DE102011007996A1 - Athletic shoe has curvatures that are formed in damping element and are displaced when load exceeds predefined load limit along longitudinal direction - Google Patents

Abstract

The athletic shoe has a damping element (12) that is arranged into a sole. The curvatures are formed in damping element and are displaced when load exceeds predefined load limit along longitudinal direction. The fixation element (24) is arranged between heel (26) of shoe and the contact point (20) of a twin S-shaped portion (16). A stop element is provided to limit movement of one element (14) with respect to other element (18) in damping element.

Description

The invention relates to a sports shoe, in particular running shoe, with a damping element integrated in a sole.

Modern sports shoes, for example sneakers, which are intended for use as a running shoe, meanwhile have different constructions, in particular in the area of the sole of the sports shoe, in order to ensure the highest possible wearing comfort. Of particular importance in this case are the damping elements arranged in the region of the sole which are intended, for example, to absorb shocks occurring when they occur, in order to prevent overburdening of muscular and skeletal structures of the athlete. For this purpose, it is known to provide cushioning or resilient elements as dampers which deform elastically under load, in particular on the occurrence and the subsequent unwinding, and absorb occurring load peaks. Corresponding damping elements are designed, for example, as gas-filled chambers or as blocks of EVA (ethylene-vinyl acetate).

By using special constructions, furthermore, a part of the energy absorbed by the damping element can be fed back into the movement sequence in order to make the movement more efficient.

For example, from the EP 1 418 989 B1 , of the US 6,964,119 B2 and the US 2010/0269368 A1 Each shoe with special damping elements known that attenuate load peaks in various ways and improve the efficiency of movement through a targeted redelivery stored energy. Common to all designs, however, is the complex structure of the damping elements used, which are arranged at least partially outside the actual shoe, so that external influences can disturb the function of the damping elements sensitive. In addition, the damping elements described claim large volumes, so that the dimensions of the shoe described compared to conventional models are significantly increased.

The present invention is therefore an object of the invention to provide a sports shoe, which solves the aforementioned problems.

The object is achieved with the features of the independent claims.

Advantageous embodiments and further developments of the invention are specified in the dependent claims.

The present invention is based on the generic sports shoe in that the damping element in the unloaded state includes a curvature that shifts wavewise when exceeding a predetermined load limit in the longitudinal direction of the sports shoe. In this way, the longitudinal damper can be made particularly compact, in particular, a very low height of the longitudinal damper is possible, which even allows the complete positioning of the entire longitudinal damper inside the sports shoe, especially in the interior of the midsole. The longitudinal damper can thus be integrated without a change in outer dimensions of the sports shoe in this, in addition, the longitudinal damper is protected from harmful external environmental influences that could affect the function of the Längsdämpfers.

It may be provided that the damping element is designed as a longitudinal damper, wherein the damping element comprises a first element which has a double-S-shaped portion with the curvature, and a second element which at least partially covers the double-S-shaped portion , wherein the second member abuts the double-S-shaped portion at least at a contact point when a weight force acts in the direction of the first member on the second member, the first member via a fixation between a heel of the sports shoe and the point of contact is set relative to the second element.

Advantageously, it can be provided that the first element and the second element are manufactured in one piece and / or that the fixation comprises a stop element which limits a movement of the first element and the second element in the direction of the heel of the sports shoe, and / or that the fixation Means, which rigidly couple the first element and the second element in a fixing point with each other.

Furthermore, it can be provided that the contact point lies on a wave peak of the double-S-shaped section.

Usefully, it may be provided that an edge of a wave crest facing the heel of the sports shoe is softer than an opposite further flank of the same wave crest. In this way, the deformation of the longitudinal damper can be adjusted under a weight force. The term "softer" refers to the stiffness of the flank compared to the stiffness the further edge, that is, the flexural rigidity, which is given by the product of the modulus of elasticity of the material used and the area moment of inertia of the cross section of the workpiece at the considered flank.

It can also be provided that one of the heel of the sports shoe facing edge of a wave peak is shallower than an opposite further edge of the same wave peak. The term "flatter" means that the present in the undeformed state of the longitudinal damper angle between the flank and the attacking weight force is greater than the corresponding angle which includes the further flank with the attacking weight. Also in this way, the deformation of the longitudinal damper can be influenced under the attacking weight.

In particular, it can also be provided that the first element is elastically deformable by the second element under the action of the weight force.

In this context, it can be provided that, in the case of an elastic deformation of the first element, a wave peak of the double-S-shaped section can be displaced from a tip of the sports shoe in the direction of the heel of the sports shoe. In this way, the longitudinal damper can store the attacking weight in the form of a displacement of the wave peak.

Furthermore, adaptation means can also be provided in order to adapt the weight force necessary for displacing the wave peak. In this way, the wearing comfort of the sports shoe can be improved, since the damping effect of the longitudinal damper can be dimensioned so that storage of energy by the displacement of the wave crest starts only at weight forces that are not reached during a walking motion. The adjustment means may represent, for example, cross-sectional or material adjustments, with the aid of which the elasticity of the longitudinal damper is adapted to the weight of the wearer of the sports shoe. In particular, with such an adaptation, the weight force required to displace the wave peak should correspond approximately to twice the weight force of the wearer.

Usefully, it can be provided that a surface of the first element and / or a further surface of the second element are designed as a plain bearing at the point of contact. In this way, the amount of energy converted by the longitudinal damper in the storage of energy by the displacement of the wave peak in heat can be reduced, so that a larger amount of energy from the longitudinal damper can be proportionately stored and released again.

Furthermore, it can be provided that a coupling device is articulated on the damping element in order to couple the sports shoe with a sports device. In this way, the sports shoe "fixed" to a sports equipment, such as a bicycle or a rowing bench can be fixed. This can also allow a more efficient movement when riding a bicycle or rowing, since energy stored in the damping element can also be released in the direction of movement during these cyclical movements.

It can also be provided that the damping element is adapted to tilt in the region of a wave bottom to deliver stored energy at least partially in a direction of movement of the sports shoe. The term "tilting" while the rotational movement of the sports shoe when rolling around the pivot point of the movement, which is above the football, referred to, wherein the tilting also includes a bending of the damping element in this region of the sole.

The invention will now be described by way of example with reference to the accompanying drawings by way of particularly preferred embodiments.

Show it:

1 a sports shoe in a side view;

2 a longitudinal damper in a side view;

3 a first element in a soffit;

4 a sole of a sports shoe in a side view;

5 a sole of a sports shoe in a side view;

6 a form for a longitudinal damper in a three-dimensional view; and

7 a form for a longitudinal damper in a side view.

In the following drawings, like reference characters designate the same or similar components.

1 shows a sports shoe in a side view. The illustrated sports shoe 10 includes an upper shoe 52 and a sole 62 , Of the Sport shoe still has a tip 40 and a heel 26 , The sole 62 of the sports shoe 10 has an outsole 48 and an insole 50 on, between which a damping element 12 , which is designed as a longitudinal damper, is arranged in an unspecified midsole. The longitudinal damper 12 has a first element 14 on which a double S-shaped section 16 with a curvature ( 34 . 36 . 38 ). Furthermore, a second element 18 that the double-S-shaped section 16 of the first element 14 at least partially covered, also part of the longitudinal damper 12 , On the second element 18 may be waived if its function is taken over by the overlying part of the sole. The overlap takes place from the "top" seen from the direction of the one weight 22 on the longitudinal damper 12 acts. The first element 14 and the second element 18 are at a fixation 24 in the back of the sports shoe 10 , ie in the heel area 26 connected with each other. Under the influence of weight 22 continues to create a point of contact 20 between the first element 14 and the second element 18 , The longitudinal damper 12 is arranged in the midsole, for example, a non-illustrated cavity may be provided for receiving the longitudinal damper. The longitudinal damper 12 can as a whole opposite the sports shoe 10 be set against slipping, for example by at least partially bonding with the midsole, the outsole 48 or the insole 50 , It is also possible that the longitudinal damper 12 is clamped in the cavity, so that in this way slipping is also prevented. The longitudinal damper 12 can also be enclosed in an enclosure, in which case the enclosure can provide for the cavity, which allows easier deformation of the longitudinal damper. However, such a cavity is optional. The functioning of the longitudinal damper 12 will be described in more detail below.

2 shows a longitudinal damper in side view. The illustrated longitudinal damper 12 includes the first element 14 with the double S-shaped section 16 that about the fixation 24 with the second element 18 is coupled. The double S-shaped section 16 thus includes a wave peak 34 in the direction of fixation 24 a flank 36 and in the opposite direction another flank 38 having. This therefore represents the curvature ( 34 . 36 . 38 ). The flank 36 runs into a trough 56 and the further flank 38 runs into a wave bottom 58 , The wave peak 34 that is this part of the vault ( 34 . 36 . 38 ), represents the highest point and the wave bottom 58 the lowest point of the first element 14 dar. The wave peak 34 coincides with the point of contact 20 together. The point of contact 20 lies within a plain bearing 46 to the friction between the first element 14 and the second element 18 at the point of contact 20 keep as low as possible. For this purpose is a coating 54 in the area of the sliding bearing 46 on another surface 44 on the second element 18 provided, which may for example consist of Teflon, graphite or other suitable material. Alternatively, also the second element 18 in the area of the sliding bearing 46 be made directly from a material having the lowest possible coefficient of friction. Furthermore, a surface can also be used 42 of the first element 14 in the area of the wave summit 34 that is within the range of the plain bearing 46 be coated with a corresponding material or made of such a material. In the illustrated continuous longitudinal damper 12 are the first element 14 and the second element 18 from the outset together in one piece manufactured as a single coherent component, so that the fixation 24 ultimately as a curved continuation of both the first element 14 as well as the second element 18 can be viewed. The illustrated longitudinal damper 12 For example, it may be made of one or more fiber composites known to those skilled in the art, for example glass fiber reinforced glass, metal matrix composites (MMC), carbon fiber reinforced silicon carbide, inherently reinforced thermoplastics, fiber-ceramic composites or fiber-plastic composites. In particular, carbon fiber reinforced plastic (CFRP), glass fiber reinforced plastic (GRP), aramid fiber reinforced plastic (AFK), natural fiber reinforced plastic (NFK) and wood plastic composites (WPC) can be constructed as fiber-plastic composites. Furthermore, a production of the longitudinal damper 12 made of layered composites conceivable. Which materials are used exactly in which thickness depends ultimately on the desired stiffness of the longitudinal damper 12 from. Especially in the area of the wave bottom 58 can a coupling device, not shown 74 be arranged with the longitudinal damper 12 for example, screwed or glued. This coupling device 74 can enable a person skilled in the art known connection in the manner of a click pedal with a sports equipment. The coupling device can be arranged completely inside the sole to allow a "normal" use of the outsole of the sports shoe.

Under the influence of weight 22 becomes the second element 18 in the area of the sliding bearing 46 , especially at the point of contact 20 against the wave peak 34 pressed. This is the longitudinal damper 12 in the field of fixation 24 bent, leaving a change of fixation 24 It can be determined how big the weight 22 must be before the second element 18 to the first element 14 encounters. The distance between the second element 18 and the wave peak 34 in the unloaded condition of the longitudinal damper 12 For example, it can be between four and five millimeters. However, it is also conceivable that this distance is significantly smaller even in the relaxed state of the longitudinal damper, in particular zero, that is, that the second element 18 constantly on the first element 14 is applied. When the weight 22 for pressing the second element 18 to the first element 14 exceeds necessary amount, sets a deformation of the first element 14 one that can be elastic at the crest of the wave 34 towards the "back" in the direction of the fixation 24 standing near an unrepresented heel 26 of the sports shoe 10 is, "wavy" is moved. At the same time, the point of contact slides 20 in the plain bearing 46 on the second element 18 along. In the wave-like displacement of the wave peak, the touch point 20 be moved along the contour line shown in the side view. The shift of the wave peak 34 can by the design of the flank 36 and the further flank 38 be supported such that an increase in weight 22 forcibly a displacement of the wave peak in the direction of the fixation 24 entails. For this purpose, the flank 36 softer and / or shallower than the other flank 38 be executed. "Softer" means a lower bending stiffness, which consists of the product of the modulus of elasticity and the area moment of inertia of the cross section of the flank 36 is given, compared to the corresponding value of the further edge 38 , "Flat" in this context means a lower slope of the flank 36 in comparison to the other flank 38 , Both measures ensure that the flank 36 under the action of the contact point 20 attacking weight 22 becomes more deformed, so that the wave peak 34 towards the fixation 24 is moved. In this way, in the longitudinal damper 12 the weight arising when it occurs 22 partially saved. Thus, for example, when running, shocks through the longitudinal damper 12 cushioned. In the further course of the movement, that is, when rolling, disappears on the second element 18 upcoming weight 22 , whereby at the same time in the area of the wave reason 58 , which lies below the fulcrum of the movement, a tilt occurs. This tilting or tilting can also be the longitudinal damper 12 in the area of the wave bottom 58 bend. Without the on the longitudinal damper 12 acting weight 22 is the in the longitudinal damper 12 stored energy is released again, the release of the stored energy by tilting now in the form of a. Force takes place, which at least partially points in the direction of movement, whereby the efficiency of the movement is increased.

3 shows a first element in a bottom view. This in 3 illustrated first element 14 Already has the 1 and 2 known sections or points. In the lower view is also a contour 60 recognizable, which is modeled on a human foot. This increases the comfort, as the forces act evenly on the entire sole of the foot. But there are also other contours 60 can be realized as needed. These may, for example, be adapted to overpronation or underpronation and correct it. In the stand is the center of gravity of the wearer of the sports shoe 10 between the wave peak 34 and the wave bottom 58 , about one centimeter in front of the wave peak 34 towards the wave bottom 58 , As you can easily see from the bottom view, the trough drops 56 with the heel 26 the wearer of the sports shoe 10 and the wave bottom 58 with the footpad of the wearer of the sports shoe 10 together.

4 shows a sole of a sports shoe in a side view. The in the 4 illustrated sole 62 includes the outsole 48 and the insole 50 between the one damping material 66 is intended as a midsole. In a cavity 64 inside the damping material is the longitudinal damper 12 arranged. The Indian 4 illustrated longitudinal damper 12 differs in the area of fixation 24 from the already known longitudinal damper 12 , In the field of fixation 24 are means 30 provided that the first element 14 and the second element 18 at a fixation point 32 couple rigidly together. The means 30 For example, they may include screwing, crimping, clamping, gluing, welding, or nailing. The mode of action in the 4 shown Längsdämpfers corresponds to the operation of the already from the 1 and 2 known longitudinal damper 12 ,

5 shows a sole of a sports shoe in a side view. The in the 5 illustrated sole 62 also differs in the area of fixation 24 of the longitudinal damper 12 from the already known longitudinal dampers. In the heel area 26 is a stop element 28 provided, which is the slippage of the second element 18 opposite the first element 14 towards the heel 26 prevented. The second element 18 can, for example, with the stop element 28 be coupled to also a shift of the second element 18 towards the top 40 opposite the first element 14 to prevent. The mode of action in the 5 shown longitudinal damper 12 is identical to the already known longitudinal dampers.

6 shows a mold for a longitudinal damper in a three-dimensional view and 7 shows the corresponding shape for the longitudinal damper in a side view. Form 68 has one top 70 and a bottom 72 on. For better visualization are still prominent points or lines, for example, for the contour 60 , for the wave trough 56 , the wave peak 34 and the wave bottom 58 located. The longitudinal damper 12 can with the help of a conventional in the art conventional method of the mold 68 , are produced, and then the contour 60 can be cut out. For example, impregnated fiber mats for the production of CFRP or GRP to the mold 68 be created, depending on the desired stiffness a greater or lesser number of mats in individual sections of the form 68 can be used. After curing, the composite of the mold 68 be separated and the contour 60 be cut out. In this manufacturing process, the first element 14 and the second element 18 on the bottom 72 or the top 70 manufactured in one piece, since the mats are continuous in one piece around the edge in the area of the fixation 24 can be placed to the fixation 24 to form oneself. After cutting out the contour 60 from the molded composite material, the finished longitudinal damper in the from the 4 and 5 known cavity 64 be introduced, wherein the cavity 64 can be produced for example by milling in a damping material. The one in the sole 62 introduced longitudinal damper may be surrounded on all sides by damping material of the midsole or covered only by the outsole and / or the insole down / up. In this way, the longitudinal damper is protected from disturbing environmental influences that could affect its functionality. After positioning the longitudinal damper 12 in the midsole, first the insole and then the upper shoe are placed from above and fastened to produce the running shoe.

The features of the invention disclosed in the foregoing description, in the drawings and in the claims may be essential to the realization of the invention both individually and in any combination.

LIST OF REFERENCE NUMBERS

10

Sports Shoe

12

longitudinal damper

14

first element

16

double S-shaped section

18

second element

20

point of contact

22

weight force

24

fixation

26

heel

28

stop element

30

medium

32

fixation

34

wave peaks

36

flank

38

another flank

40

top

42

surface

44

further surface

46

bearings

48

outsole

50

insole

52

upper shoe

54

coating

56

trough

58

shaft base

60

contour

62

sole

64

cavity

66

damping material

68

shape

70

top

72

bottom

74

coupling device

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• EP 1418989 B1 [0004]
• US 6964119 B2 [0004]
• US 2010/0269368 A1 [0004]

Claims (12)

Sports shoe ( 10 ), in particular running shoe, with one in a sole ( 62 ) integrated damping element ( 12 ), characterized in that the damping element ( 12 ) in the unloaded state a curvature ( 34 . 36 . 38 ) which, when a predetermined load limit is exceeded, extend in a wave-like manner in the longitudinal direction of the sports shoe ( 10 ) shifts. Sports shoe ( 10 ), according to claim 1, characterized in that the damping element ( 12 ) is designed as a longitudinal damper, wherein the damping element ( 12 ) - a first element ( 14 ), which has a double S-shaped section ( 16 ) with the curvature ( 34 . 36 . 38 ), and - a second element ( 18 ), which forms the double S-shaped section ( 16 ) is at least partially covered, comprising, - the second element ( 18 ) at the double S-shaped section ( 16 ) at least at a point of contact ( 20 ) is applied when a weight ( 22 ) in the direction of the first element ( 14 ) on the second element ( 18 ), the first element ( 14 ) via a fixation ( 24 ) between a heel ( 26 ) of the sports shoe ( 10 ) and the touch point ( 20 ) compared to the second element ( 18 ). Sports shoe ( 10 ) according to claim 2, characterized in that the first element ( 14 ) and the second element ( 18 ) are made in one piece and / or that the fixation ( 24 ) a stop element ( 28 ) comprising a movement of the first element ( 14 ) and the second element ( 18 ) in the direction of the heel ( 26 ) of the sports shoe ( 10 ), and / or that the fixation ( 24 ) Medium ( 30 ) comprising the first element ( 14 ) and the second element ( 18 ) in a fixation point ( 32 ) rigidly couple with each other. Sports shoe ( 10 ) according to claim 2 or 3, characterized in that the point of contact ( 20 ) on a wave peak ( 34 ) of the double S-shaped section ( 16 ) lies. Sports shoe ( 10 ) according to one of claims 2 to 4, characterized in that one of the heel ( 26 ) of the sports shoe ( 10 ) facing flank ( 36 ) of a wave peak ( 34 ) softer than an opposite further flank ( 38 ) of the same wave peak ( 34 ). Sports shoe ( 10 ) according to one of claims 2 to 5, characterized in that one of the heel ( 26 ) of the sports shoe ( 10 ) facing flank ( 36 ) of a wave peak ( 34 ) flatter than an opposite further flank ( 38 ) of the same wave peak ( 34 ). Sports shoe ( 10 ) according to one of claims 2 to 6, characterized in that the first element ( 14 ) by the second element ( 18 ) under the influence of the weight ( 22 ) is elastically deformable. Sports shoe ( 10 ) according to claim 7, characterized in that in an elastic deformation of the first element ( 14 ) a wave peak ( 34 ) of the double S-shaped section ( 16 ) from a tip ( 40 ) of the sports shoe ( 10 ) towards the heel ( 26 ) of the sports shoe ( 10 ) is displaceable. Sports shoe ( 10 ) according to claim 8, characterized in that adaptation means are provided for carrying out the displacement of the wave peak ( 34 ) necessary weight ( 22 ). Sports shoe ( 10 ) according to one of the preceding claims, characterized in that a surface ( 42 ) of the first element ( 14 ) and / or another surface ( 44 ) of the second element ( 18 ) at the touch point ( 20 ) as a plain bearing ( 46 ) are executed. Sports shoe ( 10 ) according to one of the preceding claims, characterized in that a coupling device on the damping element ( 12 ) is hinged to the sports shoe ( 10 ) to pair with a sports equipment. Sports shoe ( 10 ) according to one of the preceding claims, characterized in that the damping element ( 12 ) is set up in the area of a wave base ( 58 ) stored energy at least partially in a direction of movement of the sports shoe ( 10 ).

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