TWM587596U - Light-storage type light-emitting thermoplastic composite laminate - Google Patents

Abstract

A light-storing light-emitting thermoplastic composite layer is provided with at least one layer. The at least one layer is provided with a body and a reinforcing member combined with the body. The body is a strip made of a polymer base material. Body or sheet-like body, the polymer base material includes a thermoplastic resin and a light storage member, the light storage member is provided in the thermoplastic resin and contains a plurality of particles distributed inside the thermoplastic resin, and the reinforcement member is pressurized and The heating is combined with the body to be distributed in the thermoplastic resin, and is in contact with the light storage member to form the light storage type light emitting thermoplastic composite layer, so as to provide a light storage type which can improve production efficiency, reuse and improve structural toughness. Luminous thermoplastic composite layer.

Description

Light-storing type luminescent thermoplastic composite layer

This creation relates to a light-storing light-emitting thermoplastic composite layer, especially a light-storing light-emitting thermoplastic composite layer which can improve production efficiency, reuse and improve structural toughness.

According to the existing light-storing light-emitting thermosetting composite layer, the light-storing thermosetting resin mainly includes a light-storing thermosetting resin and an artificial fiber, wherein the light-storing thermosetting resin is composed of a thermosetting resin and a light-storing material. After the thermosetting resin is heated and pressurized, the molecular chain There will be a cross-linking reaction between them, and then a network structure will be formed to polymer solidify. The existing common thermosetting resins include epoxy resin, phenolic resin and polyester resin, etc., and this light-storing material can have a wavelength between 200 and 700 nanometers. (nanometer; nm) between the excitation light source for absorption and storage, when the excitation light source stops providing light energy, the light storage material can gradually release the stored energy in the form of light, and the process of releasing light can last for several hours Furthermore, the light-storage material has the effect of temporarily emitting light. The existing common light-storage materials include sulfide, aluminate, silicate, etc. The artificial fiber is used as a reinforcing material for the existing light-storage light-emitting thermosetting composite layer. To increase the structural strength of the existing light-storing light-emitting thermosetting composite layer.

When the existing light-storing light-emitting thermosetting composite layer is manufactured, a thermosetting resin, a light-storing material, an auxiliary agent, a curing agent and an accelerator are evenly mixed to form a colloid, and the colloid is evenly coated on an artificial fiber. At the same time, with temperature and pressure, the colloid can infiltrate into the void of the artificial fiber, and after cooling, trimming, covering release paper, and winding and other processing processes, a prepreg (semi-finished product) is formed, and finally according to the product For shape requirements, polymer types, and fiber types, the hot stamping process for this prepreg requires 10 to 60 minutes and the processing temperature ranges from 120 to 180 ° C.

However, although the existing light-storing light-emitting thermosetting composite layer has the effects of light storage and light emission, in order to avoid curing of raw materials such as resins and prepregs (semi-finished products) during the manufacturing process, the raw materials are usually Store at low temperature (<-15 ° C), the storage conditions are quite strict and will increase the cost required for production; further, because the prepreg is sticky, in order to avoid sticking with surrounding objects, a release paper must be used. Packing will relatively increase the time and cost required for production, and lack economic benefits. Furthermore, due to the properties of thermosetting materials, the existing light-storing light-emitting thermosetting composite layers cannot be repeatedly processed and used after being cured by heating. The value of utilization; In addition, the existing light-storing type light-emitting thermosetting composite layer after hot pressing has a structural toughness value of insufficient (0.1-1 kJ / m ² ). In view of the above problems and shortcomings, the existing light-storing type light-emitting type The thermosetting composite layer has its needs for improvement.

Therefore, this creation takes into account the lack and problems of the existing light-storing light-emitting thermosetting composite layers in actual use, which are difficult to save, need to be packaged with release paper, cannot be reused, and have insufficient structural toughness. Finally, a kind of light-emitting light-emitting thermoplastic composite layer that can improve the existing missing work has been developed. This work mainly uses thermoplastic resin as the material. During production, the raw materials do not need to be stored at low temperature and do not need to be used. The paper is coated and can be reused after being processed into a finished product. Further, the toughness of the thermoplastic resin is higher than that of the thermosetting resin, so as to provide a light-emitting light-emitting thermoplastic composite layer that can improve production efficiency, reuse and improve structural toughness. The purpose of things.

Based on the above purpose, the present invention is to provide a light-storing light-emitting thermoplastic composite layer, which is provided with at least one layer, the at least one layer is provided with a body and a reinforcing member combined with the body, and the body is a high A stripe or sheet made of a molecular substrate. The polymer substrate includes a thermoplastic resin and a light-storage member. The light-storage member is disposed in the thermoplastic resin and includes a plurality of distributed in the thermoplastic resin. Granules, the reinforcing member is combined with the body to be distributed in the thermoplastic resin after being pressurized and heated, and is in contact with the light storage member to form the light storage type light emitting thermoplastic composite layer.

Further, the light-storing light-emitting thermoplastic composite layer as described above, wherein the thermoplastic resin includes crystalline, semi-crystalline, and amorphous polymers.

Still further, the light-storage type light-emitting thermoplastic composite layer as described above, wherein the light-storage member includes a plurality of particles made of a sulfide, a rare earth aluminate, a rare earth silicate, and a rare earth sulfur oxide. .

Preferably, the light-storing light-emitting thermoplastic composite layer as described above, wherein the reinforcing member includes a plurality of artificial fibers distributed inside the thermoplastic number, and the artificial fibers include carbon fibers, glass fibers, and mineral fibers. And high-molecular fibers, the types of which can be short fibers, long fibers, continuous fibers, woven fibers, or powdery fibers.

Preferably, the light-storage type light-emitting thermoplastic composite layer as described above, wherein the light-storage type light-emitting thermoplastic composite layer is provided with a plurality of layers, and the layers are arranged on top and bottom.

Preferably, the light-storing type light-emitting thermoplastic composite layer as described above, wherein the light-storing type light-emitting thermoplastic composite layer is provided with a plurality of layers, the layers are stacked on top and bottom, and two tops and bottoms There is an included angle between adjacent layer bodies.

Preferably, the light-storing light-emitting thermoplastic composite layer is as described above, wherein each layer has the same or different thickness.

With the above-mentioned technical means, the light-storing light-emitting thermoplastic composite layer system of the present invention has at least the following advantages and effects:
I. Improve production efficiency: The light-storing light-emitting thermoplastic composite layer of this creation uses thermoplastic resin as one of the raw materials of the polymer base material, so that this creation does not need to provide low-temperature equipment during manufacture, but can be used at room temperature. The thermoplastic resin and the prepreg are stored; further, the surface of the prepreg made by the thermoplastic resin is dried without sticking, so it is not necessary to use a release paper for coating during the production process, not only It can shorten production time and reduce costs; and the time required for hot pressing (less than 5 minutes) is shorter than the existing thermosetting resin (10 ~ 60 minutes), which can effectively improve production efficiency.
2. Reuse: Due to the material properties of the thermoplastic resin, the light-storing light-emitting thermoplastic composite layer can be reprocessed and reused after curing after curing. It has the value of reuse and conforms to the trend of environmental protection.
3. Improving structural toughness: The light storage type light emitting thermoplastic composite layer made through the thermoplastic resin has a toughness value of 1-10 kJ / m ² , which is higher than the existing light storage type light emitting thermosetting composite layer. Therefore, the present invention can effectively improve the structural toughness of the light-storing light-emitting thermoplastic composite layer, thereby increasing its application range and breadth.

In order to understand the technical features and practical effects of this creation in detail and can be realized in accordance with the contents of the description, the preferred embodiment shown in the figure is further described in detail as follows:

This creation provides a light-storing light-emitting thermoplastic composite layer. Please refer to FIG. 1 to FIG. 3. The light-storing light-emitting thermoplastic composite layer is provided with at least one layer 10, and the at least one layer 10 is provided with a body. And a reinforcing member 40 combined with the body, wherein the body is a strip or sheet made of a polymer base material, the polymer base material includes a thermoplastic resin 20 and a light storage member 30, the The thermoplastic resin 20 includes crystalline, semi-crystalline, and non-crystalline polymers. The light storage member 30 is disposed in the thermoplastic resin 20 and includes a plurality of particles. The plurality of particles are distributed inside the thermoplastic resin 20, and further The light storage member 30 includes a plurality of particles made of sulfide, rare earth aluminate, rare earth silicate, and rare earth sulfur oxide. Furthermore, the light storage member 30 is made of rare earth aluminate. The plurality of particles are formed, and the average particle diameter of the plurality of particles is between 10 and 80 micrometers (μm).

Preferably, the polymer substrate is further provided with a plasticizing member and an auxiliary agent, wherein the plasticizing member serves as a carrier of the thermoplastic resin 20 and the light storage member 30, so that the thermoplastic resin 20 and the light storage member 30 are plural Particles, which can be combined with the reinforcing member 40, and the auxiliary agent is an antioxidant (increasing the anti-oxidation ability of the polymer substrate), a dispersant (the light storage member 30 is uniformly dispersed in the polymer substrate) or A coupling agent, wherein the coupling agent can increase the bonding between the polymer substrate and the reinforcing member 40. As shown in FIG. 4, the thermoplastic resin, the light-storing member, the plasticizing member, and the auxiliary agent are evenly mixed to form the body into a The light-storing thermoplastic resin is the first operation step of manufacturing the light-storing light-emitting thermoplastic composite layer: compounding; further, the thermoplastic resin, the light-storing member, the plasticizing member, and the auxiliary agent are 50-95%, 5 ~ 50%, 0 ~ 60% and 0 ~ 10% by weight.

The reinforcing member 40 is combined with the body to be distributed in the thermoplastic resin 20 and is in contact with the light storage member 30. The reinforcing member 40 includes a plurality of artificial fibers; preferably, the artificial fiber includes carbon fibers , Glass fiber, mineral fiber, polymer fiber, etc., the type can be short fiber, long fiber, continuous fiber, woven fiber or powdery fiber, etc. When manufacturing, the light-storing thermoplastic resin is evenly applied to the plurality of artificial fibers. And applying pressure through a roller to infiltrate the light-storing thermoplastic resin into the voids of the plurality of artificial fibers, and at the same time heating to melt the light-storing thermoplastic resin and uniformly compound with the plurality of personal fibers of the reinforcement, wherein the thermoplastic resin is heated After being pressurized, the molecular chains slide against each other, so that the polymer exhibits a melt flow dynamics. After cooling, it is rolled up to form a prepreg material of the light-storing light-emitting thermoplastic composite layer. The foregoing operation is shown in FIG. 4 The second step in the manufacturing process: impregnation, and then according to the product shape requirements, polymer types and fiber types, etc. Procedure hot press forming, which is the time required is less than 5 minutes, the processing temperature is between 140 ~ 300 ℃, formed thermoplastic composite layer type light emitting light storing substance after hot press forming according to the present writing.

Further, as shown in FIGS. 1 and 2, the light-storing light-emitting thermoplastic composite layer is provided with three layers 10, and the layers 10 are stacked on top and bottom. Further, please refer to FIG. 3 for cooperation. The light-storing type light-emitting thermoplastic composite layer is provided with a plurality of layers 10, the layers 10 are stacked on top of each other, and an angle is included between two upper and lower adjacent layers 10; preferably, the The thicknesses of the layers 10 may be the same or different.

Based on the above technical features, the light-storing light-emitting thermoplastic composite layer of this creation uses thermoplastic resin 20 as one of the raw materials of the polymer base material, so that this creation does not need to provide low-temperature equipment and can The thermoplastic resin 20 and the prepreg are stored at a temperature; further, the surface of the prepreg made through the thermoplastic resin 20 is dried without sticking, so no release paper is needed in the production process. Coating can not only shorten production time and reduce costs; further, due to the material properties of the thermoplastic resin 20, the light-storing light-emitting thermoplastic composite layer of this invention can be repeatedly processed and used again after curing, after curing, It has the value of recycling and conforms to the environmental protection trend, and the time required for hot pressing (less than 5 minutes) is shorter than the existing thermosetting resin (10 ~ 60 minutes), which can effectively improve the production efficiency. In addition, through the thermoplastic Photoluminescent emission thermoplastic resin composite layer was formed, the toughness is 1 ~ 10 J / m ^2, higher than the conventional light emitting thermosetting STORING The toughness value of the composite layer has a tensile strength of more than 300 MPa, a tensile modulus of more than 17 GPa, and a continuous light emission time of more than 12 hours. Therefore, the present invention can effectively improve the structure of the light-storing light-emitting thermoplastic composite layer. Toughness, and further increase its application range and breadth, so as to provide a light-emitting light-emitting thermoplastic composite layer that can improve production efficiency, reuse and improve structural toughness.

The above is only a preferred embodiment of the creation, and does not limit the creation in any form. Any person with ordinary knowledge in the technical field to which this invention belongs will use the present invention without departing from the scope of the technical solution proposed in the creation. Equivalent embodiments of partial changes or modifications made to the technical content disclosed in the creation without departing from the technical solution content of the creation are still within the scope of the technical solution of the creation.

10‧‧‧layer

20‧‧‧ thermoplastic resin

30‧‧‧Light storage

40‧‧‧ Reinforcement

FIG. 1 is a schematic cross-sectional side view of the light-storing light-emitting thermoplastic composite layer of the present invention.
FIG. 2 is a schematic partial cross-sectional side view of the light-emitting thermoplastic composite layer of the present invention.
FIG. 3 is a schematic top view of the light-storing light-emitting thermoplastic composite layer of the present invention.
FIG. 4 is a block diagram of a manufacturing process of the light-storing light-emitting thermoplastic composite layer of the present invention.

Claims (12)

A light-storing light-emitting thermoplastic composite layer is provided with at least one layer. The at least one layer is provided with a body and a reinforcing member combined with the body. The body is a strip made of a polymer base material. Body or sheet-like body, the polymer base material includes a thermoplastic resin and a light storage member, the light storage member is provided in the thermoplastic resin and contains a plurality of particles distributed inside the thermoplastic resin, and the reinforcement member is pressurized and The heating is combined with the body to be distributed in the thermoplastic resin, and is in contact with the light storage member to form the light storage type light emitting thermoplastic composite layer. The light-storing light-emitting thermoplastic composite layer according to claim 1, wherein the thermoplastic resin includes crystalline, semi-crystalline, and amorphous polymers. The light-storing light-emitting thermoplastic composite layer according to claim 1 or 2, wherein the light-storing member comprises a plurality of sulfides, rare-earth aluminates, rare-earth silicates, and rare-earth sulfur oxides. Particles. The light-storing light-emitting thermoplastic composite layer according to claim 3, wherein the reinforcing member includes a plurality of artificial fibers distributed inside the thermoplastic number, and the artificial fibers include carbon fiber, glass fiber, mineral fiber, and polymer Fibers and the like can be short fibers, long fibers, continuous fibers, woven fibers, or powdered fibers. The light-storage type light-emitting thermoplastic composite layer according to claim 4, wherein the light-storage type light-emitting thermoplastic composite layer is provided with a plurality of layers, and the layers are arranged on top of each other. The light-storage type light-emitting thermoplastic composite layer according to claim 1 or 2, wherein the light-storage type light-emitting thermoplastic composite layer is provided with a plurality of layers, and the layers are arranged on top and bottom. The light-storing light-emitting thermoplastic composite layer according to claim 4, wherein the light-storing light-emitting thermoplastic composite layer is provided with a plurality of layers, and the layers are stacked on top and bottom, and two tops and bottoms are adjacent to each other. There is an included angle between the layers. The light-storing light-emitting thermoplastic composite layer according to claim 1 or 2, wherein the light-storing light-emitting thermoplastic composite layer is provided with a plurality of layers, and the layers are stacked on top and bottom, and two tops and bottoms There is an included angle between adjacent layer bodies. The light-storing light-emitting thermoplastic composite layer according to claim 5, wherein each layer has the same or different thickness. The light-storing light-emitting thermoplastic composite layer according to claim 6, wherein each layer has the same or different thickness. The light-storing light-emitting thermoplastic composite layer according to claim 7, wherein each layer has the same or different thickness. The light-storing light-emitting thermoplastic composite layer according to claim 8, wherein each layer has the same or different thickness.