KR20000058478A - Producing method for luminous yarn having long afterglow and high brightness properties - Google Patents

Abstract

PURPOSE: Provided is a process for producing a long persistence luminous grey yarn of high brightness, which has improved time of luminosity and color of luminosity. Thereby, it is possible to produce a long persistence luminous grey yarn of high brightness which has long time of luminosity and various color of luminosity. CONSTITUTION: The long persistence luminous grey yarn of high brightness is obtained by a process containing the steps of: mixing a photo storage luminous raw material of 3-55wt.% and a synthetic resin of 45-97wt.% having chemical fiber ability; extruding the mixture to produce a luminous chip by using an extrusion system; and then coating-extruding the synthetic resin and the luminous chip by using a complex spinning system. The photo storage luminous raw material represents MAl2O4, wherein M is selected from the group consisting of Ca, Sr, Ba. The synthetic resin uses a synthetic fiber, a regenerated fiber, a semi synthetic fiber and an inorganic fiber. The produced long persistence luminous grey yarn of high brightness has a volume ratio of a part containing the photo storage luminous raw material to the other part being 1/1-1/4.

Description

Producing method for luminous yarn having long afterglow and high brightness properties

The present invention relates to a method of manufacturing a high brightness long afterglow light emitting yarn, and more particularly, after manufacturing a light emitting chip using a extrusion system using a photoluminescent light emitting material and a synthetic fiber having a chemical fiber capability, the manufactured light emitting chip and light emitting The present invention relates to a method of manufacturing a high brightness long afterglow light emitting yarn capable of emitting light with high brightness for a long time by constructing a composite resin extruded using a composite spinning system.

In general, a brief description will be made of the state in which the photoluminescent light-emitting yarn is manufactured. And chemical fiber raw materials. The second step of extruding the mixed photoluminescent luminescent raw material and the chemical fiber raw material by using an extruder in the first step, and the mixed photoluminescent luminescent raw material and the chemical fiber raw material by the extruder in the second process The photoluminescent light emitting chip is manufactured. The photoluminescent light emitting chip manufactured through the second process is classified into a third process of manufacturing a light emitting yarn using a radiation system.

When using the photoluminescent light-emitting yarn prepared as described above, various problems were exposed.

First, the photoluminescent luminous yarn manufactured as described above collects the stimulus source (light) when it is irradiated from the outside, but it is emitted only by the action of the photoluminescent raw material contained in the yarn. There was a problem that the intensity was low and the light emission time was short.

In addition, although the luminance can be increased to a certain level by increasing the content of the photoluminescent light emitting material, there is a limitation of the luminance, and when the content of the photoluminescent light emitting material is too large, there is a problem that the quality of the yarn is deteriorated.

In view of the above problems according to the present invention, the object of the present invention is to manufacture a light emitting chip and a light emitting chip after manufacturing a synthetic resin having a photoluminescent light emitting material and a chemical fiber ability using an extrusion system The present invention provides a method of manufacturing a high brightness long afterglow light emitting yarn capable of emitting high luminance for a long time and of emitting various colors by constructing a composite resin extruded using a composite spinning system.

1 is a process diagram according to an embodiment of the present invention

Figure 2 is an enlarged cross-sectional view of the main portion of a high brightness long afterglow light emitting yarn according to the present invention

♣ Explanation of symbols for main part of drawing ♣

A: photoluminescent luminescent material

B: synthetic resin with chemical fiber capacity

C: high brightness long afterglow luminous yarn

The object of the present invention is a mixing process of mixing a 3 to 55 weight ratio (%) of the photoluminescent luminescent material and 45 to 97 weight ratio (%) of the synthetic resin having a chemical fiber ability, and a photoluminescent luminescent raw material mixed in the mixing process and A light emitting chip manufacturing process in which a synthetic resin having chemical fiber capability is manufactured as a light emitting chip by an extrusion system, and a coating extrusion process in which the synthetic resin and the light emitting chip used in manufacturing the light emitting chip are coated and extruded by a composite spinning system. It can be achieved by a method of manufacturing a high brightness long afterglow light emitting yarn.

In the present invention, the photoluminescent light emitting material is a compound represented by MAl₂O₄, M is a compound of at least one or more metal elements in the group consisting of Ca, Sr, Ba as a parent crystal, Mg can be added to M As the activator, Eu is added, and a photoluminescent luminous material may be added, and a synthetic resin having a chemical fiber ability is chemically synthesized from petroleum such as polyester or nylon. Synthetic fiber made from the material made from it, recycled fiber made from raw materials made by chemical treatment of fiber containing wood or protein such as rayon or cupra, and cellulose and rubber such as acetate or cellulose. Organic fibers including semi-synthetic fibers made from raw materials such as chemicals applied to raw materials, and inorganic materials such as glass Books made include those of inorganic fibers such use. In addition, the present invention includes that the prepared high-brightness long afterglow light emitting yarn has a volume ratio of 1/1 to 1/4 of a portion containing a photoluminescent light emitting material and a portion thereof.

Hereinafter, a preferred embodiment of the method of manufacturing a high brightness long afterglow light emitting yarn according to the present invention will be described in more detail based on the accompanying drawings.

1 is a process chart according to an embodiment of the present invention, Figure 2 is an enlarged cross-sectional view of the main portion of a high brightness long-afterglow light-emitting yarn according to the present invention. 1 and 2, first, the 3 to 55 weight ratio (%) of the photoluminescent luminescent raw material (A) and the 45 to 97 weight ratio (%) of the synthetic resin (B) having a chemical fiber capability are mixed. At this time, the photoluminescent light emitting material (A) is a compound represented by MAl₂O₄, M is a compound of at least one or more metal elements in the group consisting of Ca, Sr, Ba as a parent crystal, Mg may be added to M As the activator, Eu may be added, and a photoluminescent luminous material may be added. A synthetic resin (B) having chemical fiber capability may be petroleum such as polyester or nylon. Synthetic fibers made from chemically synthesized materials, etc., and fibres containing wood or protein such as Rayon and Cuprammonium Rayon. Fibers and semi-synthetic fibers made from raw materials obtained by reacting chemicals to raw materials such as cellulose and rubber, such as acetate and cellulose. The inorganic fibers and the like are used are made from inorganic materials such as organic fibers and, glass.

When the phosphorescent light emitting raw material (A) 3 to 55% by weight (%) and the synthetic resin (B) having a chemical fiber capacity (B) 45 to 97% by weight (%) are mixed, a light emitting chip is manufactured using an extrusion system (Extrusion Pelletizer). When the photoluminescent light emitting material (A) and the synthetic resin (B) having chemical fiber capability are manufactured as the light emitting chip by the extrusion system, the composite resin and the light emitting chip used in manufacturing the light emitting chip are coated and extruded using a complex spinning system to achieve high brightness. It is manufactured from a long afterglow luminescent yarn (C). At this time, the prepared high-brightness long afterglow light-emitting yarn (C) is preferably made of a volume ratio of the portion containing the photoluminescent light emitting material (A) and the portion that is not.

When the high brightness long afterglow light emitting yarn (C) manufactured as described above is irradiated with a stimulus source (light) from the outside, the stimulus source (light) is collected in the luminescent light emitting material (A) contained in the yarn and emits light. At this time, the luminance emitted is to increase the luminance by the spatial action of the yarn coating the portion, the luminance is increased. In other words, the light generated by the high brightness long afterglow light emitting yarn (C) is irradiated by the refraction of the light on the coated portion (reflection: the light hits an object on a rough surface and scatters in all directions). It is to promote the enhancement of the luminous brightness.

As described above, the manufacturing method of the high brightness long afterglow light emitting yarn according to the present invention is prepared by manufacturing a light emitting chip and a light emitting chip after manufacturing a synthetic resin having a photoluminescent light emitting material and a chemical fiber capability using an extrusion system. Synthetic resin used in the coating is configured to be coated and extruded using the composite spinning system, which can emit light with high brightness for a long time, and has the effect of emitting light in various colors.

Claims (3)

A mixing process of mixing 3 to 55 weight ratio (%) of the photoluminescent luminescent material and 45 to 97 weight ratio (%) of the synthetic resin having a chemical fiber ability; A light emitting chip manufacturing process in which the photoluminescent light emitting material mixed in the mixing process and a synthetic resin having chemical fiber capability are manufactured as light emitting chips by an extrusion system; The method of manufacturing a high brightness long afterglow light emitting yarn, characterized in that the coating resin extrusion process is made by coating the synthetic resin and the light emitting chip used in manufacturing the light emitting chip. The method of claim 1, The photoluminescent light emitting material is a compound represented by MAl₂O₄, M is a compound of at least one or more metal elements in the group consisting of Ca, Sr, Ba as a mother crystal, Mg may be added to M, and as an activator Phosphorescent luminescent raw materials can be used to add Eu and to study agents. Synthetic resins with chemical fiber capability are made from chemically synthesized materials such as polyester or nylon and petroleum. Chemicals are used in regenerated fibers made from raw materials made by chemical treatment of fibers, such as rayon and cupra, which contain wood or protein, and chemicals such as cellulose and rubber, such as acetate and cellulose. Radish made from organic fibers including semi-synthetic fibers made from raw materials made of chemicals, and inorganic materials such as glass A method of manufacturing a high brightness long afterglow light emitting yarn, characterized in that a base fiber or the like is used. The method of claim 1, The prepared high brightness long afterglow light emitting yarn is a method of manufacturing a high brightness long afterglow light emitting yarn, characterized in that the volume ratio of the portion containing the photoluminescent light emitting material and the other portion is 1/1 to 1/4.