JP2012120678A - Structure and method for fastening lace - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a structure and a method for fastening a lace that reliably eliminate the generation of a gap between a tongue of a shoe and an instep or an ankle of a wearer.SOLUTION: The structure and the method for fastening the lace include: the tongue 1 having the back 3 and a shank 4, formed of bending, and movably disposed relative to a shoe body 14; a first lace-passing part H1 disposed on the shank 4 of the tongue 1; and a second-passing part H2 disposed on the shoe body 14 at a position lower than the first lace-passing part H1. The lace W1 passing through the first and second lace-passing parts H1 and H2 is fastened, thereby causing the shank 4 of the tongue 1 to be drawn downward.

Description

  The present invention relates to a shoelace tightening structure and a shoelace tightening method, and more specifically, shoes such as boots used for skiing, snowboarding, skating, mountain climbing, and riding a motorcycle. The present invention relates to a shoelace fastening structure and a shoelace fastening method suitable for fastening a strap.

  Conventionally, in boots used for skiing, snowboarding, skating, mountain climbing, riding a motorcycle, etc., shoes that cover these parts in order to protect the upper leg and the lower leg (near the shin) above the heel. The main body has a certain degree of rigidity.

  Further, as a shoelace fastening structure suitable for use when fastening the shoelaces of the boots and fastening the instep (ankle) of the boot, a shoelace fastener as shown in FIG. 9 is provided. A skate boot 90 has been proposed (Patent Document 1).

In the boot 90 provided with the shoe lace fastener, a substantially “V” -shaped or substantially “U” -shaped opening 91 is formed in the shoe body upper part and the shoe body shin part, and the opening 91 is formed in the shoe. A tongue (tongue) 92 having a bent shape covering the instep and shin of the foot is attached in the shoe main body so as to be closed from the inside of the main body.
The boot 90 passes a shoelace W through a shoelace passage portion H provided in a flap 93 of the shoe body, and tightens the shoelace W in order to hold down the upper part of the wearer's foot.

  In these conventional shoelace tightening structures, the shoelace W is inserted into the shoelace passage portion H provided on the shoe 93 flap 93 to close the opening 91 of the shoe body, and is attached to the shoe body. The upper portion of the boot wearer is indirectly pressed by the tongue 92 (see FIG. 9B).

However, especially boots used for sports such as snowboarding, skiing, and skating, because the shoe body is made of a fairly rigid material, the opening of the shoe body is not easily deformed, and the upper part of the boot wearer is efficiently I can't hold it down.
For this reason, when the ankle is moved while walking or playing sports, the position of the tongue 92 remains displaced, and there is a problem that the tightening of the wearer's foot and the ankle becomes insufficient.

  That is, in the conventional shoelace tightening structure, the shoelace is indirectly tightened in the shoe body by tightening the shoelace in the left-right direction (the direction in which the shoe body opening is closed) that draws both side edges of the shoe body opening. Because the attached tongue is pressed against the wearer's upper part and ankle, if there is a gap between the tongue and the wearer's upper part or ankle, the gap cannot be eliminated. There is.

  In order to solve the above problem, boots with additional shoelaces or buckles for pressing near the bent part of the ankle have been proposed, but even if these additional tightening structures are adopted, Is not directly pushed downward, and the gap formed between the tongue and the upper part of the wearer cannot be reliably eliminated.

  In addition, providing these additional tightening structures complicates the structure of the upper part of the shoe body, adversely affects the flexibility near the upper part of the boot, and increases the weight of the upper part. It also leads to problems.

Japanese Patent No. 4514383

  Therefore, the problem to be solved by the present invention is that in conventional boots, when the ankle is moved by walking or playing sports, the position of the tongue remains shifted, and the wearer's foot upper part and ankle The purpose of the present invention is to reliably eliminate the gap between the tongue and the wearer's upper part or ankle by pulling the tongue directly downward. An object of the present invention is to provide a shoelace tightening structure and a tightening method.

  The present invention includes a tongue having an instep and a shin portion, which is bent and provided so as to be relatively movable with the shoe body, a first shoelace passing portion provided in the shin portion of the tongue, A second shoelace passing portion provided in the shoe body at a position below the first shoelace passing portion, and tightening the shoelace passing through the first and second shoelace passing portions, The most important feature is a shoelace tightening structure in which the shin portion of the tongue can be pulled downward.

  The tongue includes a crossing guide portion that allows the shoelaces to pass through the bent portion, and a winding device for preventing the shoelaces from contacting each other or winding the shoelaces on the front surface of the shin portion of the tongue. You may have.

The first shoelace passing portion may be a shoelace passing hole formed so as to extend from the front side to the inside or the back side of the tongue, and may be provided near the bent portion of the tongue.
The tongue includes a winding device for winding a shoelace of a different system from the shoelace passing through the first and second shoelace passing portions in order to fasten the upper portion of the shoe body to the front surface of the shin portion. May be.

  In the shoelace tightening method of the present invention, a tongue having an upper part and a shin part, which is bent and provided so as to be movable relative to the shoe main body, and a first tongue provided on the shin part of the tongue. A shoelace passing portion and a second shoelace passing portion provided in the shoe body at a position below the first shoelace passing portion are provided, and the second shoelace is provided from the first shoelace passing portion. By tightening the shoelace inserted through the threading portion, the shin portion of the tongue is always drawn directly downward.

  In the present invention, the shoelace tightening structure and the tightening method described above are provided so as to be movable relative to the shoe main body by tightening the shoelace passing through the first and second shoelace passing portions. The effect of always pulling the shin portion of the tongue downward can be exhibited, and the occurrence of a gap between the tongue and the back and ankle of the wearer can be reliably eliminated.

Further, by providing the crossing guide portion, it is possible to prevent the shoelace from being cut, and it can be used as a shoelace tightening structure having excellent durability.
Furthermore, by providing a winder to wind the shoelace on the front of the shin of the tongue, the shoelace can be easily and strongly tightened even with the cold protection gloves attached, and the tightening force can be adjusted. Is also easy.

  The first shoelace passage portion of the present invention is a shoelace passage hole formed so as to extend from the front side of the tongue to the inside or the back side, and is provided in the vicinity of the bent portion of the tongue. The effect of attracting the tongue downward can be efficiently exhibited without complicating the structure of the tongue and the shoe body.

  Furthermore, by providing a winding device for winding a shoelace of a different system from the shoelace passing through the first and second shoelace passing portions on the front of the shin portion of the tongue, The upper part of the shoe body can be easily tightened without complicating the structure.

FIG. 1 is a perspective view showing a snowboard boot embodying the shoelace tightening structure of the present invention. FIG. 2 is a front view showing an outline of a first embodiment of a shoelace fastening structure embodying the present invention. FIG. 3 is a view showing a tongue of a shoelace fastening structure embodying the present invention, wherein (A) and (B) are perspective views of the tongue, and (C) are sectional views of the tongue. 4A and 4B are views showing a tongue of a shoelace tightening structure embodying the present invention, wherein FIG. 4A is a side view of the tongue showing the position of the bent portion by a one-dot chain line, and FIG. 4B is a front view of the tongue. It is. FIG. 5 is an exploded perspective view of a shoelace winding device that can be suitably used in a shoelace fastening structure embodying the present invention. FIG. 6 is a view showing a tongue of a shoelace tightening structure embodying the present invention, wherein (A) is a side view of the tongue, and (B) is a front view of the tongue. FIG. 7 is a front view showing a modification of the tongue of the shoelace tightening structure embodying the present invention. FIG. 8 is a front view showing another embodiment of a shoelace fastening structure embodying the present invention. FIG. 9 is a view showing a conventional shoelace tightening structure.

  The present invention includes a tongue having an instep and a shin portion, which is bent and provided so as to be relatively movable with the shoe body, a first shoelace passing portion provided in the shin portion of the tongue, A second shoelace passing portion provided in the shoe body at a position below the first shoelace passing portion, and tightening the shoelace passing through the first and second shoelace passing portions, Tightening structure for shoelaces that allows the shin portion of the tongue to be pulled downward. ”And“ a tongue that is bent and formed so as to be relatively movable with respect to the shoe body, and the tongue. A first shoelace passing portion provided in the shin portion and a second shoelace passing portion provided in the shoe main body at a position lower than the first shoelace passing portion. By tightening the shoelace inserted into the second shoelace passage from the shoelace passage The method tightening laces, characterized in that the shin portion of the tongue and to draw down. "A A, can be suitably embodied by such examples of embodiment to be described below.

  Hereinafter, an embodiment in which the shoelace tightening structure of the present invention is embodied in a snowboard boot will be described.

  FIG. 1 to FIG. 4 are views showing an embodiment in which the shoelace tightening structure of the present invention is embodied in a snowboard boot 10, which includes 1) a sole 11 and 2) the sole. 11, a shoe body 14 having a shoe body upper portion 12 extending in a substantially horizontal direction from a toe and a shoe body upper portion (lower limb portion) 13 extending in a substantially vertical direction from the vicinity of an ankle.

  The shoe body 14 is formed by laminating members made of materials such as synthetic leather, natural leather, fabric, foam, and synthetic resin so that the snowboard can be correctly operated by firmly fixing the boot wearer's lower limb to the snowboard. , Integrated and rigid structure. The shoe body 14 has an opening 15 in which a shin portion corresponding to the upper surface of the shoe body upper portion 12 and the front surface of the shoe body upper portion 13 is cut out in a substantially “V” shape. A foot can be inserted from the upper end of the upper portion 13.

  The boot 10 includes an inner 16 having cushioning properties in the shoe main body 14, and the boot 10 is disposed at a shin portion corresponding to the front surfaces of the shoe main body upper portion 12 and the shoe main body upper portion 13. The tongue 1 is provided.

  The tongue 1 is formed by three-dimensionally pressing a front part 1a made of high-strength synthetic leather or water-repellent coated fabric and a back part 1b made of a material (such as EVA foam) more flexible than the front part 1a after bonding. It is manufactured by bending and forming an approximately “L” shape, attaching a backing fabric 1c, and sewing the edges, and forming an upper portion 3 that forms the lower portion of the bent portion 2 and an upper portion of the bent portion 2. A shin part 4 is provided.

  When the shoelace winding device 20 described later is mounted on the front surface of the tongue 1 as in this embodiment, the upper back surface of the back surface portion 1b is made of a hard foam material (such as EVA foam material or PE foam material). ) It may be replaced with 1d to eliminate the uncomfortable feeling.

  The tongue 1 has a configuration in which the strength of the upper portion 3 and the shin portion 4 is high, and the strength of the bent portion 2 between them is low, like the tongue generally employed in this type of boot. The upper part 3 and the shin part 4 can approach and separate from each other with the bent part 2 as the center (see FIG. 3A).

  The tongue 1 is disposed inside the shoe main body 14 so as to close the opening 15 cut out in a substantially “V” shape from the inside of the shoe main body 14, and the distal end portion 3 a of the tongue 1. Is sewn to the shoe body upper part 12 so that it can move relative to the shoe body 14.

  At a position slightly above the bent portion 2 of the tongue 1, the shin portion 4 is provided with a first shoelace through hole H1 as a pair of left and right first shoelace passage portions. The first shoelace through hole H1 is formed so as to extend substantially along the vertical direction (longitudinal direction) of the tongue 1 and from the front side of the tongue 1 to the inside.

The tongue 1 is provided with a cross guide portion 5 for allowing the shoelace W1 to pass through the bent portion 2 on the front portion 1a thereof. The cross guide portion 5 is provided with a shoelace W1 in guide holes 5a and 5b having different heights. So that the shoelaces W1 are not in contact with each other and are not cut off.
Further, since the cross guide portion 5 is disposed at the mountain-shaped portion of the upper portion 3, when the shoelace W1 is tightened, the top portion of the upper portion 3 is pushed down by the shoelace W1. Demonstrate.
In addition, a shoelace guide 6 having a groove is provided in the shin portion 4 of the tongue 1 at a position above the cross guide portion 5 in the horizontal direction.

On the other hand, the shoe main body upper part 12 crosses the opening 15 from side to side in the vicinity of the bent part 2 of the tongue 1 and at a position below the first shoelace through hole H1. A pair of second shoelace passing holes H2 are provided as a second shoelace passing portion so as to face each other.
Further, the shoe body upper portion 12 is provided with a third end facing the opening 15 so as to cross the opening 15 to the left and right in the vicinity of the distal end portion 3a of the tongue 1 (a position in front of the second shoelace through hole H2). Three pairs of shoelace holes H3 are provided.

The tongue 1 is provided with a winding device 20 at a position above the shoelace guide 6 on the front surface of the shin portion 4, and a tube having rigidity in the winding device 20 inside the shin portion 4. 7 is connected, and the lower end of the tube 7 is connected to the first shoelace through hole H1, so that the shoelace W1 inserted through the tube 7 can be smoothly wound up. It has become.
In this embodiment, the tube 7 is provided so as to pass through the inside of the tongue 1 (the back portion 1b), but is formed until the first shoelace through hole H1 reaches the back side of the tongue 1. In this case, the tube 7 may be disposed along the back side of the tongue 1.

The winding device 20 includes a first drum D1 for winding the shoelace W1 therein and a second drum D2 for winding another shoelace W2, and a handle 21 provided on the front is moved back and forth. The shoelace W1 and the other shoelace W2 can be wound up by switching and rotating.
The another shoelace W2 is a shoelace of a different system from the shoelace W1 that passes through the first and second shoelace passage holes H1 in order to tighten the shoe body upper portion 13.

  The shoelaces W2 of this different system are inserted through the fourth shoelace through holes H4 provided in two pairs so as to cross the opening 15 in the left-right direction in the shoe body upper portion 13, and the shoes The main body upper portion 13 can be tightened independently from the shoelace W1.

The winding device 20 can release the wound shoelaces W1, W2 at the same time to loosen the shoelaces W1, W2.
Further, the second to fourth shoelace passing portions H2, H3, and H4 embed a shoelace guide 8 having a substantially “U” -shaped pipe line embedded in the shoe main body 14 along the opening 15. (See FIG. 2).

  In this embodiment, the shoelaces W1 and W2 can be suitably used with a low coefficient of friction such as a woven metal wire rope, but a wire coated with a synthetic resin (coating rope) May be used. Further, it is also possible to use normal fiber shoelaces as the shoelaces W1 and W2 and tighten the shoelaces W1 and W2 without using the winding device 20.

  As a metal wire rope, a wire rope made by twisting 49 strands of stainless steel with a diameter of 0.11 to 0.13 mm is processed with a swaging machine, and the rope diameter is finished to 0.86 mm and cut. A wire rope having a weight of 729N or more can be suitably used.

  Examples of fiber shoelaces include 1) natural fibers such as Manila hemp and sisal, 2) general-purpose synthetic resins such as polyamide, polyester, polyethylene, polypropylene, and polyvinylidene chloride, 3) aramid, Polyarylate-based and ultra-high-molecular-weight polyethylene-based super synthetic fibers can be used, but the take-up device or the method of tightening these shoelaces depends on the strength and characteristics of the shoelaces and the use of the boots. It is necessary to select appropriately.

  That is, according to the selection of the shoelace, a shoelace is inserted through a conventionally known one such as a tube, a shoelace guide formed with a tube-like conduit, an eyelet, a “U” -shaped or “Ω” -shaped metal fitting. It can be used as a thing provided with a shoelace through part.

Next, the structure of the winding device 20 will be described (see FIG. 5).
The winding device 20 includes a mechanism X for rotating the drum D1 for winding the shoelace W1, and a mechanism Y for rotating the drum D2 for winding the shoelace W2.
The mechanism X includes a rotating shaft 30, a bevel gear 31 disposed on the front side of the handle 21 and connected to the rotating shaft 30, a sun gear 35 provided on the rotating shaft 30, and the sun gear 35. Three planetary gears 36 meshing with each other, a planet carrier 37 integrated with the drum D1, an annular gear 38 meshing with the planetary gears 36, and three retaining claws 39a engaged with the annular gear 38. And a static friction force control member 39.

  On the other hand, the mechanism Y includes a rotating shaft 50, a bevel gear 51 disposed on the rear side of the handle 21 and connected to the rotating shaft 50, a sun gear 55 provided on the rotating shaft 50, and the sun gear 55. Three planetary gears 56 that mesh with each other, a planet carrier 57 that is integrated with the drum D2, an annular gear 58 that meshes with the planetary gear 56, and three retaining claws 59a that engage with the annular gear 58. And a static friction force control member 59.

An annular gear 23 is formed on the front surface of the handle 21, and a bevel gear 31 connected to the rotating shaft 30 can be engaged with the gear 23.
On the other hand, an annular gear (not shown) is also formed on the rear surface of the handle 21, and the gear is connected to the rotary shaft 50 in a state where the handle 21 is pushed rearward (toggle 1 side). Engagement with the bevel gear 51 is possible.

When winding the shoelace W1 around the drum D1, the handle 21 pulled forward is rotated leftward (counterclockwise in FIG. 2), and when the shoelace W2 is wound around the drum D2, The handle 21 pushed backward is rotated rightward (clockwise in FIG. 2).
Accordingly, when the shoelace W1 and the shoelace W2 are tightened, the wrist is alternately rotated leftward and rightward with the handle 21 held, so that the shoe is continuously and quickly released without releasing the hand. The string W1 and the shoelace W2 can be tightened.

  In the state where a large tension is not applied to the drums D1 and D2 from the shoelaces W1 and W2, the rotation of the rotary shafts 30 and 50 is performed from the retaining claws 39a and 59a of the static friction force control members 39 and 59 to the annular gears 38 and 59. 58, the drums D1 and D2 are quickly driven to rotate at the same angle as the rotation of the rotary shafts 30 and 50.

  On the other hand, when the shoelaces W1 and W2 are gradually tightened and a large tension is applied from the shoelaces W1 and W2 to the drums D1 and D2, the rotation of the rotary shafts 30 and 50 causes the static friction force control members 39 and 59 to rotate. Can no longer be transmitted to the annular gears 38 and 58, and is transmitted as the rotation of the planetary gears 36 and 56.

Here, the lock pieces 40 and 60 are engaged with the outer peripheral surfaces of the annular gears 38 and 58, and the annular gears 38 and 58 are controlled as a ratchet mechanism so as to rotate only in the direction of tightening the shoelaces W1 and W2. ing.
Therefore, the rotation of the planetary gears 36 and 56 drives the drums D1 and D2 as rotations obtained by decelerating the rotation of the rotation shafts 30 and 50 (with increased torque).

  Note that the ratchet mechanism using the lock pieces 40 and 60 switches the rotation lock state of the annular gears 38 and 58 by the lock pieces 40 and 60 by switching the switch 26 attached to the front surface of the winding device 20 to the left and right positions. It can be controlled to be released at the same time or to rotate only in the direction of tightening the shoelaces W1, W2 by the lock pieces 40,60.

Next, a method for manufacturing the snowboard boot 10 having the shoelace tightening structure of the present invention will be described.
To manufacture the boot 10 having the shoelace tightening structure of the present invention, a sole 11 similar to a normal snowboard boot, and a shoe (having a shoe body upper part 12, a shoe body upper part 13 and an opening part 15). A main body 14 and an inner 16 are provided.

  A second shoelace through hole H2 to a fourth shoelace through hole H4 are formed in the shoe main body 14 along the opening 15 thereof. These shoelace through holes H2 to H4 are provided with a substantially "U" -shaped groove 8a that opens to the side, and a tubular tube is formed by engaging the groove 8a with the lid 8b from the side. The shoelace guide 8 forming the path can be suitably prepared by a conventional manufacturing method in which the shoe main body 14 is embedded (see FIG. 2).

Next, as already explained, by integrating the front portion 1a made of a material having a high strength and the back portion 1b made of a material more flexible than the front portion 1a and bending it into a substantially “L” shape, A tongue 1 having an upper part 3 constituting a lower part of the bent part 2 and a shin part 4 constituting an upper part of the bent part 2 is prepared.
In the tongue 1, at a position slightly above the bent portion 2, a pair of left and right first shoelace holes H 1 are formed in the shin portion 4 along the substantially vertical direction of the tongue 1 so as to reach the inside from the front side of the tongue 1. Form.

  Further, a cross guide portion 5 is fixed to the bent portion 2 of the front portion 1 a of the tongue 1, and a shoelace guide provided with a groove on the shin portion 4 at a position above the cross guide portion 5. 6 is fixed. In the present embodiment, an additional cross guide portion 9 and shoelace guide 6a are fixed on the upper portion 3 of the tongue 1 to prevent the shoelace W1 from being cut due to friction of the shoelace W1 and the tongue 1 from being damaged. .

  Further, a winding device 20 is fixed to the front surface of the shin portion 4 of the tongue 1 at a position above the shoelace guide 6, and the winding device 20 has rigidity in the winding device 20 inside the tongue 1. The upper end is connected, and the lower end of the tube 7 is connected to the first shoelace through hole H1.

The opening 15 cut out in a substantially “V” shape is closed from the inside of the shoe body 14 by sewing the tip 3 a of the tongue 1 manufactured as described above to the shoe body upper part 12. The tongue 1 is attached, and the tongue 1 is disposed inside the shoe main body 14 so as to be movable relative to the shoe main body 14.
Thereafter, the shoelaces W1 and W2 are passed through the shoelace holes H1 to H4 and the tube 7 so that the shoelaces W1 and W2 can be tightened by the winding device 20.

Therefore, the shoelace fastening structure according to the present invention can be manufactured by using the shoe body 14 having the same structure as the conventional shoelace fastening structure.
However, the position of the first shoelace through hole H1 and the second shoelace through hole H2 is the second position when viewed from the side of the tongue 1, as shown in FIG. As shown in FIG. 6 (B), the shoelace through hole H2 has a distance of 1 to 4 cm obliquely downward from the first shoelace through hole H1 across the bent portion 2. When viewed from the front of 1, it is necessary that the second shoelace through hole H <b> 2 be positioned 1 to 4 cm below the first shoelace through hole H <b> 1 with the bent portion 2 interposed therebetween.

If the second shoelace through hole H2 is formed in the front position (toe side) from the above, the tongue 1 is bent so as to be bent forward (see FIG. 3 (A)), so that the tongue 1 is drawn downward. It becomes difficult to exert the action and effect of the invention.
That is, the first shoelace passing portion and the second shoelace passing portion of the present invention that define the exit position of the shoelace are located in the vicinity of the bent portion 2 of the tongue 1 (the bent portion of the ankle of the boot wearer). In order to effectively embody the present invention, it is important to dispose them close to each other with the bent portion 2 in between.

  Even when the first shoelace through hole H1 is formed at a position higher than the above, since the tongue 1 is bent so as to be bent forward, the action and effect of the present invention that draws the tongue 1 downward is exhibited. It becomes difficult to do.

Further, the shoelace W1 from the first shoelace passage hole H1 through the cross guide portion 5 to the second shoelace passage hole H2 is wired so as to be bent downward at the cross guide portion 5, and the shoelace W1 is connected. When the shoelace W1 is made to be close to a straight line by tightening, the effect of efficiently pulling the bent portion 2 of the tongue 1 downward can be exhibited.
Further, by arranging the crossing guide portion 5 in the portion formed in the mountain shape of the upper portion 3 of the tongue 1, when the shoelace W1 is tightened, the upper portion 3 is attracted downward by the shoelace W1. (See FIG. 4A). That is, while the shoelace W1 extends from the shoelace passage hole H1 to the shoelace passage hole H2, the shoelace W1 comes into contact with the upper portion of the upper portion 3 (in the present embodiment, the cross guide portion 5). It is also possible to exert an effect of urging the upper part 3 of the back of the back part 3 by the shoelace W1.

  Even with a relatively small tightening force, the boot 10 having the shoelace tightening structure configured as described above draws the tongue 1 toward the upper part of the boot wearer, The area around the bent part of the ankle could always be directly and effectively tightened, and good control performance could be stably exhibited during snowboarding.

Next, with respect to the structure in which the first shoelace through hole H1 is formed in the tongue 1, in the above embodiment, the through hole extending from the front side of the tongue 1 to the inside is formed. It can also be realized by forming a first shoelace threading portion H1a that guides the shoelace W1 through the shoelace W1.
The first shoelace passing portion H1a is formed, for example, by forming a cylindrical protrusion having a through hole in the radial direction on the surface of the tongue 1, or a substantially “Ω” -shaped member or “2” -shaped member. It can be provided by fixing the member to the front side of the tongue 1.

  Thus, when the shoelace W1 is passed through the front side (outside) of the tongue 1 ((A) to (C) shown in FIG. 7) and when the shoelace W1 is passed through the inside (inside) of the tongue 1 ( Table 1 below shows the results of a comparative study by changing the installation position (height) in each case of (D) to (F) shown in FIG.

  Therefore, even if the present invention is embodied by forming the first shoelace threading portion H1a through which the shoelace W1 passes through the outside of the tongue 1, the first shoe through which the shoelace W1 passes through the tongue 1 is realized. As with the case where the lace-through hole H1 is formed in the tongue 1, the effect of tightening the ridge portion 4 of the tongue 1 downward and pulling the boot wearer's back and ankle directly directly can be demonstrated. It has been found that when the string W1 is passed through the tongue 1, the applicable range as the position for forming the first lace shoelace passing portion is preferably wider.

  This is considered to be because it is easier for the shoelace W1 to be pulled out from the back side of the tongue 1 to exhibit the effect of pulling the tongue 1 downward rather than forward.

  The shoelace tightening structure configured as described above can reliably eliminate gaps between the tongue and the back and ankle of the wearer, and keeps the boot properly attached at all times. Therefore, the original performance of the boots and snowboard and the wearer's skill can always be maximized.

The present invention is not limited to the above-described embodiment. As shown in FIG. 8A, the second shoelace passing through the first shoelace passing portion H1 without crossing the shoelace W1 is provided. The shoelace W1 may be passed through the hole H2.
However, in this case, the tightening force in the direction of closing the opening 15 of the shoe main body 14 is slightly inferior, the effect of pulling the upper part 3 of the tongue 1 downward is reduced, or between the shoe main body 14 and the tongue 1 Although there is a possibility that a gap may be formed, the strength distribution and shape of the shoe body 14 around the tongue 1 and the opening 15 may be changed as appropriate, and the shoelace through holes H1 and H2 may be arranged without departing from the spirit of the present invention. It is also possible to reduce these problems by making appropriate changes.

Furthermore, as shown in FIG. 8 (B), only one first shoelace through hole H1 is formed at the slightly upper central portion of the bent portion 2 of the tongue, and the shoelace W1 is formed as the second shoelace through hole H2. You may implement so that it may penetrate.
Even in this case, since the crossing guide part 5 does not cross the shoelaces W1, the effect of attracting the upper part 3 of the tongue 1 downward may be lowered. However, the strength distribution and shape of the tongue 1 are appropriately determined. It is possible to alleviate these problems by changing them.

Further, the present invention is not limited to the above-described embodiments, and may be embodied by being embodied in a shoelace tightening structure for boots used for skiing, skating, mountain climbing, riding a motorcycle, and the like.
Further, without using the winding device 20 that winds up the shoelace W1 and the shoelace W2 in order to fasten the upper portion of the shoe body, a winding device that winds only the shoelace W1 is used, and a belt or You may implement by attaching the buckle 70 and fastening the shoe main body upper part 13 with those belts or the buckle 70 (refer FIG. 8 (B)).

Further, without using a winding device for winding the shoelace W1, the shoelace is pulled out from a hole formed in the upper portion of the tongue (for example, a position corresponding to the upper end of the tube 7), and the shoelace is tightened by hand. You may carry out like that.
Moreover, when the possibility that the shoelaces W1 are damaged due to rubbing of the shoelaces W1 does not cause a problem in practice, the cross guide portions 5 and 9 may be omitted.

  When the present invention is embodied, at least the vicinity of the bent portion of the tongue has a certain degree of rigidity as described above, and the bent portion of the tongue is tightened by tightening the shoelace inserted into the first shoelace passing portion. It is necessary to be able to demonstrate the effect of pulling the vicinity downward, but within the range not departing from the spirit of the present invention, the material, shape, dimensions, strength, installation, etc. of tongue, shoe body, shoelace through hole, shoelace, winding device, etc. The position, thickness, size, number, and the like may be changed as appropriate.

  The present invention relates to a shoe lace in a boot used for skiing, snowboarding, skating, mountain climbing, riding a motorcycle, etc. (preferably a boot having a tongue extending above an ankle and having a shoe body having rigidity). It can be used as a fastening structure and a shoelace fastening method.

DESCRIPTION OF SYMBOLS 1 Tan 1a Front part 1b Back part 2 Bending part 3 Back part 3a Tip part 4 Shank part 5 Crossing guide part 5a Guide hole 5b Guide hole 6 Shoelace guide 6a Shoelace guide 7 Tube 8 Shoelace guide 8a Concave groove 8b Lid 9 Crossing guide part 10 Snowboard boot 11 Sole 12 Shoe body upper part 13 Shoe body upper part 14 Shoe body 15 Opening part 16 Inner 20 Winding device 21 Handle 23 Gear 26 Switch 30 Rotating shaft 31 Bevel gear 35 Sun gear 36 Planetary gear 37 Planet Carrier 38 Annular gear 39 Static friction force control member 39a Stop claw 40 Lock piece 50 Rotating shaft 51 Bevel gear 55 Sun gear 56 Planet gear 57 Planet carrier 58 Annular gear 59 Static friction force control member 59a Stop claw 60 Lock piece 70 Belt or buckle 90 Skate Boots (prior art)
91 opening 92 tongue (tongue)
93 Flap H1 First shoelace through hole H1a First shoelace through hole H2 Second shoelace through hole H3 Third shoelace through hole H4 Fourth shoelace through hole W Shoelace W1 Shoelace W2 Shoe String X Mechanism for winding shoelace W1 Y Mechanism for winding shoelace W2

Claims (6)

A tongue that has an instep and a shin and is bent and formed so as to be movable relative to the shoe body;
A first shoelace passing portion provided at the shin portion of the tongue;
A second shoelace passing portion provided in the shoe body at a position below the first shoelace passing portion;
A shoelace tightening structure characterized in that the shin portion of the tongue can be drawn downward by tightening a shoelace passing through the first and second shoelace passage portions.   2. The shoelace tightening structure according to claim 1, wherein the tongue includes a cross guide portion that allows the shoelace to pass through at a bent portion thereof, so that the shoelaces do not contact each other. .   3. The shoelace tightening structure according to claim 1, wherein the tongue includes a winding device for winding the shoelace on the front surface of the shin portion.   The first shoelace passing portion is a shoelace passing hole formed so as to extend from the front side to the inside or the back side of the tongue, and is provided in the vicinity of the bent portion of the tongue. The shoelace tightening structure according to any one of claims 1 to 3.   The tongue includes a winding device for winding a shoelace of a different system from the shoelace passing through the first and second shoelace passing portions in order to fasten the upper portion of the shoe main body on the front surface of the shin portion. The shoelace tightening structure according to any one of claims 1 to 4, wherein the shoelace tightening structure is provided. A tongue that has an instep and a shin and is bent and formed so as to be movable relative to the shoe body;
A first shoelace passing portion provided at the shin portion of the tongue;
A second shoelace passing portion provided on the shoe body at a position below the first shoelace passing portion;
A method for tightening shoe laces, wherein the shin portion of the tongue is drawn downward by tightening a shoe lace inserted into the second shoe lace passage portion from the first shoe lace passage portion. .

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