TW201634780A - Production method, processing tool and product of high-toughness light reflecting yarn - Google Patents

Abstract

This invention aims at providing a production method, processing tool and product of a high-toughness light reflecting yarn which is high in production speed, low in defective rate, good in light reflecting effect and durable. The production method comprises the steps: providing several high-toughness yarns, introducing a first glass light reflecting microparticle hot-melt film and a second glass light reflecting microparticle hot-melt film at the upper and lower sides of the high-toughness yarns through the processing tool, and respectively carrying out first baking and heating and second baking and heating to ensure that an adhesive of the first glass light reflecting microparticle hot-melt film and the second glass light reflecting microparticle hot-melt film is melted to be stably transferred and attached to the upper and lower side surfaces of the high-toughness yarns, wherein the adhesive contains glass light reflecting microparticles, so that the surfaces of the high-toughness yarns are to be attached with the glass light reflecting microparticles, then, the high-toughness yarns are output strip by strip and are reeled to finally form the high-toughness light reflecting yarn. The high-toughness light reflecting yarn is composed of the high-toughness yarns, the adhesive uniformly attached and fixed onto the surfaces of the high-toughness yarns and the glass light reflecting microparticles.

Description

High-toughness reflective yarn manufacturing method, processing machine and product thereof

The invention relates to a high toughness reflective yarn manufacturing method, a processing machine and a product thereof, in particular to a yarn manufacturing method capable of producing a reflective effect and a yarn which can be applied to a daily necessities.

Workers who work in the morning and at night, such as traffic police, cleaning staff, roads or construction workers, and sportsmen who often work in the morning or at night, must be in a poorly sighted, dimly lit environment. Work or exercise, because there are vehicles on the road, in the case of poor lighting, it is easy to cause accidental traffic accidents caused by work or sports personnel being hit by vehicles due to temporary negligence.

Therefore, some predecessors invented reflective cloth, which is to sew a number of anti-lights on the clothes to remind the driver of the vehicle, but the traditional anti-light is made of PET polyester, which is limited by the fragility of its own material. When combined with clothing, there are many restrictions. For example, when the cloth is too small and too thin, the failure rate will be greatly increased during the sewing process, and the anti-light strip has a short service life, which is easy to age and break and lose the original effect. It must be replaced every once in a while.

In view of the above, it is a subject of the present invention to provide a high-toughness reflective yarn manufacturing method, a processing tool and a product thereof which can solve the above problems.

The object of the present invention is to provide a high-toughness reflective yarn making method, a processing machine and a product thereof which can be quickly produced, have low defect rate, high finished product, good toughness, good reflective effect, wide application and durability.

In order to solve the above problems and achieve the object of the present invention, the technical means of the present invention is In this way, in the manufacturing method of the high-toughness reflective yarn, a plurality of high-toughness yarns (1) are provided and introduced into a processing tool (100); first, the above-mentioned high-toughness yarns (1) are transmitted through After the first conveyor wheel set (103) at the front end of the processing tool (100) is pulled, it is moved at equal intervals side by side toward the rear end of the processing tool (100), and under the high toughness yarn (1) Introducing a first glass reflective fine particle hot melt film (2), the first glass reflective fine particle hot melt film (2) is transmitted through the first transport wheel set (103) corresponding to each of the high toughness yarns (1) The lower side surface is in close contact and continuously moves toward the rear end of the processing tool (100) after the contact; then, the above high-toughness yarns (1) and the first glass-reflecting fine particle hot-melt film ( 2) simultaneously introducing into the first baking box (101) of the processing tool (100), performing the first baking heating, so that the glue (11) on the one-side surface of the first glass reflective fine particle hot melt film (2) is generated. Melting; subsequently, the high tenacity yarn (1) and the first glass reflective microparticles are passed through a second transport wheel set (104) in the processing tool (100) The melt film (2) is guided by the first baking box (101) and then continuously moved toward the rear end of the processing tool (100); at this time, the upper side of each high-toughness yarn (1) is introduced. a second glass reflective fine particle hot melt film (3), the second glass reflective fine particle hot melt film (3) is transmitted through the second transport wheel set (104) to the upper surface corresponding to each of the high tenacity yarns (1) In close contact, and continuously moving toward the rear end of the processing tool (100) after the contact; then, the high-tough yarns contacting the first and second glass reflective fine particles hot melt films (2), (3) The wire (1) is simultaneously introduced into the second baking box (102) of the processing tool (100) for a second baking heating, which causes the first and second glass reflective fine particles to be hot melted (2), ( 3) the inner surface adhesive (11) in contact with the high tenacity yarn (1) is thermally melted; after being connected, the first and second glass reflective fine particles are melted through the third transport wheel set (105). (2), (3) simultaneously guiding the high-toughness yarn (1) from the second baking box (102), and thermally melting the second glass-reflecting fine particles through the third conveying wheel set (105) Membrane (3) heat The adhesive (11) is transferred to the upper surface of each of the high-toughness yarns (1), and the glass reflective fine particles (10) contained in the adhesive (11) are firmly and uniformly attached to the respective high toughness. yarn The upper surface of the wire (1); at the same time, the second glass reflective fine particle hot melt film (3) after transfer becomes a release paper (3'), which is rolled up after passing through the third transfer wheel set (107). The wheel (111) is wound up, and each of the high tenacity yarns (1) and the first glass reflective fine particle hot melt film (2) continue to move toward the rear end of the processing tool (100); and then, the above The high tenacity yarn (1) and the first glass reflective fine particle hot melt film (2) are passed through the fourth transport wheel set (106), and the first glass reflective fine particle hot melt film (2) is hot melted (11) Transferring to the lower surface of each of the high-toughness yarns (1), and adhering the glass reflective fine particles (10) contained in the adhesive (11) to the high-toughness yarns stably and uniformly together ( 1) the lower side surface; at the same time, the first glass reflective fine particle hot melt film (2) after transfer becomes the release paper (2'), and the lower reel (after the fourth transport wheel set (106)) 112) Retracted; at this time, the high-toughness yarn (1) has become a high-toughness reflective yarn (200) with adhesive (11) and glass reflective particles (10) attached to the upper and lower sides, and continues to be processed. Machine (10 0) moving in the rear end direction; then, the high-toughness reflective yarn (200) is divided by the slitting wheel set (109) of the processing tool (100) to form independent and non-sticky high-toughness reflective Yarn (200); Finally, the high-toughness reflective yarns (200), which are independent and non-adhesive, are separately diffused through the expanding wheel set (110) at the end of the processing tool (100) and individually wound up.

More preferably, the pressure wheel sets (107), (108) are respectively disposed in front of and/or behind the fourth transport wheel set (106) to respectively adhere the adhesive adhered to the surface of the high tenacity yarn (1). (11) The glass reflective fine particles (10) are pressed to be closely adhered to the upper and lower surfaces of the high-toughness yarn (1).

More preferably, the first glass reflective fine particle hot melt film (2) and the second glass reflective fine particle hot melt film (3) are reflective papers produced by Minnesota Mining and Manufacturing Co., Ltd., and the reflective paper is soft. The one-side surface of the plastic film (12) is coated with a layer of hot-melt glue (11), and the glue (11) contains a plurality of glass-reflecting particles (10).

More preferably, the first to fourth transport wheel sets (103), (104), (105), (106) is the twisting method of the above two rounds of clamping, and the applied pressure ranges from 2.5 to 3.5 kg.

More preferably, the first and second baking boxes (101), (102) have a baking heating temperature ranging from 100 ° C to 120 ° C, and the length of the two baking boxes is at least 1 m. More preferably, when the plurality of high-toughness yarns (1) are introduced into the four conveying wheel sets (103), (104), (105), (106), the side-by-side spacing between the yarns is 200 μm. And the rim surface of each of the conveying wheel sets has a plurality of parallel-stitched grooves for embedding the high-toughness yarn (1) to guide it to advance linearly.

In the processing tool for high-toughness reflective yarn, the processing tool (100) is arranged from front to back in sequence: the guide wheel set (113) is composed of a plurality of guide wheels for pulling the high-toughness yarn (1) The first conveying wheel set (103) is composed of upper and lower clamping wheels for guiding and conveying the high-toughness yarn (1) and the first glass reflective fine particle hot-melting film (2); the first baking a box (101) for heating the glue of the first glass reflective fine particle hot melt film (2); the second transport wheel set (104) is composed of upper and lower pinch wheels for guiding and conveying High tenacity yarn (1) and first and second glass reflective fine particles hot melt film (2), (3); second baking box (102) for first and second glass reflective fine particles hot melt film (2), (3) the glue melting heater; the third conveying wheel set (105) is composed of upper and lower clamping wheels for guiding and conveying the high-toughness yarn (1) and the first and the first Two glass reflective fine particles hot melt film (2), (3); the fourth transfer wheel set (106) is composed of upper and lower pinch wheels for guiding and conveying high toughness yarns (1) and first and second Two glass reflective fine particles hot melt film (2), (3); a slitting wheel set (109) for dividing the side-by-side high-toughness reflective yarn (200) into separate upper and lower symmetrical cutter wheels; and an expansion wheel (110) for guiding and diffusing the high-toughness reflective yarn ( 200) upper and lower guide wheels.

More preferably, the front and/or the rear of the fourth transport wheel set (106) are respectively provided for pressing and fixing the adhesive (11) and the plurality of glass reflective fine particles (10) on the high-toughness yarn (1). The pressure wheel sets (107) and (108) on the upper and lower sides.

In the aspect of the product of the high-toughness reflective yarn, the high-toughness reflective yarn (200) is composed of: a plurality of high-toughness yarns (1) composed of a single strand; and uniformly attached and fixed to the high-toughness yarn described above. (1) The outer surface of the adhesive (11) and a plurality of glass reflective fine particles (10); the high-toughness yarn (1) is a nylon yarn having a diameter ranging from 150 to 200 μm; the glass reflective particles ( 10) The particle size ranges from 200 to 270 mesh.

Compared with the prior art, the functions and effects of the present invention are as follows:

First point: The invention provides a method for preparing a high-toughness reflective yarn, which can effectively make the first and second glass reflective fine particles hot melt film (2), (3) adhesive (11) and glass reflective fine particles ( 10), it adheres stably and quickly to the surface of the high-toughness yarn (1), and there is no problem that it will fall off easily after attaching the glass reflective particles (10), and the overall reflective effect is good, achieving high-quality reflective level. .

The second point: in the high-toughness reflective yarn (200) of the present invention, the high-toughness yarn (1) is a nylon yarn, which can provide sufficient toughness, and effectively solves the problem that the conventional anti-light strip of the existing application is easy to break and bear low force. The shortcomings of short life, and can also be directly applied to sewing clothes or woven fabrics, and can be used as general yarns, so the application range is extremely wide.

1‧‧‧High toughness yarn

2‧‧‧First glass reflective microparticle hot melt film

3‧‧‧Second glass reflective microparticle hot melt film

100‧‧‧Processing tools

101‧‧‧First baking box

102‧‧‧second oven

103‧‧‧First conveyor wheel set

104‧‧‧Second transport wheel set

105‧‧‧ Third conveyor wheel set

106‧‧‧Fourth conveyor wheel set

107‧‧‧Pressure wheel set

108‧‧‧Pressure wheel set

109‧‧‧ slitting wheel set

110‧‧‧Expanded wheel set

111‧‧‧Up roll

112‧‧‧Reel

113‧‧‧guide wheel set

200‧‧‧High toughness reflective yarn

10‧‧‧Glass Reflective Microparticles

11‧‧‧Viscos

12‧‧‧Soft plastic film

A‧‧‧Some enlarged view

B‧‧‧Part enlarged view

C‧‧‧Some enlarged view

Figure 1 is a schematic side view showing the flow of the manufacturing method of the present invention.

Fig. 2 is a schematic plan view showing the flow of the manufacturing method of the present invention.

Figure 3: A partially enlarged schematic view of a glass-reflective fine particle hot melt film.

Fig. 4 is an enlarged schematic view of a portion A in Fig. 1.

Fig. 5 is an enlarged schematic view of a portion B in Fig. 1.

Fig. 6 is an enlarged schematic view of a portion C in Fig. 1.

Figure 7 is a perspective view of the article of the invention.

Figure 8 is a schematic perspective view of the article of the invention.

Figure 9 is a schematic illustration of another perspective embodiment of the article of the invention.

The following is a detailed description of the embodiment shown in the drawings. As shown in the figures 1, 2, 4-6, the figure discloses a method for manufacturing a high-toughness reflective yarn, which comprises: providing a plurality of high toughness Yarn (1) is introduced into a processing tool (100); first, after the above-mentioned high-toughness yarns (1) are pulled through the first conveying wheel set (103) at the front end of the processing tool (100), The first glass reflective fine particle hot melt film (2) is introduced at a lower side of the high-toughness yarn (1), and is moved at equal intervals to the rear end of the processing tool (100), and the first glass is reflective. The microparticle hot melt film (2) is in close contact with the lower surface corresponding to each of the above high tenacity yarns (1) through the first transport wheel set (103), and continues to face the processing tool (100) after contact. Moving in the rear end direction; then, the above-mentioned high-toughness yarns (1) and the first glass-reflecting fine particle hot-melt film (2) that are in contact are simultaneously introduced into the first baking box (101) of the processing tool (100). , performing the first baking heating to melt the adhesive (11) on the one-side surface of the first glass reflective fine particle hot melt film (2); a second transport wheel set (104) in the processing tool (100), the high tenacity yarn (1) and the first glass reflective fine particle hot melt film (2) are guided by the first baking box (101) And then continuously moving toward the rear end of the processing tool (100); at this time, a second glass reflective fine particle hot melt film (3) is introduced at the upper side of each of the high tenacity yarns (1), and the second glass reflective fine particles The hot melt film (3) is in close contact with the upper side surface of each of the high tenacity yarns (1) through the second transport wheel set (104), and continues to the rear end of the processing tool (100) after the contact. Moving; then, each of the high-toughness yarns (1) contacting the first and second glass reflective fine particle hot melt films (2), (3) is simultaneously introduced into the second baking box of the processing tool (100) ( 102), performing a second baking heating, which causes the inner surface adhesives of the first and second glass reflective fine particle hot melt films (2), (3) to contact the high tenacity yarn (1) ( 11) generating hot melt; after only connecting, the first and second glass reflective fine particle hot melt films (2), (3) and the high toughness yarn (1) are simultaneously passed through the third transport wheel set (105) Second baking box (102) guiding the plastic glue (11) which is hot-melted by the second glass reflective fine particle hot melt film (3) through the third transport wheel set (105) to each high-toughness yarn (1) ) the upper surface and the glass reflective in the adhesive (11) The particles (10) are stably and evenly attached to the upper surface of the high-toughness yarns (1); at the same time, the second glass-reflecting fine particles of the transferred hot melt film (3) become a release paper (3') After passing through the third transport wheel set (107), it is taken up by an upper reel (111), and each of the high-toughness yarns (1) and the first glass reflective fine-particle hot melt film (2) continue to be processed. Moving the rear end of the implement (100); and then, the first high-toughness yarn (1) and the first glass-reflecting fine particle hot melt film (2) are transmitted through the fourth transport wheel set (106) to make the first Glass-reflecting fine particles hot melt film (2) The hot-melt adhesive (11) is transferred to the lower surface of each of the high-toughness yarns (1), and the glass reflective particles contained in the adhesive (11) are 10) firmly and uniformly attached to the lower surface of each of the high tenacity yarns (1); at the same time, the first glass reflective fine particle hot melt film (2) after transfer becomes a release paper (2'), After passing through the fourth transfer wheel set (106), it is retracted by the lower reel (112); at this time, the high-toughness yarn (1) has become adhered to the upper and lower sides with adhesive (11) and glass reflective particles (10). ) The high-toughness reflective yarn (200) continues to move toward the rear end of the processing tool (100); then, the high-toughness reflective yarn (200) is passed through the slitting wheel set of the processing tool (100) (109) Dividing to form independent and non-sticky high-toughness reflective yarns (200), as shown in Figure 7; finally, the expanding wheel sets (110) through the end of the processing tool (100) will be independent and mutually The non-sticky high-toughness reflective yarns (200) are separately spread and individually wound up.

Highly tough reflective yarn can be produced quickly and easily by this manufacturing method (200), and the processing optics (100) allows the first and second glass reflective fine particle hot melt films (2), (3) the glass reflective fine particles (10) to continuously adhere to the high toughness yarn (1) Corresponding to the upper and lower sides, the high-toughness yarn (1) becomes a high-toughness reflective yarn (200), and the high-toughness yarn (1) has a good reflection effect on the entire circumference, and can be like a general yarn. Apply the same.

Secondly, because the glass reflective particles (10) are baked and adhered to the high-toughness yarn On the line (1), there is no need to worry about the problem that the glass reflective particles (10) will easily peel off, and can be washed or dried. It is different from the general application of traditional anti-light, and can be kept clean and free from worry. Stinky or unclean problems are beneficial for long-term applications.

In the above, the front and/or the rear of the fourth transport wheel set (106) are respectively set The pressure wheel sets (107) and (108) respectively press the glue (11) and the glass reflective fine particles (10) attached to the surface of the high-toughness yarn (1) so as to be closely attached and fixed at a high level. The upper and lower surfaces of the tough yarn (1); the high-toughness yarn (1) and the first and second glass-reflecting fine-particle hot melt films (2), (3) are brought into close contact by pressurization.

In the above, the first glass reflective fine particle hot melt film (2) and the second glass reflective micro The particle hot melt film (3) is a reflective paper made by the Minnesota Mining and Manufacturing Company (3M Company). The reflective paper structure is shown in Figure 3. It is coated on the one side of the soft plastic film (12). The glue (11) melted in the heat, and the glue (11) contains a plurality of glass reflective particles (10).

In the above, the first to fourth transport wheel sets (103), (104), (105), (106) It is the above two rounds of clamping, and the pressure is in the range of 2.5-3.5kg. By this light pressure, the glass reflective particles (10) can be easily attached to the high-toughness yarn (1). The surface, while avoiding excessive contact, causes the glass reflective particles (10) to be stacked together or to reduce the adhesion.

In the above, the baking and heating temperature ranges of the first and second baking boxes (101) and (102) The length of the two baking boxes is at least 1 m from 100 ° C to 120 ° C; according to the above, different glass heating particles are used to make the glass reflective particles (10) adhere to the surface of the high-toughness yarn (1) more stably and uniformly. It makes it less easy to fall off; the length of the oven is designed to provide enough baking time to provide enough heat to allow the glass reflective particles (10) to be quickly fixed to the surface of the high-toughness yarn (1).

In the above, the plurality of high-toughness yarns (1) are introduced into the four conveyor wheels (103), (104), (105), (106), the side-by-side spacing between the yarns is 200 μm; and the rim surface of each conveyor wheel set has a plurality of parallel-stitched grooves for embedding high-toughness yarns. (1) Guide it in a straight line. Moreover, the first and second glass reflective particles can be applied by the application of four transport wheel sets The hot melt films (2) and (3) are pressurized so that the glass reflective particles (10) of both of them can be surely bonded to the surface of the high tenacity yarn (1).

Hereinafter, the processing tool (100) for manufacturing a high-toughness reflective yarn of the present invention will be described. As shown in Figs. 1 and 2, the configuration is sequentially arranged from the front to the rear of the processing tool (100): a guide wheel set (113). ) is composed of a plurality of guide wheels for pulling high-toughness yarns (1); the first conveyor wheel set (103) is composed of upper and lower pinch wheels for guiding and conveying high-toughness yarns ( 1) and a first glass reflective fine particle hot melt film (2); a first baking box (101), a heater for melting the glue of the first glass reflective fine particle hot melt film (2); a second conveying wheel The group (104) is composed of upper and lower pinch wheels for guiding and conveying the high-toughness yarn (1) and the first and second glass-reflecting fine particles hot-melt film (2), (3); the second baking a box (102), a heater for melting the first and second glass reflective fine particle hot melt films (2), (3); the third transport wheel set (105) is composed of upper and lower pinch wheels , for guiding and conveying high-toughness yarn (1) and first and second glass reflective micro-particle hot melt film (2), (3); fourth conveying wheel set (106), which is composed of upper and lower clamping wheels For guiding and conveying high-toughness yarns (1 And first and second glass reflective fine particles hot melt film (2), (3); slitting wheel set (109) for dividing the side-by-side high-toughness reflective yarn (200) into separate upper and lower symmetrical knives a wheel; and an expansion wheel (110) for guiding and diffusing the upper and lower guide wheels of the high toughness reflective yarn (200).

The front side and/or the rear side of the fourth transport wheel set (106) are respectively provided for pressing and fixing the adhesive (11) and the plurality of glass reflective fine particles (10) on the upper and lower sides of the high-toughness yarn (1). Pressurized wheel sets (107), (108).

The high-toughness reflective yarn (200) of the present invention comprises: a plurality of high-toughness yarns (1) composed of a plurality of strands; and a glue uniformly adhered and fixed to the outer peripheral surface of the high-toughness yarn (1) (11) And a plurality of glass reflective fine particles (10); the high-toughness yarn (1) is a nylon yarn having a diameter ranging from 150 to 200 μm; and the glass reflective fine particles (10) having a particle size ranging from 200 to 270 mesh.

By using the high-toughness reflective yarn (200), it can be different from the conventional anti-light, and can be applied to the sewing clothes as shown in Fig. 8 or the woven fabric as shown in Fig. 9, which is not easy to be broken, and can be easily broken. With greater force, the application range is wider, there will be no protruding and awkward problems in implementation, and it will be applied like general clothing and weaving.

The embodiments, features, and effects of the present invention are described in detail above with reference to the embodiments shown in the drawings. However, the above description is only a preferred embodiment of the present invention, but the present invention is not limited to the scope of the present invention. Modifications that are consistent with the intent of the present invention are intended to fall within the scope of the invention as long as they are within the scope of the invention.

1‧‧‧High toughness yarn

2‧‧‧First glass reflective microparticle hot melt film

3‧‧‧Second glass reflective microparticle hot melt film

100‧‧‧Processing tools

101‧‧‧First baking box

102‧‧‧second oven

103‧‧‧First conveyor wheel set

104‧‧‧Second transport wheel set

105‧‧‧ Third conveyor wheel set

106‧‧‧Fourth conveyor wheel set

107‧‧‧Pressure wheel set

108‧‧‧Pressure wheel set

109‧‧‧ slitting wheel set

110‧‧‧Expanded wheel set

111‧‧‧Up roll

112‧‧‧Reel

113‧‧‧guide wheel set

200‧‧‧High toughness reflective yarn

Claims (9)

A method for producing a high-toughness reflective yarn, comprising: providing a plurality of high-toughness yarns (1) and introducing them into a processing tool (100); first, passing the above-mentioned high-toughness yarns (1) After the first conveyor wheel set (103) at the front end of the processing tool (100) is pulled, it is moved at equal intervals side by side toward the rear end of the processing tool (100), and under the high toughness yarn (1) Introducing a first glass reflective fine particle hot melt film (2), the first glass reflective fine particle hot melt film (2) is transmitted through the first transport wheel set (103) corresponding to each of the high toughness yarns (1) The lower side surface is in close contact and continuously moves toward the rear end of the processing tool (100) after the contact; then, the above high-toughness yarns (1) and the first glass-reflecting fine particle hot-melt film ( 2) simultaneously introducing into the first baking box (101) of the processing tool (100), performing the first baking heating, so that the glue (11) on the one-side surface of the first glass reflective fine particle hot melt film (2) is generated. Melting; subsequently, the high tenacity yarn (1) and the first glass reflective particle are passed through a second conveyor wheel set (104) in the processing tool (100) The hot melt film (2) is guided by the first baking box (101) and then continuously moved toward the rear end of the processing tool (100); at this time, at the upper side of each of the high toughness yarns (1) Introducing a second glass reflective fine particle hot melt film (3), the second glass reflective fine particle hot melt film (3) is an upper surface corresponding to each of the high tenacity yarns (1) through the second transfer wheel set (104) Performing close contact and continuously moving toward the rear end of the processing tool (100) after contact; then, the high toughness of the above-mentioned first and second glass reflective fine particle hot melt films (2), (3) The yarn (1) is simultaneously introduced into the second baking box (102) of the processing tool (100) for a second baking heating, so that the first and second glass reflective fine particles are melted (2), (3) the inner surface adhesive (11) in contact with the high-toughness yarn (1) is thermally melted; after being connected, the first and second glass reflective fine particles are thermally fused through the third transport wheel set (105). The film (2), (3) and the high-toughness yarn (1) are simultaneously guided by the second baking box (102), and are transmitted through The third transport wheel set (105) transfers the above-mentioned second glass reflective fine particle hot melt film (3) hot-melt adhesive (11) to the upper surface of each high-toughness yarn (1), and makes the adhesive ( The glass reflective fine particles (10) contained in 11) are firmly and uniformly adhered to the upper surface of each of the high tenacity yarns (1); at the same time, the second glass reflective fine particle hot melt film after transfer (3) ) becomes a release paper (3'), which is taken up by a winding reel (111) after passing through the third conveying wheel set (107), and each of the high-toughness yarns (1) and the first glass-reflecting fine particles are thermally melted. The film (2) continues to move toward the rear end of the processing tool (100); and then, the high-toughness yarns (1) and the first glass-reflecting fine particles (2) are transmitted through the fourth conveying wheel set ( 106), the adhesive (11) for thermally melting the first glass reflective fine particle hot melt film (2) is transferred to the lower surface of each of the high tenacity yarns (1), and the adhesive (11) is obtained. The glass reflective fine particles (10) contained in the same are firmly and uniformly adhered to the lower surface of the high-toughness yarn (1); at the same time, the first glass reflective fine particle hot melt film after transfer (2) Become away The type paper (2') is retracted by the lower reel (112) after passing through the fourth transport wheel set (106); at this time, the high-toughness yarn (1) has become adhered to the upper and lower sides with adhesive (11). a high-toughness reflective yarn (200) with glass reflective particles (10), and still moving toward the rear end of the processing tool (100); and then passing the high-toughness reflective yarn (200) through the processing tool (100) The slitting wheel set (109) is divided to form independent and non-sticky high-toughness reflective yarns (200); finally, the expanding wheel sets (110) passing through the end of the processing tool (100) are independent and The non-tacky high-toughness reflective yarns (200) are spread out and individually wound up. The method for manufacturing a high-toughness reflective yarn according to claim 1, wherein the pressure wheel sets (107) and (108) are respectively disposed in front of and/or behind the fourth transport wheel set (106) to respectively adhere The adhesive (11) and the glass reflective fine particles (10) on the surface of the high-toughness yarn (1) are pressed to be closely adhered to the upper and lower surfaces of the high-toughness yarn (1). The method for producing a high-toughness reflective yarn according to claim 1, wherein the first glass is reflective The particle hot melt film (2) and the second glass reflective fine particle hot melt film (3) are reflective papers produced by the Minnesota Mining and Manufacturing Company of the United States, and the reflective paper is coated on the one side surface of the soft plastic film (12). A layer of hot melted glue (11), the glue (11) containing a plurality of glass reflective particles (10). The method for producing a high-toughness reflective yarn according to claim 1, wherein the first to fourth conveying wheel sets (103), (104), (105), and (106) are crimped by the upper and lower wheels. The mode is carried out, and the applied pressure ranges from 2.5 to 3.5 kg. The method for preparing a high-toughness reflective yarn according to claim 1, wherein the first and second baking boxes (101), (102) have a baking heating temperature ranging from 100 ° C to 120 ° C, and two baking The length of the box is at least 1m. The method for producing a high-toughness reflective yarn according to claim 1, wherein the plurality of high-toughness yarns (1) are introduced into four conveying wheel sets (103), (104), (105), (106) The side-by-side spacing between the yarns is 200 μm; and the rim surface of each of the conveyor wheels has a plurality of parallel-stitched grooves for embedding the high-toughness yarn (1) to guide its linear advancement. A processing tool for a high-toughness reflective yarn, which is a processing tool (100) provided according to the manufacturing method of the high-toughness reflective yarn according to claim 1, which is arranged from front to back in sequence: a guide wheel set (113) is a plurality of guide wheels for drawing high-toughness yarns (1); the first conveyor wheel set (103) is composed of upper and lower pinch wheels for guiding and conveying high-toughness yarns (1) and a glass reflective fine particle hot melt film (2); a first baking box (101), a heater for melting the glue of the first glass reflective fine particle hot melt film (2); a second conveying wheel set (104) It is composed of upper and lower pinch wheels for guiding and conveying high-toughness yarn (1) and first and second glass-reflecting fine particles hot-melt film (2), (3); second baking box (102) For bonding the first and second glass reflective fine particles hot melt film (2), (3) a rubber melted heater; the third transport wheel set (105) is composed of upper and lower pinch wheels for guiding and conveying the high-toughness yarn (1) and the first and second glass reflective fine particles hot melt film (2) And (3); the fourth conveying wheel set (106) is composed of upper and lower clamping wheels for guiding and conveying the high-toughness yarn (1) and the first and second glass reflective fine particles hot melt film (2) (3); a slitting wheel set (109) for dividing the side-by-side high-toughness reflective yarn (200) into separate upper and lower symmetrical cutter wheels; and an expansion wheel (110) for guiding and diffusing Upper and lower guide wheels of high toughness reflective yarn (200). The high toughness reflective yarn processing tool according to claim 7, wherein the front and/or the rear of the fourth conveying wheel set (106) are respectively provided for bonding the adhesive (11) and the plurality of glass reflective particles. (10) Pressing the pressure wheel sets (107) and (108) fixed to the upper and lower sides of the high-toughness yarn (1). A high-toughness reflective yarn (200) made of the high-toughness reflective yarn manufacturing method according to claim 1, which comprises: a plurality of high-toughness yarns (1) composed of a plurality of strands; a viscose (11) uniformly attached to and fixed to the outer surface of the high-toughness yarn (1) and a plurality of glass reflective particles (10); the high-toughness yarn (1) is a nylon yarn having a diameter range At 150 to 200 μm; the above-mentioned glass reflective fine particles (10) have a particle size ranging from 200 to 270 mesh.