DEVICE FOR THREE-DIMENSIONAL CONTROL OF FOOT MOVEMENT AND REDISTRIBUTION OF PLANTARY PRESSURE

专利摘要:
The device (1) comprises: a main arch supporting body (10), used to support the medial longitudinal arch, the transverse arch and the lateral longitudinal arch of the foot, comprising a rear end (10b) having at least one lateral side extending as far as the location of the calcaneus of the foot; said vault support main body (10) is a three-dimensional structure formed by curvatures of the medial longitudinal vault, the transverse vault and the lateral longitudinal vault, adapted to collaborate therewith; and a rear foot movement adjustment portion (20) used to modify the heel strike angles.
公开号:FR3046723A1
申请号:FR1750008
申请日:2017-01-02
公开日:2017-07-21
发明作者:Keh Tao Liu；Sai Wei Yang；Tsung-Hsin Chen；Hisayoshi Kobayashi
申请人:Global Action Inc；
IPC主号:

专利说明:

FIELD OF THE INVENTION
The present invention relates to a support device and movement control of a foot in three dimensions, used to control movements of the ankle joint and plantar pressure adjustments during movements of a human body.
BACKGROUND OF THE INVENTION
[0002] The feet serve as a base for supporting a human body, and each foot is known to include 28 bones, 107 ligaments, 32 muscles and 57 joints. It is the most complicated musculoskeletal system of the human body. The main joints of this include the ankle joint, subtalar joint, transverse tarsal joint, metatarsophalangeal joint and interphalangeal joint.
In general, the feet can be classified into three different types depending on the height of the arch: hollow foot ("pes cavus"), normal foot and flat foot. During the walking of flat-footed people, normally, because the arch is drooping, there is a greater pronation during the period from contact of the heel to the ground to the middle of the feet so that this tends to cause excessive supination over the pulse period of the foot. As a result, heel and metatarsal feet of flat feet have a higher level of plantar pressure compared to a normal level of normal feet. In normal activities, no particular symptoms appear; however, in the long term, the feet are likely to produce fatigued, painful or even pathological plantar changes compared to those with normal feet, which can also cause damage to the knee joints and joints. spine. For those with flat feet, due to the longest period of excessive pronation on the feet, the joints of the feet, ankle joints and lower extremities are likely to have to withstand excessive tension and compensation by the internal rotation of the hip joints; these also cause excessive pressure and lateral pulling force in the medial patella leading to pain in the patella, chronic foot fatigue, tendonitis, plantar fasciitis and metatarsalgia.
[0004] In order to maintain the balance of the body and the stability of forward movements during walking, the relative movements produced by the foot and the joints thereof are very complicated. The foot adjusts the movements of each foot joint with the tendons, ligaments and other soft tissues of the foot to achieve stability while walking, and adapts to different environments. When a human body is walking or running, the relative movements between the foot and the ground can be classified into three stages: heel swing, ankle swing and forefoot swing. When the foot touches the ground, a reaction force is applied to the calcaneus and increases rapidly during the initial contact of the heel. At this time, the reaction force will reach 40% of the weight in 0.05 seconds, reaching 110 percent to 120 percent of the weight in 0.13 seconds (loading response). Following the sway forward of the body, the center of pressure moves forward from the back foot. The forefoot reaction force reaches more than 120% of the weight during the foot push period, and this reaction force is even higher during a run.
The medial side of the lateral side may occasionally contact the ground moderately, and the reaction force of this area is often only 10 percent of body weight. The pressure of the metatarsal varies according to the differences of each individual. Usually, the highest pressure level appears between the second and third metatarsals. People with cavus pes have higher plantar pressure in the hallux and 1st metatarsal. People with low vaults or flat feet generally have higher plantar pressure on the first, second, third metatarsal and heel.
During the walk of people to cavus pes, due to insufficient internal rotation of the tibia affecting the under-pronation, these people tend to have excessive supination during the push, which leads to postures of walking rigid and causes muscular and skeletal problems with a high arch. The ankle joint has greater bending motion during ankle tilting to compensate for the excessive plantar flexion angle of the metatarsal and to increase the foot point clearance altitude during the push. In addition, high-vaulted people who run have clearly higher impact forces than those with low vaults.
[0007] Genu Valgum and Genu Varum: the foot is constructed by a femur, a tibia, a fibula and a patella. During a search on a radiograph, a normal angle between the tibia and the diaphysis of the femur is 6 ° outwards observing in the coronal plane; Genu Valgum (legs in X) or Genu Varum (legs in O) exist when the angle is too big or too small. An easy way to observe clinically would be to ask an individual to put both knees forward and both ankles with the medial sides together; if the width of at least two fingers can be placed between the two knees, there is what is called Genu Varum, which causes excessive external rotation of the tibia and excessive supination of the forefoot during walking . Abnormal use of the muscles of the lower limbs leads to pain in the medial side of the knees and metatarsals or even osteoarthritis. If an individual can put the width of at least two fingers between the medial side of the ankles when both knees are placed against each other, there is what is called Genu Valgum. This type of lower limb leads the knees and ankles to roll inward while advancing; in the long term, lateral knee joint lesions and plantar fasciitis may occur.
[0008] Custom foot orthoses can increase the contact area, rearranging forces to reduce plantar pressure. In the current years, foot orthotics are commonly used for modification and walking assistance to treat foot disorders caused by poor foot structure or other problems in the musculoskeletal system. Since 1983, research studies have shown that foot orthotics can reduce lower limb symptoms. Such devices may be able to reduce the pain caused by plantar fasciitis by 80%, in addition to facilitating the healing of wounded runners' feet.
[0009] Another important goal of foot orthoses is to allow biomechanical behaviors to become normal. Many researches show that foot orthoses can reduce pronation or movement speed on the hind foot. The support sole of the vault obviously affects the movements of the lower limbs; during a run, they are able to reduce internal tibia rotation by 2 ° over an initial period of 50% rest time. Such an influence on the axial rotation of the tibia and the varus and valgus of the calcaneus is capable of lowering the internal and external rotational speeds and internal rotation angles of the tibia in order to further reduce the plantar pressure at the level of the hallux and the medial side of the heel from 30% to 40%.
[0010] The known arch support insoles mainly provide a high height compensation under the navicular using an insole to compensate for the heel foot or flat foot arch heights to allow the foot to absorb the impact and to achieve the effect of weight distribution of the human body. Although known arch support soles are useful for muscle pain associated with a flat foot or cavus, the method only elevates the navicular medial side of the medial foot so that it is useful for improving relative movements of the medial and forefoot. For patients with flat feet with valgus heel or cavus with weak pronation, the movements of the subtalar joint can not be effectively improved. This damage to the musculoskeletal system still exists for those who use these arch support insoles known for long-term exercises.
Given the disadvantages of the known technique, the inventor of the present invention provides a device for the three-dimensional control of the movement of a foot and the redistribution of plantar pressure, this device for the three-dimensional control of the movement of one foot and the redistribution of plantar pressure that can be used to support the arch and calcaneus without excessively occupying the interior space of the shoes, by adjusting the excessive valgus and varus of the sub-tarsal joint, modifying the angles supination and pronation of the ankle, reducing the incorrect movements of the muscles of the lower limbs; and thereby improving muscle pain experienced during walking or running and reducing skeletal and muscle damage.
CONTENT OF THE INVENTION
The object of the present invention is to overcome the defects of the prior art by providing a device for the three-dimensional control of the movement of a foot and the redistribution of the plantar pressure to obtain the effect of controlling the relative movements foot joints, moderate plantar pressures and reduce unwanted impacts on lower limb muscles.
The present invention relates to a device for the three-dimensional control of the movement of a foot and the redistribution of the plantar pressure to effectively control the relative movements of the foot joints and adjust the angle of attack of the heel and the relative plantar pressures thereof, comprising: a main arch support body, used to support the medial longitudinal arch, the transverse arch and the lateral longitudinal arch of the foot, comprising a rear end having at least one lateral side; extending as far as the location of the calcaneus of the foot; said vault support main body is a three-dimensional structure formed by curvatures of the medial longitudinal vault, the transverse vault and the lateral longitudinal vault, adapted to collaborate therewith; and an adjustment part of the movement of the back foot, used to modify the angles of attack of the heel.
In one embodiment, the rear foot motion adjustment portion at the rear end of said arch support main body extends rearwardly from a corresponding cuboid, laterally and rearwardly. , to the calcaneus.
In one embodiment, the rear foot motion adjustment portion located at the rear end of said main arch support body extends from a corresponding navicular, medially and rearwardly, to the calcaneus.
In one embodiment, said rear foot motion adjustment portion includes a first rear foot movement adjustment portion and a second rear leg movement adjustment portion; the first rear foot movement adjustment portion, located at the rear end of the arch support main body, extends from a corresponding navicular, medially and rearwardly, to the calcaneus; the second rear foot movement adjustment portion at the rear end of the arch support main body extends from a corresponding cuboid laterally and rearward to the calcaneus.
In one embodiment, the three-dimensional control device for the movement of a foot and plantar pressure distribution further comprises a rigid reinforcement portion disposed at a surface of said main arch support body and extending from a medial portion of the main vault support body to a corresponding lateral longitudinal arch of the foot.
In one embodiment, the three-dimensional control device for the movement of a foot and plantar pressure distribution further comprises a rigid reinforcement portion disposed at a surface of said main arch support body and extending from a medial portion of the arch support main body to a corresponding medial longitudinal arch of the foot.
In one embodiment, the three-dimensional control device for foot movement and plantar pressure redistribution further comprises a rigid reinforcement portion disposed at a surface of said vault support main body and extending from the middle part of the rear end towards the front, towards the central part of the front end.
In one embodiment, said rear foot movement adjustment portion roughly has a hook shape.
In one embodiment, the main arch support body comprises a proximal metatarsal support portion formed in correspondence of a first metatarsal foot.
In one embodiment, the main arch support body and the rear foot movement adjustment portion are made of a plastic material, a fiberglass, a fiber mixture or a a metallic material.
As mentioned above, the present invention of the device for the three-dimensional control of the movement of a foot and the redistribution of the plantar pressure has the following advantages: (1) When a human body is moving, the control device Three-dimensional foot movement and redistribution of plantar pressure can effectively control the movements of the subtalar joint to adjust the excessive angles of pronation and supination. Using the rigid support of the rear foot movement adjustment part to control excessive or defective pronation and supination angles in the foot joints in a normal range, allows for additional adjustment, and redistribution, of plantar pressures; thus, a reduction of the incorrect movements of the muscles of the lower limbs, to improve the reduction of the muscular pain undergone during the march or the race, and to reduce the skeletal and muscular damages is obtained. (2) Three-dimensional control of foot movement and redistribution of plantar pressure adjusts the heights of the arch, regularly controlling the movements of the medial foot and the forefoot, reducing planar pressures irregular during the movements that are followed by the impact of the ground reaction force; at the same time, without increasing the thickness of the support part of the foot vault; so without overly occupying the interior space in the shoes to make them comfortable to wear.
The "CONTENT OF THE INVENTION" above is not used to limit the scope of application of the protection. Each brief description of the present invention will be further described in the description of the method of implementation below.
BRIEF DESCRIPTION OF THE DRAWINGS
Figures 1A and 1B are views of the position of a right foot arch and corresponding bones in a human body.
FIG. 2 is an illustration of a device for the three-dimensional control of the movement of a foot and the redistribution of the plantar pressure according to the present invention, corresponding to a right foot and presenting excessive valgus and excessive pronation during the movements of the foot. the ankle joint. For example: use only with a flat foot or a foot with a low arch.
FIG. 3 is an illustration of a flat foot patient using the device for three-dimensional control of foot movement and redistribution of plantar pressure according to FIG.
FIG. 4 is an illustration of one embodiment of the device for the three-dimensional control of foot motion and the redistribution of plantar pressure according to the present invention which corresponds to the right foot having ankle movements with excessive varus and weak pronation. For example: use only with a high arch type of foot.
Figure 5 is an illustration of a tall arch type of foot according to Figure 4 using the device for three-dimensional control of the movement of a foot and the redistribution of plantar pressure.
FIG. 6 is an illustration of an embodiment of the device for the three-dimensional control of foot movement and the re-distribution of plantar pressure according to the present invention, relating to a use thereof with a type of foot normal arch only.
Figure 7 is an illustration of the type of normal arch foot according to Figure 6 using the device for three-dimensional control of the movement of a foot and the redistribution of plantar pressure.
DETAILED DESCRIPTION OF THE INVENTION
To describe in detail the technical content, the structural features, the objects and the effects achieved according to the present invention, there are provided below embodiments with figures to explain the details.
The main object of the present invention is to provide a device for the three-dimensional control of the movement of a foot and the redistribution of the plantar pressure to effectively control the relative movements of the foot joints, then adjust the angles foot, the relative plantar pressures of the foot and reduce the inappropriate use of the muscles of the lower limbs.
Referring to Figures 1A and 1B, it appears that the human foot has a plantar arch 100 to absorb impacts and redistribute the weight of the human body. The arch 100 contains the first metatarsal, the first wedge bone, the navicular and the talus of the foot along the medial side of the foot to form a medial longitudinal arch 110. The transverse arch 120 is formed between the first metatarsal and the fifth metatarsal. A lateral longitudinal arch 130 is formed between the fifth metatarsal and the calcaneus. When a human body is in motion, said medial longitudinal arch 110, said transverse arch 120 and said lateral longitudinal arch 130 together absorb the impacts and redistribute the weight of the human body. When said plantar arch 100 is too high, there is what is called pes cavus, or when it is too low, it has flat foot or low vault; abnormal plantar pressure is also caused.
Referring to Figure 1 and Figure 2, it appears that the present invention relates to a device 1 for the three-dimensional control of the movement of a foot and the redistribution of plantar pressure, comprising a body 10 of arch support and a movement adjustment portion 20 of the back foot. Said vault support body 10 is a three-dimensional structure that is compatible with the curvatures of the medial longitudinal vault 110, the transverse vault 120 and the lateral longitudinal vault 130, which is used to support said medial longitudinal vault 110, the vault 120 and the lateral longitudinal vault 130. Said vault support body 10 contains a front end 10a and a rear end 10b. At least one side of the rear end 10b of said arch support body 10 extends a rear foot movement adjustment portion 20 to the corresponding position of the foot calcaneus to adjust the heel angle of attack and to control the movements of the back foot. The device 1 for the three-dimensional control of the movement of a foot and the redistribution of the plantar pressure according to the present invention can also be arranged in a 900 foot arch insole.
The front end 10a of said vault support body 10, which corresponds to a proximal portion 11 of metatarsal support at the first metatarsal foot. As a proximal support of the first metatarsal, said proximal metatarsal support portion 11 is used to provide stability to the forefoot and to reduce the forces exerted on the toes during thrusting. Said arch support body 10 and said rear foot movement adjusting portion 20 may be a chemical or metallic material and may withstand forces, especially of an alloy of metals, plastics, fiberglass or fibers. of carbon.
Referring to FIG. 2, it appears that said rear foot movement adjusting portion 20 extends rearwardly from the navicular side, so as to correspond to said rear end 10b of said main body 10 from arch support to calcaneus, and appearing roughly hook-shaped; it is used to adjust the angles of attack of the heel of a low vault or a flat foot.
During the movement process of the human body, because the foot will periodically have three-dimensional movements of supination or pronation, the high or low height of the arch produces supination or over-pronation during walking. People with O legs can have high arch type; over-supination is produced when the heel bears, so that an excessive varus of the ankle joints occurs in the loading response. People with X legs can have the flat foot type; over-pronation is produced when the foot comes into support, an excessive valgus of the ankle joints occurs in the loading response. Too much or too little pronation or supination will produce abnormal plantar pressure which is causing great damage to human bodies. Said back foot movement adjustment portion 20 can compensate for excessive angles of valgus and varus as the foot abuts against the ground to avoid damage to human bodies.
To further explain, the angle of attack of the heel is adjusted with the support of said rear foot movement adjusting portion 20 which can adjust the relative movements of the foot joints. During the stride, because the ankle joints are close to the median side M, overpronation occurs. With the rigid foot support portion of said back foot motion adjustment portion 20, the ankle joints are moved toward the lateral side L to maintain the angle of the ankle joint in a normal position during the stride; as shown in Figure 3, there is further adjustment of the plantar pressure distribution of the flat foot.
In addition, the heel will be modified to a softer position of the insole to change the angle of attack of the ankle joint to prevent damage from the flat foot to the human body after the foot touches the foot. ground with the rigid support of said portion 20 for adjusting the movement of the rear foot.
With reference to FIG. 4, it appears that, in one embodiment, said rear foot movement adjustment portion 20 extends rearwardly from the side of the cuboid bone that corresponds to said rear end 10b of said main arch support body 10, up to the calcaneus, and appears to have roughly a hook shape to support a foot of the high arch type. During walking, since the ankle joints move excessively towards the lateral side L, an over-supination appears. With the rigid foot support portion of said back foot motion adjustment portion, the ankle joints move toward the medial side M to maintain the angle of the ankle joint in a normal position during the walk ; as shown in FIG. 5, an additional adjustment of the relative movements of the foot joints is obtained. In addition, the heel will be modified to a softer position of the insole to change the angle of attack of the ankle joint to avoid damage to human bodies by high arch feet after the foot touches the ground, with the rigid support of said rear foot movement adjustment portion.
Referring to FIG. 6, it appears that, in another embodiment, said rear foot movement adjustment portion 20 contains a first rear foot movement adjustment portion 200 and a second rearward leg portion 201. adjustment of the movement of the back foot. This first rear foot movement adjustment portion 200 is close to the navicular side which corresponds to said arch support body 10 which extends rearward to the medial portion of the calcaneus. Said second movement adjustment portion 201 of the hind foot is close to the side of the cuboid bone which corresponds to the main arch support body 10, which extends to the medial portion of the calcaneus to support a foot type foot normal vault. As shown in FIG. 7, said first back foot movement adjusting portion 200 and said second rear foot movement adjusting portion 201 are not limited in extending to the calcaneus; Their goal is to be placed on two sides of the calcaneus to provide heel support. When walking, human bodies can change the angle of attack of the foot to lose balance; in this way the supports of the first portion 200 of adjustment of the movement of the rear foot and the second portion 201 of adjustment of the movement of the rear foot can stabilize the foot.
In addition, the main arch support body 10 which is constructed in a manner compatible with the curvatures of said longitudinal medial arch 110, the transverse arch 120 and the lateral longitudinal arch 130 can control the stability during dynamic movements. by arranging a rigid reinforcement part 12. Said rigid reinforcing portion 12 is a convex object directed upwardly on the surface of the arch support main body 10 or is a solid body combined with the surface of the arch support main body 10. Referring to FIG. 2, it appears that said rigid stiffening portion 12 which is used for the flat foot type, is disposed on the surface of the main arch support body; it continues to extend from the medial portion of the rear end 10b of the arch support main body 10 to the position of the medial longitudinal arch 110. Thus, the stiffness of the medial side arch support body can be greater than the lateral side of the foot; it thus increases the rigidity of the arch support body and reduces the level of foot sag for the medial longitudinal arch 110 in dynamic movements.
With reference to FIG. 4, it appears that said rigid reinforcing portion 12 which is used for the high arch type of foot, extending from the median part of the rear end 10b in the main body 10 of arch support up to the position of the lateral longitudinal arch 130 which corresponds to the foot; it thus increases the rigidity of the arch support body and reduces the level of foot droop for the lateral longitudinal arch 130 in dynamic movements.
Referring to Figure 6, it appears that said rigid portion 12 of reinforcement which is used for a type of normal arched foot, extending from the middle portion of the rear end 10b of the main body 10 of support to the middle portion of the front end 10a to increase the support stiffness in the middle of the main arch support body. Because the thicknesses and rigidity of the medial longitudinal vault 110 and the lateral longitudinal vault 130 are substantially the same, the stiffness in the medial portion is greater than that of the medial and lateral sides; the level of sagging medial longitudinal vault 110 and lateral longitudinal vault 130 during dynamic motions are approximately the same.
To further explain, said rigid reinforcing portion 12 on the surface of the main arch support body 10 can change the over-pronation or superspection of the foot to a normal angle of attack with different positions which are defined by said rigid reinforcing portion 12; it is thus possible to control the distribution of rigidity on the surface of the main arch support body 10 and to reduce the level of foot sagging in the corresponding arch position in order to adjust and control the pressure distribution plantar.
When a human body walks, the cycle of walking involves a swing phase and a posture phase. Which phase of posture occupies about sixty percent of the time in the entire cycle of walking, so it is important to keep the stability of the posture phase. The device 1 for the three-dimensional control of the movement of a foot and the redistribution of the plantar pressure according to the present invention makes it possible to modify the angles of pronation or supination to provide a stable gait for the coming posture phase.
When a human body is moving, the device 1 three-dimensional control of the movement of a foot and redistribution of plantar pressure can effectively control the movements of the subtalar joint to adjust the excessive angles by pronation and supination. It makes it possible to use the rigid support of the rear foot movement adjustment portion 20 to control excessive or defective valgus and varus angles of the foot joints in a normal range in order to modify and redistribute the plantar pressure in each plantar area; which reduces the incorrect movements of the muscles of the lower limbs, improves muscle pain during walking or running and reduces skeletal and muscle damage.
The three-dimensional control device of the movement of a foot and redistribution of the plantar pressure regularly adjusts the heights of the arch with the impact of the ground reaction force during the movements, controlling the movements midfoot and forefoot, and reducing irregular plantar pressures; at the same time it does not increase the thickness of the support part of the arch; thus, it does not occupy an excessive interior space in the shoes, which makes it comfortable to wear.
In summary, the device for the three-dimensional control of the movement of a foot and the redistribution of the plantar pressure according to the present invention provides a method for effectively controlling the relative movements of the foot joints. With the structure according to the present invention, the foot appears to be in a stable gait during movements to stabilize the movements of human bodies and increase the effectiveness of exercises to meet the needs of normal people to professional runners.
Preferred embodiments of the present invention have been described in the examples. However, the examples should not be construed as limiting the true scope of the invention and, as such, any modifications and alterations that depart from the spirit of the invention and the appended claims will remain in the scope of the invention. the scope of the claims of the invention.
DESCRIPTION OF DIGITAL REFERENCES I: device for three-dimensional control of the movement of a foot and the redistribution of plantar pressure 10: main arch support body 10a: front end 10b: rear end 100: plantar arch 110: medial longitudinal arch 120 transverse vault 130: longitudinal lateral arch II: proximal metatarsal support portion 12: rigid reinforcement portion 20: rear foot movement adjustment portion 200: first rear foot movement adjustment portion 201: second adjustment portion of the movement of the back foot M: medial side L: lateral side 900: plantar inner sole

权利要求:
Claims (10)
[1" id="c-fr-0001]
1. Device (1) for three-dimensional control of the movement of a foot and the redistribution of plantar pressure, used to effectively control the relative movements of the foot joints and adjust the angle of attack of the heel, allowing adjustment the relative planar pressures of a foot, characterized in that it comprises: a main arch supporting body (10) used to support the medial longitudinal arch (110), the transverse arch (120) and the lateral longitudinal arch (130) of the foot, comprising a rear end (10b) having at least one lateral side extending to match the location of the calcaneus of the foot; said vault support main body (10) is a three-dimensional structure formed by curvatures of the medial longitudinal vault (110), the transverse vault (120) and the lateral longitudinal vault (130), able to collaborate with these this ; and a rear foot movement adjustment portion (20) used to modify the heel strike angles.
[2" id="c-fr-0002]
2. Device (1) for the three-dimensional control of the movement of a foot and the redistribution of the plantar pressure according to claim 1, characterized in that the portion (20) for adjusting the movement of the rear foot located at the end. rearward portion (10b) of said main arch support body (10) extends rearwardly from a corresponding cuboid, laterally and rearwardly, to the calcaneus.
[3" id="c-fr-0003]
Device (1) for the three-dimensional control of the movement of a foot and the re-distribution of the plantar pressure according to claim 1, characterized in that the portion (20) for adjusting the movement of the rear foot located at the end. rearward portion (10b) of said main arch support body (10) of said planar motion adjustment portion extends from a corresponding navicular, rearwardly, to the calcaneus.
[4" id="c-fr-0004]
4. Device (1) for the three-dimensional control of the movement of a foot and the redistribution of the plantar pressure according to claim 1, characterized in that said portion (20) for adjusting the movement of the rear foot comprises a first portion ( 200) for adjusting the movement of the rear foot and a second portion (201) for adjusting the movement of the rear foot; the first rear foot movement adjustment portion (200), located at the rear end (10b) of the arch support main body (10), extends from a corresponding navicular, medially and to the back to the calcaneus; the second rear foot movement adjusting portion (201) at the rear end (10b) of the arch support main body (10) extends from a corresponding cuboid laterally and rearwardly to calcaneus.
[5" id="c-fr-0005]
5. Device (1) for the three-dimensional control of the movement of a foot and the redistribution of the plantar pressure according to claim 2, characterized in that it further comprises a rigid portion (12) of reinforcement disposed at the level of a surface of said vault support main body (10) and extending from a medial portion of the vault support main body (10) to a corresponding lateral longitudinal vault (130) of the foot.
[6" id="c-fr-0006]
6. Device (1) for the three-dimensional control of the movement of a foot and the redistribution of the plantar pressure according to claim 3, characterized in that it further comprises a rigid portion (12) of reinforcement disposed at the level of a surface of said vault support main body (10) and extending from a medial portion of the vault support main body (10) to a corresponding medial longitudinal arch (110) of the foot.
[7" id="c-fr-0007]
7. Device (1) for the three-dimensional control of the movement of a foot and the redistribution of plantar pressure according to claim 4, characterized in that it further comprises a rigid portion (12) of reinforcement disposed at the level of a surface of said vault support main body (10) and extending from the middle portion of the rear end (10b) forwards to the central portion of the forward end.
[8" id="c-fr-0008]
8. Device (1) for the three-dimensional control of the movement of a foot and the redistribution of the plantar pressure according to any one of claims 1 to 3, characterized in that said portion (20) of adjustment of the movement of the foot rear has a roughly hooked shape.
[9" id="c-fr-0009]
9. Device (1) for the three-dimensional control of the movement of a foot and the redistribution of plantar pressure according to any one of claims 1 to 4, characterized in that the main body (10) of arch support comprises a proximal portion (11) of metatarsal support formed in correspondence of a first metatarsal of the foot.
[10" id="c-fr-0010]
10. Device (1) for the three-dimensional control of the movement of a foot and the redistribution of the plantar pressure according to any one of claims 1 to 4, characterized in that the main arch support body and the part of rear foot movement adjustment consist of a plastic material, a fiberglass, a mixture of fibers or a metallic material.

类似技术:

---

公开号 | 公开日 | 专利标题

---

FR3046723A1|2017-07-21|DEVICE FOR THREE-DIMENSIONAL CONTROL OF FOOT MOVEMENT AND REDISTRIBUTION OF PLANTARY PRESSURE

---

US4620376A|1986-11-04|Forefoot valgus compensated footwear

---

JP2015526251A|2015-09-10|Basketball insole

---

US8387278B2|2013-03-05|Sole for footwear

---

US9167864B1|2015-10-27|Footwear with dynamic arch system

---

US9872534B2|2018-01-23|Footwear with dynamic arch system

---

US20170049182A1|2017-02-23|Orthotic devices

---

US9192502B2|2015-11-24|Ankle-foot orthotic

---

US8732981B2|2014-05-27|Eccentric toe-off cam lever

---

CA2894454C|2021-01-12|Orthopaedic device for a lower limb of a human, footwear and prosthesis provided with such a device

---

US9392842B2|2016-07-19|Footwear with dynamic arch system

---

US20040118020A1|2004-06-24|Plantar fascia support apparatus

---

WO2014203399A1|2014-12-24|Insole for shoe

---

CA2772167A1|2011-03-03|Insole for shoes

---

US4813159A|1989-03-21|Foot support for optimum recovery

---

AU2016303794A1|2018-02-08|Orthotic device for shoes

---

US20210022439A1|2021-01-28|Footwear with dynamic arch system

---

US9867419B1|2018-01-16|Sandal

---

JP2014233563A|2014-12-15|Sole pad

---

US20170164688A1|2017-06-15|Orthotic System

---

JP5190574B2|2013-04-24|Insole for footwear

---

Sylvia2018|A biomechanical examination of the lower extremities in high heeled shoes

---

Zipfel2021|The wounded forefoot-an evolutionary perspective.

---

Richardson et al.2016|An Overview of Footwear and Orthotics

---

US20160235154A1|2016-08-18|Orthopedic footwear with dynamic medial longitudinal arch support

同族专利:

---

公开号 | 公开日

---

JP6353511B2|2018-07-04|

---

GB2546412A|2017-07-19|

---

JP2017124157A|2017-07-20|

---

GB201700024D0|2017-02-15|

---

DE102017100657A1|2017-07-20|

---

TWI569743B|2017-02-11|

---

KR20170085965A|2017-07-25|

---

TW201724982A|2017-07-16|

---

US10251443B2|2019-04-09|

---

CN106974756B|2020-08-14|

---

US20170202299A1|2017-07-20|

---

CN106974756A|2017-07-25|

引用文献:

---

公开号 | 申请日 | 公开日 | 申请人 | 专利标题

---

---

US2498624A|1948-03-23|1950-02-21|Garnett C Skinner|Foot cushion|

---

US3081774A|1960-05-19|1963-03-19|Lelyveld Joseph|Arch support with metatarsal support bar|

---

US4360027A|1981-06-29|1982-11-23|Bruce Friedlander|Thin, light-weight flexible orthopedic device|

---

US5713143A|1995-06-06|1998-02-03|Kendall Orthotics|Orthotic system|

---

KR0173096B1|1996-11-11|1999-01-15|박인식|Insole|

---

JP3049643U|1997-12-09|1998-06-19|ダイナゲイト株式会社|Shoes and insoles|

---

US6393736B1|2000-05-25|2002-05-28|Greer Reed Biomedical, Llc|Adjustable brace orthotic and method of treating plantar fasciitis and related foot disorders|

---

US6301805B1|2000-07-31|2001-10-16|Shering-Plough Healthcare Products, Inc.|Full length insole for obese people|

---

JP4002109B2|2002-01-22|2007-10-31|株式会社村井|Shoe insole and manufacturing method thereof|

---

AU2003203502B2|2002-04-10|2005-05-19|Wolverine World Wide, Inc.|Footwear Sole|

---

US6915598B2|2002-08-06|2005-07-12|Schering-Plough Healthcare Products Inc.|Insole with arch spring|

---

US7120958B2|2003-03-19|2006-10-17|Paul Copeskey|Mass producible custom-made shoe inserts|

---

JP2005013682A|2003-06-23|2005-01-20|Yuji Sato|Footwear and insole for footwear|

---

DE102005015863A1|2005-04-07|2006-10-12|Stumpf, Jürgen|footbed|

---

US7707751B2|2006-06-16|2010-05-04|Schering-Plough Healthcare Products, Inc.|Adjustable orthotic|

---

US20080047166A1|2006-08-24|2008-02-28|Jeffrey Conforti|Arch support with ribbed surface|

---

US7958653B2|2006-09-21|2011-06-14|Schering-Plough Healthcare Products, Inc.|Cushioned orthotic|

---

TWI314043B|2007-08-29|2009-09-01|Wen-Long Chen|

---

JP5070445B2|2010-08-04|2012-11-14|有限会社プレスコントロール|Insoles|

---

JP5729558B2|2011-05-25|2015-06-03|株式会社アサヒコーポレーション|Insoles|

---

JP2013192742A|2012-03-21|2013-09-30|Nishizawa Yoshiji|Internal structure and insole structure of shoe|

---

TW201408233A|2012-08-17|2014-03-01|Hsin He Hsin Co Ltd|Shoe pad with pressure relief function|

---

JP3183393U|2013-02-27|2013-05-16|老牛皮國際股▲ふん▼有限公司|Insoles of shoes combined with seahorse-shaped reinforcing members|

---

USD748387S1|2013-04-24|2016-02-02|Stable Step LLC|Insole|

---

US20170027277A1|2014-01-21|2017-02-02|Implus Footcare, Llc|Customizable Component Insole System|

---

TWM493371U|2014-09-12|2015-01-11|Innova Materials Company Ltd|Medical insole configuration block|US20190008230A1|2015-06-19|2019-01-10|Correct Motion Inc.|Insole for sport footwear|

---

TWI675629B|2017-10-27|2019-11-01|劉懿賢|A tunable rigidity insole with interchangeable stiffeners|

---

CN107898464B|2017-11-09|2020-10-09|上海市共进医疗科技有限公司|System and method for measuring plantar pressure distribution|

---

FR3080007B1|2018-04-13|2020-03-13|Nathalie Palkowski|FLEXIBLE INNER SOLE FOR FOOTWEAR AND ORTHOPEDIC SHOE COMPRISING SUCH SOLE|

---

DE102018009262A1|2018-11-26|2020-05-28|Carsten Moch|Afference-stimulating shoe insert|

---

CN111686418A|2019-03-15|2020-09-22|徐林娟|Body-building walking device for senior citizens|

法律状态:
2018-01-22| PLFP| Fee payment|Year of fee payment: 2 |

---

2018-11-16| PLSC| Publication of the preliminary search report|Effective date: 20181116 |

---

2019-01-28| PLFP| Fee payment|Year of fee payment: 3 |

---

2020-01-31| PLFP| Fee payment|Year of fee payment: 4 |

---

2021-01-29| PLFP| Fee payment|Year of fee payment: 5 |

---

2022-01-28| PLFP| Fee payment|Year of fee payment: 6 |

优先权:

---

申请号 | 申请日 | 专利标题

---

TW105101256A|TWI569743B|2016-01-15|2016-01-15|A device for foot three dimensional motion control and plantar pressure redistribution|

---