CN219645138U - Shoe cover - Google Patents

Abstract

The utility model relates to the technical field of daily necessities, and provides a shoe cover, wherein an opening is arranged on the shoe cover, and the opening has elasticity to open and contain shoes; the shoe cover is characterized in that anti-slip lines are arranged on the parts, corresponding to soles of the shoes, of the shoe cover, wherein the parts, corresponding to soles of the shoes, of the shoe cover are provided with the anti-slip lines, and each anti-slip line comprises a plurality of first anti-slip ways which are arranged side by side and extend towards the length direction of the shoe cover. The first cleat includes: a plurality of first anti-skid units arranged at intervals along the length direction of the first anti-skid way; the first anti-slip unit is shaped to have a first direction in which friction is relatively greatest; in each first anti-skid way, the directions of the first anti-skid units in at least two first anti-skid ways are opposite to each other. The shoe cover provided by the utility model can give consideration to the adaptability under more scenes.

Description

Shoe cover

Technical Field

The utility model relates to the technical field of daily necessities, in particular to a shoe cover.

Background

The shoe cover is a daily appliance sleeved outside the shoe and used for protecting the shoe or the ground.

The shoe cover is divided into a disposable shoe cover and a reusable shoe cover. Disposable shoe covers are commonly used in rooms where a large number of computers are placed, and are now being used more in dust-free workshops, clean rooms, and even in homes, thereby protecting the indoor environment. The disposable shoe cover is often made of plastic, is not environment-friendly, is easy to damage and cannot be used outdoors.

With the development of the living standard of people, more and more consumers like to purchase shoes with high price. These shoes are prone to dirt and wear during outdoor activities, such as mountain climbing. Similar to the need for protecting a mobile phone screen by a mobile phone screen protecting film, the need for protecting shoes by using shoe covers has been gradually developed and accepted by the market. Such shoe covers are generally reusable shoe covers, which have certain wear-resistant, easy-to-put-on and-take-off performance requirements.

In addition, when outdoor sports, the grip of the shoe cover is required to be high. Therefore, in the prior art, the bottoms of a plurality of shoe covers are provided with anti-skid lines, and larger friction force is obtained through the provided anti-skid lines. However, the anti-slip lines provided by the shoe cover in the prior art cannot generally meet the anti-slip requirement in a specific application scene.

Disclosure of Invention

In order to solve or at least partially solve the above technical problems, the present utility model provides a shoe cover, wherein an opening is arranged on the shoe cover, and the opening has elasticity to open and accommodate the shoe;

the shoe cover is provided with anti-skid lines on the parts corresponding to the soles of the shoes, wherein the anti-skid lines comprise a plurality of first anti-skid ways which are arranged side by side and extend towards the length direction of the shoe cover.

The first cleat includes: a plurality of first anti-skid units arranged at intervals along the length direction of the first anti-skid way; the first anti-slip unit is shaped to have a first direction in which friction is relatively greatest;

in each first anti-skid way, the directions of the first anti-skid units in at least two first anti-skid ways are opposite to each other.

Optionally, in each first anti-skid way, the directions of the first anti-skid units of every two adjacent first anti-skid ways are opposite to each other.

Optionally, the number of the first anti-skid ways is greater than or equal to six.

Optionally, in each first anti-slip way, the number of the first anti-slip units in the first direction towards the direction of the shoe cover corresponding to the heel is greater than the number of the first anti-slip units in the first direction towards the direction of the shoe cover corresponding to the toe.

Optionally, the number of the first anti-slip ways is an even number, and in each first anti-slip way, the length of the first anti-slip way relatively close to the sole central line of the shoe cover is shorter than that of the first anti-slip way relatively far away from the sole central line of the shoe cover;

wherein, the first direction of the first anti-slip unit of the first anti-slip way which is farthest from the sole central line of the shoe cover faces the direction of the shoe cover corresponding to the heel.

Optionally, the anti-skid lines further comprise two second anti-skid ways respectively arranged at two sides of the first anti-skid way;

the second cleat includes: a plurality of second anti-skid units arranged at intervals along the length direction of the second anti-skid way; the second anti-skid unit is in a strip shape, and the long side direction of the second anti-skid unit is perpendicular to the length direction of the second anti-skid way.

Optionally, the length of the second anti-slip unit of the second anti-slip way sequentially changes from the direction close to the shoe cover and corresponding to the toe to the direction close to the shoe cover and corresponding to the heel:

the method comprises the steps of gradually increasing, gradually decreasing, gradually increasing, gradually decreasing and gradually increasing.

Optionally, the first anti-slip unit includes two anti-slip strips connected with each other at a preset included angle, the angle of the preset included angle is greater than 90 degrees and less than 170 degrees, and the first direction is opposite to the direction in which the tip of the included angle faces.

Optionally, the angle of the preset included angle is between 100 degrees and 130 degrees.

Alternatively, among the two cleats connected to each other, the length of the cleats near the sole midline of the shoe cover is shorter than the length of the cleats far from the sole midline of the shoe cover.

The shoe cover provided by the utility model can give consideration to the adaptability under more scenes.

Drawings

In order to more clearly illustrate the embodiments of the present utility model, a brief description of the related drawings will be provided below. It is to be understood that the drawings described below are only for illustrating some embodiments of the present utility model, and that one of ordinary skill in the art can obtain many other technical features and connection relationships not mentioned herein from the drawings.

Fig. 1 is a schematic view of a shoe cover according to an embodiment of the present utility model in front view;

fig. 2 is a schematic perspective view of a shoe cover in a top view according to an embodiment of the present utility model;

fig. 3 is a schematic view of another shoe cover according to an embodiment of the present utility model in front view;

fig. 4 is a schematic view of a shoe cover according to another embodiment of the present utility model in a front view;

fig. 5 is a schematic perspective view of another shoe cover according to an embodiment of the present utility model in a bottom view;

FIG. 6 is a schematic view of a portion of the interior surface of a cover of a shoe in accordance with an embodiment of the present utility model in a portion of the cover corresponding to the heel of the shoe in which the cover is incorporated;

fig. 7 is a schematic view of a shoe cover according to another embodiment of the present utility model in a front view;

fig. 8 is a schematic view of a first cleat unit of a shoe cover according to an embodiment of the present utility model;

fig. 9 is a schematic view of a second cleat unit of a shoe cover according to an embodiment of the present utility model;

fig. 10 is a schematic illustration of another first cleat unit of a shoe cover provided by an embodiment of the present utility model.

Reference numerals and names in the drawings are as follows:

1. an opening; 11. a first side; 12. a second side; 2. a thickened portion; 21. a half sole portion; 22. the root of the rear foot; 3. an undensified portion; 4. hanging rope; 5. a hanging hole; 6. a shoelace imitation part; 7. an anti-slip texture; 8. anti-skid lines; 81. a first anti-skid way; 811. a first anti-slip unit; 8111. an anti-slip strip; 82. a second anti-skid way; 821. and a second anti-slip unit.

Detailed Description

The following describes the technical solution in the embodiment of the present utility model in detail with reference to the drawings in the embodiment of the present utility model.

In the Chinese patent application No. 201710966193X, a shoe cover type rain boot is provided, which is provided with a rain boot main body and a zipper. The rain boots are integrally formed rubber shoe bodies, the sole parts are designed with anti-skid lines, and meanwhile, the heel parts are designed with zippers, so that the rain boots can be directly sleeved on shoes in daily use when the rain boots are used, and the shoes can be effectively prevented from being wet and dirtied by pulling the zippers. When not in use, the rain boots can be rolled up, and the rain boots are convenient to carry.

However, the inventor of the present utility model found that in the prior art, the anti-slip pattern of the sole portion of the shoe cover is generally adapted to only daily use, but is difficult to adapt to mountain climbing and some extreme exercises.

In view of this, the present utility model provides a shoe cover that improves the adaptation of the shoe cover in these application scenarios.

Embodiment one

A first embodiment of the present utility model proposes a shoe cover, as shown in fig. 7 and 8, in which an opening 1 is provided on the shoe cover, the opening 1 having elasticity to open and receive a shoe;

the shoe cover is provided with anti-slip lines 8 at positions corresponding to soles of the shoes, and the anti-slip lines 8 comprise a plurality of first anti-slip ways 81 which are arranged side by side and extend towards the length direction of the shoe cover.

The first anti-skid 81 includes: a plurality of first anti-slip units 811 provided at intervals along the length direction of the first anti-slip path 81; the first slip prevention unit 811 is shaped to have a first direction in which friction is relatively maximum;

of the first anti-slip grooves 81, at least two first anti-slip units 811 in the first anti-slip grooves 81 are directed in opposite directions to each other.

It should be noted that the first anti-skid 81 according to the present utility model is not necessarily disposed completely parallel to each other, although it is disposed side by side. The first anti-skid 81 may also be slightly angled.

In fig. 8, an exemplary first anti-skid unit 811 is illustrated. It includes two anti-slip strips 8111 connected at a predetermined angle to each other. The angle of the preset included angle can be more than 90 degrees and less than 170 degrees. As can be seen from fig. 8, the friction force F applied to the first anti-slip unit 811 in the direction from right to left in the drawing will be greater than the friction force F applied in the direction from left to right in the drawing due to the preset angle. That is, in fig. 8, the first direction of the first anti-slip unit 811 is the right side, and the first anti-slip unit 811 can provide a greater friction force when the shoe cover is advanced to the left side. That is, the first direction is opposite to the direction in which the tip of the included angle is oriented.

It should be noted that the shape of the anti-slip strip 8111 is not limited to the straight shape illustrated in fig. 8, but may be wavy or other shapes to provide additional friction performance.

From the above analysis, it is known that, for the first anti-skid 81 having a whole row of the first anti-skid units 811, the friction force that can be provided in the direction of the first direction is greater, and the magnitude of this friction force exhibits a strong correlation with the angle of the preset included angle. Optionally, when the angle of the preset included angle is between 100 degrees and 130 degrees, the friction force in the first direction can reach a more ideal value.

For the shoe cover provided by the embodiment of the utility model, as the plurality of first anti-slip ways 81 are arranged, and the directions of the first anti-slip units 811 in at least two first anti-slip ways 81 are opposite to each other, larger friction force can be provided in the front direction and the rear direction, and better anti-slip effect is achieved. The number and positions of the first anti-skid 81 in different directions can be allocated according to the application scene by a person skilled in the art to adjust the frictional force in two directions.

For example, in a daily life scenario, people walk forward more often and the probability of backing up in place is extremely small, so the number of first anti-skid rails 81 in the first direction rearward can be increased, and the number of first anti-skid rails 81 in the first direction forward can be reduced.

The situation is different for mountain climbing. The outdoor mountain climbing exercise needs to complete the complete process of climbing and descending the mountain, when the outdoor mountain climbing exercise is influenced by bad weather and the road is muddy, the shoes or the shoe covers with large normal forward friction force are easy to slip in the process of descending the mountain, and personal safety risks are caused. Therefore, friction in both the forward and reverse directions is important for mountain climbing.

In view of this, in one embodiment of the present utility model, optionally, as shown in fig. 7, in each of the first anti-slip grooves 81, the first directions of the first anti-slip units 811 of each adjacent two first anti-slip grooves 81 are opposite to each other. In this way, in two directions, the shoe cover product provided by the embodiment of the utility model has excellent friction performance, and can better adapt to the special situation requirement of mountain climbing.

It is to be understood that, for the present utility model, if the number of the first anti-slip ways 81 is singular, the effect of asymmetric friction force in the front-rear direction is easily constructed, which is also suitable for fine-tuning the expression of friction force of the shoe cover in all directions. Wherein, alternatively, the number of the first anti-skid 81 may be greater than or equal to six. For example, in fig. 8, a first anti-skid 81 of four on one side and eight on both sides is illustrated.

Alternatively, in each of the first anti-slip grooves 81, the number of the first anti-slip units 811 in the first direction toward the direction of the shoe cover corresponding to the heel is greater than the number of the first anti-slip units 811 in the first direction toward the direction of the shoe cover corresponding to the toe. When the first direction faces the direction of the shoe cover corresponding to the heel, the shoe cover provides forward friction force more, so that the ground grabbing capacity of the shoe cover in the advancing process of a user can be improved, and the application scene is wider.

Accordingly, as a further alternative, referring to fig. 7, the number of the first anti-slip ways 81 is an even number, and in each of the first anti-slip ways 81, the first anti-slip way 81 relatively close to the sole center line of the shoe cover is shorter in length than the first anti-slip way 81 relatively far from the sole center line of the shoe cover; wherein a first direction of the first slip prevention unit 811 of the first slip prevention course 81 farthest from the midline of the sole of the shoe cover faces a direction of the shoe cover corresponding to the heel.

It should be noted that, since the shoe cover is not square, the first anti-slip unit 811 of the different first anti-slip rail 81 is not free from being in-out. On a shoe cover similar to that illustrated in fig. 7, the first slip prevention unit 811 of the first slip prevention course 81, which is relatively short, may be disposed toward the tip of the shoe by disposing the first slip prevention unit 811 of the first slip prevention course 81, which is relatively long and far from the center of the shoe cover, toward the heel direction. In this way, the technical effect that the forward friction force is slightly larger than the backward friction force can be achieved without additionally arranging the first anti-skid ways 81 with different numbers, and the cost is reduced.

In addition to the adjustment of the magnitude and direction of the frictional force by the direction of each first anti-slip unit 811 in the first anti-slip way 81, the adjustment may be performed by adjusting the shape of the first anti-slip unit 811. For example, alternatively, as shown in fig. 10, among two cleats 8111 connected to each other, the length of the cleats 8111 near the sole midline of the shoe cover is shorter than the length of the cleats 8111 far from the sole midline of the shoe cover.

By making the lengths of the two anti-slip strips 8111 unequal, it is possible to provide an oblique friction force in addition to the friction force along the length direction of the first anti-slip strip 81, thereby adapting to a wider application scenario.

In addition, as shown in fig. 7 and 9, the anti-skid grain 8 may further include two second anti-skid ways 82 disposed on two sides of the first anti-skid way 81;

the second anti-skid 82 includes: a plurality of second anti-skid units 821 arranged at intervals along the length direction of the second anti-skid rail 82; the second anti-skid unit 821 has a long strip shape, and the long side direction of the second anti-skid unit 821 is perpendicular to the length direction of the second anti-skid rail 82.

The second anti-slip way 82 is additionally arranged on the side surface, so that the friction force provided by the first anti-slip way 81 can be additionally supplemented. Optionally, the length of the second anti-slip unit 821 of the second anti-slip track 82 sequentially changes from the direction approaching the shoe cover to correspond to the toe to the direction approaching the shoe cover to correspond to the heel: the method comprises the steps of gradually increasing, gradually decreasing, gradually increasing, gradually decreasing and gradually increasing.

The second anti-slip way 82 arranged at the edge can be corresponding to the stress demands of the parts such as the sole part, the foot root part and the like when the rule changes, so that the shoe cover and the shoe can be better integrated.

Second embodiment

In the Chinese patent of the utility model of the patent number 942390946, a rain-proof shoe cover is provided, the body is made of latex and is in a sock-shaped plane structure, the upper and the sole are all on the same plane, the anti-skid wear-resistant rubber is attached to the sole, and the sole of the upper has better elasticity. In the patent, the openings are generally in the same plane, or the heel part is at a slightly higher position, so that the heel part of the shoe is difficult to enter the openings when the shoe cover is worn; when the shoe is taken off, the heel part of the shoe is difficult to move out of the opening.

In view of this, a second embodiment of the present utility model proposes a shoe cover, which is a further improvement of the first embodiment, the main improvement being that, as shown in combination with fig. 1 and 2, the shoe cover is provided with an opening 1, the opening 1 having elasticity to open and receive the shoe;

the opening 1 has a first side 11 close to the vamp of the incorporated shoe and, opposite thereto, a second side 12 close to the heel of the incorporated shoe;

in the present utility model, the first angle α formed by the connection line between the first side 11 and the second side 12 and the bottom surface of the shoe cover ranges from 10 ° to 45 °.

For the shoe cover of the present utility model, it may generally have a certain elasticity, that is, the shoe cover itself tends to take on a relatively fixed initial shape, which we call natural, before being incorporated into the shoe. In this natural state, the opening 1 is usually small and flat. For convenience of description and definition, various shape and size parameters of the shoe cover are based on the shoe cover in a natural state, and not based on the state after deformation.

In view of the requirement of easy storage in natural state, the shoe cover can be constructed as in the prior art of 942390946. Namely, the shoe cover body is in a form that two overlapped side surfaces are connected. At this time, the bottom surface of the shoe cover is approximately a horizontal straight line. Of course, the shoe cover structure can also have a relatively flat bottom surface. In addition, the bottom surface of the shoe cover of the utility model can also refer to the bottom surface of the shoe cover after standing up, namely the ground.

With this premise, as illustrated in fig. 1 and 2, the first angle α formed by the line connecting the first side 11 and the second side 12 and the bottom surface of the shoe cover is limited to a range of 10 ° to 45 °. It will be appreciated that the angle between the line connecting the first side 11 and the second side 12 and the vertical plane is correspondingly between 100 ° and 135 °.

The first included angle α determines the degree of wrapping of the heel of the cover of the second side 12 about the heel area of the shoe after the shoe is received, while simultaneously exhibiting ease of donning and doffing of the cover.

When people walk on a muddy and wet road, the heel of the shoe is easy to be polluted by splashed liquid or solid-liquid mixture. Obviously, the smaller the value of the first included angle alpha is, the more difficult the wearing and taking off are, but the better the degree of wrapping the heel part of the shoe cover on the heel part of the shoe is. When the wrapping degree is better, the shoe can be prevented from being polluted, and the shoe cover is more convenient to slip. However, the better the wrapping, the more difficult it is to put on and take off in reverse, and the poorer the comfort of the shoe cover.

The inventor of the present utility model found that when the range of the first included angle α is limited to between 10 ° and 45 °, both the difficulty of putting on and taking off and the protective ability of the shoe cover can be considered, so that the shoe cover can also adequately keep up with the foot and better protect from dirt and rainwater on the premise of relatively easy putting on and taking off. In addition, compared with the condition that the heel part of the shoe is completely wrapped, when the range of the first included angle alpha is limited to between 10 degrees and 45 degrees, the material consumption of the shoe cover can be reduced, and the production cost of the shoe cover is reduced.

Further, the first angle may be in the range of 10 ° to 20 °, especially 15 °, to achieve the best effect.

In addition, as shown in fig. 6, an anti-slip texture 7 may be provided on the inner surface of the shoe cover corresponding to the heel of the shoe into which it is incorporated. The anti-slip texture 7 can increase the friction force of the part to the heel, and further prevent the heel from sliding out of the shoe cover.

As described in the background section above. Generally, the shoe cover is easy to put on and take off, which means that the shoe cover needs to be made of a soft and elastic material, but the material is easy to break, and the wear resistance is difficult to meet the requirement.

The present inventors have found that latex materials have excellent deformability, and thus the prior art often employed latex materials as the base material for shoe cover products. However, latex materials are generally not abrasion resistant, and therefore it is necessary to add an abrasion resistant but poorly deformable rubber material at critical locations to improve abrasion resistance.

For example, in the chinese utility model patent No. 942390946, there is provided a shoe cover for rain protection, the body is made of latex, and the sole is attached with anti-slip wear-resistant rubber. The high variability of the latex and the excellent wear resistance of the rubber material are used for realizing the combination of easy putting on and taking off and wear resistance of the shoe cover.

However, when two materials are used simultaneously, the two materials are involved in the manufacturing process, and the process of joining the two materials is obviously much more complex and costly than using only a single material. Since the latex material has a problem of not being cut-resistant in addition to not being abrasion-resistant. In the process of forcibly expanding the opening 1 to receive the shoe, it is easily scratched by the nail to cause breakage of the shoe cover. There have therefore been attempts in the prior art to make shoe covers from rubber materials alone. Reference is made to the chinese utility model patent No. 2006201637978, which discloses a waterproof, durable rubber shoe cover, wherein the shoe cover is made of rubber material.

However, the shoe cover thus manufactured is difficult to put on and take off because of the poor variability of the rubber material. In this patent, therefore, the leg and foot connections of the shoe cover are also provided with zippers. However, the zipper structure obviously greatly increases the cost and complexity of the shoe cover, and the gaps of the zipper are easy to be filled with water.

In contrast, the shoe cover of the embodiments of the present utility model may alternatively be integrally formed from a rubber material. This is because, in the shoe cover according to the embodiment of the present utility model, the range of the first included angle α is limited to 10 ° to 45 °, particularly 10 ° to 20 °, and even if a rubber material having poor deformability is used, the shoe cover can be put on and taken off very conveniently. Therefore, the shoe cover product can simultaneously take on and off convenience, dirt protection capability, wear resistance and usability, and has the advantages of lower production cost.

In addition to the first angle α, the inventors of the present utility model have found that the object of easy putting on and taking off can be also achieved by controlling the distance between both sides of the opening 1 and the sole. Alternatively, as shown in fig. 1, the first side 11 is a first distance d1 from the bottom surface of the cover and the second side 12 is a second distance d2 from the bottom surface of the cover. This can also be achieved when the ratio of the first distance d1 to the second distance d2 is between 1:0.5 and 1:0.75. Further, the ratio of the first distance d1 to the second distance d2 is 1:0.6, so that the disposable diaper has better wearing and taking-off convenience and dirt protection capability.

Embodiment III

A third embodiment of the present utility model proposes a shoe cover, which is a further improvement of the first or second embodiment, and the main improvement is that, referring to fig. 3, a portion of the shoe cover corresponding to the sole includes a thickened portion 2 and an un-thickened portion 3, and a thickness ratio of the thickened portion 2 to the un-thickened portion 3 is 1.7:1 to 2.0:1.

The thickened part 2 can be thickened on the outer surface of the shoe cover or on the inner surface. For shoe covers made of flexible materials, if the thickness is too thick, the putting on and taking off difficulty will rise. If the thickness is too small, breakage is likely to occur. Thus, in order to balance thickness and durability, in embodiments of the utility model, the overall thickness of the cover may alternatively be in the range of 0.5 to 1mm, with around 0.8mm being particularly preferred. At this time, the thickness of the thickened portion 2 may be in the range of 1.2 to 1.8mm according to the above thickness ratio.

This thickness range is suitable for the thickness of most parts of the shoe cover, but since the sole part is the main part which is subject to friction, if the part can be thickened alone, the durability can be increased and the cost can be reduced without affecting the wearing and taking-off easiness. In particular, the preferred ratio of the thickness of the thickened portion 2 to the non-thickened portion 3 is within 1.8 to 1.9. The thickness of the thickened portion 2 may be about 1.5 mm. In addition, it is worth mentioning that the thicker the thickness is, the poorer the deformability is, so the local thickening can effectively prevent the shoe cover from slipping due to deformation, and the safety is improved.

Further, alternatively, the thickened portion 2 includes a half sole portion 21 corresponding to a half sole provided at a portion of the shoe cover corresponding to the sole, and a heel portion 22 corresponding to a heel portion, the half sole portion 21 and the heel portion 22 being separated by an non-thickened portion 3. Because the parts mainly stressed by the sole are arranged on the half sole part 21 and the heel part 22 when a person walks and exercises, the thickening of the two parts can effectively increase the durability and the local friction force, so that the ground grabbing performance of the shoe cover is better. However, when the thickened areas of the forefoot portion 21 and the heel portion 22 are joined, the entire sole is completely less likely to deform. With this premise, putting on and taking off the shoe cover becomes difficult. Therefore, the half sole portion 21 and the heel portion 22 are separated by the non-thickened portion 3, and durability and convenience of putting on and taking off can be simultaneously achieved.

Further, the half sole portion 21 may further include a left half sole portion and a right half sole portion (not shown) separated from each other, and the left half sole portion and the right half sole portion may be separated by the non-thickened portion 3. The left half sole part and the right half sole part can be arranged in bilateral symmetry. The left half sole part and the right half sole part are separated, so that the wearing and the taking-off can be further facilitated. Obviously, the heel portion 22 can equally be divided into left and right parts by the non-thickened portion 3.

It is worth mentioning that the area of the thickened portion 2 occupying the portion of the shoe cover corresponding to the sole may be in the range of 25% to 40%. It is easy to understand that the larger the area occupied by the thickened portion 2, the more difficult it is to put on and take off, and the higher the production cost. The novel anti-slip shoe has lower cost, more convenient putting on and taking off performance and better anti-slip effect in the proportion range.

The present embodiment improves the convenience of putting on and taking off the shoe cover product by locally thickening, and can achieve the effect of promoting each other on the premise of adopting the technical features of the first included angle α, the ratio of the first distance d1 to the second distance d2, and the like mentioned in the first embodiment together, which is a more preferable scheme.

Fourth embodiment

A fourth embodiment of the present utility model also provides a shoe cover. The fourth embodiment is a further improvement of the first, second or third embodiment. The main improvement is that in the fourth embodiment of the utility model, as shown in fig. 4, the part of the shoe cover near the second side 12 is extended with the hanging rope 4 towards the direction away from the first side 11, and the hanging rope 4 is wound around the part of the shoe cover near the second side 12 to form the hanging hole 5.

One common scenario for shoe cover products is mountain climbing. Large mountain climbing may take days to complete. When the user ends the mountain climbing on the first day or takes a rest, the shoe cover can be taken off. At this time, the shoe cover is dirty. Under traditional circumstances, people often place shoe covers in plastic bags that are prepared in advance and store them in bags. This is obviously not environmentally friendly, cumbersome and psychologically uncomfortable for the user.

Accordingly, in the present utility model, by providing the hanging hole 5 at this position on the shoe cover, the user can conveniently hang the shoe cover on the mountain-climbing bag. And after the hotel is cleaned, the shoe cover is hung and aired conveniently.

Further alternatively, as shown in fig. 5, the suspension cord 4 comprises at least two branches, one of which is wound back around the portion of the cover near the second side 12, forming one suspension hole 5, the other of which protrudes away from the portion of the cover corresponding to the sole and forms another suspension hole 5 at its distal end.

The two hanging holes 5 are arranged, one is close to the second side 12, and the other is far away from the second side 12 and extends out, so that the two hanging holes can adapt to the requirements of different hooks, and convenience is improved in detail. In addition, the hanging hole 5 may have a trilateral shape as shown in the figure, and the hook may have a guide function to prevent the shoe cover from shaking.

In addition, as mentioned above, in the shoe cover product according to the embodiment of the present utility model, when a single material and an integral molding process are adopted, the production cost can be greatly reduced. And when all the rubber materials are adopted, the wear resistance of the product can be improved. However, shoe covers formed from a single material are often not suitable for maintenance in the event of breakage. The hanging hole 5 is often pulled, which easily causes the hanging rope 4 to break. Therefore, the plurality of hanging holes 5 connected in series can also be used as spare parts, and the service life of the shoe cover is prolonged.

With additional reference to fig. 4 and 5, an optional shoelace-like portion 6 may be provided on the shoe cover at a location corresponding to the vamp. This shoelace-like portion 6 is not a true shoelace, but is a thickened structure of the shoelace shape. The shoe cover is thickened locally at the position and made into the shoelace shape, so that the shoe cover is attractive, the fracture caused by repeatedly stretching the vamp position can be prevented, and the position is more close to the vamp, so that the shoe cover is more heel.

It will be evident to those skilled in the art that the utility model is not limited to the details of the foregoing illustrative embodiments, and that the present utility model may be embodied in other specific forms without departing from the spirit or essential characteristics thereof. The present embodiments are, therefore, to be considered in all respects as illustrative and not restrictive, the scope of the utility model being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Claims (10)

1. A shoe cover, characterized in that an opening is arranged on the shoe cover, and the opening has elasticity to open and contain the shoe;

the shoe cover is provided with anti-slip lines at the positions corresponding to the soles of the shoes, wherein the anti-slip lines comprise a plurality of first anti-slip ways which are arranged side by side and extend towards the length direction of the shoe cover;

the first cleat includes: a plurality of first anti-skid units arranged at intervals along the length direction of the first anti-skid way; the first anti-slip unit is shaped to have a first direction in which friction is relatively greatest;

in each first anti-skid way, the directions of the first anti-skid units in at least two first anti-skid ways are opposite to each other.

2. A cover according to claim 1, wherein the first cleat of each first cleat is oriented in opposite directions to each other for each adjacent two of the first cleat's first cleat units.

3. A cover according to claim 1, wherein the number of first anti-slip tracks is greater than or equal to six.

4. A shoe cover according to claim 1, wherein in each first cleat the number of first cleat elements in a first direction towards the shoe cover in a direction corresponding to the heel is greater than the number of first cleat elements in a first direction towards the shoe cover in a direction corresponding to the toe.

5. A cover according to claim 4, wherein the number of first cleats is an even number, and wherein each of the first cleats has a shorter length than a first cleats that is relatively farther from the sole midline of the cover;

wherein, the first direction of the first anti-slip unit of the first anti-slip way which is farthest from the sole central line of the shoe cover faces the direction of the shoe cover corresponding to the heel.

6. The shoe cover of claim 1, wherein the anti-slip pattern further comprises two second anti-slip tracks disposed on each side of the first anti-slip track;

the second cleat includes: a plurality of second anti-skid units arranged at intervals along the length direction of the second anti-skid way; the second anti-skid unit is in a strip shape, and the long side direction of the second anti-skid unit is perpendicular to the length direction of the second anti-skid rail.

7. A shoe cover according to claim 6, wherein the length of the second anti-slip unit of the second anti-slip track sequentially changes from a direction approaching the shoe cover corresponding to the toe to a direction approaching the shoe cover corresponding to the heel:

the method comprises the steps of gradually increasing, gradually decreasing, gradually increasing, gradually decreasing and gradually increasing.

8. A cover according to any one of claims 1 to 7, wherein the first cleat comprises two cleats connected at a predetermined included angle to each other, the predetermined included angle being greater than 90 degrees and less than 170 degrees, the first direction being opposite to the direction in which the tip of the included angle is oriented.

9. A cover according to claim 8, wherein the predetermined included angle is between 100 degrees and 130 degrees.

10. A shoe cover according to claim 9, wherein the length of the cleats adjacent the midline of the sole of the shoe cover is shorter than the length of the cleats remote from the midline of the sole of the shoe cover, of the two cleats attached to each other.