JP2020081681A - mat - Google Patents

Abstract

To provide a mat capable of achieving recovery and enhancement of a walking function and a balance function of a user by giving appropriate instability to the user walking or running on the mat, and safely usable by a person who has difficulty in walking by raising the feet.SOLUTION: A mat 1 for walking training or running training, comprising a net-like knitted resin structure 1A in which a plurality of linear molten resins are entangled and partially heat-deposited is configured such that: a plurality of hard areas 10 and soft areas 20 are alternately formed in an advancing direction of a user; a bulk density of the hard area 10 is larger than that of the soft area 20; a width V of the hard area 10 is smaller than a width W of the soft area 20; and the widths W of the soft areas 20 are different in one soft area 20 and the other soft area 20 adjacent each other across the hard area 10.SELECTED DRAWING: Figure 1

Description

TECHNICAL FIELD The present invention relates to a mat for recovering or enhancing a motor function by a user walking or running.

Heretofore, mats have been proposed for the purpose of recovering and improving motor function.
For example, Patent Document 1 discloses a balance mat in which water or air is enclosed in a plurality of rooms formed in a mat in a balloon shape and holes or tubes are provided so that water or air partially flows between the rooms. It is disclosed that when walking on this balance mat, the balance of the body is lost and the muscles of the whole body are used in an attempt to restore the balance, so that the exercise can be effectively performed in a short time.
Further, in Patent Document 2, a plurality of target patterns or non-target patterns colored in two or more different colors are displayed at predetermined intervals on the upper surface which is a walking surface, and a route connecting target patterns of the same color is provided. An exercise mat for fall prevention is disclosed in which the walking difficulty is arranged differently for each color depending on the arrangement relationship with a non-target pattern separating the same.
Further, in Patent Document 3, an air chamber for adjusting cushioning property and resilience is provided inside a resilient mat-shaped main body, and air pressure generated when stepping or walking is performed on the mat. A running mat is disclosed in which fluctuations are measured with a pressure sensor.
Further, in Patent Document 4, a large number of ridge-shaped peaks formed by intersecting each other while forming an irregular loop in each of a large number of synthetic polymer continuous filaments and further curving in the thickness direction to form an arc shape. There is disclosed a bedding mat which has a mesh-shaped matte surface formed by forming a groove-shaped trough that is recessed between the upper portion and the mountain portion, and which has a foot sole stimulating function.
Further, Patent Document 5 discloses a three-dimensional net structure including a spring structure composed of continuous filaments that are randomly entangled in a loop shape and partially heat-welded, and have a bulk density of 0.07 to 0.4 g/ cm ^{3 and} a soft portion having a bulk density of 0.03 to 0.2 g/cm ³ which is set to have a bulk density lower than that of the hard portion, the hard portion has a body pressure of 3466 to 12532 Pa, and the soft portion has a body pressure of 19999. There is disclosed a stepping mat which is set to 8 to 6666.0 Pa and has a hard portion formed in a band shape.

JP, 2004-136052, A JP, 2014-36740, A JP, 2007-61581, A JP, 9-313430, A JP, 2007-229288, A

The balance mat of Patent Document 1 has a large number of balloon-shaped lumps, and thus may be stumbled over the lumps, and is particularly difficult to use for persons who have difficulty walking with their feet raised. Further, since the rooms are arranged vertically and horizontally on the mat, the balance is disturbed not only in the traveling direction of the user but also in the lateral direction, so that the instability given to the user becomes too large. Further, since water or air is enclosed in the mat, if the mat is damaged even partially, water or air leaks from the damaged portion and the function as the balance mat is greatly impaired. In addition, when water is enclosed, the weight of the mat increases and the handleability deteriorates.
Further, the exercise preventive mat for fall prevention of Patent Document 2 is not intended to enhance the balance function by giving instability to the user. In addition, since it is necessary to visually recognize the walking route, people with visual impairment cannot use it.
Further, the running mat of Patent Document 3 intends to systematically execute an exercise suitable for each individual by calculating and displaying the number of times and the intensity of the exercise from the acquired pressure fluctuation data, It is not intended to give the user instability and enhance the balance function.
Further, the bedding mat of Patent Document 4 is intended to provide a mat which can walk comfortably and also has the function of a stepping fitness tool, and does not aim to improve the walking function and the balance function.
Further, the stepping mat of Patent Document 5 is intended to improve health by stepping exercise, and is not intended to improve the walking function and the balance function.

Therefore, the present invention imparts appropriate instability to a user who walks or runs on a mat, can recover or improve the walking function, the balance function, and the like of the user, and can raise the foot. It is an object of the present invention to provide a mat that can be safely used by people who have difficulty walking.

The mat of the present invention according to claim 1 is a mat for walking training or running training, comprising a mesh-shaped knitted resin structure 1A in which a plurality of linear molten resins are intertwined and partially heat-welded to each other. A plurality of hard regions 10 and soft regions 20 are alternately formed in the traveling direction, the bulk density of the hard regions 10 is larger than the bulk density of the soft regions 20, and the width V of the hard regions 10 is the soft regions. The width W is smaller than the width W of the soft region 20, and the width W of the soft region 20 is different between the one soft region 20 and the other soft region 20 that are adjacent to each other with the hard region 10 interposed therebetween.

The present invention according to claim 2 is the mat according to claim 1, wherein the width W of the soft region 20 is three or more.

The present invention according to claim 3 is the mat according to claim 1 or claim 2, wherein a width V of the hard region 10 is one of the hard region 10 and the other of the hard regions 10 that are adjacent to each other with the soft region 20 interposed therebetween. It is characterized in that it is different from the hard region 10.

According to a fourth aspect of the present invention, in the mat according to the third aspect, the hard region 10 has three or more widths.

The present invention according to claim 5 is the mat according to any one of claims 1 to 4, wherein the bulk density of the hard region 10 is 1.5 times or more the bulk density of the soft region 20. It is characterized by being less than twice.

The present invention according to claim 6 has a two-layer structure in which two layers are formed in the thickness direction in the mat according to any one of claims 1 to 5, and the diameter or material of the knitting resin is The layers are different from each other.

According to the present invention, a hard and narrow hard region and a soft and wide soft region are alternately formed, and the width of the soft region is indefinite. It is possible to provide stability and to restore or improve the walking function and balance function of the user. Further, since the mat surface can be formed flat, it can be safely used by the user of the sliding foot.

The figure which shows the structure of the mat by one Example of this invention. The figure which shows the structure of the mat by the other Example of this invention. The figure which shows the structure of the mat|matte by another Example of this invention. Schematic diagram of the mat manufacturing apparatus of the present invention The figure which shows the bottom of the linearization part of the manufacturing apparatus Reference top perspective photograph of a portion of the mat of the present invention

The mat according to the first embodiment of the present invention is a mat for walking training or running training, and is composed of a mesh-shaped knitted resin structure in which a plurality of linear molten resins are intertwined and partially heat-welded to each other. Multiple hard regions and soft regions are alternately formed in the traveling direction, the bulk density of the hard region is larger than the bulk density of the soft region, the width of the hard region is smaller than the width of the soft region, and the width of the soft region is Is different between one soft region and the other soft region that are adjacent to each other with the hard region interposed therebetween.
According to the present embodiment, a hard and narrow hard region and a soft and wide soft region are alternately formed in the traveling direction, and the width of the soft region is indefinite, so that a user walking or running on the mat. It is possible to provide appropriate instability to the user, and to recover or improve the walking function, the balance function, and the like of the user. Further, since the mat surface can be formed flat, it can be safely used even by a person who can walk only with rubbing feet or a person who can hardly walk with his feet raised.

The second embodiment of the present invention is the mat according to the first embodiment, in which the soft regions have three or more widths.
According to the present embodiment, by increasing the width pattern, it is possible to increase the instability by giving the user walking on the mat a feeling that the hardness of the scaffold changes more randomly.

In the third embodiment of the present invention, in the mat according to the first or second embodiment, the width of the hard region is different between the one hard region and the other hard region which are adjacent to each other with the soft region interposed therebetween. ..
According to this embodiment, the instability can be increased by giving the user walking on the mat a feeling that the hardness of the scaffold changes more randomly.

The fourth embodiment of the present invention is the mat according to the third embodiment, in which the widths of the hard regions are three or more.
According to the present embodiment, by increasing the width pattern, it is possible to increase the instability by giving the user walking on the mat a feeling that the hardness of the scaffold changes more randomly.

The fifth embodiment of the present invention is the mat according to any one of the first to fourth embodiments, wherein the bulk density of the hard region is 1.5 times or more and 3 times or less the bulk density of the soft region. Is.
According to this embodiment, the user can be given more appropriate instability.

The sixth embodiment of the present invention has a two-layer structure in which two layers are formed in the thickness direction in the mat according to any one of the first to fifth embodiments, and the diameter or material of the knitting resin is a layer. They are different from each other.
According to the present embodiment, the instability varies depending on whether one layer is on top or the other layer is on top. Can be used properly. Moreover, the instability different from the case of one layer can be given to the user.

Embodiments of the present invention will be described below with reference to the drawings.
1A and 1B are views showing a structure of a mat according to an embodiment of the present invention, FIG. 1A being a top view and FIG. 1B being a front view.
The rectangular parallelepiped mat 1 is composed of a mesh-shaped knitted resin structure in which a plurality of linear molten resins are intertwined and partially heat-welded. The vertical length X and the horizontal length Y of the mat 1 are set according to the place of use and the like. The user walks or runs on the vertically long mat 1 from one end P to the other end Q or from the other end Q to one end P.

The mat 1 has a plurality of hard regions 10 and a plurality of soft regions 20. The hard regions 10 and the soft regions 20 are alternately formed from one end P to the other end Q in the direction in which the user walks or runs. The hard region 10 and the soft region 20 are rectangular in a top view.
The hard region 10 is made harder than the soft region 20 by making the bulk density higher than that of the soft region 20. The width V of the hard region 10 is smaller than the width W of the soft region 20. Further, the width V of the hard region 10 is constant with no difference between the hard regions 10 (for example, 6 cm). On the other hand, in the soft region 20, one soft region 20 and the other soft region 20 that are adjacent to each other with the hard region 10 interposed therebetween have different widths W.
In this manner, a plurality of hard and narrow hard regions 10 and soft regions 20 that are softer and wider than the hard regions 10 are alternately formed in the mat 1 in the traveling direction, and the width W of the soft region 20 is made indefinite. Walking on the mat 1 is performed by giving a feeling that the hardness of the scaffold randomly changes to the user walking on the mat 1 to make the instability larger than that when the width W of the soft region 20 is constant. A moderate instability can be given to the traveling user. A user who walks in an unstable place naturally balances in an attempt to move straight, so that the muscular strength and sense of balance are trained. As a result, the user's walking function, balance function, and the like can be restored or promoted. Further, since the mat 1 can have a flat surface, it can be safely used even by a person who can walk only with rubbing feet or a person who has difficulty walking with his feet slightly raised. In addition, the hardness of the mat 1 is changed only in the traveling direction of the user, and the hardness is not changed in the lateral direction of the user (the direction orthogonal to the traveling direction), so that the instability of the user is more than necessary. I am trying not to give. Further, since the hard region 10 and the soft region 20 have a repulsive force, even an elderly person or the like having a weak muscle strength can smoothly raise their legs.

The thickness Z of the mat 1 is preferably 3 cm or more and 5 cm or less. When the thickness Z is less than 3 cm, the feeling of bottoming on the floor when stepped on is large, and the instability given to the user is insufficient. Further, the larger the thickness Z, the more unstable the user tends to be. However, if the thickness Z exceeds 5 cm, the user may stumble at a step between the mat 1 and the floor or step off the mat 1 when the user steps up or down. There is a risk of injury. It should be noted that the one end P and the other end Q may be provided with a gradual inclination to allow the user to move up and down to the mat 1 from the one end P or the other end Q side to prevent the user from stumbling. ..

The bulk density of the hard region 10 is preferably in the range of 0.15 g/cm ³ or more and 0.20 g/cm ³ or less and 1.5 times or more and 3 times or less the bulk density of the soft region 20. This can give the user more appropriate instability. The bulk density may be different between the hard regions 10 or between the soft regions 20 at each position.
The width V of the hard region 10 and the width W of the soft region 20 are preferably smaller than the size of the user's foot. This makes it easier for the user's foot to step on both the hard region 10 and the soft region 20 at the same time, and the instability given to the user can be increased. For example, the average foot size of Japanese adults is around 23 cm for women and around 26 cm for men, so if the main user of the mat 1 is a Japanese adult, the hard region 10 and the soft region 20 will be used. Is 22 cm or less.
Further, the hard region 10 more preferably has a width V of 3 cm or more and 7 cm or less. This makes it easier for the user to irritate the sole of the foot when stepping on the hard region 10, and enhance the so-called green bamboo stepping effect.

The width W of the soft region 20 is preferably three or more. By increasing the pattern of the width W, the instability can be increased by giving the user walking on the mat 1 a feeling that the hardness of the scaffold changes more randomly. In the mat 1 shown in FIG. 1, the width W of the soft region 20 is set in seven ways. For example, assuming that the widths W in seven ways are “9 cm”, “11 cm”, “13 cm”, “15 cm”, “17 cm”, “19 cm”, and “21 cm”, 15 cm→11 cm→19 cm from one end P to the other end Q. The soft regions 20 are arranged by changing the width W in the order of →13 cm→21 cm→9 cm→17 cm. The width W becomes 15 cm again after 17 cm, and the same cycle is repeated thereafter.

2A and 2B are views showing the structure of a mat according to another embodiment of the present invention. FIG. 2A is a top view and FIG. 2B is a front view. It should be noted that the same functional units as those in the above-described embodiment are designated by the same reference numerals and the description thereof will be omitted.
In the mat 100 according to the present embodiment, the width W is made different between the one soft region 20 and the other soft region 20 which are adjacent to each other with the soft region 20 sandwiching the hard region 10 in the same manner as the mat 1. Also, the width V is made different between the one hard region 10 and the other hard region 10 which are adjacent to each other with the soft region 20 interposed therebetween. As described above, by making the width V of the hard region 10 and the width W of the soft region 20 indefinite, the user walking on the mat 100 feels that the hardness of the scaffold changes more randomly, and is unstable. The size can be increased.
The width V of the hard region 10 is preferably three or more. By increasing the pattern of the width V, the instability can be increased by giving a user walking on the mat 100 a feeling that the hardness of the scaffold changes more randomly. In the mat 100 shown in FIG. 2, the width V of the hard region 10 is set in five ways. If the five widths V are, for example, “3 cm”, “4 cm”, “5 cm”, “6 cm”, and “7 cm”, the width V is 5 cm→3 cm→6 cm→4 cm→7 cm from one end P to the other end Q. The hard area|region 10 is arrange|positioned by changing. The width V becomes 5 cm again after 7 cm, and the same cycle is repeated thereafter.

3A and 3B are views showing the structure of a mat according to still another embodiment of the present invention. FIG. 3A is a top view, FIG. 3B is a rear view, and FIG. 3C is a front view. .. It should be noted that the same functional units as those in the above-described embodiment are designated by the same reference numerals and the description thereof will be omitted.
The mat 200 according to this embodiment has a two-layer structure in which two layers are formed in the thickness direction. The layer 200A on one side and the layer 200B on the other side have different diameters or materials of the knitting resin, so that the repulsive force between them is also different. As a result, instability during walking and the like changes depending on whether one layer 200A is on the other side or the other layer 200B is on the other side. You can use different layers. Further, even if the thickness Z is the same as in the case of one layer, the instability different from that in the case of one layer can be given to the user by forming two layers.
Further, the thickness Z1 of the one layer 200A and the thickness Z2 of the other layer 200B do not have to be the same. The instability given to the user can be adjusted by changing the respective thicknesses.

FIG. 4 is a schematic view of the mat production apparatus of the present invention, FIG. 5 is a view showing the bottom surface of the linearized portion of the production apparatus, and FIG. 6 is a reference top perspective photograph of a part of the mat of the present invention.
In the manufacturing apparatus 30, a large number of resins are randomly entangled with each other and partially heat-welded by linearly pouring the molten resin and dropping the molten resin aggregate into a liquid and cooling it. The knitted resin structure 1A having a three-dimensional net-like structure is continuously formed.

The manufacturing apparatus 30 includes a supply unit 31 that supplies molten resin, a linearization unit 32 that linearizes the molten resin, and a cooling tank 33 that stores a cooling liquid that cools the linear molten resin. , A guider portion 34 through which an aggregate of linear molten resins flowing down from the linearization portion 32 toward the cooling tank 33 passes, and a knitted resin structure 1A formed by cooling the aggregate with a cooling liquid. Is provided on the bottom surface side of the cooling tank 33, a sending section 36 for sending the knitted resin structure 1A to the outside of the cooling tank 33, and a speed control section 37 for controlling the drawing speed of the drawing section 35.

The supply unit 31 melts and kneads a thermoplastic resin at a predetermined temperature to form a molten resin, and extrudes the molten resin at a predetermined extrusion speed to supply the linearized unit 32.
As the thermoplastic resin, for example, polyethylene, polypropylene, polyvinyl chloride, polystyrene, polyvinyl acetate, polytetrafluoroethylene, acrylonitrile butadiene styrene resin, or the like may be used alone or in combination.
The supply unit 31 has a first resin supply unit 31A that supplies a first resin and a second resin supply unit 31B that supplies a second resin. When the knitted resin structure 1A has a two-layer structure as shown in FIG. 3, the diameter or material of the supplied resin is different between the first resin supply section 31A and the second resin supply section 31B.

The linearization part 32 has an inlet for receiving the molten resin extruded from the supply part 31 at the top and an outlet for letting out the received molten resin at the bottom. A plurality of small holes 32A are arranged in a rectangular shape at the outlet. The molten resin supplied from the supply unit 31 becomes linear by flowing out from the small holes 32A.
As shown in FIG. 5, the inside of the linearized portion 32 has a first section 32C in which the resin supplied from the first resin supply section 31A enters and a second section in which the resin supplied from the second resin supply section 31B enters. It is partitioned by a partition plate 32B into the partition 32D. In FIG. 5, in order to form the knitted resin structure 1A having a two-layer structure in which the resin diameters of the adjacent layers are different from each other, the diameters of the small holes 32A are different between the first section 32C and the second section 32D. ..
The linear molten resin flowing out from each small hole 32A becomes a substantially rectangular aggregate and flows down toward the cooling tank 33.

As shown in FIG. 4, the guider portion 34 is arranged between the linearization portion 32 and the cooling tank 33. The guider portion 34 guides the aggregate to the cooling tank 33 while compressing the aggregate in the thickness direction.
The guider portion 34 comes into contact with the first inclined plate 34A arranged at a position in contact with one portion of the knitted resin structure 1A of the aggregate, and the portion of the other knitted resin structure 1A that is in contact with the first inclined plate 34A. It has the 2nd inclination board 34B arrange|positioned in the position. The aggregate passes between the first inclined plate 34A and the second inclined plate 34B.
The first inclined plate 34A and the second inclined plate 34B are arranged to face each other, and the distance between them is gradually narrowed from the upper side to the lower side. The upper gap is larger than the thickness of the aggregate before reaching the guider portion 34, and the lower gap is smaller than the thickness of the aggregate before reaching the guider portion 34. Therefore, the thickness of the aggregate after passing between the first inclined plate 34A and the second inclined plate 34B becomes smaller than that before the passage.
In addition, in the aggregate, a portion of the aggregate that has passed through the guider portion 34 while being compressed due to contact with the first inclined plate 41 or the second inclined plate 34B has its surface smoothed and flows into the cooling tank 33. The portion that has passed through the guider portion 34 without coming into contact with the first inclined plate 41 or the second inclined plate 42 flows into the cooling tank 33 as it is without the surface being leveled. As a result, the knitted resin structure 1A formed by cooling the aggregate with the liquid in the cooling tank 33 has a flat surface state on the upper surface and the lower surface (one surface and the other surface).

A drawing section 35 and a sending section 36 are arranged in the cooling tank 33.
The lead-in portion 35 is arranged at a position where the aggregate that has passed through the guider portion 34 flows down into the cooling tank 33. The lead-in portion 35 vertically includes a pair of rotating bodies including one rotating body 35A that contacts one surface of the knitting resin structure 1A and the other rotating body 35B that contacts the other surface of the knitting resin structure 1A. Have multiple in the direction. One rotating body 35A and the other rotating body 35B are cylindrical rollers, and are arranged so that the longitudinal direction is horizontal. The distance between the one rotating body 35A and the other rotating body 35B is substantially the same as the thickness of the assembly passing through the guider portion 34.
The rotation speed of the rotating body is controlled by the speed controller 37. The speed control unit 37 alternately switches the rotation speed of the rotating body between the first speed and the second speed that is higher than the first speed at predetermined time intervals. In the knitted resin structure 1A, the portion drawn into the rotating body that rotates at the relatively low first speed becomes the hard region 10 having a large bulk density, and rotates at the relatively high second speed. The portion drawn into the body becomes the soft region 20 having a low bulk density. By changing the rotation speed of the rotating body every predetermined time in this manner, the knitted resin structure 1A has a sparse and dense structure, and the hard regions 10 and the soft regions 20 can be alternately formed. The predetermined time for switching the rotation speed is adjusted according to the set values of the width V of the hard region 10 and the width W of the soft region 20.

The delivery unit 36 has an inclined conveyor 36A. The lower end of the inclined conveyor 36A is located below the retracting section 35. The knitted resin structure 1A drawn into the bottom surface side of the cooling tank 33 is lifted obliquely upward by the inclined conveyor 36A and sent out of the cooling tank 33. It is also possible to use a rotating body such as a roller instead of the inclined conveyor 36A to lift the knitted resin structure 1A and send it out of the cooling tank 33.

The knitted resin structure 1A sent to the outside of the cooling tank 33 is cut into a predetermined size to become mats 1, 100, 200. As shown in FIG. 6, the knitted resin that has fallen sideways appears on the upper surface of the mat. The same applies to the lower surface of the mat.

Since the mat according to the present invention can restore or enhance the walking function and the balance function and has a low risk of falling, it can be used for gait rehabilitation, growth training for infants and the like.

1 Mat 1A Knitted resin structure 10 Hard region 20 Soft region 100 Mat 200 Mat 200A One layer 200B Other layer V Hard region width W Soft region width

Claims (6)

A mat for walking training or running training,
A plurality of linear molten resins are entangled and partially composed of heat-welded knitted resin structure,
A plurality of hard regions and soft regions are alternately formed in the user's traveling direction,
The bulk density of the hard region is larger than the bulk density of the soft region,
The width of the hard region is smaller than the width of the soft region,
The width of the soft region is different between the one soft region and the other soft region which are adjacent to each other with the hard region interposed therebetween. The mat according to claim 1, wherein the soft region has three or more widths. The mat according to claim 1 or 2, wherein a width of the hard region is different between the one hard region and the other hard region that are adjacent to each other with the soft region interposed therebetween. The mat according to claim 3, wherein the hard region has three or more widths. The bulk density of the said hard area|region is 1.5 times or more and 3 times or less of the bulk density of the said soft area|region, The mat as described in any one of Claim 1 to 4 characterized by the above-mentioned. It is a two-layer structure in which two layers are formed in the thickness direction,
The diameter or material of knitting resin differs between the layers, and the mat according to any one of claims 1 to 5.