CN212949497U - Carbon nanotube sponge conducting strip structure - Google Patents

Abstract

The utility model discloses a carbon nanotube sponge conducting strip structure, including pipeline and conducting strip, the outside fixedly connected with conducting strip of pipeline, the outside of conducting strip is provided with fungi-proofing structure, fungi-proofing structure's outside is provided with anticorrosion structure, anticorrosion structure's outside is provided with antistatic structure. The utility model discloses a set gradually anticorrosive coating, epoxy, isolation layer and first bond line in anticorrosive structure's inside, carbon nanotube sponge conducting strip live time may be corroded by some other materials for a long time, and in order to prevent that some positions of carbon nanotube sponge conducting strip are corroded, the inside epoxy of anticorrosive coating can prevent that other materials from corroding the inside of carbon nanotube sponge conducting strip, epoxy's bottom is provided with the isolation layer, and the isolation layer can prevent epoxy and other part contact, the first bond line of bottom fixedly connected with of anticorrosive coating, first bond line can make anticorrosive coating and the inseparable laminating of antibacterial structure.

Description

Carbon nanotube sponge conducting strip structure

Technical Field

The utility model relates to a nanometer technical field specifically is a carbon nanotube sponge conducting strip structure.

Background

The nanotechnology is developed rapidly, and the applicable field is more and more extensive, so that the nanotechnology can be compounded with different materials to generate different functions, and the carbon nanotube sponge heat-conducting strip is also one of the nanotechnologies, but the carbon nanotube sponge heat-conducting strip has some problems.

In the process of implementing the present invention, the inventor finds that at least the following problems exist in the prior art and are not solved:

(1) the traditional carbon nanotube sponge heat conducting fin structure has no antibacterial effect, and bacteria are easily adhered to the carbon nanotube sponge heat conducting fin;

(2) the traditional carbon nanotube sponge heat conducting fin structure is not subjected to anti-corrosion treatment, so that the service life of the carbon nanotube sponge heat conducting fin is shortened;

(3) the traditional carbon nanotube sponge heat conducting fin structure does not have the function of static electricity prevention and is easy to damage materials.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a carbon nanotube sponge conducting strip structure to it glues the bacterium easily, does not carry out anticorrosive processing and does not have the problem of preventing the function of static to provide carbon nanotube sponge conducting strip in solving above-mentioned background art.

In order to achieve the above object, the utility model provides a following technical scheme: the utility model provides a carbon nanotube sponge conducting strip structure, includes pipeline and heat conduction material, the outside fixedly connected with heat conduction material of pipeline, the outside of heat conduction material is provided with fungi-proofing structure, fungi-proofing structure's outside is provided with anti-corrosion structure, anti-static structure's outside is provided with.

Preferably, the inside of fungi-proofing structure has set gradually fungi-proofing membrane, fungi-proofing granule, fungi-proofing layer and articulamentum, articulamentum fixed connection is in the outside of heat conduction material, the outside fixedly connected with fungi-proofing layer of articulamentum, the top of the inside on fungi-proofing layer is provided with fungi-proofing membrane, fungi-proofing membrane's bottom is provided with fungi-proofing granule, fungi-proofing granule sets up at fungi-proofing in situ portion.

Preferably, anticorrosive coating, epoxy, isolation layer and first bond line have set gradually in anticorrosive structure's inside, first bond line sets up in the outside of antibacterial structure, the top fixedly connected with anticorrosive coating of first bond line, the inside epoxy that is provided with of anticorrosive coating, epoxy's bottom fixedly connected with isolation layer.

Preferably, the isolation layer sets up the bottom in the anticorrosive coating inside, first bond line fixed connection is between anticorrosive coating and antibacterial structure.

Preferably, the anti-static structure is internally provided with a first metal fiber, a second metal fiber, an anti-static layer and a second adhesive layer, the second adhesive layer is arranged outside the anti-corrosion structure, the top end of the second adhesive layer is fixedly connected with the anti-static layer, one side of the inner part of the anti-static layer is fixedly connected with the first metal fiber, and the other side of the inner part of the anti-static layer is fixedly connected with the second metal fiber.

Preferably, the widths of the first metal fibers and the second metal fibers are equal, and the first metal fibers and the second metal fibers are staggered.

Compared with the prior art, the beneficial effects of the utility model are that: the carbon nanotube sponge heat conducting fin structure not only realizes the antibacterial function, realizes the protection of the carbon nanotube sponge heat conducting fin, but also prevents the damage to the internal structure;

(1) the antibacterial film, the antibacterial particles, the antibacterial layer and the connecting layer are sequentially arranged in the antibacterial structure, bacteria are easily adhered to the interior of the carbon nanotube sponge heat conducting fin when the carbon nanotube sponge heat conducting fin is used, the antibacterial film and the antibacterial particles are arranged in the antibacterial layer to prevent the bacteria from being adhered to the interior of the carbon nanotube sponge heat conducting fin, the bacteria can be prevented from entering the interior of the carbon nanotube sponge heat conducting fin by the antibacterial film and the antibacterial particles, and the connecting layer enables the antibacterial layer and the heat conducting material to be fixed;

(2) the anti-corrosion structure is characterized in that an anti-corrosion layer, epoxy resin, an isolation layer and a first bonding layer are sequentially arranged in the anti-corrosion structure, the carbon nanotube sponge heat-conducting strip can be corroded by other substances after being used for a long time, in order to prevent parts of the carbon nanotube sponge heat-conducting strip from being corroded, the epoxy resin in the anti-corrosion layer can prevent other substances from corroding the interior of the carbon nanotube sponge heat-conducting strip, the isolation layer is arranged at the bottom end of the epoxy resin, the isolation layer can prevent the epoxy resin from contacting other parts, the first bonding layer is fixedly connected to the bottom end of the anti-corrosion layer, and the anti-corrosion layer can be tightly attached to the anti-bacterial structure;

(3) the first metal fiber, the second metal fiber, the anti-static layer and the second adhesive layer are arranged in the anti-static structure, so that the carbon nanotube sponge heat-conducting sheet can possibly generate static electricity due to friction, air drying and the like in use, if the heat-conducting sheet generates static electricity, the heat-conducting sheet can possibly generate electric leakage, electric shock and other dangers in use, the first metal fiber and the second metal fiber are arranged in the anti-static layer, and can prevent the static electricity from being generated due to friction, air drying and the like, so that the material of the carbon nanotube sponge heat-conducting sheet is prevented from being damaged.

Drawings

Fig. 1 is a schematic front view of a cross-sectional structure of the present invention;

FIG. 2 is a schematic side view of the antibacterial structure of the present invention;

FIG. 3 is a schematic side view of the anti-corrosion structure of the present invention;

fig. 4 is a schematic side view of the anti-static structure of the present invention.

In the figure: 1. a pipeline; 2. a thermally conductive material; 3. an antibacterial structure; 301. an anti-bacterial film; 302. antibacterial particles; 303. a bacteria-proof layer; 304. a connecting layer; 4. an anti-corrosion structure; 401. an anticorrosive layer; 402. an epoxy resin; 403. an isolation layer; 404. a first adhesive layer; 5. an anti-static structure; 501. a first metal fiber; 502. a second metal fiber; 503. an antistatic layer; 504. a second adhesive layer.

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. 1-4, an embodiment of the present invention is provided; a carbon nanotube sponge heat conducting fin structure comprises a pipeline 1 and a heat conducting material 2, wherein the heat conducting material 2 is fixedly connected to the outside of the pipeline 1, and an antibacterial structure 3 is arranged on the outside of the heat conducting material 2;

the antibacterial structure 3 is internally provided with an antibacterial film 301, antibacterial particles 302, an antibacterial layer 303 and a connecting layer 304 in sequence, the connecting layer 304 is fixedly connected to the outside of the heat conducting material 2, the outside of the connecting layer 304 is fixedly connected with the antibacterial layer 303, the top end of the inside of the antibacterial layer 303 is provided with the antibacterial film 301, the bottom end of the antibacterial film 301 is provided with the antibacterial particles 302, and the antibacterial particles 302 are arranged inside the antibacterial layer 303;

specifically, as shown in fig. 1 and fig. 2, when the mechanism is used, firstly, bacteria are easily adhered to the inside of the carbon nanotube sponge heat conducting sheet when the carbon nanotube sponge heat conducting sheet is used, in order to prevent the bacteria from adhering to the inside of the carbon nanotube sponge heat conducting sheet, the antibacterial film 301 and the antibacterial particles 302 are arranged inside the antibacterial layer 303, both the antibacterial film 301 and the antibacterial particles 302 can prevent the bacteria from entering the inside of the carbon nanotube sponge heat conducting sheet, and the connecting layer 304 fixes the antibacterial layer 303 and the heat conducting material 2;

an anti-corrosion structure 4 is arranged outside the anti-bacterial structure 3;

an anticorrosive layer 401, epoxy resin 402, an isolating layer 403 and a first adhesive layer 404 are sequentially arranged inside the anticorrosive structure 4, the first adhesive layer 404 is arranged outside the antibacterial structure 3, the top end of the first adhesive layer 404 is fixedly connected with the anticorrosive layer 401, the epoxy resin 402 is arranged inside the anticorrosive layer 401, and the bottom end of the epoxy resin 402 is fixedly connected with the isolating layer 403;

the isolation layer 403 is arranged at the bottom end inside the anticorrosive layer 401, and the first bonding layer 404 is fixedly connected between the anticorrosive layer 401 and the antibacterial structure 3;

specifically, as shown in fig. 1 and 3, when the mechanism is used, firstly, the carbon nanotube sponge heat conducting strip may be corroded by some other substances after being used for a long time, in order to prevent some parts of the carbon nanotube sponge heat conducting strip from being corroded, the epoxy resin 402 in the anticorrosive layer 401 may prevent the other substances from corroding the inside of the carbon nanotube sponge heat conducting strip, the bottom end of the epoxy resin 402 is provided with an isolation layer 403, the isolation layer 403 may prevent the epoxy resin 402 from contacting other parts, the bottom end of the anticorrosive layer 401 is fixedly connected with a first adhesive layer 404, and the first adhesive layer 404 may enable the anticorrosive layer 401 to be tightly attached to the antibacterial structure 3;

an anti-static structure 5 is arranged outside the anti-corrosion structure 4;

a first metal fiber 501, a second metal fiber 502, an antistatic layer 503 and a second adhesive layer 504 are arranged inside the antistatic structure 5, the second adhesive layer 504 is arranged outside the anti-corrosion structure 4, the top end of the second adhesive layer 504 is fixedly connected with the antistatic layer 503, one side inside the antistatic layer 503 is fixedly connected with the first metal fiber 501, and the other side inside the antistatic layer 503 is fixedly connected with the second metal fiber 502;

the widths of the first metal fibers 501 and the second metal fibers 502 are equal, and the first metal fibers 501 and the second metal fibers 502 are arranged in a staggered manner;

specifically, as shown in fig. 1 and 4, when this mechanism is used, static electricity may be generated in the carbon nanotube sponge thermally conductive sheet due to friction, air drying, and the like during use, and if static electricity is generated in the thermally conductive sheet, there may be a risk of electric leakage, electric shock, and the like during use of the thermally conductive sheet, and the first metal fiber 501 and the second metal fiber 502 are provided inside the antistatic layer 503, and the first metal fiber 501 and the second metal fiber 502 can prevent static electricity from being generated due to friction, air drying, and the like, and prevent damage to the material of the carbon nanotube sponge thermally conductive sheet.

The working principle is as follows: the utility model discloses when using, at first, inside has the bacterium easily to glue when carbon nanotube sponge conducting strip uses, glues in the inside of carbon nanotube sponge conducting strip in order to prevent that the bacterium from, and the inside of fungi-proofing layer 303 is provided with fungi-proofing membrane 301 and fungi-proofing granule 302, and fungi-proofing membrane 301 and fungi-proofing granule 302 all can prevent that the bacterium from getting into the inside of carbon nanotube sponge conducting strip, and the articulamentum 304 is that the messenger prevents that fungi-proofing layer 303 and heat conduction material 2 are fixed.

Later, carbon nanotube sponge conducting strip live time may be corroded by some other materials for a long time, in order to prevent that some positions of carbon nanotube sponge conducting strip from being corroded, the inside epoxy 402 of anticorrosive coating 401 can prevent that other materials from corroding the inside of carbon nanotube sponge conducting strip, the bottom of epoxy 402 is provided with isolation layer 403, isolation layer 403 can prevent epoxy 402 and other part contact, the bottom fixedly connected with first bond line 404 of anticorrosive coating 401, first bond line 404 can make anticorrosive coating 401 and fungi-proofing structure 3 closely laminate.

Finally, the carbon nanotube sponge heat conducting sheet may generate static electricity due to friction, air drying and the like during use, if the heat conducting sheet generates static electricity, the heat conducting sheet may generate electric leakage, electric shock and other dangers during use, the first metal fiber 501 and the second metal fiber 502 are arranged in the antistatic layer 503, and the first metal fiber 501 and the second metal fiber 502 can prevent static electricity from being generated due to friction, air drying and the like, so as to prevent damage to the material of the carbon nanotube sponge heat conducting sheet.

It is obvious to a person skilled in the art that the invention is not restricted to details of the above-described exemplary embodiments, but that it can be implemented in other specific forms without departing from the spirit or essential characteristics of the invention. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention 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 (6)

1. The utility model provides a carbon nanotube sponge conducting strip structure, includes pipeline (1) and heat conduction material (2), its characterized in that: the pipeline is characterized in that the heat conduction material (2) is fixedly connected to the outside of the pipeline (1), the antibacterial structure (3) is arranged on the outside of the heat conduction material (2), the anti-corrosion structure (4) is arranged on the outside of the antibacterial structure (3), and the anti-static structure (5) is arranged on the outside of the anti-corrosion structure (4).

2. The carbon nanotube sponge heat-conducting fin structure according to claim 1, wherein: the inside of fungi-proofing structure (3) has set gradually fungi-proofing membrane (301), fungi-proofing granule (302), fungi-proofing layer (303) and articulamentum (304), articulamentum (304) fixed connection is in the outside of heat conduction material (2), outside fixedly connected with fungi-proofing layer (303) of articulamentum (304), the top of the inside of fungi-proofing layer (303) is provided with fungi-proofing membrane (301), the bottom of fungi-proofing membrane (301) is provided with fungi-proofing granule (302), fungi-proofing granule (302) set up inside fungi-proofing layer (303).

3. The carbon nanotube sponge heat-conducting fin structure according to claim 1, wherein: anticorrosion structure (4) inside has set gradually anticorrosive coating (401), epoxy (402), isolation layer (403) and first adhesive layer (404), first adhesive layer (404) set up the outside at fungi-proofing structure (3), the top fixedly connected with anticorrosive coating (401) of first adhesive layer (404), anticorrosive coating (401) inside is provided with epoxy (402), the bottom fixedly connected with isolation layer (403) of epoxy (402).

4. The carbon nanotube sponge heat-conducting fin structure according to claim 3, wherein: isolation layer (403) set up in the inside bottom of anticorrosive coating (401), first adhesive layer (404) fixed connection is between anticorrosive coating (401) and fungi-proofing structure (3).

5. The carbon nanotube sponge heat-conducting fin structure according to claim 1, wherein: the anti-static structure is characterized in that a first metal fiber (501), a second metal fiber (502), an anti-static layer (503) and a second adhesive layer (504) are arranged inside the anti-static structure (5), the second adhesive layer (504) is arranged outside the anti-corrosion structure (4), the top end of the second adhesive layer (504) is fixedly connected with the anti-static layer (503), the first metal fiber (501) is fixedly connected to one side of the inside of the anti-static layer (503), and the second metal fiber (502) is fixedly connected to the other side of the inside of the anti-static layer (503).

6. The carbon nanotube sponge heat-conducting fin structure according to claim 5, wherein: the widths of the first metal fibers (501) and the widths of the second metal fibers (502) are equal, and the first metal fibers (501) and the second metal fibers (502) are arranged in a staggered mode.

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