TWI482807B - The method of applying a functional shrink film to a light source body - Google Patents

Description

Method for coating functional shrink film on light source body

The invention relates to a method for coating a functional shrink film on a light source body, in particular to an inorganic material with a photocatalyst, a phosphor, a pigment, an organic dye, a light and various electromagnetic wave absorption and release materials, or other materials. Shrink film of nano material and its preparation method.

General functional materials (such as: photocatalysts, phosphors, pigments and other inorganic materials; or organic dyes, light absorbing release materials, or other nanomaterials) for better results, are coated by various spray methods Covering or printing on the surface of the tube to utilize the various spectrum of light emitted by it to give the functional material a better representation or function. However, all kinds of spraying have large loss, heavy pollution, time-consuming processing, and it is difficult to recover or re-spray or print after the failure of functional materials, so when the life of the light source is reached, it is coated on it. Functional materials can't work, or the life of the light source is not finished, but the functional materials fail first, and the expected performance of the functional materials cannot be achieved. Therefore, the whole set of equipment (ie, the light source equipment containing functional materials) is needed. Abandonment, in addition to being uneconomical, it also imposes a heavy burden on the environment, so it is stored There is room for improvement.

Therefore, the inventors of the present invention have proposed a functional shrink film which is attached to a preset shrink film or incorporated or coated or printed with a functional material such as a photocatalyst, a phosphor, or a shrink film. Inorganic materials such as pigments; or organic dyes, light and various electromagnetic wave absorption and release materials, or other nanomaterials, and then the functional shrink film is placed on the light source body (such as a lamp) to make functional shrinkage The membrane exerts its inherent function of continuous illumination, antibacterial, deodorization, absorption and release of various electromagnetic wave equivalent energy or other functional materials, and when the performance of the functional material is reduced or the life is extended or the new performance of the light source body is to be re-applied, Replace the new functional shrink film.

In order to clearly show the embodiment of the present invention, the inventors have only proposed a preferred embodiment, which is described as follows: The shrink film is a high molecular polymer product composed of a raw material such as PP or PE, and the high molecular polymer is at a high temperature. It is elastic, so in the production, the film is elongated under high heat, and then rapidly cooled, the molecules are frozen and lose their elasticity, so that a shrink film can be produced.

When the shrink film is heated, it will reappear elasticity. And because it has been in the elongation stage before, the shrink film will shrink heat without applying force.

Since the shrink film has the above-mentioned convenient characteristics, the shrink film is widely used in the industry, and is used in products packaging, electrical insulation, etc., and in view of the advantages in quality and price of the shrink film, the shrinkage adopted by the embodiment of the present invention Membrane, which means a commercially available shrink film, is not limited to this, as explained first.

A functional shrink film (20) of the present invention coats a functional material on the shrink film as described above by two methods, which are: A. Injecting a common resin coating (or printing) or functioning The material is directly coated (or printed) on the surface of the shrink film; B. In the shrink film manufacturing process, a certain ratio of action is added to the molding material of the shrink film to make it a shrink film with functional material function. That is, the functional shrink film (20). The functional shrink film (20) is placed inside or outside the lamp or the lamp tube (10), and the functional shrink film (20) is heated by a heating program of a suitable temperature (heat oven, hot air heater, etc.) The invention can be completed by closely covering the luminaire or the outer layer of the tube (10). In addition, functional materials will gradually lose their function after being used for a certain period of time or will be damaged by environmental damage. To replace, the present invention is provided with a tear line (21) on the functional shrink film (20) for simply removing the shrink film and re-applying a new functional shrink film (20). After the heating process, it is placed over the light source to restore its function.

As for the photocatalyst described in the present case, a catalyst which utilizes light energy for catalytic reaction does not itself sustain the driving of the catalytic reaction due to reaction consumption. Since the natural light source can be used to remove harmful substances without secondary pollution, the photocatalyst is of great application value. Among the photocatalyst materials, titanium dioxide (TiO ₂ ) has semiconductor characteristics, is chemically stable, and has strong redox properties, and is the most representative of the current photocatalytic material components. However, in theory, the particles of titanium dioxide photocatalyst material should have a nanometer grade (about 1 to 100 nanometers (nm), 1 nanometer (nm) equal to 10-9 meters (m)), in order to produce a higher efficiency photocatalytic effect. , to achieve the effect of antibacterial deodorization, it is also known as "nano photocatalyst". Preferably, the present invention can be applied to or on the shrink film by using the aforementioned "nano photocatalyst" material. Meanwhile, the photocatalyst material used in the present invention may be titanium dioxide, titanium oxide, zinc oxide, zinc sulfide, tin dioxide or cadmium sulfide, or may be one of metal/nonmetal/oxide/nitride/sulfide or A plurality of structures incorporated in the foregoing materials may also be prepared as a nucleation shell or composite material with one or more of metal/nonmetal/oxide/nitride/sulfide and the foregoing materials.

In terms of the shrink film, the material used in the preferred embodiment of the present invention may be PVC or PE or PET or OPS or OPP or POF, etc., and is classified into a shrink film (HEAT SHRINKABLE FILM) according to different states of use and needs. HEAT SHRINKABLE BAG and HEAT SHRINKABLE TUBING, except that the present invention covers the above various types of shrink film. At the same time, the functional shrink film (20) can also have an explosion-proof function.

In order to more clearly illustrate the preferred embodiment of the present invention, the inventors will exemplify the implementation steps of the present invention. Referring to Figure 1, the functional shrink film (20) coated on the light source (10) of the present invention is shown. Detailed implementation flow chart, as shown in step S1 of Figure 1, the implementation of the present invention can be divided into two steps: A. Injecting common resin coating (or printing) or directly coating functional materials (Or printing) on the surface of the shrink film; B. In the shrink film manufacturing process, a certain ratio of action is added to make it a functional shrinkage film (20) having a functional material function.

Special attention, the two steps of A and B are not single in implementation. If the B step is performed in advance and the standby energy shrink film (20) is prepared, the A step can also be performed to increase the effect of the functional shrink film (20). After the functional shrink film (20) is obtained, step S2 is then performed to sleeve the shrink film (20) of the functional material on the lamp or the lamp tube (10), since the lamp or the lamp tube (10) has various Type, such as bulb shape, fluorescent tube shape or spiral shape, in principle, as long as the functional shrink film (20) is wrapped around the periphery of the light source body, the desired effect can be produced. As for the installation method, there are many methods. . After the functional shrink film (20) is set, the film can be heat-shrinked and tightly coated on the light source body by means of hot air or the like as shown in step S3. Accordingly, the functional shrink film (30) coated on the light source body of the present invention can be obtained.

Please refer to FIG. 2 again, which is a schematic view of the implementation of the present invention, in which a tear line (21) is further provided for easily peeling off the film after the life of the functional shrink film (20) is reached. It is an excellent and convenient means of removal.

Further, the tensile force data of the functional shrink film (20) was: longitudinal stretching: 8.0 kgf; transverse stretching: 9.4 kgf. Due to the setting of the functional shrink film (20), if the light source body bursts, the functional shrink film (20) Pulling, fragmented fragments will not scatter.

In summary, the functional shrink film (30) coated on the light source body of the present invention can solve the environmental pollution of the conventional functional material sprayed on the light, and can be replaced by only replacing the functional shrink film. The cycle is applied to the existing light source device, and after the standby energy material is aged, the aging functional shrink film is removed through the tear line (21), and can be updated. Therefore, it can be seen that the functional shrink film (30) coated on the light source body can be self-renewed without the effect of purchasing related equipment, and is highly advanced, unprecedented, and novel. Granting patents is a matter of feeling.

10‧‧‧Light source body or tube

20‧‧‧ functional shrink film

21‧‧‧Dream line

30‧‧‧ Functional shrink film coated on the light source body

1 is a detailed implementation flowchart of the present invention; and FIG. 2 is a schematic diagram of an embodiment of the present invention.

Claims (6)

A method for coating a functional shrink film on a light source body, characterized in that a functional material is added to the shrink film or the surface by adding or coating a resin on a preset shrink film, and then The functional shrink film can be sleeved on the light source body, and the functional shrink film is coated on the light source body by a heating program of a hot oven or a heat sealer. When the light source body emits light, the light can be excited. Or enhancing activation of the functional material, the material of the shrink film is any one of PVC or PE or PET or OPS or OPP or POF, and the functional material is any one of photocatalyst, phosphor, pigment, or nano material; The shrink film is further provided with a tear line through which the shrink film can be easily removed by the tear line to replace the new functional shrink film. A method for coating a functional shrink film on a light source body according to claim 1, wherein the photocatalyst is a general-purpose nanoscale grade material having a particle size of 1 to 100 nanometers (nm). The method for coating a functional shrink film on a light source according to claim 1, wherein the functional material may be titanium dioxide, titanium oxide, zinc oxide, zinc sulfide, tin dioxide or cadmium sulfide, or may be metal. /nonmetal/oxide/nitrogen One or more of the compound/sulphide may be incorporated into the structure of the foregoing material, or may be a nucleated shell or composite material with one or more of metal/nonmetal/oxide/nitride/sulfide and the foregoing materials. . The method for coating a functional shrink film on the light source body according to claim 1, wherein the shrink film may be any one of a heat shrinkable bag (HEAT SHRINKABLE BAG) and a heat shrinkable tube (HEAT SHRINKABLE TUBING). The method of coating the functional shrink film on the light source according to claim 1, wherein the light source body can be any one of a fluorescent lamp, a white heat lamp, a neon lamp, a high pressure discharge lamp, an LED lamp, and a fluorescent lamp. The functional shrink film coated on the light source according to claim 1, wherein the shrink film has a tensile force range of: longitudinal stretching: 8.0 kgf; transverse stretching: 9.4 kgf.