CN210114092U - Anti-static shoes - Google Patents

Abstract

The utility model relates to the technical field of antistatic equipment, and provides an antistatic shoe, which comprises a vamp and a sole, wherein the vamp and the sole are connected and enclosed to form an accommodating cavity for accommodating the foot of a user, the inner surface of the vamp is provided with a first non-metal conducting layer which is used for wrapping the foot and is electrically connected with the foot, and the sole is internally provided with a non-metal conducting component which is used for being electrically connected with the ground; the first nonmetal conducting layer comprises a first conducting part used for abutting against the instep of the foot and a second conducting part extending from the first conducting part to the side edge of the vamp, and the second conducting part is fixed on the sole and is electrically connected with the nonmetal conducting component; the utility model provides an antistatic shoes can not be examined out by metal safety inspection device, has improved antistatic shoes's the convenience of going out.

Description

Anti-static shoes

Technical Field

The utility model relates to an antistatic equipment technical field, more specifically say, relate to an antistatic shoes.

Background

In production and life, there are many places with strict requirements on whether human bodies are charged or not, and among numerous anti-static devices, anti-static shoes are one of the most important and most convenient devices for removing human body static electricity. In the prior antistatic shoes, in order to ensure the electrical connection between the foot and the upper of the user, some conductors such as metal wires are usually laid on the upper to achieve the electrical connection with the foot, but the antistatic shoes equipped with metal wires have the following disadvantages:

when a user wears the shoes and enters a place with security check equipment, unnecessary troubles are easily caused, for example, when the user enters a subway with a security check door or gets on an airplane, a security check alarm can be triggered due to the fact that the inside of the shoes contains the metal wires, so that misunderstandings are caused, and the misunderstandings can be eliminated by taking off the shoes, so that inconvenience is caused to the user.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide an antistatic shoes to solve prior art's antistatic shoes and be detected by metal safety inspection device easily and cause the inconvenient technical problem of user.

In order to achieve the above object, the utility model adopts the following technical scheme: the antistatic shoe comprises a vamp and a sole, wherein the vamp and the sole are connected and enclosed to form an accommodating cavity for accommodating a foot of a user, a first nonmetal conducting layer used for being wrapped on the foot and electrically connected with the foot is arranged on the inner surface of the vamp, and a nonmetal conducting component used for being electrically connected with the ground is arranged in the sole;

the first non-metal conductive layer comprises a first conductive portion used for abutting against the instep of the foot and a second conductive portion extending from the first conductive portion to the side edge of the upper, and the second conductive portion is fixed on the sole and electrically connected with the non-metal conductive assembly.

Further, the first non-metal conducting layer is a graphite product or a graphene product.

Furthermore, the nonmetal conductive component is a nonmetal conductive block, the nonmetal conductive block is embedded in the sole, one end of the nonmetal conductive block is exposed out of the bottom surface of the sole, and the other end of the nonmetal conductive block is exposed out of the top surface of the sole and is electrically connected with the second conductive part.

Furthermore, the antistatic shoe further comprises an insole arranged in the accommodating cavity, two second nonmetal conducting layers and a third nonmetal conducting layer which are electrically connected with each other are arranged on opposite side surfaces of the insole, the second nonmetal conducting layers are electrically connected with the first nonmetal conducting layers, and the third nonmetal conducting layers are electrically connected with the nonmetal conducting blocks.

Furthermore, the second nonmetal conducting layer and the third nonmetal conducting layer are connected at the outer side edge of the insole, and a ring shape is formed between the second nonmetal conducting layer and the third nonmetal conducting layer.

Furthermore, the insole is provided with a plurality of through holes penetrating through the insole, and the second nonmetal conducting layer and the third nonmetal conducting layer are in mutual contact and are electrically connected through the through holes.

Further, the non-metal conductive block is a graphite block or a graphene block, and the second non-metal conductive layer and the third non-metal conductive layer are graphite products or graphene products.

Further, the non-metal conductive component is non-metal conductive particles, and the non-metal conductive particles are mixed in the inner part of the sole and are electrically connected with the first non-metal conductive layer.

Further, a non-metal conducting wire is arranged between the first non-metal conducting layer and the sole.

Furthermore, a non-metal conductive adhesive is arranged between the first non-metal conductive layer and the sole.

The utility model provides an antistatic shoes's beneficial effect lies in:

firstly, the vamp comprises a first non-metal conductive layer, the sole comprises a non-metal conductive component, the vamp and the sole have the function of leading out human body static electricity, the alarm of a metal security inspection device cannot be caused, and the convenience of a user who wears the anti-static shoe to go out is improved;

secondly, the first nonmetal conducting layer is arranged on the surface of the vamp body, and is used for wrapping the foot and electrically connected with the foot and the ground respectively, so that the first nonmetal conducting layer wrapped on the foot can always keep a stable electrical connection relation with the foot in the walking process of the foot, and the condition that a conducting path is disconnected between the foot and the first nonmetal conducting layer is avoided;

finally, the second conductive part extends from the side edge of the first conductive part to the opposite side edge of the vamp and is electrically connected with the sole, and electricity of the first conductive part can be smoothly guided to the sole and further to the ground.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings required for the embodiments or the prior art descriptions will be briefly introduced below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and it is obvious for those skilled in the art to obtain other drawings without inventive labor.

Fig. 1 is a schematic perspective view of an antistatic shoe according to an embodiment of the present invention;

FIG. 2 is a front view of an upper provided by an embodiment of the present invention;

FIG. 3 is a schematic representation of a layered structure of an upper provided by an embodiment of the present invention;

FIG. 4 is a front view of an insole provided by an embodiment of the present invention;

fig. 5 is a rear view of the insole provided by the embodiment of the present invention.

Wherein, in the figures, the respective reference numerals:

shoe upper	1	A first conductive part	111	Third non-metallic conductive layer	32
						Sole of shoe	2	Second conductive part	112	Through hole	33
First non-metallic conductive layer	11	Shoe-pad	3
						Non-metallic conductive component	21	Second non-metallic conductive layer	31

Detailed Description

In order to make the technical problem, technical solution and advantageous effects to be solved by the present invention more clearly understood, the following description is given in conjunction with the accompanying drawings and embodiments to illustrate the present invention in further detail. It should be understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention.

It will be understood that when an element is referred to as being "secured to" or "disposed on" another element, it can be directly on the other element or be indirectly on the other element. When an element is referred to as being "connected to" another element, it can be directly connected to the other element or be indirectly connected to the other element.

It will be understood that the terms "length," "width," "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," and the like are used in an orientation or positional relationship indicated in the drawings for convenience in describing the invention and to simplify the description, and are not intended to indicate or imply that the device or element so referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus should not be construed as limiting the invention.

Furthermore, the terms "first", "second" and "first" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include one or more of that feature. In the description of the present invention, "a plurality" means two or more unless specifically limited otherwise.

Fig. 1 to 5 show the antistatic shoe provided in the present embodiment.

Referring to fig. 1 to 3 together, the anti-static shoe according to the embodiment of the present invention will be described. The embodiment provides an anti-static shoe, which is used for electrically connecting a human body and the ground so as to conduct static electricity of the human body to the ground, thereby eliminating the influence of the static electricity on the operation of various electrical appliances.

The antistatic shoe comprises a vamp 1 and a sole 2, wherein the vamp 1 and the sole 2 are connected and enclosed to form an accommodating cavity for accommodating the foot of a user, a first nonmetal conducting layer 11 is arranged on the inner surface of the vamp 1 and used for wrapping the foot and electrically connected with the foot, and a nonmetal conducting component 21 for electrically connecting with the ground is arranged in the sole 2;

the first non-metal conductive layer 11 includes a first conductive portion 111 for abutting against the instep of the foot, and a second conductive portion 112 extending from an outer side edge of the first conductive portion 111 to a corresponding outer side edge of the upper 1, a distal end of the second conductive portion 112 is flush with the corresponding outer side edge of the upper 1, the second conductive portion 112 has an inverted "U" shape, and the second conductive portion 112 is fixed to the sole 2 and electrically connected to the non-metal conductive member 21.

The embodiment of the utility model provides an antistatic shoes's beneficial effect lies in:

firstly, the vamp 1 comprises a first non-metal conductive layer 11, the sole 2 comprises a non-metal conductive component 21, the non-metal conductive component and the vamp have the function of leading out human body static electricity, the alarm of a metal security inspection device cannot be caused, and the convenience of a user wearing the anti-static shoe for going out is improved;

secondly, the first nonmetal conducting layer 11 is arranged on the inner surface of the vamp 1, and the first nonmetal conducting layer 11 is used for wrapping the foot and is respectively electrically connected with the foot and the ground, so that the first nonmetal conducting layer 11 wrapped on the foot can always keep a stable electrical connection relation with the foot in the walking process of the foot, and the condition that a conducting path is disconnected between the foot and the first nonmetal conducting layer 11 is avoided;

finally, the second conductive portion 112 extends from the side of the first conductive portion 111 to the opposite side of the upper 1 and the sole 2 is electrically connected to the sole 2, so that electricity from the first conductive portion 111 can be smoothly guided to the sole 2 and thus to the ground.

Further, as a specific implementation manner of the antistatic shoe provided by the present invention, the first non-metal conductive layer 11 is a graphite product or a graphene product. Graphite and graphene are all non-metals, a metal security inspection device cannot detect the non-metals, the graphite is easy to obtain, low in cost and conductive, and has good chemical stability at normal temperature and resistance to acid, alkali and organic solvent corrosion, so that the antistatic shoe used for industrial purposes can be used in various severe environments. The conjugated structure of the graphene enables the graphene to have high electron mobility and excellent electrical properties, and belongs to a superconductor. The traditional conductive coating achieves the purpose of film coating conductivity by adding a conductive substance as an additive, the conductive additive is usually metal or metal oxide particles (such as silver powder, copper powder, zinc oxide and the like), and taking silver powder which is widely applied as an example, the using amount, the particle size and the form of the silver powder have great influence on the conductivity of the coating. Compared with the traditional metal particles, the graphene has excellent mechanical properties and thermal properties besides good conductive performance, and is an excellent conductive coating additive.

Further, as the utility model provides an antistatic shoe's a specific embodiment, non-metallic conductive component 21 is non-metallic conductive block, and non-metallic conductive block inlays and locates sole 2, and non-metallic conductive block's one end exposes in the bottom surface of sole 2, and its other end exposes in the top surface of sole 2 and electricity second conductive part 112.

Further, as the utility model provides a concrete implementation mode of antistatic shoes, antistatic shoes are still including setting up shoe-pad 3 in the holding chamber, and shoe-pad 3's opposite flank is provided with the nonmetal conducting layer 31 of second and the nonmetal conducting layer 32 of third that two mutual electricity are connected, and first nonmetal conducting layer 11 is connected to nonmetal conducting layer 31 electricity of second, and nonmetal conducting block is connected to nonmetal conducting layer 32 electricity of third. The specific electric connection mode is as follows: when the user is wearing antistatic shoes walking, first non-metal conducting layer 11 winds in user's foot, be connected with the instep electricity of foot, second non-metal conducting layer 31 is stepped on the sole of foot and contacts and reach electric connection with first non-metal conducting layer 11 by the user, and second non-metal conducting layer 31 is connected with third non-metal conducting layer 32 electricity, third non-metal conducting layer 32 contacts and reaches electric connection with the non-metal conducting block of sole 2 again, the static of user's foot is in proper order from first non-metal conducting layer 11, second non-metal conducting layer 31, third non-metal conducting layer 32 to non-metal conducting block, then the conduction is discharged to ground. The wearing comfort of the antistatic shoe can be improved by arranging the insole 3, and under the pressure generated during the walking of the foot of a user, the insole 3 is continuously contacted with the vamp 1 and the sole 2 at the same time, so that the effectiveness of electric connection is kept, and the danger caused by the disconnection of the electric connection is avoided.

Optionally, as a specific embodiment of the antistatic shoe provided by the present invention, the second non-metal conductive layer 31 and the third non-metal conductive layer 32 are connected at the outer side edge of the insole 3, and a ring shape is formed between the second non-metal conductive layer 31 and the third non-metal conductive layer 32. Even if one of the connection ends of the second nonmetal conductive layer 31 and the third nonmetal conductive layer 32, which are formed in a ring shape, is disconnected, the connection effectiveness of the other end can be maintained, and the effectiveness of the electrical connection is further ensured.

Optionally, as shown in fig. 4 and 5, as a specific embodiment of the anti-static shoe provided by the present invention, the insole 3 is provided with a plurality of through holes 33 penetrating through itself, and the second non-metal conductive layer 31 and the third non-metal conductive layer 32 are in contact with each other and electrically connected through the through holes 33. Second non-metallic, electrically conductive layer 31 and third non-metallic, electrically conductive layer 32 may be disposed on insole 3 in a variety of ways: the first and the second molten non-metal conducting layers 31 and the third molten non-metal conducting layers 32 are respectively coated on the opposite side surfaces of the insole 3, the second non-metal conducting layers 31 and the third non-metal conducting layers 32 respectively penetrate into the through holes 33, and after the two are solidified, the two reach the state of being communicated in the through holes 33 and are mutually and electrically connected; the second, second and third non-metal conductive layers 31 and 32 are attached to opposite sides of the insole 3 in the form of conductive cloth, respectively, and the second and third non-metal conductive layers 31 and 32 are sewn together by means of conductive wires passing through the through holes 33. In the two modes, the second nonmetal conductive layer 31 and the third nonmetal conductive layer 32 have a plurality of connection points, so that after some connection points are disconnected, enough connection points are provided to maintain the electric connection state of the second nonmetal conductive layer 31 and the third nonmetal conductive layer 32, and the electric connection effectiveness of the antistatic shoe is further ensured.

Further, as the utility model provides a specific embodiment of antistatic shoes, non-metallic conductive piece is graphite piece or graphite alkene piece, and non-metallic conductive layer 31 of second and non-metallic conductive layer 32 are graphite goods or graphite alkene goods.

Further, as the utility model provides an antistatic shoes's a specific embodiment, non-metallic conductive component is non-metallic conductive particle, and non-metallic conductive particle mixes in the inside of sole 2 and is connected with first non-metallic conductive layer 11 electricity.

Optionally, as a specific embodiment of the anti-static shoe provided by the present invention, a non-metal conductive wire (not shown) is disposed between the first non-metal conductive layer 11 and the sole 2. This non-metal conductive wire has electric conductive property to by non-metal material, non-metal conductive wire is used for sewing up between first non-metal conducting layer 11 and the sole 2, makes first non-metal conducting layer 11 be fixed in on the sole 2 and first non-metal conducting layer 11 reaches the electricity through non-metal conductive wire and sole 2 and is connected.

Further, as the utility model provides an antistatic shoes's a specific embodiment, non-metallic conductor wire has attached graphite or graphite alkene. The manufacturing method of the nonmetal conducting wire can be that the wire base material is soaked in a graphite or graphene solution, and the manufacturing of the nonmetal conducting wire is completed when the graphite or graphene is uniformly attached to the wire base material.

Optionally, as a specific embodiment of the anti-static shoe provided by the present invention, a non-metal conductive adhesive (not shown) is disposed between the first non-metal conductive layer 11 and the sole 2. Colloidal nonmetal conducting resin has electric conductivity, and it is used for connecting first nonmetal conducting layer 11 and sole 2, and when equipment vamp 1 and sole 2, nonmetal conducting resin is convenient for fixing between the two, promotes process velocity. Nonmetal conducting resin mixes there is graphite or graphite alkene, through doping graphite or graphite alkene in nonmetal conducting resin to reach nonmetal conducting resin and have the function of conduction static, guarantee simultaneously that the whole part that has conductive function of antistatic shoes can not be detected by metal safety inspection device.

The above description is only exemplary of the present invention and should not be construed as limiting the present invention, and any modifications, equivalents and improvements made within the spirit and principles of the present invention are intended to be included within the scope of the present invention.

Claims (10)

1. An antistatic shoe, comprising an upper and a sole, wherein the upper and the sole are connected and enclosed to form an accommodating cavity for accommodating the foot of a user, the antistatic shoe is characterized in that:

the inner surface of the vamp is provided with a first non-metal conducting layer which is used for wrapping the foot and is electrically connected with the foot, and a non-metal conducting component which is used for being electrically connected with the ground is arranged in the sole;

the first non-metal conductive layer comprises a first conductive portion used for abutting against the instep of the foot and a second conductive portion extending from the first conductive portion to the side edge of the upper, and the second conductive portion is fixed on the sole and electrically connected with the non-metal conductive assembly.

2. The antistatic shoe as claimed in claim 1, wherein: the first nonmetal conducting layer is a graphite product or a graphene product.

3. The antistatic shoe as claimed in claim 1, wherein: the nonmetal conductive component is a nonmetal conductive block, the nonmetal conductive block is embedded in the sole, one end of the nonmetal conductive block is exposed out of the bottom surface of the sole, and the other end of the nonmetal conductive block is exposed out of the top surface of the sole and is electrically connected with the second conductive part.

4. The antistatic shoe as claimed in claim 3, wherein: the anti-static shoe further comprises an insole arranged in the accommodating cavity, two second nonmetal conducting layers and a third nonmetal conducting layer which are electrically connected with each other are arranged on opposite side faces of the insole, the second nonmetal conducting layers are electrically connected with the first nonmetal conducting layers, and the third nonmetal conducting layers are electrically connected with the nonmetal conducting blocks.

5. The antistatic shoe as claimed in claim 4, wherein: the second nonmetal conducting layer and the third nonmetal conducting layer are connected at the outer side edge of the insole, and a ring shape is formed between the second nonmetal conducting layer and the third nonmetal conducting layer.

6. The antistatic shoe as claimed in claim 4, wherein: the insole is provided with a plurality of through holes penetrating through the insole, and the second nonmetal conducting layer and the third nonmetal conducting layer are in mutual contact and electric connection through the through holes.

7. The antistatic shoe as claimed in claim 5 or 6, wherein: the non-metal conductive block is a graphite block or a graphene block, and the second non-metal conductive layer and the third non-metal conductive layer are graphite products or graphene products.

8. The antistatic shoe as claimed in claim 1, wherein: the non-metal conductive component is non-metal conductive particles, and the non-metal conductive particles are mixed in the inner part of the sole and are electrically connected with the first non-metal conductive layer.

9. The antistatic shoe as claimed in claim 8, wherein: and a non-metal conductive wire is arranged between the first non-metal conductive layer and the sole.

10. The antistatic shoe as claimed in claim 8, wherein: and a non-metal conductive adhesive is arranged between the first non-metal conductive layer and the sole.

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