CN112793245A

CN112793245A - APET film for UV offset printing

Info

Publication number: CN112793245A
Application number: CN202011633666.2A
Authority: CN
Inventors: 刘斌辉; 练士豪
Original assignee: Wuxi Aokete Packaging Material Co ltd
Current assignee: Wuxi Aokete Packaging Material Co ltd
Priority date: 2020-12-31
Filing date: 2020-12-31
Publication date: 2021-05-14

Abstract

The invention discloses an APET film for UV offset printing, and particularly relates to the technical field of APET films. According to the invention, the surface layer is arranged at the bottom end of the substrate layer, the antioxidant layer and the heat stabilizer in the surface layer can retard flame and prevent the substrate layer from burning, the polycarbonate and the microencapsulated red phosphorus further protect the substrate layer to retard flame, the polycarbonate and the microencapsulated red phosphorus can protect the substrate layer and prevent the substrate layer from burning, the polycarbonate and the microencapsulated red phosphorus have outstanding flame-retardant effect and do not influence the service performance of the substrate layer, and the practicability of the substrate layer is effectively improved.

Description

APET film for UV offset printing

Technical Field

The invention relates to the technical field of APET films, in particular to an APET film for UV offset printing.

Background

With the rapid economic development of China, the environmental pollution of China is more and more serious, people pay more and more attention to the environment protection at present, as the APET film belongs to a thermoplastic environment-friendly plastic product, the rim charge and the waste products can be continuously recycled, the APET film becomes a film which is used by more environment-friendly people, and the requirements of users on the APET film are higher and higher along with the technological progress.

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

(1) the traditional APET film for UV offset printing has no effective flame retardant property and poor safety;

(2) the traditional APET film for UV offset printing cannot effectively prevent static electricity, does not have a fluorescent effect and has poor practicability;

(3) the abrasion resistance of the APET film used for the UV offset printing is poor, and the surface of the APET film is easy to scratch.

Disclosure of Invention

The invention aims to provide an APET film for UV offset printing, which solves the problems of ineffective flame retardant performance and poor safety in the background technology.

In order to achieve the purpose, the invention provides the following technical scheme: an APET film for UV offset printing comprises a substrate layer, wherein an anti-static structure is arranged at the top end of the substrate layer, an anti-skid structure is arranged at the bottom end of the substrate layer, and a flame-retardant structure is arranged between the substrate layer and the anti-skid structure;

the flame-retardant structure comprises a surface layer, the surface layer is arranged at the bottom end of the base material layer, the bottom fixedly connected with anti-oxygen layer inside the surface layer, the top fixedly connected with microencapsulated red phosphorus inside the surface layer, a heat stabilizer is fixedly connected between the anti-oxygen layer and the microencapsulated red phosphorus, and the bottom fixedly connected with polycarbonate on the surface layer.

Preferably, the heat stabilizer and the microencapsulated red phosphorus have the same thickness, and the polycarbonates are arranged at equal intervals at the bottom end of the surface layer.

Preferably, the anti-static structure comprises fluorescent powder, a fluorescent layer, an anti-static layer, first fibers and second fibers, the anti-static layer is arranged at the top end of the base material layer, the first fibers are fixedly connected to one side of the interior of the anti-static layer, the second fibers are fixedly connected to the other side of the interior of the anti-static layer, the fluorescent layer is arranged at the top end of the anti-static layer, and the fluorescent powder is arranged in the fluorescent layer.

Preferably, the fluorescent powder is arranged in a plurality of groups, and the fluorescent powder is arranged in the fluorescent layer at equal intervals.

Preferably, the anti-skidding structure comprises skid resistant course, wearing layer, glass microballon, articulamentum and standing groove, the articulamentum sets up the bottom on the top layer, the inside bottom of articulamentum is provided with the standing groove, the inside of standing groove is provided with the glass microballon, the outside fixedly connected with wearing layer of glass microballon, the outside of wearing layer is provided with the skid resistant course.

Preferably, the glass microspheres are arranged inside the placing groove, and the wear-resistant layer is arranged between the glass microspheres and the anti-slip layer.

Compared with the prior art, the invention has the beneficial effects that: the APET film for UV offset printing not only realizes that the APET film has effective flame retardant performance, realizes that the APET film has fluorescent effect and is antistatic, but also realizes that the APET film is wear-resistant and the service life of the APET film is prolonged;

(1) the surface layer is arranged at the bottom end of the substrate layer, the antioxidant layer and the heat stabilizer inside the surface layer can be used for inflaming retarding to prevent the substrate layer from burning, the polycarbonate and the microencapsulated red phosphorus further protect the substrate layer to retard the inflaming retarding, the substrate layer can be protected and prevented from burning by arranging the polycarbonate and the microencapsulated red phosphorus, the polycarbonate and the microencapsulated red phosphorus have outstanding inflaming retarding effects and do not influence the service performance of the substrate layer, and the practicability of the substrate layer is effectively improved;

(2) by arranging the fluorescent powder, the fluorescent layer, the anti-static layer, the first fibers and the second fibers, the fluorescent powder in the fluorescent layer can enable the base material layer to have a unique fluorescent effect, the base material layer can also keep good appearance performance in an environment with weak light, the practicability of the base material layer is improved, the first fibers and the second fibers are arranged in the anti-static layer, and the surface of the base material layer can have an anti-static effect by arranging the first fibers and the second fibers;

(3) through being provided with the skid resistant course, the wearing layer, the glass microballon, articulamentum and standing groove, so the substrate layer surface is comparatively smooth when using the polypropylene film main part, the substrate layer bonds together with self or other things easily, the substrate layer is if the very influence that bonds together uses the substrate layer, the inside glass microballon of standing groove can prevent that the substrate layer from bonding together with self or other things, can make things convenient for the use of substrate layer through setting up the glass microballon, improve the efficiency when using the substrate layer, skid resistant course and wearing layer not only can make the wear-resisting antiskid of substrate layer can prevent that the substrate layer from being scraped the flower, damage when can preventing the substrate layer from using through setting up skid resistant course and wearing layer, can improve the practicality of.

Drawings

FIG. 1 is a schematic front sectional view of the present invention;

FIG. 2 is a schematic view of a partial cross-sectional structure of the surface layer of the present invention in front view;

FIG. 3 is a schematic view of a front view of a partial cross-sectional structure of the anti-slip structure of the present invention;

FIG. 4 is an enlarged partial cross-sectional view taken at A in FIG. 1 according to the present invention.

In the figure: 1. a substrate layer; 2. an anti-static structure; 201. fluorescent powder; 202. a fluorescent layer; 203. an antistatic layer; 204. a first fiber; 205. a second fiber; 3. an anti-slip structure; 301. an anti-slip layer; 302. a wear layer; 303. glass microspheres; 304. a connecting layer; 305. a placement groove; 4. a surface layer; 5. an oxygen resistant layer; 6. a polycarbonate; 7. a heat stabilizer; 8. microencapsulated red phosphorus.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Example 1: referring to fig. 1-4, an APET film for UV offset printing includes a substrate layer 1, an anti-static structure 2 is disposed at the top end of the substrate layer 1, an anti-skid structure 3 is disposed at the bottom end of the substrate layer 1, and a flame retardant structure is disposed between the substrate layer 1 and the anti-skid structure 3;

referring to fig. 1-4, the APET film for UV offset printing further includes a flame retardant structure, the flame retardant structure includes a surface layer 4, the surface layer 4 is disposed at the bottom end of the substrate layer 1, the bottom end inside the surface layer 4 is fixedly connected with an antioxidant layer 5, the top end inside the surface layer 4 is fixedly connected with microencapsulated red phosphorus 8, a heat stabilizer 7 is fixedly connected between the antioxidant layer 5 and the microencapsulated red phosphorus 8, and the bottom end of the surface layer 4 is fixedly connected with polycarbonate 6;

the heat stabilizer 7 and the microencapsulated red phosphorus 8 are equal in thickness, and the polycarbonate 6 is arranged at the bottom end of the surface layer 4 at equal intervals;

specifically, as shown in fig. 1 and fig. 2, the surface layer 4 is disposed at the bottom end of the substrate layer 1, the antioxidant layer 5 and the heat stabilizer 7 inside the surface layer 4 can prevent the substrate layer 1 from burning, the polycarbonate 6 and the microencapsulated red phosphorus 8 further protect the substrate layer 1 to retard the flame of the substrate layer 1, not only the substrate layer 1 can be protected but also the substrate layer 1 can be prevented from burning by disposing the polycarbonate 6 and the microencapsulated red phosphorus 8, the polycarbonate 6 and the microencapsulated red phosphorus 8 have an outstanding flame retardant effect and do not affect the service performance of the substrate layer 1, and the practicability of the substrate layer 1 is effectively improved.

Example 2: the anti-static structure 2 is composed of fluorescent powder 201, a fluorescent layer 202, an anti-static layer 203, first fibers 204 and second fibers 205, the anti-static layer 203 is arranged at the top end of the substrate layer 1, one side inside the anti-static layer 203 is fixedly connected with the first fibers 204, the other side inside the anti-static layer 203 is fixedly connected with the second fibers 205, the fluorescent layer 202 is arranged at the top end of the anti-static layer 203, and the fluorescent powder 201 is arranged inside the fluorescent layer 202;

the fluorescent powder 201 is arranged in a plurality of groups, and the fluorescent powder 201 is arranged in the fluorescent layer 202 at equal intervals;

specifically, as shown in fig. 1 and 4, the fluorescent powder 201 in the fluorescent layer 202 can make the substrate layer 1 have a unique fluorescent effect, so that the substrate layer 1 can maintain a good appearance performance in an environment with weak light, the practicability of the substrate layer 1 is improved, the first fibers 204 and the second fibers 205 are arranged in the antistatic layer 203, and the surface of the substrate layer 1 can have an antistatic effect by arranging the first fibers 204 and the second fibers 205.

Example 3: the antiskid structure 3 consists of an antiskid layer 301, a wear-resistant layer 302, glass microspheres 303, a connecting layer 304 and a placing groove 305, wherein the connecting layer 304 is arranged at the bottom end of the surface layer 4, the placing groove 305 is arranged at the bottom end inside the connecting layer 304, the glass microspheres 303 are arranged inside the placing groove 305, the wear-resistant layer 302 is fixedly connected to the outside of the glass microspheres 303, and the antiskid layer 301 is arranged outside the wear-resistant layer 302;

the glass microspheres 303 are arranged inside the placing groove 305, and the wear-resistant layer 302 is arranged between the glass microspheres 303 and the anti-slip layer 301;

specifically, as shown in fig. 1 and fig. 3, the surface of the substrate layer 1 is relatively smooth so when the polypropylene film main body is used, the substrate layer 1 is easily adhered to itself or other objects, if the substrate layer 1 is adhered to the substrate layer 1, the substrate layer 1 is used with itself or other objects, the glass microspheres 303 inside the placement groove 305 can prevent the substrate layer 1 from being adhered to itself or other objects, the use of the substrate layer 1 can be facilitated by arranging the glass microspheres 303, the efficiency when the substrate layer 1 is used is improved, the anti-skid layer 301 and the wear-resistant layer 302 can not only make the substrate layer 1 wear-resistant and anti-skid, but also prevent the substrate layer 1 from being scratched, the substrate layer 1 can be prevented from being damaged when used by arranging the anti-skid layer 301 and the wear-resistant layer.

The working principle is as follows: when the flame-retardant substrate layer is used, firstly, the surface layer 4 is arranged at the bottom end of the substrate layer 1, the antioxidant layer 5 and the heat stabilizer 7 in the surface layer 4 can retard flame and prevent the substrate layer 1 from burning, the polycarbonate 6 and the microencapsulated red phosphorus 8 further protect the substrate layer 1 to retard flame, the polycarbonate 6 and the microencapsulated red phosphorus 8 can protect the substrate layer 1 and prevent the substrate layer 1 from burning, the polycarbonate 6 and the microencapsulated red phosphorus 8 have an outstanding flame-retardant effect and do not influence the service performance of the substrate layer 1, and the practicability of the substrate layer 1 is effectively improved.

Afterwards, the fluorescent powder 201 in the fluorescent layer 202 can make the substrate layer 1 have a unique fluorescent effect, so that the substrate layer 1 can also keep good appearance performance in an environment with weak light, the practicability of the substrate layer 1 is improved, the first fibers 204 and the second fibers 205 are arranged in the antistatic layer 203, and the surface of the substrate layer 1 can have an antistatic effect by arranging the first fibers 204 and the second fibers 205.

Finally, the comparatively smooth so of substrate layer 1 surface is when using the polypropylene film main part, substrate layer 1 is easily in the same place with self or other things stick, substrate layer 1 is if gluing together and influence very much and use substrate layer 1, the inside glass microballon 303 of standing groove 305 can prevent that substrate layer 1 from gluing together with self or other things, can make things convenient for substrate layer 1's use through setting up glass microballon 303, improve the efficiency when using substrate layer 1, skid resistant course 301 and wearing layer 302 not only can make substrate layer 1 wear-resisting antiskid can also prevent that substrate layer 1 from being scraped the flower, it is damaged when can preventing substrate layer 1 from using through setting up skid resistant course 301 and wearing layer 302, can improve the practicality of polypropylene film main part.

It will be evident to those skilled in the art that the invention is not limited to the details of the foregoing illustrative embodiments, and that the present invention may be embodied in other specific forms without departing from the spirit or essential attributes thereof. 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

1. An APET film for UV offset printing, which comprises a substrate layer (1), and is characterized in that: an anti-static structure (2) is arranged at the top end of the substrate layer (1), an anti-skid structure (3) is arranged at the bottom end of the substrate layer (1), and a flame-retardant structure is arranged between the substrate layer (1) and the anti-skid structure (3);

the flame-retardant structure comprises a surface layer (4), wherein the surface layer (4) is arranged at the bottom end of the substrate layer (1), the bottom end fixedly connected with an anti-oxygen layer (5) inside the surface layer (4), the top end fixedly connected with microencapsulated red phosphorus (8) inside the surface layer (4), a heat stabilizer (7) is fixedly connected between the anti-oxygen layer (5) and the microencapsulated red phosphorus (8), and the bottom end fixedly connected with polycarbonate (6) on the surface layer (4).

2. The APET film for UV offset printing according to claim 1, characterized in that: the thickness of the heat stabilizer (7) is equal to that of the microencapsulated red phosphorus (8), and the polycarbonate (6) is arranged at the bottom end of the surface layer (4) at equal intervals.

3. The APET film for UV offset printing according to claim 1, characterized in that: the anti-static structure (2) is composed of fluorescent powder (201), a fluorescent layer (202), an anti-static layer (203), first fibers (204) and second fibers (205), the anti-static layer (203) is arranged on the top end of the base material layer (1), the first fibers (204) are fixedly connected to one side of the inner portion of the anti-static layer (203), the second fibers (205) are fixedly connected to the other side of the inner portion of the anti-static layer (203), the fluorescent layer (202) is arranged on the top end of the anti-static layer (203), and the fluorescent powder (201) is arranged inside the fluorescent layer (202).

4. The APET film for UV offset printing according to claim 3, characterized in that: the fluorescent powder (201) is arranged in a plurality of groups, and the fluorescent powder (201) is arranged in the fluorescent layer (202) at equal intervals.

5. The APET film for UV offset printing according to claim 1, characterized in that: the antiskid structure (3) comprises an antiskid layer (301), an abrasion-resistant layer (302), glass microspheres (303), a connecting layer (304) and a placing groove (305), wherein the connecting layer (304) is arranged at the bottom end of the surface layer (4), the placing groove (305) is arranged at the bottom end of the connecting layer (304), the glass microspheres (303) are arranged inside the placing groove (305), the abrasion-resistant layer (302) is fixedly connected to the outside of the glass microspheres (303), and the antiskid layer (301) is arranged outside the abrasion-resistant layer (302).

6. The APET film for UV offset printing according to claim 5, wherein: the glass microspheres (303) are arranged inside the placement groove (305), and the wear-resistant layer (302) is arranged between the glass microspheres (303) and the anti-slip layer (301).