CN211657510U - Anti-skid shoes - Google Patents

Abstract

The utility model relates to an antiskid shoes relates to the shoes field, and the whole anti-skidding design of having solved shoes among the prior art exists not enoughly, the problem of the technical problem who plays the antiskid effect that can not be fine. The method comprises the following steps: the shoe comprises a shoe body and a multi-stress-point anti-skidding structure arranged at the sole of the shoe body; the multi-stress-point anti-slip structure comprises three anti-slip areas of the sole in different stress states, namely a front sole stress point anti-slip area in a forward leaning state, a heel stress point anti-slip area in a backward leaning state and other anti-slip areas; the front sole stress point anti-slip area in the forward tilting state is arranged at the front sole of the shoe body; the heel stress point anti-slip area in the backward bending state is arranged at the heel of the sole of the shoe body; the other anti-skid areas are arranged at the sole of the shoe body except for the anti-skid area of the stress point of the front sole in a forward leaning state and the anti-skid area of the stress point of the heel in a backward leaning state. The antiskid shoes can be designed to be antiskid according to different stress points of the shoes under different states when people fall down.

Description

Anti-skid shoes

Technical Field

The utility model relates to a shoes field, in particular to antiskid shoes.

Background

Shoes have a long history of development. Approximately 5000 years ago in the yangshao culture period, the most primitive shoe made of hide appeared. Shoes are a tool for protecting feet of people from being injured. At first, in order to overcome special conditions and prevent feet from being difficult or injured, fur shoes are invented. The development of shoes has now made this look. Shoes with various styles and functions can be seen everywhere.

At present, a plurality of anti-skid shoes are provided, the anti-skid design is that the whole anti-skid design is carried out on the bottom surface of the sole, the anti-skid effect is best when the bottom surface of the whole sole is landed, however, when people really slide along, the anti-skid shoes mainly have two states, firstly, when the body of people leans forward, the front sole of the sole is bent and has a tendency of sliding backwards, and the real stress point and the anti-skid point are all arranged on one part of the front sole after the sole is bent; secondly, when the human body leans backwards, the heel of the sole is stressed and tends to slide forwards, the real anti-skid point is arranged at the heel of the sole, the two points show that the existing integral anti-skid design of the shoe is not enough, and the anti-skid effect at the two anti-skid points which really need to be anti-skid is weak, so that the anti-skid effect cannot be well played. To improve this, it is necessary to design a non-slip shoe.

SUMMERY OF THE UTILITY MODEL

The utility model discloses the whole anti-skidding design of solving shoes among the prior art exists not enoughly, and the technical problem who plays the antiskid effect that can not be fine provides an antiskid shoes.

In order to solve the technical problem, the technical scheme of the utility model is specifically as follows:

a non-slip shoe comprising:

the shoe comprises a shoe body and a multi-stress-point anti-skidding structure arranged at the sole of the shoe body;

the multi-stress-point anti-slip structure comprises three anti-slip areas of the sole in different stress states, namely a front sole stress point anti-slip area in a forward leaning state, a heel stress point anti-slip area in a backward leaning state and other anti-slip areas;

the front sole stress point anti-slip region in the forward tilting state is arranged at the front sole of the shoe body, and when a human body tilts forward and the front sole of the shoe body is bent and stressed, the front sole stress point anti-slip region in the forward tilting state increases resistance to the shoe body when the shoe body slides backwards;

the heel stress point anti-slip region in the backward bending state is arranged at the heel of the sole of the shoe body, and when a human body bends backward and the heel of the sole of the shoe body is stressed, the heel stress point anti-slip region in the backward bending state increases resistance to the shoe body when the shoe body slides forwards;

the other anti-skid areas are arranged at the sole of the shoe body except the front-leaning state front sole stress point anti-skid area and the back-leaning state heel stress point anti-skid area.

Preferably, the forward-leaning state sole stress point anti-slip areas are three groups with the same structure and are distributed in three different areas of the sole of the shoe body, namely a sole inner area, a sole outer area and a sole middle area.

Preferably, each set of the front sole force-bearing point anti-slip areas in the forward leaning state comprises:

the sole anti-skid protrusions are arranged at the front soles of the shoe bodies, arc-shaped through grooves are formed in the lower surfaces of the sole anti-skid protrusions, and the arc-shaped through grooves extend along the transverse direction of the shoe bodies;

the front sole antiskid nail fixing embedded plate is embedded and fixed inside the sole antiskid bulge and is parallel to the sole of the shoe body;

one end of the front sole antiskid nail is fixedly connected to the front sole antiskid nail fixing embedded plate, and the other end of the front sole antiskid nail is a sharp end and extends out of the arc-shaped through groove;

the sharp end of the front sole anti-skid stud inclines towards the rear of the shoe body and is perpendicular to the arc-shaped through groove tangent plane, and the sharp end of the front sole anti-skid stud is flush with the lower end face of the sole anti-skid protrusion.

Preferably, the heel stress point anti-slip area in the backward leaning state is four groups with the same structure and distributed at the heel of the sole of the shoe body in a matrix manner.

Preferably, each group of heel stress point anti-slip areas in the backward leaning state comprises:

the heel anti-skid bulge is arranged at the sole of the shoe body, and a groove is formed in the center of the lower surface of the heel anti-skid bulge;

the heel anti-skid stud fixing embedded plate is embedded and fixed inside the heel anti-skid bulge and is parallel to the sole of the shoe body;

one end of the heel anti-skid nail is fixedly connected to the heel anti-skid nail fixing embedded plate, and the other end of the heel anti-skid nail is a sharp end and extends out of the upper bottom surface of the groove;

the sharp end of the heel antiskid nail is flush with the lower end face of the heel antiskid bulge.

Preferably, the other anti-slip regions include a toe anti-slip strip group, a sole anti-slip strip group and a heel anti-slip strip group which are arranged at the sole of the shoe body.

Preferably, the toe antiskid strip group comprises a plurality of arc antiskid strips which are correspondingly matched with the front tip of the sole of the shoe body in shape, and the plurality of arc antiskid strips are arranged at equal intervals from the front tip of the sole of the shoe body to the front sole stress point antiskid area in the forward tilting state.

Preferably, sole department antislip strip group is in including being the matrix distribution and setting the multiunit ring shape antislip strip of sole department before shoes body sole, multiunit ring shape antislip strip all is located sole stress point antislip zone rear side before the state of leaning forward.

Preferably, heel department antislip strip group is in including being the matrix and distributing and setting the multiunit bar antislip strip of shoes body sole heel department, multiunit the bar antislip strip all is located heeling state heel stress point antiskid district front side.

Preferably, the sole antiskid bulges and the heel antiskid bulges are rubber soft bulges.

The utility model discloses following beneficial effect has:

the utility model discloses an antiskid shoe, which achieves good overall antiskid effect and better local antiskid effect through a multi-stress-point antiskid structure in a shoe body, in particular, when a human body leans forward and the sole of the shoe body is bent and stressed, and when the front sole stress point antiskid area in a forward leaning state increases resistance to the shoe body when the shoe body slides backwards, the shoe body is prevented from slipping backwards to cause unstable standing and falling forwards; when a human body leans backwards and the heel of the sole of the shoe body is stressed, the resistance of the heel stress point anti-slip area in a backward leaning state to the shoe body is increased when the shoe body slides forwards, so that the shoe body is prevented from sliding forwards to cause people to stand unstably and fall backwards; other anti-skidding areas enable the shoe body to play a good integral anti-skidding role when a person stands upright. To sum up, this antiskid shoes can be according to the people under the different states that will fall down, and the stress point of shoes is different and carry out corresponding anti-skidding design, has both guaranteed whole antiskid effect, has also promoted local antiskid effect, makes antiskid shoes antiskid effect better.

Drawings

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

FIG. 1 is a schematic view of a non-slip shoe according to the present invention;

FIG. 2 is a front view of the sole of the anti-slip shoe of the present invention;

FIG. 3 is an enlarged view of A in FIG. 1 of a non-slip shoe according to the present invention;

fig. 4 is an enlarged view of B in fig. 1 of the anti-slip shoe of the present invention.

The reference numerals in the figures denote:

1. a shoe body; 2. the sole is raised in an anti-slip way; 3. an arc-shaped through groove; 4. fixing the pre-embedded plate by the front sole antiskid nail; 5. front sole cleats; 6. the heel is raised in a skidproof way; 7. a groove; 8. fixing the pre-embedded plate by the heel anti-skid nail; 9. a heel cleat; 10. an arc-shaped anti-slip strip; 11. a circular anti-slip strip; 12. a strip-shaped anti-slip strip.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Referring to fig. 1 to 4, a non-slip shoe includes:

the shoe comprises a shoe body 1 and a multi-stress-point anti-skidding structure arranged at the sole of the shoe body 1;

the multi-stress-point anti-slip structure comprises three anti-slip areas of the sole in different stress states, namely a front sole stress point anti-slip area in a forward leaning state, a heel stress point anti-slip area in a backward leaning state and other anti-slip areas;

the front sole stress point anti-slip region in the forward-leaning state is arranged at the front sole of the shoe body 1, and when a human body leans forward and the front sole of the shoe body 1 is bent and stressed, the front sole stress point anti-slip region in the forward-leaning state increases resistance to the shoe body 1 when sliding backwards;

the heel stress point anti-slip area in the backward bending state is arranged at the heel of the sole of the shoe body 1, and when a human body bends backward and the heel of the sole of the shoe body 1 is stressed, the resistance of the heel stress point anti-slip area in the backward bending state to the shoe body 1 is increased when the shoe body 1 slides forwards;

the other anti-skid regions are arranged at the sole of the shoe body 1 except the front sole stress point anti-skid region in a forward leaning state and the heel stress point anti-skid region in a backward leaning state.

The front sole stress point anti-skid areas in the forward leaning state are three groups with the same structure and are distributed in three different areas of the front sole of the shoe body 1, namely a front sole inner area, a front sole outer area and a front sole middle area.

Each group of front sole stress point anti-skid areas in the forward leaning state comprises:

the sole anti-skid protrusions 2 are arranged at the front sole of the shoe body 1, the lower surfaces of the sole anti-skid protrusions 2 are provided with arc-shaped through grooves 3, and the arc-shaped through grooves 3 extend along the transverse direction of the shoe body 1;

the front sole antiskid nail fixing embedded plate 4 is embedded and fixed inside the sole antiskid bulge 2 and is parallel to the sole of the shoe body 1;

one end of the front sole antiskid nail 5 is fixedly connected to the front sole antiskid nail fixing embedded plate 4, and the other end of the front sole antiskid nail 5 is a sharp end and extends out of the arc-shaped through groove 3;

the sharp end of the front sole anti-skid stud 5 inclines towards the rear of the shoe body 1 and is vertical to the tangent plane of the arc through groove 3, and the sharp end of the front sole anti-skid stud 5 is flush with the lower end surface of the sole anti-skid bump 2.

The heel stress point anti-slip areas in the backward bending state are four groups with the same structure and are distributed at the heel of the sole of the shoe body 1 in a matrix manner.

Each group of heel stress point anti-slip areas in the backward leaning state comprise:

the heel anti-skid bulge 6 is arranged at the sole of the shoe body 1, and a groove 7 is formed in the center of the lower surface of the heel anti-skid bulge 6;

the heel anti-skid nail fixing embedded plate 8 is embedded and fixed inside the heel anti-skid bulge 6 and is parallel to the sole of the shoe body 1;

one end of the heel anti-skid nail 9 is fixedly connected to the heel anti-skid nail fixing embedded plate 8, and the other end of the heel anti-skid nail 9 is a sharp end and extends out of the upper bottom surface of the groove 7;

the sharp end of the heel antiskid nail 9 is flush with the lower end surface of the heel antiskid bulge 6.

The other anti-slip areas comprise a toe anti-slip strip group, a sole anti-slip strip group and a heel anti-slip strip group which are arranged at the sole of the shoe body 1.

The anti-slip strip group at the toe comprises a plurality of arc anti-slip strips 10 which are correspondingly matched with the shape of the front toe of the sole of the shoe body 1, and the arc anti-slip strips 10 are arranged at equal intervals from the front toe of the sole of the shoe body 1 to the anti-slip area of the stress point of the sole in a forward inclining state.

Sole department antislip strip group is including being the matrix and distributing and setting up the multiunit ring shape antislip strip 11 of sole department before 1 sole of shoes body, and multiunit ring shape antislip strip 11 all is located the preceding sole stress point antiskid zone rear side of the state that leans forward.

Heel department antislip strip group is including being the matrix and distributing and setting up the multiunit bar antislip strip 12 in 1 sole heel department of shoes body, and multiunit bar antislip strip 12 all is located the heel stress point antiskid zone front side of heeling back state.

The sole antiskid lugs 2 and the heel antiskid lugs 6 are rubber soft lugs.

The working principle is as follows:

the utility model discloses an antiskid shoes makes shoes reach good whole antiskid effect and better local antiskid effect through the many stress points anti-skidding structure in shoes body 1, and is specific, when the human body leans forward and the preceding sole department of shoes body 1 sole is crooked and atress, the preceding sole stress point antiskid area of the state that leans forward increases the resistance to shoes body 1 when sliding to the rear, prevents that shoes body 1 from slipping backward and making the people stand the shakiness and fall forward. Specifically, when preceding sole department of 1 sole of shoes is crooked and atress, sole antiskid lug 2 is crooked along with preceding sole department of 1 sole of shoes is crooked, it warp to make the arc on the sole antiskid lug 2 lead to groove 3, stretch out the sharp end of preceding sole antiskid nail 5 that the arc leads to groove 3 simultaneously and incline to 1 rear of shoes body, consequently preceding sole antiskid nail 5 leads to groove 3 deformation state under the arc and presses close to the bottom surface more, prick the bottom surface even, improve the frictional force between shoes body 1 and the bottom surface, to increasing the resistance of shoes body 1 when sliding backward, prevent that shoes body 1 from slipping backward to make the people stand and shakiness forward and fall down. Wherein, the pre-embedded plate 4 for fixing the front sole anti-skid nails plays a role of fixing the front sole anti-skid nails 5, so that the front sole anti-skid nails 5 can be stably fixed at the arc-shaped through grooves 3. Wherein, the sole antiskid bulge 2 is a rubber soft bulge which can bend along with the bending of the sole of the shoe body 1, and the front sole antiskid nail 5 can more easily stretch out of the arc-shaped through groove 3. When the human body leans back and the heel of the sole of the shoe body 1 is stressed, the resistance of the heel stress point anti-slip area in a backward leaning state to the shoe body 1 is increased when the shoe body 1 slides forwards, and the shoe body 1 is prevented from sliding forwards to enable the user to stand unstably and fall backwards. Specifically, when the human body leans back and the heel department atress of 1 sole of shoes, because heel non-slip raised 6 is the soft arch of rubber, when heel non-slip raised 6 atress, will compress the volume, make heel anti-slip nail 9 stretch out and prick the bottom surface in recess 7, improve the frictional force between shoes body 1 and the bottom surface, to shoes body 1 increase the resistance when sliding to the place ahead, prevent that shoes body 1 from slipping forward and make the people stand the shakiness and fall backward. The heel anti-skid nail fixing embedded plate 8 plays a role in supporting and fixing the heel anti-skid nails 9, so that the heel anti-skid nails 9 can be stably fixed at the grooves 7. Other anti-slip areas enable the shoe body 1 to play a good role of integral anti-slip when a person stands upright. Specifically, a plurality of arc-shaped anti-slip strips 10 which are matched with the front tip of the sole of the shoe body 1 in a shape corresponding to the shape of the front tip of the sole are arranged at equal intervals from the front tip of the sole of the shoe body 1 to the anti-slip area of the stress point of the front sole in a forward tilting state, so that the anti-slip effect of the front tip of the sole of the shoe body 1 can be ensured; the multiple groups of annular anti-slip strips 11 are positioned at the rear side of the anti-slip area of the stress point of the sole in the forward leaning state, so that the multiple groups of annular anti-slip strips 11 are fully contacted with the bottom surface to increase the friction force between the bottom surface and the ground in the standing state, and the anti-slip effect is good. The same multiple groups of strip-shaped anti-slip strips 12 are positioned at the front side of the anti-slip area of the stress point of the heel in the backward leaning state, and the multiple groups of strip-shaped anti-slip strips 12 at the heel are fully contacted with the bottom surface to increase the friction force between the bottom surface and the ground, so that the anti-slip shoe has a good anti-slip effect. To sum up, this antiskid shoes can be according to the people under the different states that will fall down, and the stress point of shoes is different and carry out corresponding anti-skidding design, has both guaranteed whole antiskid effect, has also promoted local antiskid effect, makes antiskid shoes antiskid effect better.

It should be understood that the above examples are only for clarity of illustration and are not intended to limit the embodiments. Other variations and modifications will be apparent to persons skilled in the art in light of the above description. And are neither required nor exhaustive of all embodiments. And obvious variations or modifications therefrom are within the scope of the invention.

Claims (10)

1. A non-slip shoe, comprising:

the shoe comprises a shoe body (1) and a multi-stress-point anti-skid structure arranged at the sole of the shoe body (1);

the multi-stress-point anti-slip structure comprises three anti-slip areas of the sole in different stress states, namely a front sole stress point anti-slip area in a forward leaning state, a heel stress point anti-slip area in a backward leaning state and other anti-slip areas;

the front sole stress point anti-slip region in the forward tilting state is arranged at the front sole of the shoe body (1), and when a human body tilts forward and the front sole of the shoe body (1) is bent and stressed, the front sole stress point anti-slip region in the forward tilting state increases resistance to the shoe body (1) when the shoe body (1) slides backwards;

the heel stress point anti-slip region in the backward bending state is arranged at the heel of the sole of the shoe body (1), and when a human body bends backward and the heel of the sole of the shoe body (1) is stressed, the resistance of the heel stress point anti-slip region in the backward bending state to the shoe body (1) is increased when the shoe body (1) slides forwards;

the other anti-skid areas are arranged in other areas of the sole of the shoe body (1) except the front inclined sole stress point anti-skid area and the back inclined heel stress point anti-skid area.

2. The anti-slip shoe according to claim 1, characterized in that the forward-leaning state forefoot force-bearing point anti-slip regions are three groups with the same structure and are distributed in three different regions at the forefoot of the sole of the shoe body (1), namely a forefoot medial region, a forefoot lateral region and a forefoot middle region.

3. The anti-slip shoe according to claim 2, wherein each set of said forward forefoot force receiving points anti-slip zones comprises:

the sole anti-skid protrusions (2) are arranged at the front sole of the shoe body (1), the lower surfaces of the sole anti-skid protrusions (2) are provided with arc-shaped through grooves (3), and the arc-shaped through grooves (3) extend along the transverse direction of the shoe body (1);

the front sole antiskid nail fixing embedded plate (4) is embedded and fixed inside the sole antiskid bulge (2) and is parallel to the sole of the shoe body (1);

one end of the front sole antiskid nail (5) is fixedly connected to the front sole antiskid nail fixing embedded plate (4), and the other end of the front sole antiskid nail (5) is a sharp end and extends out of the arc-shaped through groove (3);

the sharp end of the front sole anti-skid stud (5) inclines towards the rear of the shoe body (1) and is perpendicular to the tangent plane of the arc-shaped through groove (3), and the sharp end of the front sole anti-skid stud (5) is flush with the lower end face of the sole anti-skid bump (2).

4. The anti-slip shoe according to claim 3, wherein the heel force-bearing point anti-slip areas in the backward leaning state are four groups with the same structure and distributed at the heel of the sole of the shoe body (1) in a matrix manner.

5. The anti-slip shoe according to claim 4, wherein each set of said heel stress point anti-slip zones in a supine position comprises:

the heel anti-skid protrusions (6) are arranged at the soles of the shoe bodies (1), and grooves (7) are formed in the center positions of the lower surfaces of the heel anti-skid protrusions (6);

the heel anti-skid stud fixing embedded plate (8) is embedded and fixed inside the heel anti-skid bulge (6) and is parallel to the sole of the shoe body (1);

one end of the heel anti-skid nail (9) is fixedly connected to the heel anti-skid nail fixing embedded plate (8), and the other end of the heel anti-skid nail (9) is a sharp end and extends out of the upper bottom surface of the groove (7);

the sharp end of the heel antiskid nail (9) is flush with the lower end face of the heel antiskid bulge (6).

6. Non-slip shoe according to claim 5, characterized in that said other non-slip zones comprise a group of anti-slip strips at the toe, a group of anti-slip strips at the ball and a group of anti-slip strips at the heel, arranged at the sole of said shoe body (1).

7. The anti-slip shoe according to claim 6, characterized in that the set of anti-slip strips at the toe comprises a plurality of arc-shaped anti-slip strips (10) which are correspondingly matched with the front toe of the sole of the shoe body (1), and the plurality of arc-shaped anti-slip strips (10) are arranged at equal intervals from the front toe of the sole of the shoe body (1) to the anti-slip area of the front sole stress point in the forward inclined state.

8. The anti-slip shoe according to claim 6, characterized in that the sole anti-slip strip set comprises a plurality of sets of circular ring-shaped anti-slip strips (11) distributed in a matrix form and arranged at the sole front sole of the shoe body (1), and the plurality of sets of circular ring-shaped anti-slip strips (11) are all positioned at the rear side of the forward-inclined state sole stress point anti-slip region.

9. The anti-slip shoe according to claim 6, characterized in that the heel-position anti-slip strip group comprises a plurality of groups of strip-shaped anti-slip strips (12) distributed in a matrix form and arranged at the heel position of the sole of the shoe body (1), and the plurality of groups of strip-shaped anti-slip strips (12) are all positioned at the front side of the heel stress point anti-slip area in the heeling-back state.

10. Non-slip shoe according to claim 5, characterized in that the sole stud (2) and the heel stud (6) are both rubber soft studs.

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