CN212911925U - Bionic anti-skid slippers - Google Patents

Abstract

The utility model relates to a bionic anti-skidding slippers belongs to the technical field of slippers, and it includes sole and vamp, bionic anti-skidding district, arch of foot antiskid district and heel supporting area have set gradually from the tip to the tail on the outsole of sole, be provided with the support paster in the heel supporting area, then be provided with on the support paster and support anti-skidding structure, support anti-skidding structure including the first support piece and the second support piece of alternative setting, first support piece includes the first sloping piece of multiunit, every group first sloping piece all includes two at least first sloping pieces, second support piece includes multiunit second sloping piece, every group the second sloping piece all includes two at least second sloping pieces, first sloping piece with contained angle more than or equal to ninety degrees that the second sloping piece formed, adjacent two sets of first sloping piece with the sloping piece interval of second sets up. The utility model has the advantage of good antiskid effect.

Description

Bionic anti-skid slippers

Technical Field

The utility model relates to the technical field of slippers, in particular to a pair of bionic anti-skidding slippers.

Background

The slipper is one of shoes, the heel is completely empty, only the front is provided with the toe cap, the toe cap is mostly flat, and the material is usually quite light and soft leather, plastic, cloth and the like. The types of slippers are differentiated according to wearing occasions and performance and purposes. For example, beach slippers are not made of cloth, but made of plastic, because the beach slippers are waterproof and easy to clean, and the toe cap type is also specially designed and is often called as foot-clamping slippers, namely herringbone slippers. However, in winter, the slippers in the room may use fluff cloth instead of plastics for keeping warm, so that people can enjoy better in the room. Also provided with antiskid slippers for bathing and wearing. And antistatic slippers and the like which are commonly used in electronic factories and dust-free workshops are also provided.

Chinese patent with grant publication number CN207870392U discloses a massage slipper, including slipper sole, slipper pad and slipper upper are all located the upper end of slipper sole, slipper upper is located the top of slipper pad, slipper upper and slipper sole swing joint, the upper end of slipper sole is equipped with the spacing groove, the cross-section of spacing groove is the same with the cross-sectional shape of slipper sole, and the cross-section of spacing groove is less than the cross-section of slipper sole, the cross-section of spacing groove is the same with the cross-sectional shape of slipper pad, be equipped with a plurality of massage balls between slipper pad and the slipper sole, a plurality of massage balls evenly distributed along the length direction of slipper sole, the upper end of slipper sole is equipped with holds in the palm the toe groove, hold in the palm the toe groove and be provided with five, five hold in the palm the toe groove shape size inequality.

The above prior art solutions have the following drawbacks: the use scenes of the slippers often include a wet and slippery bathroom, tiles are generally laid in the bathroom, undried water, shampoo, shower cream and the like often exist on the tiles, and therefore the anti-slip effect of the slippers is greatly tested. The sole of the slipper in the technical scheme is not provided with any anti-slip structure, so that once a user wears the slipper in the technical scheme to a wet and slippery place, the slipper is easy to slip, and therefore the slipper with a good anti-slip effect is needed.

SUMMERY OF THE UTILITY MODEL

Aiming at the defects existing in the prior art, the utility model aims at providing a bionic anti-skid slipper which has the advantage of good anti-skid effect.

The above object of the present invention can be achieved by the following technical solutions:

the utility model provides a bionical anti-skidding slippers, includes sole and vamp, bionic anti-skidding district, arch of foot antiskid district and heel support area have set gradually from the tip to the tail on the outsole of sole, be provided with the support paster in the heel support area, then be provided with on the support paster and support anti-skidding structure, support anti-skidding structure including first support piece and the second support piece of setting in turn, first support piece includes the first sloping piece of multiunit, every group first sloping piece all includes two at least first sloping pieces, second support piece includes the sloping piece of multiunit second, every group the second sloping piece all includes two at least sloping pieces, first sloping piece with the contained angle that the sloping piece of second formed is more than or equal to ninety degrees, adjacent two sets of first sloping piece with the sloping piece interval of second sets up.

By adopting the technical scheme, the bionic anti-slip area, the arch anti-slip area and the heel supporting area are arranged on the outsole of the sole to prevent slipping in a synergic manner, so that the anti-slip effect of the slipper is improved. Wherein, first support piece and second support piece in the heel support region cooperate, through the cooperation of the first sloping block of multiunit and second sloping block, form rhombus mutual resistance structure to improve the non-skid property of sole greatly. And a plurality of first sloping blocks and second sloping block constitute a plurality of strong points to improve the support ability of the heel department of sole.

The present invention may be further configured in a preferred embodiment as: the supporting patch is circumferentially provided with a plurality of drainage patches in the heel supporting area, and a drainage groove is formed between the drainage patches and the supporting patches.

Through adopting above-mentioned technical scheme, drainage paster and support paster cooperation form water drainage tank to improve the drainage non-slip ability of sole.

The present invention may be further configured in a preferred embodiment as: the drainage patch is provided with a plurality of rubber rings, supporting blocks are arranged in the rubber rings, and the thickness of the supporting blocks is smaller than that of the rubber rings.

Through adopting above-mentioned technical scheme, the rubber circle can form miniature sucking disc structure to make the ability of grabbing of sole further strengthen, and set up the supporting shoe in the rubber circle additionally and then can extrude the moisture in the rubber circle, and further provide the holding power, strengthen the holding power of the heel department of sole.

The present invention may be further configured in a preferred embodiment as: the bionic anti-slip shoe is characterized in that a bionic patch is arranged in the bionic anti-slip area, a first bionic piece is arranged on the bionic patch and comprises a plurality of first bionic anti-slip strips, and the first bionic anti-slip strips face towards the toe cap of the sole.

Through adopting above-mentioned technical scheme, the cooperation of a plurality of first bionical antislip strips, and set up first bionical antislip strip into the tip department slope of orientation sole, then can form the cross fold of similar gecko foot to further improve the non-skid property of sole.

The present invention may be further configured in a preferred embodiment as: the bionic shoe comprises a shoe sole and is characterized in that a second bionic piece is further arranged on the bionic patch on one side of the first bionic piece, the second bionic piece comprises a plurality of second bionic anti-slip strips, and the second bionic anti-slip strips face the shoe tail of the shoe sole in an inclined mode.

Through adopting above-mentioned technical scheme, the cooperation of the bionical antislip strip of a plurality of seconds, and set up the bionical antislip strip of second into the slope of shoe tail department towards the sole, then can further form the cross fold of similar gecko foot. And the first bionic anti-slip strip and the second bionic anti-slip strip are matched, so that the sole has good anti-slip performance no matter on an uphill slope or a downhill slope. This is because, under the effect of the wearer's gravity, first bionical antislip strip and the bionical antislip strip of second take place deformation and contact with ground to the area of contact of greatly increased sole and ground. And when first bionical antislip strip and the deformation of the bionical antislip strip of second, can also extrude the water of sole to improve the drainage effect of sole.

The present invention may be further configured in a preferred embodiment as: and the first bionic anti-slip strip and the second bionic anti-slip strip are both provided with a convex block.

Through adopting above-mentioned technical scheme, under the effect of wearer's gravity, the lug supports tightly and takes place deformation with first bionical antislip strip or the bionical antislip strip of second to make lug and ground support tightly, and the part that supports tightly with ground is the part that really plays anti-skidding effect, consequently, the lug of extra setting can further improve the anti-skidding effect of sole.

The present invention may be further configured in a preferred embodiment as: the bionic patch is further provided with a flow guide groove, and the flow guide groove penetrates through the first bionic piece and the second bionic piece.

Through adopting above-mentioned technical scheme, set up the water conservancy diversion ditch on bionical paster, then the hydroenergy between the first bionical antislip strip and the second bionical antislip strip can further flow out through the water conservancy diversion ditch to further improve the drainage effect of sole.

The present invention may be further configured in a preferred embodiment as: the foot arch anti-slip area is provided with anti-slip patches, each anti-slip patch is provided with a plurality of anti-slip blocks, and each anti-slip block is provided with anti-slip particles.

Through adopting above-mentioned technical scheme, the sole of arch department is stressed lessly, and the frictional force that can provide is also less. And an anti-slip patch is additionally arranged in the arch anti-slip area, and an anti-slip block with anti-slip particles is arranged on the anti-slip patch, so that the supporting force and the friction force of the arch of the sole are improved, and the anti-slip effect of the sole is further improved.

The present invention may be further configured in a preferred embodiment as: the insole of the sole is provided with wavy anti-skid patterns.

Through adopting above-mentioned technical scheme, antiskid decorative pattern can reduce the gliding possibility between wearing person's foot and the sole.

To sum up, the utility model discloses a following at least one useful technological effect:

1. the bionic anti-slip area, the arch anti-slip area and the heel supporting area are arranged on the outsole of the sole to prevent slipping in a coordinated manner, so that the water drainage anti-slip effect of the slipper is improved;

2. the drainage anti-skid capacity of the sole is further improved by arranging the drainage patch with the rubber ring and the supporting block;

3. by arranging the first bionic piece and the second bionic piece, the cross folds similar to the feet of the gecko are formed on the sole, so that the sole has good drainage and antiskid effects under the conditions of an uphill slope and a downhill slope;

4. the first bionic piece and the second bionic piece are additionally provided with the bumps, so that the effective anti-skidding area of the sole is further increased, and the anti-skidding effect of the sole is improved;

5. the anti-skidding blocks with anti-skidding particles are additionally arranged in the arch anti-skidding area, so that the supporting force and the anti-skidding effect of the arch of the sole are further improved.

Drawings

Fig. 1 is a schematic view of the overall structure of the present invention.

Fig. 2 is a bottom view of the present invention for showing the structure of the sole.

Fig. 3 is the structure of the bionic patch of the present invention.

Fig. 4 shows the structure of the anti-slip patch of the present invention.

Fig. 5 shows the structure of the support patch of the present invention.

Fig. 6 shows the structure of the drainage patch of the present invention.

In the figure, 1, a sole; 11. anti-skid patterns; 2. a shoe upper; 3. a bionic anti-slip area; 31. bionic paster; 32. a first biomimetic element; 33. a second biomimetic element; 34. a bump; 35. a flow guide groove; 4. an arch anti-slip region; 41. anti-skid paster; 42. anti-skid blocks; 43. anti-skid particles; 44. a LOGO patch; 5. a heel support region; 51. supporting the patch; 52. supporting the anti-skid structure; 521. a first support member; 522. a second support member; 6. water drainage paster; 61. a water discharge tank; 62. a rubber ring; 63. and (7) a supporting block.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings.

As shown in figures 1 and 2, the bionic anti-skid slippers disclosed by the utility model comprise soles 1 and vamps 2 arranged on the soles 1. The insole of the sole 1 is provided with wave-shaped anti-slip patterns 11, and the outsole of the sole 1 is provided with a bionic anti-slip area 3, an arch anti-slip area 4 and a heel support area 5 in sequence from the toe cap to the tail.

As shown in fig. 2 and 3, four oval bionic patches 31 made of rubber are arranged in the bionic anti-slip region 3, a first bionic piece 32 is arranged on the bionic patch 31, the first bionic piece 32 comprises a plurality of first bionic anti-slip strips parallel to each other, and the first bionic anti-slip strips are arranged at intervals along the length direction of the bionic patches 31. And the length direction of first bionical antislip strip is perpendicular with the length direction of bionical paster 31, and first bionical antislip strip is located one side that bionical paster 31 is close to the tip, and just first bionical antislip strip all sets up towards the tip direction slope of sole 1.

Still be provided with the bionical piece 33 of second on the bionical paster 31, the bionical piece 33 of second includes a plurality of bionical antislip strips of second of parallel arrangement each other, and the bionical antislip strip of second sets up along bionical paster 31's length direction interval, and the bionical antislip strip of second is parallel with first bionical antislip strip. The bionic anti-slip strips of the second are located on one side, close to the shoe tail, of the bionic patch 31, and the bionic anti-slip strips of the second are all obliquely arranged towards the shoe tail of the sole 1.

The first bionic anti-slip strip and the second bionic anti-slip strip are far away from one end of the bionic patch 31 and are mutually far away from the side wall on one side, and the lugs 34 are formed integrally on the side wall, wherein the lugs 34 on the first bionic anti-slip strip are obliquely arranged towards the toe cap direction of the sole 1, and the lugs 34 on the second bionic anti-slip strip are obliquely arranged towards the tail direction of the sole 1.

The bionic patch 31 is further provided with a flow guide groove 35 along the length direction of the bionic patch 31, and the flow guide groove 35 penetrates through and cuts the first bionic piece 32 and the second bionic piece 33.

As shown in fig. 2 and 4, the arch antiskid region 4 is provided with an antiskid patch 41, and the antiskid patch 41 and the bionic patch 31 are connected by a connecting patch. The anti-slip patch 41 is provided with a plurality of anti-slip blocks 42, and anti-slip particles 43 are uniformly distributed on the side wall of one side of each anti-slip block 42, which is far away from the anti-slip patch 41. And a LOGO patch 44 is also arranged in the arch antiskid area 4 on one side of the antiskid patch 41.

As shown in fig. 2 and 5, the heel supporting area 5 is provided with a supporting patch 51, the supporting patch 51 is provided with a supporting anti-slip structure 52, and the supporting anti-slip structure 52 comprises a first supporting piece 521 and a second supporting piece 522 which are alternately arranged along the length direction of the sole 1. The first support 521 comprises a plurality of first inclined blocks, each first inclined block comprises two first inclined blocks, and the plurality of first inclined blocks are arranged along the width direction of the sole 1. The second supporting member 522 includes a plurality of sets of second inclined blocks, each set of second inclined blocks includes two second inclined blocks, and the plurality of sets of second inclined blocks are arranged along the direction of the sole 1. The included angle that first sloping block and second sloping block formed is the right angle, and adjacent two sets of first sloping blocks and second sloping block interval set up, and the first sloping block of multiunit and second sloping block form rhombus mutual resistance.

As shown in fig. 2 and 6, a plurality of drainage patches 6 are also circumferentially disposed in the heel support area 5 on the circumferential side of the support patch 51, and a drainage groove 61 is formed between the plurality of drainage patches 6 and the support patch 51. A plurality of rubber rings 62 are uniformly distributed on the drainage patch 6, a cylindrical supporting block 63 is arranged in each rubber ring 62, and the thickness of the supporting block 63 is smaller than that of the rubber ring 62.

The implementation principle of the embodiment is as follows:

when the slipper is worn by a wearer, the sole of the foot contacts the anti-slip pattern 11 inside the sole 1, thereby reducing the possibility of slipping between the wearer and the sole 1.

The wearer's own weight is mostly concentrated at the heel, and the heel of the sole 1 is also subjected to the maximum force. At this time, the first support 521 and the second support 522 in the heel support area 5 cooperate with each other to form a plurality of support points and a plurality of rhombic mutual resistance structures through the cooperation of the plurality of sets of the first inclined blocks and the second inclined blocks, so as to improve the support capability and the anti-slip property of the heel of the sole 1. And the wearer's own weight also presses the rubber ring 62 and the supporting block 63 on the drain patch 6, wherein the rubber ring 62 can form a small-sized suction cup structure, so that the gripping ability of the sole 1 is further enhanced, and the supporting block 63 can squeeze out moisture in the rubber ring 62 and further provide a supporting force.

Because the arch of the human body is concave, the arch of the sole 1 is less stressed, and the anti-slip blocks 42 with the anti-slip particles 43 arranged on the anti-slip patches 41 can still provide better supporting force and anti-slip performance on the premise of less stress.

When the wearer walks, the heel is raised, so that the heel of the sole 1 is also disengaged from the ground, while the main slip resistance of the sole 1 is provided at the toe of the sole 1. In the process, the first bionic anti-slip strip, the second bionic anti-slip strip and the convex block 34 are deformed and inclined towards the shoe tail or the shoe head, so that the contact area of the sole 1 and the ground is greatly increased, and the cross folds similar to the feet of the gecko are formed, so that the sole 1 has good anti-slip performance on both an uphill slope and a downhill slope.

The embodiment of this specific implementation mode is the preferred embodiment of the present invention, not limit according to this the utility model discloses a protection scope, so: all equivalent changes made according to the structure, shape and principle of the utility model are covered within the protection scope of the utility model.

Claims (9)

1. The utility model provides a bionic anti-skidding slipper, includes sole (1) and vamp (2), its characterized in that: the bionic anti-slip region (3), the arch anti-slip region (4) and the heel support region (5) are sequentially arranged on the outsole of the sole (1) from the toe cap to the heel tail, a supporting patch (51) is arranged in the heel supporting area (5), a supporting anti-skid structure (52) is arranged on the supporting patch (51), the supporting anti-skid structure (52) comprises a first supporting piece (521) and a second supporting piece (522) which are alternately arranged, the first support member (521) comprises a plurality of sets of first swash blocks, each set of first swash blocks comprises at least two first swash blocks, the second support (522) comprises a plurality of sets of second swash blocks, each set of the second swash blocks comprises at least two second swash blocks, the included angle formed by the first inclined block and the second inclined block is more than or equal to ninety degrees, and the first inclined block and the second inclined block are arranged at intervals in two adjacent groups.

2. The bionic anti-slip slipper according to claim 1, wherein: a plurality of drainage patches (6) are circumferentially arranged in the heel supporting area (5) on the peripheral side of the supporting patch (51), and a drainage groove (61) is formed between the drainage patches (6) and the supporting patch (51).

3. The bionic anti-slip slipper as claimed in claim 2, wherein: the drainage patch (6) is provided with a plurality of rubber rings (62), supporting blocks (63) are arranged in the rubber rings (62), and the thickness of the supporting blocks (63) is smaller than that of the rubber rings (62).

4. The bionic anti-slip slipper according to claim 1, wherein: the bionic anti-skid shoe is characterized in that a bionic patch (31) is arranged in the bionic anti-skid area (3), a first bionic piece (32) is arranged on the bionic patch (31), the first bionic piece (32) comprises a plurality of first bionic anti-skid strips, and the first bionic anti-skid strips face towards the toe cap of the shoe sole (1).

5. The bionic anti-slip slipper according to claim 4, wherein: the bionic shoe is characterized in that a second bionic piece (33) is further arranged on the bionic patch (31) on one side of the first bionic piece (32), the second bionic piece (33) comprises a plurality of second bionic anti-slip strips, and the second bionic anti-slip strips face towards the tail of the shoe sole (1).

6. The bionic anti-slip slipper according to claim 5, wherein: and the first bionic anti-slip strip and the second bionic anti-slip strip are both provided with a convex block (34).

7. A bionic anti-slip slipper as claimed in claim 5 or 6, wherein: the bionic patch (31) is further provided with a flow guide groove (35), and the flow guide groove (35) penetrates through the first bionic piece (32) and the second bionic piece (33).

8. The bionic anti-slip slipper according to claim 1, wherein: the arch antiskid area (4) is provided with an antiskid patch (41), a plurality of antiskid blocks (42) are arranged on the antiskid patch (41), and antiskid particles (43) are arranged on each antiskid block (42).

9. The bionic anti-slip slipper according to claim 1, wherein: the inner bottom of the sole (1) is provided with wavy anti-slip patterns (11).

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