DE29818243U1 - Shoe drive - Google Patents

Description

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Dr. P.C. Krüger, Jütländer Allee 48, 22527 Hamburg

Shoe drive

Field of application of the invention

The invention relates to the design of the tread of footwear in order to complement and optimize the physiological gait with regard to progression and cushioning.

Characteristics of known technical solutions

The upright gait of humans has evolved and been optimized over a long period of time. The walking movement is very complex and is ensured by a highly developed neuromuscular feedback system. Major technical changes to optimize it often failed due to the very sensitive sensor and reflex mechanisms that signal instability and intolerance to the organism. Exceptions to this are movements in the form of roller skates, roller skates, etc., i.e. technical developments that do not exist in nature for good reason. They undoubtedly have advantages in terms of progress, but are tied to training and athleticism with the disadvantages mentioned above and are therefore only suitable and applicable to a specific, small population group.

Physiologically long-term mechanisms to improve progress for everyone do not exist, but there are numerous variants of shoes in terms of shock absorption, fit, grip, etc. that are satisfactorily solved for different requirements. There is a wide range from cushioning jogging shoes to various grip soles for almost every purpose.

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Even early inventions feature double-track soles with bars (DE 31 03 230 Al, DE 26 42 946 Al, DE 29 01 084 Al, DE 34 40 206 Al), but their construction and shape are solely intended to improve cushioning. Furthermore, studs, bars and grooves are known (DE 27 52 239 Al, DE 30 21 129 C2), which improve grip. Last but not least, numerous variants optimize the physiological rolling process of the feet (DE 41 01236 Al). All subsequent innovations differ only slightly from this in terms of intention and design.

Aim of the invention

The aim of this invention is to optimize progress at step level at low cost! This could benefit, among others, professional groups that are characterized by a high walking workload with expected fatigue.

Essence of the invention

The invention is based on the knowledge that force vectors directed forward during walking, e.g. by the weight of the body, are not used sufficiently for forward movement. The length of the stride is determined by the heel being placed on the ground and by the repulsive force of the rear foot, the sole of which bends under the front forefoot of the rear leg for at least a short period of time that is important for movement. This is where the improvements according to the invention come in. _t . On the one hand, the soles are provided with elastic but dimensionally stable, hardly compressible elements in the form of bars or studs that point backwards and downwards on the shoe and fold or bend towards the heel when the foot is stepped on, attaching themselves to the sole and pushing the foot forward a little, e.g. depending on the length of the studs. The stride is thus lengthened even after the contact with the

heel strikes the ground. Since the foot usually rolls from back to front, the individual elements will not reach the ground at the same time, but preferably one after the other, fold/tilt or bend and the sole or shoe structure will gain a partial distance relative to the ground. These partial distances sometimes add up to a step gain of several centimeters.

Rolling is made even easier by the fact that the sole is preferably convex towards the ground, so that on the one hand many functional elements can be placed on the larger surface, and on the other hand the curved shape means that the rolling distance is greater than with a flat sole. The elements must be elastic but at the same time dimensionally stable, i.e. not very compressible in height, so that on the one hand they can fold or bend over and on the other hand they can push the foot forwards. After the foot is relieved by the shifted body weight, they must straighten up again in order to go through the same movement cycle with the next step. The slanted positioning of the elements backwards and downwards on the sole side is necessary in order to determine the direction of the partial forces when pressure is applied from above.

These primarily slanted elements can now also be combined with bars, strips, etc. that are attached perpendicular to the sole, if these are secondarily pushed backwards in an inclined position by the pressure load of the former, or are carried along with them, which depends on their assignment to them. These combination elements have the advantage of a further gain in distance. In principle, the elements can be elastic strips arranged in series across the length of the sole, but also studs or pyramids that are asymmetrical in terms of their elasticity, etc. The spacing of strips must be chosen so that they can fold or bend as far as possible, which influences the distance between their arrangement. For this reason, it may be advantageous to place studs on gaps in order to keep the distance between the elements smaller.

i.e. also to increase the density, which ensures a more uniform process. It is therefore sensible to provide replaceable elements that can be adjusted to the respective body weight. It is also desirable to change them, e.g. if the knobs are lengthened or shortened, etc.

Another solution does not refer to the front, coming leg, but to the rear, pushing leg. When the shoe sole, which according to the invention consists of two or more layers that can be moved against each other, are dimensionally stable but flexible, is curved, these move in such a way that the immediate foot support, as part of the shoe's running mechanism, slides forward in the concavity when all sole layers are fixed towards the heel. The foot is carried along, which in turn results in a gain in distance compared to the ground-side sole or the running surface itself. The sole layers are preferably held by elastic, flexible or tiltable webs that move radially to the sole layers when subjected to pressure and move the foot-side layer forwards as much as possible according to its length, using up the space between them. After the bending load is relieved, the elastic system returns to its starting position.
In order to achieve the greatest possible distance gain, it is advantageous to have bars that are perpendicular to the sole, but these can also have a different angle or circular shape.

It is worth emphasizing the decreasing shock absorption of the systems according to the invention, which make walking and running on hard floors much easier and are gentle on the joints.

Technically, the shoe drive can be made from a single cast, e.g. from elastic, rubber-like material. The individual systems according to the invention can also be used in isolation or in combination.

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Due to these inventive solutions (primary slanted studs or bars, combination elements with secondary inclination, convex tread and tangentially movable multi-layer sole), it is possible to save over 10% of steps per distance, which naturally leads to reduced fatigue and improved running effectiveness.

Example

The invention will be explained in more detail below using some exemplary embodiments. The accompanying figures show:

Fig. 1: a longitudinal section through a shoe drive according to the invention

Fig. 2: a longitudinal section through an outsole that only consists of a lower sole layer or overlay and bars or studs

Fig. 3: Longitudinal section through a convex, compact sole with different profiles in the form of pyramids or triangles

Fig. 4 : Shoe drive in action showing the partial distance gains.

Fig. 5 and 6 a and b: Cross sections through combination studs or webs with graphic representation of the distance gained under pressure load by the body weight (KG).

The running surface of a shoe shown in Fig. 1 consists of two functional parts. The layer located towards the foot is relatively hard and inelastic in the rear part, the heel ( 1 ), due to its thickness alone, while in the front area ( 2,3 ) it is flexible, elastic and yet dimensionally stable, like almost every shoe sole.

and adapts to the curvature of the forefoot in the front area.

Here it preferably consists of two layers (2,3) which are connected by elastic but dimensionally stable webs (4,4a) and are held in place so that they can tilt, thus allowing shear movements of the sole layers. The webs should preferably be perpendicular to them. For technical reasons, however, it may be necessary for them to be positioned at a smaller angle to the upper layer.

The lower layer, the actual outsole, has initially or only after pressure loading, ground- and backward-facing studs or strips (5-7 ), which, due to the material, are able to bend when the body is under pressure.

( KG) tip backwards on the shoe side without being significantly compressed in height and come closer to the tread and rest on it. The strips or studs can have different shapes. Curved with a tapered course ( 6 ), possibly closed off by a rear seal ( 6a ) to form a cavity to prevent contamination, then straight and pin-shaped while retaining their diameter ( 5,7 ) etc.

Shorter strips or studs ( 10,15 ) arranged almost perpendicular to the running surface are pushed backwards into an angle by the primarily inclined ones ( e.g. 5,7 ) when they come into contact with the ground ( Fig. 5b ) or are carried into this position ( Fig. 6b ) because the latter are attached to them close to the sole.

It is advantageous to keep the lateral (not shown) and end studs or strips (5a,7a,13a) shorter in order to ensure a more harmonious flow. Another variant is studs that can be unscrewed using threaded pins (9) and can be easily varied in length and thickness. It is also advantageous that the studs have a rear-curved base support (8.), which also harmonizes the flow.

In Fig. 3 further shapes of knobs or strips are shown. With a front, reinforced, foldable edge ( 14 ) it is part of a cross-section

Pyramid-, wedge- or triangular-shaped strip or stud (12,13), which consists essentially of easily compressible material.

Finally, Figure 2 shows a sole (corresponding to the lower sole layer (3) from Figure 1 with studs or strips (5) made of firm but elastic material such as rubber etc., which can be applied to any conventional shoe.

In Fig.3, a further variant of Fig.1 is shown in longitudinal section, which is characterized in that the lower running surface (11) is convex towards the ground and promotes successive folding over of the knobs or strips during the rolling process.

The heel-to-toe distance of a convex sole is greater than that of a straight one. The difference between the two in turn means distance gain (sz), and more functional studs can be accommodated, which also results in further distance gain.

In Fig. 4, a longitudinal section of a shoe drive according to the invention with pyramid-shaped elements from Fig. 1 and 3 is shown in operation. The load on the heel has already taken place and the body weight is on the ball of the forefoot, which is curved, during the physiological walking process. The pyramid-shaped studs or strips are compressed in this area by folding backwards (13,14). With unchanged traction, they push the outsole (3,11) and thus the foot forwards by the distance sx. The curvature of the two sole layers (2,3) separated by webs (4) results in an additional advance of the upper lamella (2) by the distance sy due to tangential displacement. Finally, Fig. 5 shows a longitudinal section of combination studs or strips according to the invention, which are only optimally effective when two elements interact. The vertical webs only come into operation when they have come into contact with the ground in an inclined position. The primary inclined element ( 5 ) pushes the rear and vertically arranged element ( 10 ) into

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Sloping position (Fig.5b,10b) so that it can now fold back in a direction oriented under pressure and push the shoe forwards, on the other hand the vertical element (15) is attached in front of and close to the sole of the sloping element (5) so that it is carried along when the latter is folded over in the sloping position (Fig.6b,15b). In this case too the vertical element is shorter than the sloping one. The process is sequential, with the sloping element becoming effective first, but then when the previously vertical element touches the ground it takes over the "leadership". In both variants an additional distance gain (s comb.) can be achieved by combining these two functional elements.

(( Fig.5,6: Distance gained by the inclined element (10,15 ): sx (= sxl+ sx2); partial distance until the vertical element ( 10b, 15b) touches the ground: sxl; Distance gained by the vertical element: sw. S komb (= sxl+sw ); s komb> sx))

The total distance achieved per step is determined by partially adding together the individual distances (sum of s combined, sx, sy, sz) that occur during the rolling process from back to front, so that a distance gain from the ground results. The variants according to the invention can also be used in practice in isolation.

Claims (17)

Expectations 1. Running gear for shoes, sandals etc. with different single and multi-layered sole constructions, bars, studs and profiles for better grip, cushioning, protection from injuries, ventilation etc. characterized in that parts of the shoe running gear in the area of the sole are elastically and thus reversibly deformed in the running direction forwards by body pressure and typical walking bending, taking the foot with them, so that a longer step with distance gain (sx to sz) relative to the ground is achieved beyond the selected distance of a physiological step. 2. Shoe structure for walking and running, in particular according to claim 1, characterized in that from the lower, ground-side sole layer (3,11) extend backwards or heel-ward directed, elastic, but largely dimensionally stable, backward-tilting, individually ground-adhering strips or studs (5 to 7,7a,10,14,15). 3. Shoe structure for walking and running, in particular according to claim 1, characterized in that the sole in the middle and front area consists of two or more flexible, but dimensionally constant, mutually displaceable, parallel sole layers (2,3) which are firmly and flexurally stable connected to the heel (1) in the rear part and are spaced apart by tiltable webs (4, 4a). 4. Shoe drive according to claims 1 to 3, characterized in that the webs (4,4a,5-7) run transversely to the longitudinal axis of the sole. 5. Shoe drive according to claims 1 and 2, characterized in that the shaped elements (5-7, 7a) have an angle of preferably 45 to less than 90 degrees to the sole towards the rear. &iacgr;&ogr; 6. Shoe drive according to claims 1, 2, 5, characterized in that the shaped elements (10, 15), which are arranged primarily perpendicular to the sole (3), only become functionally effective in combination with elements according to claims 2 and 5, in that they are carried or pushed into an inclined position (15b, 10b) under pressure load, either adhering to their front side (15) or contacting them at the back (10). 7. Shoe drive according to the preceding claims, characterized in that the elements (lo, 15) in claim 6 are shorter than the oblique ones (5-7, 7a) according to claims 2,5. 8. Shoe drive according to the preceding claims, characterized in that the studs or strips have a triangular (12) or pyramidal (13) cross-section, are either hollow or consist of elastic, compressible material, and have a reinforcement (14) on the front side which can perform tilting movements backwards. 9. Shoe drive according to the preceding claims with elements (4, 5, 5a, 7, 7a, lo, 15), characterized in that they preferably consist of rubber-elastic or similar material and after pressure relief they return to their original position and straighten up. 10. Shoe drive with device according to the preceding claims, characterized in that the sole (3, 11, 12) has a curvature convex to the ground. 11. Shoe drive according to the preceding claims, characterized in that the shaped elements such as nubs, strips, etc. (7,7a) are exchangeable. 12. Shoe drive according to one of the preceding claims 1 to 11, characterized in that the strips, studs and the like are shorter at the side and at the heel and toe of the shoe (7a, 5a). 11 13. Shoe drive according to claims 1 to 12, characterized in that the studs (5-7) are spaced apart. 14. Shoe drive according to the preceding claims with sole (1,3), characterized in that it has convex-arched, rear rolling surfaces (8) for studs or strips (5,7). 15. Shoe drive according to claim 1 and 3 with sole, characterized in that the sole layers are connected by elastic webs (4, 4a) which are preferably arranged at right angles to them and which enable the upper, foot-facing or convex-side layer (2) to slide forwards when curved relative to the lower layer (3) and thus the ground (16). 16. Shoe drive with device according to claim 1 and characterized in that the soles (2, 3) and webs (4) form hollow spaces that preferably communicate freely with one another, outwards and inwards. 17. Shoe drive according to claims 1 to 17, characterized in that all functional units according to the above claims can be used in isolation or in combination. Hamburg 7.10.98 Dr. P.C. Kruger