surface material 3 does not contribute to the buffering function. In both cases, the hardness of base material 2 is 35
~75, If the thickness is within the range of 10 to 40 mm, the acceleration at the time of collision in a head model drop test assuming a human fall is 50 G or less in most cases. From this, it is clear that the above-mentioned tile 1 has an extremely superior impact buffering function compared to the conventional product shown in FIG.

Incidentally, the flooring material of the present invention is not limited to the tile 1 of the above-mentioned embodiment, but may be a continuous tile molded according to the size of the indoor floor surface. In addition, in such a flooring material, the base material 2 has air bubbles,
The bubble layer also has the effect of acting as a heat insulating layer and a sound absorbing layer.

As explained above, in the present invention, the hardness of the base material made of sponge material is set to 35 to 75, the thickness is set to 10 to 40 mm, and the sheet-like surface material is attached to the base material. , it is possible to provide a flooring material that has sufficient hardness to provide good walking and maneuverability under normal conditions, and has an excellent ability to buffer shocks when a person falls. Therefore, when such flooring materials are installed indoors, in hallways, on playgrounds, in amusement parks, on the roofs of buildings, etc., they are extremely safe. Furthermore, the flooring material of the present invention has the effect that the air bubbles in the base material act as a heat insulating layer and a sound absorbing layer.

[Brief explanation of drawings]

Fig. 1 is a diagram showing the acceleration corresponding to a fall of a person in a conventional flooring material, Fig. 2 is a vertical cross-sectional view of a tile as a flooring material according to the present invention, and Figs. 3 to 6 are the above-mentioned tiles. 12 is a drawing showing the acceleration corresponding to a fall of a person when the material, thickness, and hardness of the base material are changed. 1...floor material (tile), 2...base material, 3...surface material.

Claims (1)

[Claims] 1. The hardness value measured by a spring-type hardness tester C type specified by Japanese Industrial Standards is 35 to 75,
A shock-absorbing floor material comprising a base material made of a sponge material such as a rubber sponge or a polyethylene sponge having a thickness of 10 to 40 mm, and a sheet-like surface material such as rubber or vinyl chloride adhered to the base material.