The present invention relates to a hand rim for a wheelchair, especially a hand rim for a wheelchair for racing used for track race, marathon, or the like.
Conventionally, as a hand rim for a wheelchair provided at a drive wheel of a wheelchair for racing, there is known a hand rim provided with an anti-slippage layer on a surface of a base material formed by fiber-reinforced resin material or metal. As this type of anti-slippage layer, there is known to form the anti-slippage layer by winding a tape, a tube, or a code to the base material (for example, refer to Patent Literature 1: Japanese Patent Laid-open No. 2006-305006).
However, since the tapes, tubes, or codes used in such a conventional hand rim as disclosed in Patent Literature 1 are formed by materials such as rubber material or the like, there is a problem that the hand rim is slippery in a case the surface gets wet by rain or sweat, and there is water existing on the contact surface with the hands (glove).
The present invention has been made in view of the above, and it is an object of the present invention to provide a hand rim which does not become slippery even if the surface is wet.
In order to achieve the above object, a hand rim of the present invention is a hand rim for a wheelchair provided at a drive wheel including: an annular base material, and an anti-slippage layer formed on a surface of the base material, wherein the anti-slippage layer includes an adhesive layer formed on the surface of the base material and particles fixed through the adhesive layer, and wherein the particles are fixed so as to protrude from the adhesive layer.
As such, in the hand rim of the present invention, the particles are fixed so as to protrude from the adhesive layer of the anti-slippage layer. Therefore, a plurality of concaves and convexes exist on the surface of the hand rim, thereby maintaining a state of high friction resistance against the hand (glove) of the user even in a wet state. Therefore, the hand rim of the present invention does not become slippery even if the surface is wet.
Moreover, it is preferable in the hand rim of the present invention that a thickness of the adhesive layer is equal to or less than a half of an average particle diameter of the particles. According to such configuration, sufficient roughness (concaves and convexes) is formed by the particles, thereby becoming easy to obtain sufficient friction resistance. Moreover, since it is able to reduce the amount of adhesive agent forming the adhesive layer, the manufacturing cost can be suppressed.
Moreover, it is preferable in the hand rim of the present invention that the anti-slippage layer is formed on a peripheral surface of the base material in a region of an opposite side of a wheel when attached to the wheel and in a region of inner peripheral side.
Since the anti-slippage layer is formed in order to increase the friction resistance against the hand of the user, it only needs to be formed at least in the region which the hands of the user contact. In this regard, by forming the anti-slippage layer at the above regions, the amount of particles required for forming the anti-slippage layer can be suppressed, thereby enabling to suppress the manufacturing cost without decreasing the friction resistance.
Moreover, it is preferable in the hand rim of the present invention that the particles are plant-based particles, and wherein a content of oil and fat in the particles is equal to or less than 0.4%. When the oil and fat is 0.4% or less, it is able to increase the adhesive property with respect to the adhesive layer.
Moreover, it may be configured in the hand rim of the present invention that an occupancy area of a region in which the particles exist with respect to a surface of the anti-slippage layer is equal to or more than 80%.
Hereinafter, the configuration of a wheelchair W according to an embodiment will be explained with reference to the drawings. The wheelchair W is a wheelchair used for track race, marathon, or the like.
First, referring to
As shown in
As shown in
The handle 3 is connected to the end portion of the column 5a of the front fork 5 prefer to
The rear wheel 6 is configured by a wheel 6a and a tire 6b fitted to the wheel 6a. The rear wheel 6 is attached to the cage 1 in a state inclined such that the upper side of the rear wheel 6 approaches more to the center side of the cage 1.
The hand rim 7 is fixed such that it is able to integrally rotate with the rear wheel 6. The player seated on the sitting seat 1a transmits the driving force to the rear wheel 6 through the hand rim 7.
As shown in
The column 5a is cylindrically formed and is pivotally supported by the forward end portion of the vehicle body frame 2 via a bearing (not illustrated). Handle 3 (refer to
Next, with reference to
As shown in
The base material 70 is annually formed by connecting a plurality of pipes formed by laminating fiber-reinforced plastics using a boss made of metal such as aluminum, iron, or the like (refer to
Here, the hand rim of the present invention may be attached to the front wheel depending on the structure of the wheelchair, since it only requires to be fixed to the drive wheel which is driven by the user.
As the fiber-reinforced plastic forming the base material 70, for example, fiber-reinforced plastic using polyacrylonitrile (PAN)-based carbon fiber, aramid fiber-reinforced plastic, or fiber-reinforced plastic or the like reinforced by glass fiber, pitch-based carbon fiber, PBO fiber, polyarylate fiber, or polyethylene fiber.
The base material 70 does not necessarily have to be formed by connecting the plurality of pipes formed by fiber-reinforced plastic by a boss. For example, instead of fiber-reinforced plastic, the pipe may be formed by metal. Moreover, instead of forming the base material by connecting the plurality of pipes by the boss, the base material may be integrally formed without using a boss. Moreover, the cross sectional shape of the base material may be a rectangular tubular shape or a solid columnar shape instead of a cylindrical shape.
The anti-slippage layer 71 includes an adhesive layer 71a formed on the surface of the base material 70 and particles 71b fixed through the adhesive layer 71a.
The anti-slippage layer 71 is formed on a peripheral surface of the base material 70 in a region which becomes the opposite side of the wheel 6a when attached to the wheel 6a and in a region of the inner peripheral side. More specifically, when a line orthogonal to the surface of the wheel 6a being a reference line, the anti-slippage layer 71 is formed in a range of 135° to the inner peripheral side and 90° to the outer peripheral side.
This is because the anti-slippage layer 71 is formed to increase the friction resistance against the user's hand, it only needs to be formed at least in a region in which the hands of the user contact. By limiting the range of forming the anti-slippage layer 71 as such in the hand rim 7, the amount of particles 71b required for forming the anti-slippage layer 71 is suppressed, thereby suppressing the manufacturing cost, without decreasing the friction resistance.
The region for forming the anti-slippage layer 71 is not limited to the above regions, and may be appropriately changed according to the size of the hand of the user, the amount of particles which can be used, or the like. For example, the anti-slippage layer 71 may be formed across the whole region of the peripheral surface of the base material 70.
The adhesive layer 71a is formed of thermosetting resin such as epoxy, urethane, unsaturated polyester, vinyl ester resin, or the like.
The particles 71b have an average particle diameter of 200 μm to 300 μm, and are fixed such that at least a part of it protrudes from the adhesive layer 71a. More specifically, as shown in
Moreover, the particles 71b are plant-based particles, and those having oil and fat of 0.07% are used. More specifically, grained seeds and shells of peach, nut, apricot, or the like are used. This is, in order to improve the adhesive property with respect to the adhesive layer 71a.
Here, the particles 71b are not limited to the plant-based particles having an average particle diameter of 200 μm to 300 μm and oil and fat of 0.07%. For example, if the oil and fat is 0.4% or less, sufficient adhesive property can be obtained. Moreover, the particle diameter may be any size projectable from the adhesive layer. Moreover, ceramic-based particles may be used instead of plant-based particles.
Moreover, sufficient friction resistance can be obtained if the particles 71b are fixed so as to protrude at least approximately 70 μm from the adhesive layer 71a. Therefore, the thickness of the adhesive layer may be appropriately changed according to the particle diameter of the particles or the performance of the adhesive agent forming the adhesive layer.
The occupancy area of the region where the particles 71b exist with respect to the surface of the anti-slippage layer 71 was measured at 5 points separate by even intervals on the hand rim 7. The occupancy area at each position was 96.46%, 95.68%, 97.37%, 96.61%, and 97.22%. Accordingly, since the occupancy areas are such values, the hand rim 7 is able to obtain appropriate friction resistance when the user drives the hand rim 7.
However, the occupancy area of the particles 71b on the surface of the anti-slippage layer 71 is not limited to the above values. The occupancy area may be appropriately changed according to the average particle diameter or the like of the particles 71b, or the required friction resistance or the like. It should be at least 80% or more. Especially, it is preferable that the occupancy area is over 95%.
The hand rim 7 is formed by coating the thermosetting resin forming the adhesive layer 71a on the base material 70 by a method such as brush, spray, or dip, and thereafter sprinkling the particles 71b. Then, heat treatment is performed to form the hand rim 7. The heat treatment can be omitted depending on the type of the thermosetting resin. Especially, when using plant-based particles as the particles 71b, resin which cures without performing heat treatment may be used.
The hand rim 7 may be formed using other methods. For example, thermosetting resin which is formed as a film in advance may be used as the adhesive layer 71a. Moreover, a thermosetting resin in which the particles 71b are mixed therein may be coated to form the adhesive layer 71a, and at the same time fixing the particles 71b.
Although the above explains the illustrated embodiment, the present invention is not limited to such mode.
For example, in the embodiment, the anti-slippage layer 71 is formed in the entire region of the surface of the hand rim 7. However, the anti-slippage layer may be formed only on a part of the hand rim. For example, the anti-slippage layer 71 may be formed only in a region of the hand rim on an opposite side of the surface of the rear wheel or only in a region on the outer peripheral side of the hand rim. Moreover, a portion formed with the anti-slippage layer and a portion not formed with the anti-slippage layer may be arranged alternately to form a stripe pattern.
1 . . . cage, 1a . . . sitting seat, 2 . . . vehicle body frame, 3 . . . handle, 4 . . . front wheel, 5 . . . front fork, 5a . . . column, 5b . . . fork portion, 5c . . . bearing hole, 6 . . . rear wheel, 6a . . . wheel, 6b . . . tire, 7 . . . hand rim, 70 . . . base material, 71 anti-slippage layer, 71a . . . adhesive layer, 71b . . . particle, W . . . wheelchair
Number | Date | Country | Kind |
---|---|---|---|
2016-085089 | Apr 2016 | JP | national |