NO20140104A1 - SHOES AND METHOD OF MANUFACTURING THEREOF - Google Patents

Abstract

Shoes comprising a sole and at least a portion of a thigh attached to the sole, characterized in that the shoe is designed or adapted such that the resultant force vertically from above the substrate during a step essentially moves along a particular line or path, called SGL (sensory gait line), as the line, for the right foot viewed from above, starts backwards obliquely from the outside when the heel is lowered, the line advances and turns outwards so that it goes below the center of the calcaneus (heel bone), from which the line further forward takes the form of an elongated S extending from 1 and 2nd toe.

Description

SHOES AND PROCESS FOR THE MANUFACTURE THEREOF

Field of the invention

The present invention relates to shoes or footwear. More specifically, the invention relates to shoes that are specially designed for walking with a balanced effect on the body above the shoes.

Background of the invention and prior art

It is known that footwear has a great influence on the stress on the skeleton and the body in general. Bad shoes cause uneven stress on the ankle and foot joints, which spreads to the skeleton and the rest of the body above the feet, which can cause painful suffering.

A foot that hits a surface when walking or running will normally hit at an angle slightly towards the outer side of the heel bone. As the foot rolls forward when the step is taken, the weight will shift inwards towards the center of the body. At the end of the step, the weight goes over the balls of the toes and further out at the big toe. The weight is thus transferred diagonally or obliquely across the sole of the foot as the step is executed. Such transfer or turning is called pronation. If the twist is too strong, whereby the resultant of the force comes too close to the body's vertical midline, such as under the big toe, it is called overpronation. If the inward rotation of the ankle joint is normal, as described above, it is called normal pronation. If the turn is too small, so that the force at the end of the step comes closer to the little toe, it is called underpronation or supination.

It is known that incorrect pronation results in a skewed load that propagates upwards in the body chain through the legs and up to the back and neck. In particular, long-term lopsided loading causes disorders.

It is known that running shoes can be chosen with regard to correct pronation, which can be determined, for example, by visual assessment of the running stride. The shoes that are chosen have an adapted slanted heel position and lateral support of the heel cap and upper leather with adapted stiffness, so that overpronation or underpronation is avoided. The terms overpronation and underpronation in the context of running shoes only seem to be linked to where the pressure enters the sole of the shoe when the heel is lowered and where the pressure comes out in relation to the toes, while the pressure between the aforementioned positions seems to follow a straight line.

There are shoes other than running shoes that are adapted to provide correct pronation. These shoes also seem to be constructed with adapted lateral support and adapted inclined heel, to give the right pressure in at the heel drop and out at the right place in relation to the toes, without any definite line or path being defined that the weight should follow diagonally across the sole . Some examples can be found in the patent publications WO 2009083098, GB 2456766, US 2008276491, US 5323549, US 6341432 and US2008229624

In NO 328090 (equivalent to WO2005067754 and US2008229624), page 1, lines 25-27, it is described that "The load placed on the sole of the foot moves across the diagonal of this. From the heel, which is loaded on the outside, the load line moves diagonally inwards across the sole of the foot all the way to the ball of the foot and the big toe," This applies to healthy people with natural movement, without deformation of the foot. As described in NO 328090, page 2, lines 1-3, the situation is often different in civilized societies; "This twisting of the load exerted on the foot is not found in the population of civilized societies accustomed to shoes and to hard surfaces. When walking on flat surfaces, the flat sole forces the shoe into a straight heel-to-toe motion." The invention according to NO 328090 provides a diagonally twisted sole, and a shoe with such a sole, to correct the incorrect placement of the heel and the incorrect heel-to-toe movement so that a diagonal loading curve of the sole of the feet is obtained. Nothing more is described about the load curve than that it is diagonal. For the diagonally twisted sole, it is mentioned on page 4, lines 34-36 that "In special cases, it is conceivable that it is not systematically twisted, but instead is adapted to a deformity, incorrect position or an inhibition in the foot." But there is no guidance in the direction of any particular load curve over other load curves. According to the description in patent publication NO 328090, it is described in patent publication WO 01/15560 (equivalent to US 6782639) how different types of load on the foot can be achieved with hard inserts in the sole. Allegedly, various types of inserts 15 of different hardness are arranged on the midsole bottom 11, and the sole 12 has a "sand-like elasticity." With this feature alone, a diagonal or freely definable shape of the load line can allegedly be established.

But the teaching of the person skilled in the art from WO 01/15560 / US 6782639 is that a lack of dynamic, active walking is the underlying problem for many disorders, and the invention according to said publication provides a shoe with which active walking is a necessity, the sole being convex so that the sole rolls against the ground when a step is taken. It is pointed out that the design of the sole parts is random (random - US 6782639) or freely chosen (WO 01/15560) and consequently the load curve cannot follow any specific line.

Although many are helped by specialized shoes such as those mentioned or referred to above, it has been shown that many are not helped, some of whom get more harm than good from the shoes. Therefore, there is still a great need for an improved shoe, so that the suffering associated with incorrect shoes and incorrect walking can be reduced. The need is met with the present invention, which is the purpose of the invention.

Summary of the invention

More specifically, the invention provides a shoe comprising a sole and at least part of an upper leather attached to the sole, characterized in that the shoe is constructed or adapted so that the resultant force vertically upwards from the ground during a step essentially moves along a specific line or path, denoted SGL (sensory gait line), since the line, for the right foot seen from above, starts at the back obliquely from the outside when lowering the heel, the line goes forward and turns outwards so that it goes under the middle of the calcaneus (heel bone), from where the line further forward has the shape of an elongated S that goes out between the 1st and 2nd toe.

More specifically, the shoe is advantageously constructed or adapted so that the resultant force vertically up from the surface, or center of pressure from the foot vertically down, during a step essentially moves along a specific line, designated SGL (sensory gait line), as the line, for the right foot viewed from above starts obliquely backwards, typically 40° ± 10°, from the outside at lowering of the heel, the line turns or swings laterally outwards as it moves forward so that it essentially runs straight forward under the middle of the calcaneus (heel bone), from which the line continues up to below the middle of the cuboid (ball bone), from where the line further forward first turns or swings medially inwards towards the base between the 2nd and 3rd metatarsals and then turns off forwards in the longitudinal direction of the foot so that the line is tangent to the medial side of the corpus 2nd metatarsal and then further forward along the medial side of toe 2. From the middle below the cuboid and forward towards the tip of the toe, the SGL will have the shape of an elongated S that runs out m between first and second toe. From the middle below the cuboid, the SGL goes forward and medially inwards so that the line goes to under the outer part of the 2nd metatarsal (2nd metatarsal bone), under the inner side of the outer end thereof, from where the line continues forward between the 1st and 2nd toe bones, along inner side of the 2nd toe bone, so that the line SGL from the middle below the cuboid forward has the shape of an elongated S. From below the middle of the cuboid, the SGL continues forward to the area below the base of the 3rd and 4th metatarsals, from where the SGL goes forward and swings medially to between the 1st and 2nd base joint, and turns further forward to the winding itself as the SGL runs out between the first and second toe. From in front of the posterior sharp deflection forward at the heel set, the SGL follows the calcaneus and cuboid so that the SGL passes under the middle of the calcaneus and cuboid, before the SGL continues forward.

It has surprisingly been found that resultant force or pressure against and along the curved line SGL, shaped like an elongated s with a bend outwards at the back at the heel, results in the foot getting a natural movement pattern with balanced muscle activation along and around all axes in the foot and ankle. Thus, the foundation is laid for an efficient walking movement and natural joint movements in the foot, ankle, knee, hip and spine, with resulting reduced mechanical loads. In contrast to previous constructions, more of an anti-pronation heel construction is achieved, as the design of the shoe guides the step or the twisting of the foot also through the midfoot area, towards and through the forefoot. In this way, overpronation in the forefoot is prevented and, in addition, negative loads on various joints and elastic structures in the forefoot as well as the midfoot, whereby the interaction in joint mechanics from the foot joints up through the entire body chain is balanced and thus secured.

That the resultant force or center of pressure from the foot vertically down towards the ground, or the pressure or center of pressure from the ground towards the foot, during a step essentially moves along or follows a specific line, denoted SGL, means that the resultant or center of pressure along the cross-section of the sole of the foot moves along or following SGL. With the expression at least a part of an upper leather attached to the sole, it is meant that the shoe comprises more than a sole, to keep the foot fixed to the shoe, such as an upper part, for example an upper and a heel cap. The shoe includes everything from the simplest sandals and slips to the most complex shoes, the essential thing in this context is that the forces or pressure are controlled so that the line SGL is essentially followed along the entire foot, from heel to toe. The SGL starts posteriorly obliquely, typically 40° ± 20° , more typically 40° ± 10° , which is the angle in relation to the longitudinal direction of the sole of the foot at the heel set, however, the SGL quickly swings forward and essentially follows the center axis of the heel bone or strongest line forward to the cuboid. From just inside the heel bone to below the cuboid, the line SGL follows the greatest concentration of bone in the foot or the lower edge of the dominant bone in the foot, while from the cuboid onwards another curve is followed, as defined above and below.

By essentially following the line SGL, it is preferably meant that the shoe's sole construction guides the step so that the line is followed within ±20 mm laterally, more preferably ±10 mm, possibly ±5 mm laterally, but most preferably the sole construction is such that the foot is unstable within the SGL , so that muscles and nerves are activated by the foot being able to tilt about the SGL throughout the entire length of the foot. The line can thus be defined as a band where the resultant force must lie within the band, the width of which is defined by the permitted deviations from the ideal line, as defined above.

The shoe is designed or adapted so that the sole, upper part and any insole, which are put together, provide guidance so that the foot during a step tilts around the line SGL so that the downward force goes through the SGL, which is achieved by adapting features chosen from elasticity and density, height, support points and support zones, design of the lower longitudinal edge or edge of the sole and concavity in the direction across the sole and/or insole, as well as support points or support zones in the heel cap and upper part in general. This also includes loose and attachable insoles and insoles that are designed so that those inserted into the shoe adapt the load curve to follow the line SGL.

The definitions are given for the right foot, seen from above. The same applies to the left foot, but everything is mirrored about the body's vertical midline, seen in the anterior-posterior plane (front-back). Forward means forward in the direction of the stride and toes, in the longitudinal axis of the foot, while backwards is the opposite direction. Beyond or laterally means direction across the longitudinal axis of the foot, in a direction outward from the body's vertical midline. Inwards or medially is across towards the midline of the body. The longitudinal axis of the soles of the feet in the forward direction is typically divergent to different degrees for different people, so that the definitions in relation to bones are more precise.

The shoe advantageously has some designs with a sole that is convex in the longitudinal direction towards the surface. Thereby, an instability is achieved that provides a dynamically active gait that provides balanced activation and training of muscles, ligaments and tendons.

In many designs, the sole of the shoe is advantageously concave transversely to the ground, and the outer longitudinal edges advantageously have a variable height that controls the weight along the SGL during a step, preferably the sole as seen from behind for the right foot is turned clockwise in the heel and midfoot area, but mainly flat in the forefoot area. Thereby, the shoe is lower (possibly softer) on the outer side lateral to the SGL in the heel and midfoot, compared to the inner side medial to the SGL.

The upper or inner sole of the shoe advantageously rests against the sole of the foot on both sides of the SGL, to better activate and stimulate the sensory system in the sole of the foot.

The shoe advantageously has instability when tipping about the line SGL so that muscles on both the outside and inside of the foot and ankle are activated and trained, the instability is preferably achieved by the midsole being softer and more elastic than the upper and lower parts of the sole, which provides correct tipping about SGL. The sole of the shoe has advantageously increased modulus of elasticity or stiffness against compression for harder use, and heavier people, for example so that running shoes are stiffer than walking shoes, which in turn are stiffer than company shoes. Small shoe sizes advantageously have softer elasticity than larger ones. Controlled modulus of elasticity or stiffness against compression can be achieved in known ways, for example by controlling the amount of material, for example PU (polyurethane), per volume unit injected into a mould.

The sole can advantageously be twisted according to SGL. Likewise, fixed, loose and/or attachable posts can be adapted twisted around the line SGL so that the resultant of the force follows SGL. Likewise, stiffness and elasticity, and/or supporting points or zones with greater or lesser stiffness and/or elasticity can be arranged alternately on the side of the line SGL so that the resultant force from the foot during a step follows SGL.

The line SGL can be seen as the natural line for weight, pressure through the foot so that bones, nerves (sensory) and muscles are activated in a balanced way through the step (gait line). More specifically, the body's bones, nerves, muscles, tendons and connective tissue structures will be activated in a balanced way on each side of the line SGL if the weight follows the SGL, so that suffering due to unbalanced gait is reduced or eliminated.

The invention also provides a method for manufacturing a shoe according to the invention, characterized by adapting the compression stiffness and/or height of the sole construction on each side of the line SGL so that the center of pressure from the foot during a step is moved along the SGL. The invention also provides for the use of a shoe according to the invention, on the foot of a person, to adjust the person's gait.

Figures

The invention is illustrated by means of figures, where

Fig. 1 illustrates the line SGL seen from above with a foot inside a shoe,

Fig. 2 illustrates the line SGL in relation to the bones of the foot, and

Figures 3a and 3b illustrate a shoe according to the invention.

Detailed description

Reference is made to Fig. 1 which illustrates a foot, more specifically a foot seen from the underside or a footprint as seen from the upper side, inside a right shoe or on a right sole. The purpose is to illustrate how line 1, or more precisely curve 1, SGL goes in relation to the sole of the foot and footprint. SGL 1 is shown as a thick line or a band, as a certain tolerance for deviations from the ideal line must be assumed in practice, which is illustrated by the fact that SGL has a width of approx. 10 mm, which allows deviations within ±5 mm. The tolerance is only given as an example. The illustrated line SGL (sensory gait line) starts when the heel is lowered at an angle from the outside of the heel bone calcaneus, the line goes forward and turns laterally outwards so that approximately in the middle below the heel bone it has a straight forward direction, while further forward the SGL has the shape of an elongated s which goes out from the foot forward along the inner side of the 2nd toe. It is clearly seen that the s-shape goes slightly outwards from the body's midline out and forwards from the heel bone, while further forward the SGL goes inwards and forwards as it turns or swings laterally outwards. At the points of change of direction of rotation, SGL is a straight line, and if SGL was described by a mathematical function, the second derivative would be equal to zero at said points, while the sign would change as the rotation changes. The curvature in SGL is open outwards in the rear part of the foot sole, it changes to be open inwards in a middle area before it is open outwards again in the front part of the foot sole.

Reference is also made to Fig 2 which defines SGL 1 more closely by relating SGL to the bones in the foot. The SGL is drawn in and is believed to lie correctly in relation to the bones. It is intended that the definitions in the description and requirements shall define SGL as illustrated in figures 1 and 2.

Reference is also made to Figure 3a which illustrates a shoe according to the invention, as seen from the side. The illustrated embodiment features a sole that is longitudinally convex. Reference is also made to Figure 3b, which illustrates the same shoe as seen from behind. As can be seen from Fig. 3b, the sole is concave in the transverse direction, as the sole's outer edge or edge in the longitudinal direction guides the foot to correct tilting about the SGL as a step is taken. Something that is difficult to see is that the sole is slightly twisted and with a slightly varying height on the sides. However, the shoe is built so that if a cross-section is taken along the SGL, the edge is higher and/or stiffer along the side of the SGL from which the SGL should swing away. A stiffer and/or higher outer side means that the right foot seen from behind tilts anti-clockwise and the resultant force moves inwards along the cross-sectional length. Thus, the resultant force is controlled to be transferred along the SGL.

Claims (10)

1. Shoes comprising a sole and at least part of an upper leather attached to the sole, characterized in that the shoe is constructed or adapted so that the resultant force vertically up from the ground during a step essentially moves along a specific line (1), denoted SGL (sensory gait line), the line (1), for the right foot seen from above, starts backwards obliquely from the outside when lowering the heel, the line (1) goes forward and turns outwards so that it goes under the middle of the calcaneus (heel bone), from where the line (1) further forward has the shape of an elongated S that goes out between 1. and 2 .toe. 2. Shoes according to claim 1, characterized in that the shoe is constructed or adapted so that the resultant force vertically up from the ground during a step essentially moves along a specific line, denoted SGL (sensory gait line), as the line, for the right foot seen from above, starts obliquely to the rear, typically 40° ± 10°, from the outside when lowering the heel, the line turns laterally outwards as it goes forward so that it basically goes straight forward under the center of the heel bone calcaneus (heel bone), from where the line continues to under the center of the cuboid (ball bone), from where the line further forward first turns medially inwards and then forwards so that the line goes to under the outer part of the 2nd metatarsal (2nd metatarsal bone), under the inner side of the outer end thereof, from where the line continues forward between the 1st and 2nd toe bones, along the inner side of the 2nd toe bone, so that the line SGL fira in the middle below the cuboid and forward has the shape of an elongated S, and with a bend laterally outwards to the rear at the heel set. 3. Shoes according to claim 1 or 2, characterized by the fact that the line SGL from below the middle of the cuboid continues forward to the area between the bases of the 3rd and 4th metatarsals, from where the SGL goes forward and turns medially to between the 1st and 2nd base joints, and turns further forward to the winding itself as the SGL runs out between the first and second toe. 4. Shoes according to one of claims 1-3, characterized in that the shoe is constructed or adapted so that the sole, upper part and any insole as a whole provides support so that the foot during a step tilts around the line SGL so that the center of pressure down goes through the SGL, which is achieved by adapting features chosen from among elasticity and density, height , support points and support zones, design of the lower longitudinal edge or edge of the sole and concavity in the direction across the sole and/or insole, as well as support points or support zones in the heel cap and upper part in general.. 5. Shoe according to one of the preceding claims, characterized in that the sole of the shoe is longitudinally convex towards the surface. 6. Shoe according to one of the preceding claims, characterized in that the sole of the shoe is concave transversely to the ground, and the outer longitudinal edges have a variable height which controls the weight along the SGL during a step, preferably the sole as seen from behind for the right foot is turned clockwise in the heel and the midfoot area, i.e. higher, possibly stiffer on the inside, medial to the SGL, but essentially flat in the forefoot area. 7. Shoe according to one of the preceding claims, characterized in that the upper or inner sole of the shoe rests against the sole of the foot on both sides of the SGL, in order to better activate and stimulate the sensory system in the sole of the foot. 8. Shoe according to one of the preceding claims, characterized by the fact that the shoe has instability when tilted about the line SGL so that muscles on both the outside and inside of the foot are activated and trained, the instability is preferably achieved by the midsole being softer and more elastic than the lower parts of the sole which provides correct tilting of SGL. 9. Shoe according to one of the preceding claims, characterized in that the sole of the shoe has an increased modulus of elasticity or stiffness against compression for harder use. 10. Method for manufacturing a shoe according to one of claims 1-9, characterized by adapting compression stiffness and/or height of the sole construction on each side of the line SGL so that the center of pressure from the foot during a step is moved along SGL