HIGH-HEELED SHOE SOLE STRUCTURE AND HIGH-HEELED SHOE INCLUDING SAME
The present invention discloses a sole structure of a high-heeled shoe that may have a walking mechanism similar to movement of human walking when a pedestrian wears and walks in high-heeled shoes. A sole structure of a high-heeled shoe of the present invention includes: a front portion supported on the ground; a bending portion that extends from the front portion to be positioned at a rear side of a metatarsophalangeal joint and is bent in an opposite direction to the ground; and a rear portion extending from the bending portion.
The present invention relates to a high-heeled shoe sole structure and a high-heeled shoe including the same that may have a walking mechanism similar to movement of human walking when a pedestrian wears and walks in high-heeled shoes.
BACKGROUND ARTDuring a human gait cycle, at the heel off and toe off period after the midstance, extension of the metatarsophalangeal joints occurs, and simultaneously, inversion and adduction of the heel of the foot occur.
A pedestrian wearing conventional high-heeled shoes suffers from an ankle sprain due to instability of a rearfoot depending on a high heel, when a body's weight is loaded on the ground while standing or walking. Therefore, a sole structure of the conventional high-heeled shoes is made of a very hard material in which a metal shank is inserted from a rear boundary of a front portion that is a portion where the shoe contacts the ground and is supported on the ground to an end of the rearfoot.
In addition, in the state of wearing conventional high-heeled shoes, since a plantar fascia is tightly pulled, passive movement occurs in which toes are bent toward the sole. Therefore, in the foot in the state of wearing the conventional high-heeled shoe, force to be bent to a ground direction is applied to a front portion thereof, which is a portion of the high-heeled shoe supported by the ground. Therefore, the front portion of the high-heeled shoe is substantially made to maintain a shape of the shoe in a swing phase in which the body weight is not loaded on the ground. Particularly, when a platform is attached to a sole of the front portion of the high-heeled shoe supported by the ground, movement of the forefoot and rearfoot is not allowed at all.
In addition, the extension occurs in a direction of the instep at the metatarsophalangeal joints at the heel off and toe off after the midstance. However, since the conventional high heel sole structure is not flexible, it cannot cope with this, and thus there is a problem in that the heel comes out of the shoe, so that it is difficult to normally walk.
General high-heeled shoes are manufactured through the following process.
First, a high-heeled shoe is manufactured by combining a general sole structure (S) and a last (L), putting an upper (U) thereon and then firmly combining the upper (U) to the general sole structure (S). In addition, the high-heeled shoe is manufactured by combining a heel (H) and an outsole (O) to the general sole structure (S). In the general sole structure (S), a metal shank (MS) is inserted from a rear boundary (BL) of a portion (portion A in
Meanwhile, the body weight-bearing area in the foot is the heel, the head of the first metatarsal bone, and the head of the fifth metatarsal bone. The above-mentioned three portions are connected to each other in an arch form, enabling efficient body weight-bearing and walking.
In the high-heeled shoe, a posterior part of the foot behind the heads of metatarsal bones (MTBH) is artificially raised. Therefore, a portion (B) of the conventional sole structure (S) that is not supported by the ground but is in the air is made of a very solid material. In addition, the heel (H) of the high-heeled shoe is coupled to the posterior part of the conventional sole structure (S) to maintain the shape of the shoe.
Generally, when high-heeled shoes are worn, the metatarsophalangeal joints (MTP) are always maintained in an extended state due to the shape of the shoe, so that the plantar fascia (PF) is tightly pulled (which is indicated by an arrow of an imaginary line in
The conventional sole structure (S) is not bent during the heel off even if the portion supported on the ground is made to be flexible to some extent. Since the body weight is loaded onto the ground through the heads of metatarsal bones (MTBH) during the heel off, even if the heel is separated from the ground, the front portion of the foot including the heads of metatarsal bones (MTBH) contacts to the ground. Accordingly, in the conventional sole structure (S), even if the portion supported on the ground is somewhat flexible, the sole structure (S) is not bent during the heel off, so that the heel comes out of the shoe.
During the toe off, the heads of metatarsal bones (MTBH) is separated from the ground and the body weight is loaded only on the toes. Accordingly, when the portion supported on the ground in the conventional sole structure (S) is flexibly manufactured to some extent, it may be bent to some extent in a lower portion of the metatarsophalangeal joint. However, even in this case, since it is not bent enough to follow the movement of the foot, and the heel comes out from the shoe as shown in
Therefore, since the high-heeled shoe to which the conventional sole structure S is applied is not suitable for the movement of the foot according to the walking, it is not possible to effectively support the foot.
DISCLOSURE Technical ProblemTherefore, the present invention has been made in an effort to provide a high-heeled shoe sole structure and a high-heeled shoe including the same that may maintain a shape of a shoe by limiting flexion of a metatarsophalangeal joint during a swing phase, and may improve stability of walking by supporting a body weight during a stance phase or standing when the body weight is loaded on the ground.
In addition, the present invention has been made in an effort to provide a high-heeled shoe sole structure and a high-heeled shoe including the same that may be optimized for foot movement by allowing extension of a metatarsophalangeal joint during heel off and toe-off while walking.
Technical SolutionAn embodiment of the present invention provides a sole structure of a high-heeled shoe, including: a front portion supported on the ground; a bending portion that extends from the front portion to be positioned at a rear side of a metatarsophalangeal joint and is bent in an opposite direction to the ground; and a rear portion extending from the bending portion.
The bending portion may include a bending curved portion that forms a concave curve in an opposite direction to the ground.
In the bending curved portion, a curvature of a transverse center line of the bending portion that is parallel to a transverse axis of a foot and formed along a line crossing a longitudinal center line of the bending portion may be larger than that of the longitudinal center line of the bending portion formed along a longitudinal axis of the foot.
The bending portion may be concavely bent in a direction opposite to the ground during heel off and toe off in a gait cycle, and may be limited to be bent in a ground direction during a swing phase in the gait cycle.
The bending portion may be bent during heel off and toe off in a gait cycle such that the rear portion may correspond to foot movement in inversion and adduction directions of a foot.
In the transverse center line of the bending portion, a curvature of a lateral side portion may be larger than that of a medial side portion.
In the bending portion, a thickness of a lateral side portion may be thicker than that of a medial side portion.
The bending portion may include at least one or more bending adjustment holes or bending adjustment grooves that make degrees of bending of a medial side portion and a lateral side portion different.
Another embodiment of the present invention provides a high-heeled shoe provided with a sole structure, wherein the sole structure includes: a front portion supported on the ground; a bending portion that extends from the front portion to be positioned at a rear side of a metatarsophalangeal joint and is bent in an opposite direction to the ground; and a rear portion extending from the bending portion.
Advantageous EffectsAccording to the embodiment of the present invention, by forming a one-way bending portion that is bent only in an opposite direction to the ground or a bending curved portion that is concave in the opposite direction to the ground in a sole structure behind a ground support boundary line of a front portion or behind a metatarsophalangeal joint, it is possible to improve stability of walking when walking in high-heeled shoes by limiting flexion of the metatarsophalangeal joint during a swing phase and maintaining stability of a foot during a stance phase or standing.
In addition, according to the embodiment of the present invention, movement of a sole structure coincides with extension movement of a metatarsophalangeal joint and adduction movement and inversion movement of a heel, by a bending portion formed in the sole structure at a rear side of a metatarsophalangeal joint or a ground support boundary line during heel off and toe-off while walking, thereby stably and comfortably walking.
The present invention will be described more fully hereinafter with reference to the accompanying drawings, in which embodiments of the invention are shown. As those skilled in the art would realize, the described embodiments may be modified in various different ways, all without departing from the spirit or scope of the present invention. In order to clearly describe the present invention, portions that are irrelevant to the description are omitted, and identical or similar constituent elements throughout the specification are denoted by the same reference numerals.
The terms used in the description of an embodiment of the present invention will be defined as follows.
Anterior (A) (or distal) means a direction of a toe, and posterior (P) (or proximal) means an opposite direction of the toe, that is, a direction of a heel of a foot. Medial (M) means a direction toward a center of a body, and lateral (L) means an opposite direction of the center of the body. Superior (S) (or dorsal) means a direction of an instep, and inferior (I) (or plantar) means an opposite direction of the instep, that is, a direction toward the ground.
In addition, a longitudinal axis (LA) of a foot means a length direction of the foot. A transverse axis (TA) means a line connecting the first metatarsophalangeal joint (MTP1) and the fifth metatarsophalangeal joint (MTP5) while intersecting with the longitudinal axis (LA).
A metatarsophalangeal joint (MTP) means a joint between metatarsal bones (MTB) and proximal phalanx (PP).
A forefoot FF means an anterior portion based on a tarsometatarsal joint (TMT). A midfoot MF means between a tarsometatarsal joint (TMT) and a transverse tarsal joint (TT). A rearfoot (RF) means a posterior portion of the transverse tarsal joint (TT).
Heads of metatarsal bones (MTBH) mean head portions of the metatarsal bones (MTB). The head of the first metatarsal bone (MTBH1), the head of the fifth metatarsal bone (MTBH5), and the heel are areas in which a body weight is loaded on the ground while standing or walking.
The movement of the foot according to the gait cycle of the human based on the bare foot will be described with reference to
In
The human gait cycle is divided into a stance phase and a swing phase based on one foot (hatched portions in the drawing).
The stance phase is a state in which a portion of the foot contacts the ground while walking. The stance phase may be divided into five stages: heel strike, loading response, midstance, heel off, and toe off.
The heel strike refers to the moment when the heel comes into contact with the ground. The loading response is a stage in which the entire sole of the foot comes into contact with the ground after the heel strike.
The heel strike and loading response are processes of absorbing impact from the ground and distributing the body weight (shown in
On the other hand, the swing phase refers to a state in which the foot is away from the ground. During the swing phase, there should be sufficient toe clearance. That is, when the toe is not dragged or caught on the ground, the risk of a fall is reduced and stable walking is achieved. The gait is realized by repeatedly performing the stance phase and the swing phase.
Since the heel leaves the ground after the midstance, movement of the heel occurs based on the front foot in contact with the ground. In the stage of the heel off, the body weight is loaded on the ground by contacting the ground from the heads of metatarsal bones (MTBH) to toes.
In the heel off state of the barefoot, the extension (movement in a direction of an imaginary arrow line in
In addition, at the same time, the inversion (movement in a direction of an imaginary curved arrow line (i) in
In the stage of the toe off, as the heads of metatarsal bones (MTBH) leaves the ground, the body weight is loaded on the ground only through the toes.
As shown in
As shown in
As shown in
The curvature of the curved line is expressed as a curvature at a point on the curved line. Therefore, a curvature value of a two-dimensional plane curve may be compared with a curvature value of a point having a maximum curvature value in each plane curve. Alternatively, it may also be compared with an average of the curvature values at all points on the curve.
The high-heeled shoe of the first embodiment of the present invention includes a foot fixing portion 1, an insole 3, a sole structure 5, an outsole 7, and a heel 9.
The foot fixing portion 1 is a portion that may wrap the foot, forms a shape of the shoe, and is made of leather, etc. In addition, the insole 3 is a portion that is in direct contact with the sole of the foot. The sole structure 5 may support a load of a pedestrian, and simultaneously, maintain a shape of the shoe. In addition, the insole 3 may be coupled to an upper side of the sole structure 5. The outsole 7 is coupled to a lower portion of the sole structure 5, and a front side thereof directly contacts the ground. The heel 9 is coupled to the sole structure 5 to support a load of the heel of the foot.
The sole structure 5 of the embodiment of the present invention is a sole that supports a body weight in the high-heeled shoe and serves as a frame of the shoe, and it may be referred to by a term such as a midsole or inner sole.
The sole structure 5 of the first embodiment of the present invention includes, as shown in
The front portion 11 is a portion in which the front side of the high-heeled shoe is supported on the ground during the loading response.
The first embodiment of the present invention will be described by illustrating an example in which the front portion 11 has a size that covers only some of the portion supported on the ground. In the sole structure 5 of the first embodiment of the present invention, when the front portion 11 is formed to have a size that covers only some of the portion supported on the ground, as shown in
The front portion 11 may include a ground support boundary line BL having a round-shaped boundary concave toward the front when a rear portion of the front portion 11 extending to the bending portion 13 is viewed in a plan view.
The ground support boundary line BL of the front portion 11 allows the front portion 11 to be firmly supported on the ground, thereby improving the stability of walking during the stance phase. In addition, the front portion 11 is limited in bending due to the shape of the ground support boundary line BL, so that the shape of the shoe may be maintained.
The bending portion 13 may include a one-directional bending portion that is bent only in a direction opposite to the ground, or a bending curved portion that forms a concave curve in an opposite direction to the ground.
The bending portion 13 preferably extends from the ground support boundary line BL of the front portion 11 to be positioned at the rear side of the metatarsophalangeal joint (MTP). In other words, the bending portion 13 is preferably positioned at the heel side based on the ground support boundary line BL of the front portion 11. That is, the bending portion 13 may be positioned between the ground support boundary line BL of the front portion 11 and a boundary line (indicated by dotted lines in
The bending portion 13 may be formed of the bending curved portion, so that the bending may be limited in the direction toward the ground, and may be flexibly bent in the direction opposite to the ground. That is, the bending portion 13 may be bent in one direction toward the direction opposite to the ground.
It is preferable that the bending portion 13 is formed of the bending curved portion that forms a concave curve in the direction opposite to the ground. Accordingly, in the bending portion 13, longitudinal lines 13a (imaginary lines indicated in the longitudinal direction in
It is preferable that a curvature r2 of the transverse center line 13bc of the bending portion is larger than a curvature r1 of the longitudinal center line 13ac of the bending portion. Since the curvature refers to an instantaneous change rate of a slope of a tangent line of a point that moves along a curved line at a constant speed, a curvature of a plane curve is expressed as a curvature at a point on the curve. Therefore, in the description of the present invention, “the curvature r2 of the transverse center line 13bc of the bending portion is larger than the curvature r1 of the longitudinal center line 13ac of the bending portion” means that a curvature value of a point having a maximum curvature value at the transverse center line 13bc of the bending portion is larger than a curvature value of a point having a maximum curvature value at the longitudinal center line 13ac of the bending portion. Alternatively, it means that an average of the curvature value of the transverse center line 13bc of the bending portion is larger than an average of the curvature value of the longitudinal center line 13ac of the bending portion. In addition, in comparing the curvature values, a boundary portion of the bending portion 13, particularly a boundary portion with the front portion 11 or curvature values at both ends, are substantially excluded.
As described above, when the curvature r2 of the transverse center line 13bc of the bending portion is larger than the curvature r1 of the longitudinal center line 13ac of the bending portion, as described in
The bending portion 13 has the flexibility to be bent in the same direction as the movement of the extension of the metatarsophalangeal joint (MTP) during the heel off and toe off after the midstance while walking. Therefore, like walking with bare feet, even when wearing high-heeled shoes, a pedestrian may naturally walk during the heel off and toe off.
In addition, as the bending portion 13 is bent in the same direction as the bare foot movement during the heel off and toe off while walking, since the rear portion 15 also moves upward, so that the heel rises, and the bending portion 13 serves to prevent the heel from coming out of the foot fixing portion 1.
When a wearer wears the high-heeled shoes, the plantar fascia (PF) is tautly pulled, so that force to flex the metatarsophalangeal joint (MTP) is generated (shown in
Since the bending portion 13 of the present invention is limited to be bent in the ground direction during the swing phase, the flexion of the metatarsophalangeal joint (MTP) is also limited. Therefore, sufficient toe clearance is provided during the swing phase, so that the tip of the shoe is not dragged or caught on the ground, resulting in stable walking.
Meanwhile, inner and outer edge portions of the bending portion 13 may form support reinforcing portions 13e and 13f further extending to the front portion 11 and both sides of the ground support boundary line BL. Since the support reinforcing portions 13e and 13f of the bending portion 13 extend upward from both sides of the round-shaped ground support boundary line BL, they may allow concave bending in the opposite direction to the ground, but may further limit bending in the ground direction.
Therefore, the sole structure 5 of the present invention allows more easily the extension of the metatarsophalangeal joint (MTP) during the heel off and toe off. In addition, the sole structure 5 of the present invention may further limit the flexion of the metatarsophalangeal joint (MTP) during the swing phase. Therefore, a pedestrian wearing the high-heeled shoes may walk with more stability.
As described above, since the sole structure 5 of the present invention has a simple structure, it is possible to reduce production cost. That is, the sole structure 5 of the present invention may secure the movement of the extension of the metatarsophalangeal joint (MTP) during the heel off and toe off after the midstance, as much as possible. At the same time, the sole structure 5 of the present invention has a structure that limits the movement of the flexion of the metatarsophalangeal joint (MTP) during the swing phase, and has a simple structure, so that it may be easily applied to high-heeled shoes, and it is possible to reduce the manufacturing cost.
In the bending portion 13 of the first embodiment of the present invention, it is preferable that the curvature r3 of the outer portion 13c is larger than the curvature r4 of the inner portion 13d. The bending portion 13 means that the inner portion 13d is more flexible than the outer portion 13c.
After the midstance, the heel 9 of the shoe leaves the ground, so that only the front portion 11 of the sole structure 5 contacts the ground, and the weight is loaded on the ground through the front portion 11 of the sole structure 5. Therefore, during the heel off and toe off, movement occurs in the remaining rear portion of the sole structure 5 while the front portion 11 is fixed to the ground. That is, a direction of movement of the rear portion 15 is determined by a difference in flexibility between the inner portion 13d and the outer portion 13c in the bending portion 13.
Therefore, in the sole structure 5 of the present invention, during the heel off and toe off in the gait cycle, the rear portion 15 extending rearward from the bending portion 13 rises upward (in a direction of an imaginary arrow line in
The rear portion 15 is a portion that may extend from the bending portion 13 to the rear to support the heel. As shown in
When walking in a state of wearing the high-heeled shoes, the front portion 11, the bending portion 13, and the rear portion 15 allow the sole structure 5 to be bent corresponding to the three-dimensional movement of the sole, so that stable walking may be realized. In addition, the sole structure of the present invention may be processed with a synthetic resin material of the same material, thereby reducing manufacturing cost.
Therefore, the sole structure 5 of the first embodiment of the present invention enables stable walking by maintaining the extension of the metatarsophalangeal joint during the swing phase and the heel strike.
In addition, in the bending portion 13, the front portion 11 supports the ground during the loading response immediately after the heel strike, and in this case, bending is limited as well.
The bending portion 13 of the present invention is bent while forming a concave curve upward during the heel off because the curved directions with respect to the longitudinal axis and the transverse axis are the same. In addition, the bending portion 13 is further limited in bending toward the ground along the longitudinal axis crossing the transverse axis, by the structure in which the curvature r2 of the transverse center line 13bc of the bending portion is larger than the curvature r1 of the longitudinal center line 13ac of the bending portion during the heel off.
In addition, the rear portion 15 moves corresponding to the movement of inversion and adduction of the heel, by the structure in which in the transverse center line 13bc of the bending portion, the curvature r3 of the outer portion 13c is larger than the curvature r4 of the inner portion 13d. Accordingly, the sole structure 5 of the first embodiment of the present invention is bent in the same direction as the movement of the extension of the metatarsophalangeal joint (MTP) similar to walking in bare feet, and at the same time, is bent in the same direction as the movement of the inversion and adduction of the foot. Therefore, according to the first embodiment of the present invention, walking with stability is realized even when walking with the high-heeled shoes.
In addition, according to the sole structure 5 of the first embodiment of the present invention, as the bending portion 13 is easily bent in the direction opposite to the ground, the rear portion 15 moves in the same direction as the movement of the heel, thereby preventing the shoe from being separated from the heel.
On the other hand,
In the sole structure 5 of the second embodiment of the present invention, in order to further enhance the one-way flexibility of the bending portion 13 and in order that bending degrees of an inner portion 13h (medial side portion) and an outer portion 13i (lateral side portion) are different, at least one bending adjustment groove 13g may be provided in the bending portion 13. In the second embodiment of the present invention, an example provided with one bending adjustment groove 13g will be illustrated and described.
The sole structure 5 of the second embodiment of the present invention may further enhance the one-way flexibility of the bending portion 13 by providing the bending adjustment groove 13g in a center of the bending portion 13 to reduce a thickness thereof. In other words, the bending portion 13 may be configured so that a thickness T1 of a center portion thereof is thinner than thicknesses T2 and T3 of edges thereof. In addition, the bending portion 13 may be configured so that, by making the thickness T2 of the inner edge thinner than the thickness T3 of the outer edge, it more smoothly corresponds to the inversion and adduction movements of the heel during the heel off and the toe off. In the first embodiment of the present invention described above, the example in which the boundary portion BL between the front portion 11 and the bending portion 13 is formed of the round-shaped line has been described, but in the boundary portion between the front portion 11 and the bending portion 13 of the second embodiment of the present invention, the front portion 11 and the bending portion 13 may be connected by a smooth curved surface.
In addition, as shown in
In the third embodiment of the present invention, when the front portion 11 extends in the toe direction, that is, forward, it may cover the entire support portion. That is, in the third embodiment of the present invention, the front portion 11 and the auxiliary member Sb are integrally configured, compared with the first embodiment. That is, according to the third embodiment of the present invention, the number of parts may be reduced by manufacturing the sole structure 5 in one process by omitting the auxiliary member Sb.
In the sole structure 5 of the fourth embodiment of the present invention, in order to further enhance the one-way flexibility of the bending portion 13 and in order that bending degrees of an inner portion (medial side portion) and an outer portion (lateral side portion) are different, at least one or more bending adjustment holes 13j and 13k may be provided in the bending portion 13.
As in the case of having the bending adjustment holes 13j and 13k of the fourth embodiment of the present invention and the bending adjustment groove 13g of the second embodiment, a very large curvature value may occur at a boundary portion between the bending adjustment holes 13j and 13k or the bending adjustment groove 13g. Therefore, in comparing the curvature of the transverse center line 13bc of the bending portion and the curvature of the longitudinal center line 13ac of the bending portion, it is natural that the curvature value at this boundary portion is excluded.
According to the fourth embodiment of the present invention, it is possible to more easily bend the bending portion 13 in one direction, by forming the bending adjustment holes 13j and 13k in the bending portion 13.
In addition, in the fourth embodiment of the present invention, the size of the bending adjustment hole 13j formed in the medial side portion may be larger than the size of the bending adjustment hole 13k formed in the lateral side portion. The fourth embodiment of the present invention may allow the rear portion 15 to move corresponding to the inversion and adduction movements of the heel during the heel off and the toe off. In addition, the bending adjustment holes 13j and 13k may be formed as a plurality of small holes, and a degree of bending may be varied by forming different sizes or intervals of holes and the number of holes. The fifth embodiment of the present invention also shows that it may be configured in various ways to achieve the purpose of the present invention.
While this invention has been described in connection with what is presently considered to be practical embodiments, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims.
Claims
1. A sole structure of a high-heeled shoe, comprising:
- a front portion supported on the ground;
- a bending portion that extends from the front portion to be positioned at a rear side of a metatarsophalangeal joint and is bent in an opposite direction to the ground; and
- a rear portion extending from the bending portion.
2. The sole structure of the high-heeled shoe of claim 1, wherein
- the bending portion includes a bending curved portion that forms a concave curve in an opposite direction to the ground.
3. The sole structure of the high-heeled shoe of claim 2, wherein
- in the bending curved portion,
- a curvature of a transverse center line of the bending portion that is parallel to a transverse axis of a foot and formed along a line crossing a longitudinal center line of the bending portion is larger than that of the longitudinal center line of the bending portion formed along a longitudinal axis of the foot.
4. The sole structure of the high-heeled shoe of claim 1, wherein
- the bending portion is concavely bent in a direction opposite to the ground during heel off and toe off in a gait cycle, and is limited to be bent in a ground direction during a swing phase in the gait cycle.
5. The sole structure of the high-heeled shoe of claim 1, wherein
- the bending portion is bent during heel off and toe off in a gait cycle such that the rear portion corresponds to foot movement in inversion and adduction directions of a foot.
6. The sole structure of the high-heeled shoe of claim 3, wherein
- in the transverse center line of the bending portion,
- a curvature of a lateral side portion is larger than that of a medial side portion.
7. The sole structure of the high-heeled shoe of claim 1, wherein
- in the bending portion,
- a thickness of a lateral side portion is thicker than that of a medial side portion.
8. The sole structure of the high-heeled shoe of claim 1, wherein
- the bending portion includes at least one or more bending adjustment holes or bending adjustment grooves that make degrees of bending of a medial side portion and a lateral side portion different.
9. A high-heeled shoe provided with a sole structure,
- wherein the sole structure includes:
- a front portion supported on the ground;
- a bending portion that extends from the front portion to be positioned at a rear side of a metatarsophalangeal joint and is bent in an opposite direction to the ground; and
- a rear portion extending from the bending portion.
10. The high-heeled shoe of claim 9, wherein
- the bending portion includes a bending curved portion that forms a concave curve in an opposite direction to the ground.
11. The high-heeled shoe of claim 10, wherein
- in the bending curved portion,
- a curvature of a transverse center line of the bending portion that is parallel to a transverse axis of a foot and formed along a line crossing a longitudinal center line of the bending portion is larger than that of the longitudinal center line of the bending portion formed along a longitudinal axis of the foot.
12. The high-heeled shoe of claim 9, wherein
- the bending portion is concavely bent in a direction opposite to the ground during heel off and toe off in a gait cycle, and is limited to be bent in a ground direction during a swing phase in the gait cycle.
13. The high-heeled shoe of claim 9, wherein
- the bending portion is bent during heel off and toe off in a gait cycle such that the rear portion corresponds to foot movement in inversion and adduction directions of a foot.
14. The high-heeled shoe of claim 11, wherein
- in the transverse center line of the bending portion,
- a curvature of a lateral side portion is larger than that of a medial side portion.
15. The high-heeled shoe of claim 9, wherein
- in the bending portion,
- a thickness of a lateral side portion is thicker than that of a medial side portion.
16. The high-heeled shoe of claim 9, wherein
- the bending portion includes at least one or more bending adjustment hole or bending adjustment groove that makes degrees of bending of a medial side portion and a lateral side portion different.
Type: Application
Filed: Nov 12, 2019
Publication Date: Dec 23, 2021
Inventor: Il Soo KIM (Yongin-si)
Application Number: 17/297,026