CN209950418U - Antibacterial flexible health-care down jacket easy to fold - Google Patents

Abstract

The utility model discloses an antibacterial flexible easy-folding health-care down jacket, which comprises a jacket body, wherein the jacket body comprises an antibacterial outer layer, an inner container layer, a supporting layer, an adhesive layer and an antibacterial inner layer, and a heating module is arranged in an interlayer between the supporting layer and the adhesive layer; the heating module comprises an outer protective layer, an insulating layer, an electrode layer, a conductive heating layer and an inner protective layer which are sequentially arranged from outside to inside, the conductive heating layer is a graphene silver nanowire conductive heating film, and the electrode layer is in contact connection with the graphene silver nanowire conductive heating film; the electrode layer is connected to a temperature control switch through a wire, and the graphene silver nanowire conductive heating film is powered to heat through an external power supply of the temperature control switch. The utility model has the advantages of antibiosis, flexibility, easy folding and even heating.

Description

Antibacterial flexible health-care down jacket easy to fold

Technical Field

The utility model relates to an antibiotic flexible health care down coat of easily folding.

Background

In cold environments in winter, people need a warm garment. At present, the traditional warm-keeping clothes in the market are generally made of thick cotton and velvet materials. Because the thickness of the warm-keeping clothes cannot be reduced while keeping warm due to the problem of the material of the warm-keeping clothes.

Cotton-padded clothes have good warm-keeping property, and are particularly popular with people in northern cold environments, but the heavy cotton-padded clothes always make the sports and the body stretching of people too clumsy and inconvenient.

The down coat is one of modern clothes, and the down coat is filled with animal down such as wool, goose feather, duck feather and the like, so that the down coat still has good warm-keeping property while keeping good air permeability, and meanwhile, the overall weight of the down coat is reduced, and the down coat is lighter and more portable.

Although the down jacket improves the disadvantages of the linen-cotton clothes to a certain extent, there are some problems in turn. Various down feather is filled in the down jacket, heat preservation is carried out by utilizing the characteristic that the heat preservation performance of the down feather and the heat transfer performance of air are poor, although the weight of clothes is light and the density is small, the size of the clothes is large, a relatively overstaffed state is presented after the clothes are worn, and the down feather is only passively subjected to heat preservation and cannot actively generate heat.

SUMMERY OF THE UTILITY MODEL

The utility model aims to overcome the defects of the prior art and provide an antibacterial flexible health-care down jacket easy to fold.

The utility model discloses a realize through following technical scheme:

an antibacterial flexible health-care down jacket easy to fold comprises a jacket body, wherein the jacket body comprises an antibacterial outer layer, an inner container layer, a supporting layer, an adhesive layer and an antibacterial inner layer which are sequentially arranged from outside to inside;

the heating module comprises an outer protective layer, an insulating layer, an electrode layer, a conductive heating layer and an inner protective layer which are sequentially arranged from outside to inside, wherein the conductive heating layer is a graphene silver nanowire conductive heating film, and the electrode layer is in contact connection with the graphene silver nanowire conductive heating film;

the electrode layer is connected to a temperature control switch through a wire, and is externally connected with a power supply through a USB joint of the temperature control switch so as to supply power to the graphene silver nanowire conductive heating film to heat the graphene silver nanowire conductive heating film.

Furthermore, the electrode layer comprises a positive electrode and a negative electrode, each electrode comprises a current collecting bar and a plurality of inner electrode bars perpendicular to the current collecting bar, the inner electrode bars are arranged on the inner side of the current collecting bar at equal intervals, and the inner electrode bars of the positive electrode and the negative electrode are arranged in a crossed manner at equal intervals to form an interdigital electrode structure; the graphene silver nanowire conductive heating film is in contact with the plurality of inner electrode strips, and the current collecting strips of the positive electrode and the negative electrode are positioned on the left side and the right side of the graphene silver nanowire conductive heating film and are spaced from the graphene silver nanowire conductive heating film.

Furthermore, the antibacterial outer layer and the antibacterial inner layer are both made of graphene and micron silver wire composite antibacterial non-woven fabrics.

Furthermore, the supporting layer adopts elastic lining cloth, and the bonding layer adopts elastic lining cloth with colloid attached to the surface.

Furthermore, the inner container layer is composed of a silk screen outer layer, a silk screen inner layer and a down layer wrapped between the silk screen outer layer and the silk screen inner layer.

Further, the electrode layer is made of one of metal foil, conductive cloth and conductive adhesive tape.

Furthermore, the clothes body comprises a front part, a rear part and sleeves, two heating modules are arranged in the front part, and three heating modules are arranged in the rear part.

Further, the outer protection layer and the inner protection layer are hot melt adhesive layer waterproof layers, and the insulation layer is a PI film insulation layer.

Compared with the prior art, the utility model has the following advantages:

1. the utility model provides an antibacterial flexible easy-folding health-care down jacket, which is provided with antibacterial layers inside and outside the jacket body respectively, and has good ventilation and sterilization functions; the heating module is arranged in the interlayer of the clothes body, so that active heating can be realized, and the heat-insulating property is better; due to the existence of the heating module, the inner single layer can be arranged to be thinner, so that the down jacket is lighter and smaller in size.

2. The utility model provides a pair of antibiotic flexible health care down coat of easily folding, its module that generates heat adopts the material that generates heat of this kind of film face of the electrically conductive heating film of graphite alkene silver-colored nano wire, and the temperature that generates heat is even, the programming rate piece.

3. The utility model provides a pair of antibiotic flexible health care down coat of easily folding, each layer in its module that generates heat adopts the material of flexible nothing foreign body sense, has good bendability, and the volume occupation space of easily folding is little.

4. The utility model provides a pair of antibiotic flexible health care down coat of easily folding adopts the low voltage power supply to start, if remove the precious 5V output that charges, is far less than human safe voltage 36V, does not have the potential safety hazard.

Drawings

Fig. 1 is a front view of the present invention.

Fig. 2 is a rear view of the present invention.

Fig. 3 is a cross-sectional view of the present invention at the heat generating module.

Fig. 4 is a cross-sectional view of the heating module of the present invention.

Fig. 5 is a schematic structural diagram of the electrode layer and the conductive heating layer of the present invention.

Reference numbers in the figures: the clothes comprise a clothes body, an antibacterial outer layer 11, a wire mesh outer layer 12, a down layer 13, a wire mesh inner layer 14, a supporting layer 15, an adhesive layer 16, an antibacterial inner layer 17, a front opening 18, a rear opening 19, sleeves 110, a heating module 2, an outer protective layer 21, an insulating layer 22, an electrode layer 23, a current collecting bar 231, an inner electrode bar 232, a conductive heating film of a graphene silver nanowire 24, an inner protective layer 25, a lead 26 and a temperature control switch 27.

Detailed Description

The embodiments of the present invention will be described in detail below, and the present embodiment is implemented on the premise of the technical solution of the present invention, and a detailed implementation manner and a specific operation process are given, but the scope of the present invention is not limited to the following embodiments.

Referring to fig. 1 to 5, the embodiment discloses an antibacterial flexible health-care down jacket easy to fold, which comprises a jacket body 1, wherein the jacket body 1 comprises an antibacterial outer layer 11, an inner container layer, a supporting layer 15, an adhesive layer 16 and an antibacterial inner layer 17 which are sequentially arranged from outside to inside, a heating module 2 is arranged in an interlayer between the supporting layer 15 and the adhesive layer 16, and the heating module 2 and the supporting layer 15 are attached together through the adhesive layer 16; the antibacterial outer layer 11, the inner container layer, the supporting layer 15, the adhesive layer 16 and the antibacterial inner layer 17 are sewn together through a sewing process.

The heating module 2 comprises an outer protective layer 21, an insulating layer 22, an electrode layer 23, a conductive heating layer and an inner protective layer 25 which are sequentially arranged from outside to inside, the conductive heating layer is a graphene silver nanowire conductive heating film 24, and the electrode layer 23 is in contact connection with the graphene silver nanowire conductive heating film 24; the electrode layer 23 and the graphene silver nanowire conductive heating film 24 can be connected through a high-temperature hot stamping process.

The electrode layer 23 is connected to a temperature control switch 27 through a wire 26, and is externally connected with a power supply through a USB connector of the temperature control switch 27 so as to supply power to the graphene silver nanowire conductive heating film 24 to heat the graphene silver nanowire conductive heating film. Wherein, temperature detect switch 27 accessible external wire external mobile power source. The output power of different gears can be adjusted through the temperature control switch 27, and the temperature can be regulated and controlled in a grading manner. The temperature control switch 27 can be a square integrated switch produced by Shenzhen four-dimensional health technology Limited.

Specifically, the inner container layer is composed of a silk screen outer layer 12, a silk screen inner layer 14 and a down layer 13 which is wrapped between the silk screen outer layer 12 and the silk screen inner layer 14. The clothes body 1 comprises a front part 18, a back part 19 and sleeves 110, two heating modules 2 are arranged in the front part 18, and three heating modules 3 are arranged in the back part 19.

Specifically, the electrode layer 23 includes a positive electrode and a negative electrode, each electrode includes a current collector bar 231 and a plurality of inner electrode bars 232 perpendicular to the current collector bar 231, the plurality of inner electrode bars 232 are disposed inside the current collector bar 231 and arranged at equal intervals, and the plurality of inner electrode bars 232 of the positive electrode and the negative electrode are arranged at equal intervals in a crossing manner to form an interdigital electrode structure; the collector bars 231 of the two electrodes are respectively connected with the positive electrode and the negative electrode of the power supply, so that the adjacent inner electrode bars 232 have opposite polarities; the graphene silver nanowire conductive heating film 24 is in contact with the plurality of inner electrode strips 232, and the current collecting strips 231 of the positive and negative electrodes are positioned on the left and right sides of the graphene silver nanowire conductive heating film 24 and have gaps with the graphene silver nanowire conductive heating film 24. In this embodiment, the current collecting bars 231 of the positive and negative electrodes are located at the left and right sides of the conductive heating film 24 of the graphene silver nanowire and do not contact with the conductive heating film 24 of the graphene silver nanowire, so that when the conductive heating film 24 of the graphene silver nanowire is simultaneously connected with the inner electrode bars 232 and the current collecting bars 231, local hot spots can be generated due to too small distance between the connection positions, thereby affecting the heating performance, so that the conductive heating film 24 of the graphene silver nanowire is only attached to each inner electrode bar 232 and is not connected with the current collecting bars 231, thereby ensuring the heating uniformity of the conductive heating film 24 of the graphene silver nanowire.

Specifically, the antibacterial outer layer 11 and the antibacterial inner layer 17 are both made of graphene and micron silver wire composite antibacterial non-woven fabrics. The graphene micron silver wire composite antibacterial non-woven fabric is prepared by adopting a preparation method disclosed in the patent application publication with the publication number of CN 107326534A. The supporting layer 15 is made of elastic lining cloth, and the adhesive layer 16 is made of elastic lining cloth with colloid attached to the surface. The material of the electrode layer 23 is one of metal foil, conductive cloth, and conductive tape. The outer protective layer 21 and the inner protective layer 25 are waterproof layers of hot melt adhesive layers, and the insulating layer 22 is a PI film insulating layer.

The graphene silver nanowire conductive heating film 24 used in the embodiment is commercially available from co-fertilizer microcrystalline material science and technology limited company, and is prepared by forming a film from conductive heating slurry by a casting method. The conductive heating slurry comprises the following raw materials in parts by mass: 1-20 parts of 1-10 mg/mL silver nanowire dispersion, 20-50 parts of graphene powder, 1-20 parts of carbon black, 20-50 parts of waterborne polyurethane resin with the solid content of 30-55%, 1-50 parts of waterborne epoxy resin with the solid content of 30-80%, 1-20 parts of waterborne acrylic resin with the solid content of 30-80%, 1-30 parts of water, 0.1-5 parts of dispersing agent and 0.1-2 parts of curing agent hexamethylene diamine.

The down coat that this embodiment provided has the protection of double-deck antibiotic layer, has good ventilative, disinfect and travelling comfort, can realize initiatively generating heat simultaneously, and thermal insulation performance is good. The outer protective layer 21 and the inner protective layer 25 in the heating module are hot melt adhesive layer waterproof layers, the insulating layer 22 is a PI film insulating layer, the hot melt adhesive layer waterproof layers and the PI film insulating layer are both flexible materials without foreign body sensation, and the heating module has good bending property and is easy to fold and small in occupied space.

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 (8)

1. The utility model provides an antibiotic flexible health care down coat of easily folding, includes clothes body (1), its characterized in that: the clothes body (1) comprises an antibacterial outer layer (11), an inner container layer, a supporting layer (15), an adhesive layer (16) and an antibacterial inner layer (17) which are sequentially arranged from outside to inside, a heating module (2) is arranged in an interlayer between the supporting layer (15) and the adhesive layer (16), and the heating module (2) and the supporting layer (15) are attached together through the adhesive layer (16);

the heating module (2) comprises an outer protective layer (21), an insulating layer (22), an electrode layer (23), a conductive heating layer and an inner protective layer (25) which are sequentially arranged from outside to inside, the conductive heating layer is a graphene silver nanowire conductive heating film (24), and the electrode layer (23) is in contact connection with the graphene silver nanowire conductive heating film (24);

the electrode layer (23) is connected to a temperature control switch (27) through a lead (26), and an external power supply is connected to the electrode layer through a USB connector of the temperature control switch (27), so that the graphene silver nanowire conductive heating film (24) is powered on to heat.

2. The antibacterial flexible easy-folding health-care down jacket as claimed in claim 1, wherein: the electrode layer (23) comprises a positive electrode and a negative electrode, each electrode comprises a current collecting bar (231) and a plurality of inner electrode bars (232) perpendicular to the current collecting bar (231), the inner electrode bars (232) are arranged on the inner side of the current collecting bar (231) at equal intervals, and the inner electrode bars (232) of the positive electrode and the negative electrode are arranged in a crossed manner at equal intervals to form an interdigital electrode structure; the graphene silver nanowire conductive heating film (24) is in contact with a plurality of inner electrode strips (232), and the current collecting strips (231) of the positive electrode and the negative electrode are positioned on the left side and the right side of the graphene silver nanowire conductive heating film (24) and a gap is reserved between the current collecting strips and the graphene silver nanowire conductive heating film (24).

3. The antibacterial flexible easy-folding health-care down jacket as claimed in claim 1, wherein: the antibacterial outer layer (11) and the antibacterial inner layer (17) are both made of graphene micron silver wire composite antibacterial non-woven fabrics.

4. The antibacterial flexible easy-folding health-care down jacket as claimed in claim 1, wherein: the supporting layer (15) adopts elastic lining cloth, and the bonding layer (16) adopts elastic lining cloth with colloid attached to the surface.

5. The antibacterial flexible easy-folding health-care down jacket as claimed in claim 1, wherein: the inner container layer is composed of a silk screen outer layer (12), a silk screen inner layer (14) and a down layer (13) wrapped between the silk screen outer layer (12) and the silk screen inner layer (14).

6. The antibacterial flexible easy-folding health-care down jacket as claimed in claim 1, wherein: the electrode layer (23) is made of one of metal foil, conductive cloth and conductive adhesive tape.

7. The antibacterial flexible easy-folding health-care down jacket as claimed in claim 1, wherein: the garment body (1) comprises a front part (18), a rear part (19) and sleeves (110), two heating modules (2) are arranged in the front part (18), and three heating modules (2) are arranged in the rear part (19).

8. The antibacterial flexible easy-folding health-care down jacket as claimed in claim 1, wherein: the outer protection layer (21) and the inner protection layer (25) are waterproof layers of hot melt adhesive layers, and the insulation layer (22) is a PI film insulation layer.

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