CN115182118B - Intelligent drying tunnel device for glass fiber pretreatment in colloidal gold lateral chromatography test strip - Google Patents

Abstract

The invention discloses an intelligent drying tunnel device for pretreating glass fibers in a colloidal gold lateral chromatography test strip, which comprises an unreeling mechanism, an infiltration mechanism, a drying mechanism, a driving wheel mechanism and a material receiving mechanism which are sequentially arranged, wherein the unreeling mechanism comprises a first rack, an unreeling air-expanding shaft and a first deviation-rectifying assembly, the glass fiber strips produced by unreeling of glass fiber rolls enter the infiltration mechanism after bypassing a first guide roller, the infiltration mechanism comprises a second rack, a solution tank, a liquid inlet peristaltic pump, a liquid outlet peristaltic pump and a pinch roller, the glass fiber strips are led out from a discharge port after bypassing the pinch roller, the drying mechanism comprises three drying ovens which are sequentially arranged along a straight line, the tops of the drying ovens are provided with air inlets and air outlets, the glass fiber strips sequentially pass through the three drying ovens and then enter the driving wheel mechanism, the glass fiber strips are led out from the second deviation-rectifying assembly and then enter a driving assembly, and the glass fiber strips are led out from the driving assembly and then enter the material receiving mechanism. Compared with the prior art, the invention effectively improves the uniformity of the absorption solution during the infiltration processing of the glass fiber raw material and improves the drying efficiency.

Description

Intelligent drying tunnel device for glass fiber pretreatment in colloidal gold lateral chromatography test strip

Technical Field

The invention belongs to the field of test strip processing, and particularly relates to an intelligent drying tunnel device for pretreating glass fibers in a colloidal gold lateral chromatography test strip.

Background

In the field of rapid in vitro diagnosis, test paper is generally adopted to directly detect a sample. The test paper itself is composed of a sample pad, a gold label pad, an NC membrane, absorbent paper and the like. In the process of manufacturing the test paper, all components of the test paper need to be pretreated in advance, and finally the test paper is combined into a complete test paper.

The sample pad and the gold mark pad are made of large rolls of glass fibers with the width of 300mm multiplied by the length of 100m, and the glass fibers are required to fully absorb pretreatment solution through a soaking process and are dried to be used as raw materials of the next process. Specifically, the existing pretreatment process of the glass fiber comprises the following steps: cutting a large roll of glass fiber into 300mm-300mm sheet glass fibers, soaking the sheet glass fibers in a solution tank for a certain time, scraping the product by using a tool manually to enable the product to be soaked uniformly, taking out the product, and putting the product together in a drying room for drying to obtain semi-finished glass fibers.

When the glass fiber is pretreated by adopting the mode, the uniformity of the absorption solution is not enough easily during glass fiber infiltration, namely the solution absorbed by each square centimeter of the product is unstable, and the infiltrated product needs to be transferred to a drying room for drying through manual work, so that the efficiency is low. In addition, when the glass fiber is pretreated by adopting the method, the prepared semi-finished glass fiber product is single in form (only sheet material), and the flexibility of subsequent processing is influenced.

Disclosure of Invention

The invention aims to: the utility model provides a fine intelligent drying tunnel device of glass pretreatment in colloidal gold side direction chromatography test paper strip effectively improves the fine raw materials of glass soaks the homogeneity of adding the man-hour absorption solution, improves drying efficiency, can make the fine semi-manufactured goods glass of different forms simultaneously, the follow-up processing of being convenient for.

In order to achieve the purpose, the invention adopts the following technical scheme: an intelligent drying tunnel device for pretreating glass fibers in colloidal gold lateral chromatography test paper strips comprises an unwinding mechanism, an infiltration mechanism, a drying mechanism, a driving wheel mechanism and a material receiving mechanism which are sequentially arranged, wherein the unwinding mechanism comprises a first rack, an unwinding air-expanding shaft and a first deviation-rectifying assembly, the unwinding air-expanding shaft is rotatably arranged on the first rack, a glass fiber material roll is sleeved on the unwinding air-expanding shaft, the first deviation-rectifying assembly comprises two first guide rollers, a glass fiber strip material generated by unwinding the glass fiber material roll enters the infiltration mechanism after bypassing the first guide rollers, the infiltration mechanism comprises a second rack, a solution tank, a liquid inlet peristaltic pump, a liquid outlet peristaltic pump and a pinch roller, a feed inlet is arranged on one side of the second rack, a discharge outlet is arranged on the opposite side of the second rack, solution is arranged in the solution tank, the liquid inlet peristaltic pump is connected with a liquid inlet of the solution tank, and the liquid outlet peristaltic pump is connected with a liquid outlet of the solution tank, the pinch roller stretches into the solution tank, the fine strip of glass is drawn forth from the discharge gate after walking around the pinch roller, drying mechanism includes and arranges three oven in proper order along the straight line, the oven top is provided with air intake and air outlet, fine strip of glass passes into driving wheel mechanism behind the three oven in proper order, driving wheel mechanism includes the third frame, the second rectifies subassembly and drive assembly, the second rectifies the subassembly and includes two second deflector rolls, fine strip of glass gets into drive assembly after drawing forth from the second subassembly of rectifying, drive assembly includes the support frame, the drive wheel, from the driving wheel, mounting bracket and compressing cylinder, rotatable the installing on the support frame of drive wheel, rotatable the installing on the mounting bracket from the driving wheel, mounting bracket sliding connection is on the support frame, compressing cylinder fixed mounting is on the support frame, the cylinder pole connection mounting bracket that compresses tightly the cylinder, fine strip of glass gets into receiving agencies after drawing forth from drive assembly.

As a further description of the above technical solution:

the unwinding mechanism further comprises a magnetic powder brake, and the magnetic powder brake is fixedly installed at one end of the unwinding air expansion shaft.

As a further description of the above technical solution:

the sectional area of the air inlet is larger than that of the air outlet.

As a further description of the above technical solution:

be provided with the buffer platform between third frame and the receiving agencies, the buffer bench is provided with at least one high low level sensor.

As a further description of the above technical solution:

the receiving mechanism comprises a first receiving sub-mechanism and a second receiving sub-mechanism which are sequentially arranged.

As a further description of the above technical solution:

the first material receiving mechanism comprises a plurality of first guide wheels, a first cutter driving wheel, a cutter assembly, a sheet material receiving bin and a first rolling air expansion shaft, and the sheet material receiving bin is arranged on one side of the cutter assembly.

As a further description of the above technical solution:

first rolling physiosis axle one side sets up the direction subassembly, and the direction subassembly is including being 3 guide arms that "article" style of calligraphy was arranged, and the guide arm is on a parallel with first rolling physiosis axle.

As a further description of the above technical solution:

two limiting blocks are arranged on the guide rod and are connected to the guide rod in a sliding mode.

As a further description of the above technical solution:

the second material receiving sub-mechanism comprises a second cutter driving wheel, a hob assembly, a second winding air expansion shaft and a third winding air expansion shaft, and the position of the second winding air expansion shaft corresponds to that of the device above the third winding air expansion shaft.

In summary, due to the adoption of the technical scheme, the invention has the beneficial effects that:

1. according to the invention, when the glass fiber strip is soaked in the solution, the peristaltic pump is adopted to accurately control the solution amount in the solution tank, meanwhile, the solution keeps flowing, so that the uniformity of the solution is ensured, and the moving speed of the glass fiber strip is controlled to be stable, so that the consistency and stability of the solution amount attached (absorbed) on each centimeter of product are ensured, and the pretreatment quality of the product is ensured.

2. According to the invention, the soaked product is directly dried on line through the drying mechanism without transferring, so that the drying efficiency is effectively improved.

3. In the invention, the material receiving mechanism realizes three types of material receiving through the first material receiving sub-mechanism and the second material receiving sub-mechanism, so that 3 types of semi-finished glass fibers with different forms can be obtained, and the subsequent processing is convenient.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings needed to be used in the embodiments will be briefly described below, it should be understood that the following drawings only illustrate some embodiments of the present invention and therefore should not be considered as limiting the scope, and for those skilled in the art, other related drawings can be obtained according to the drawings without inventive efforts.

FIG. 1 is a perspective view of an intelligent drying tunnel device for glass fiber pretreatment in a colloidal gold lateral chromatography test strip.

FIG. 2 is a schematic diagram of a side view angle structure of an intelligent drying tunnel device for glass fiber pretreatment in a colloidal gold lateral chromatography test strip.

Fig. 3 is a schematic structural diagram of an unwinding mechanism in an intelligent drying tunnel device for pretreating glass fibers in a colloidal gold lateral chromatography test strip.

Fig. 4 is a first structural schematic diagram of an infiltration mechanism in an intelligent drying tunnel device for pretreating glass fibers in a colloidal gold lateral chromatography test strip.

Fig. 5 is a second schematic structural diagram of an infiltration mechanism in an intelligent drying tunnel device for pretreating glass fibers in a colloidal gold lateral chromatography test strip.

Fig. 6 is a schematic structural diagram of a drying mechanism in an intelligent drying tunnel device for pretreating glass fibers in a colloidal gold lateral chromatography test strip.

FIG. 7 is a schematic structural diagram of a driving wheel mechanism in an intelligent drying tunnel device for pretreating glass fibers in a colloidal gold lateral chromatography test strip.

FIG. 8 is a schematic structural diagram of a driving wheel mechanism in an intelligent drying tunnel device for glass fiber pretreatment in a colloidal gold lateral chromatography test strip.

Fig. 9 is a first schematic structural diagram of a first material receiving mechanism in an intelligent drying tunnel device for pretreating glass fibers in a colloidal gold lateral chromatography test strip.

Fig. 10 is a second structural schematic diagram of a first material receiving mechanism in the intelligent drying tunnel device for glass fiber pretreatment in the colloidal gold lateral chromatography test strip.

Fig. 11 is a partial enlarged view of a portion a in fig. 10.

Fig. 12 is a schematic structural diagram of a second material receiving mechanism in an intelligent drying tunnel device for glass fiber pretreatment in a colloidal gold lateral chromatography test strip.

Illustration of the drawings:

1. an unwinding mechanism; 11. a first frame; 12. unwinding an inflatable shaft; 13. a first deviation rectifying assembly; 131. a first guide roller; 14. a magnetic powder brake; 2. an infiltration mechanism; 21. a second frame; 22. a solution tank; 23. a liquid inlet peristaltic pump; 24. a liquid outlet peristaltic pump; 25. a pinch roller; 3. a drying mechanism; 31. an oven; 311. an air inlet; 312. an air outlet; 4. a driving wheel mechanism; 41. a third frame; 42. a second deviation rectifying component; 421. a second guide roller; 43. a drive assembly; 431. a support frame; 432. a drive wheel; 433. a driven wheel; 434. a mounting frame; 435. a pressing cylinder; 44. a cache station; 441. a high-low position sensor; 5. a material receiving mechanism; 51. a first material receiving mechanism; 511. a first guide wheel; 512. a first cutter driving wheel; 513. a cutter assembly; 514. a sheet material receiving bin; 515. a first winding inflatable shaft; 516. a guide assembly; 5161. a guide bar; 5162. A limiting block; 52. a second material receiving mechanism; 521. a second cutter driving wheel; 522. a hob assembly; 523. a second winding air expansion shaft; 524. a third winding air expansion shaft; 6. and (3) winding the glass fiber material.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present invention clearer, 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 some, but not all, embodiments of the present invention. The components of embodiments of the present invention generally described and illustrated in the figures herein may be arranged and designed in a wide variety of different configurations.

Thus, the following detailed description of the embodiments of the present invention, presented in the figures, is not intended to limit the scope of the invention, as claimed, but is merely representative of selected embodiments of the invention. All other embodiments, which can be obtained by a person skilled in the art without inventive step based on the embodiments of the present invention, are within the scope of protection of the present invention.

Referring to fig. 1-12, the present invention provides a technical solution: the utility model provides a fine intelligent drying tunnel device of preliminary treatment of glass in colloidal gold side direction chromatography test paper strip, is including unwinding mechanism 1, infiltration mechanism 2, drying mechanism 3, action wheel mechanism 4 and the receiving agencies 5 who arranges in proper order.

The unwinding mechanism 1 comprises a first rack 11, an unwinding air-inflation shaft 12 and a first deviation rectifying assembly 13, the unwinding air-inflation shaft 12 is rotatably installed on the first rack 11, the glass fiber material roll 6 is sleeved on the unwinding air-inflation shaft 12, the first deviation rectifying assembly 13 comprises two first guide rollers 131, and a glass fiber strip material generated by unwinding of the glass fiber material roll 6 enters the infiltration mechanism 2 after bypassing the first guide rollers 131. During glass fiber pretreatment, the glass fiber material roll 6 is sleeved on the unwinding air-expanding shaft 12, and two ends of the glass fiber material roll 6 are blocked by the chuck on the unwinding air-expanding shaft 12. The chuck on the outer side of the unreeling air expansion shaft 12 can be detached, and the glass fiber material roll 6 is installed after the chuck is detached. The unwinding mechanism 1 further comprises a magnetic powder brake 14, and the magnetic powder brake 14 is fixedly installed at one end of the unwinding air expansion shaft 12. When the glass fiber material roll 6 is unreeled, the magnetic powder brake 14 applies a certain resistance, so that the glass fiber material roll 6 is not loosened when unreeling, but the force cannot be too large, and the breaking is prevented. And the deviation rectification is performed through the deviation rectification wheel (the first guide roller 131), so that the product is ensured to be flat and not to be inclined when being unreeled and discharged.

The infiltrating mechanism 2 comprises a second rack 21, a solution tank 22, a liquid inlet peristaltic pump 23, a liquid outlet peristaltic pump 24 and a pressing wheel 25, wherein a feeding hole is formed in one side of the second rack 21, a discharging hole is formed in the opposite side of the second rack, an infiltrating solution is arranged in the solution tank 22, the liquid inlet peristaltic pump 23 is connected with a liquid inlet of the solution tank 22, the liquid outlet peristaltic pump 24 is connected with a liquid outlet of the solution tank 22, the pressing wheel 25 extends into the solution tank 22, the glass fiber strips are led out from the discharging hole after bypassing the pressing wheel 25, when the solution is infiltrated, the pressing wheel presses the glass fiber strips in the solution tank 22, and the product is infiltrated at a certain speed and then moves forwards. A liquid level sensor is arranged in the solution tank 22 and used for controlling the liquid level in the solution tank 22, the liquid inlet peristaltic pump and the liquid outlet peristaltic pump work simultaneously, the solution is continuously pumped into the solution tank 22 from a solution barrel (not shown in the figure), and meanwhile, the solution is pumped back to the solution barrel from the solution tank 22, so that the solution flow is kept, the uniformity of the solution is ensured, the consistency and the stability of the solution amount attached (absorbed) on each centimeter of products are further ensured, and the pretreatment quality of the products is ensured.

The drying mechanism 3 comprises three drying ovens 31 which are sequentially arranged along a straight line, an air inlet 311 and an air outlet 312 are arranged at the top of each drying oven 31, and the glass fiber strips sequentially pass through the three drying ovens 31 and then enter the driving wheel mechanism 4. During drying, the air conditioning system sends hot air dehumidified by the rotating wheel into the oven 31 from the air inlet 311, the fan of the oven 31 uniformly mixes the hot air and blows the hot air to the product, and the hot air with humidity is sent out from the air outlet 312, so that the hot air circulates to dry the product. Three drying ovens 31 are sequentially arranged in the drying mechanism 3 to form a wet area, a semi-wet area and a dry area, so that the drying effect is ensured.

The sectional area of the air inlet 311 is larger than that of the air outlet 312, so that the air inlet amount is ensured, and the drying efficiency is improved. The side of the oven 31 is provided with a transparent observation window, so that the drying condition of the product can be observed conveniently.

The driving wheel mechanism 4 comprises a third rack 41, a second deviation rectifying assembly 42 and a driving assembly 43, the second deviation rectifying assembly 42 comprises two second guide rollers 421, the glass fiber strip is led out from the second deviation rectifying assembly 42 and then enters the driving assembly 43, the driving assembly 43 comprises a supporting frame 431, a driving wheel 432, a driven wheel 433, an installation frame 434 and a pressing cylinder 435, the driving wheel 432 is rotatably installed on the supporting frame 431, one end of the driving wheel 432 is provided with a servo driving device, the driven wheel 433 is rotatably installed on the installation frame 434, the installation frame 434 is slidably connected onto the supporting frame 431, the pressing cylinder 435 is fixedly installed on the supporting frame 431, a cylinder rod of the pressing cylinder 435 is connected with the installation frame 434, and the glass fiber strip is led out from the driving assembly 43 and then enters the receiving mechanism 5.

The dried product passes through the deviation rectifying wheel (second guide roller 421) and then enters the driving wheel mechanism 4, and the product between the unreeling mechanism 1 and the driving wheel mechanism 4 is pulled by the driving wheel 432. The drive wheel 432 is provided with an encoder at one end to calculate the distance traveled. The pressing cylinder 435 drives the driven wheel 433 to press the product (glass fiber strip) on the driving wheel 432, and the driving wheel 432 rotates to convey the product. Different products need different pressing forces when passing through the driving wheel 432, and the pressing force is obtained by adjusting (pressing the air cylinder 435) the air cylinder force by using a precise pressure adjusting valve. The driving wheel 432 and the driven wheel 433 are kept parallel, so that the products are prevented from deviating in the conveying process.

A buffer table 44 is arranged between the third frame 41 and the material receiving mechanism 5, and 2 high-low sensors 441 are arranged on the buffer table 44. The glass fiber strip can be buffered when coming out of the driving assembly 43, the arranged high-low sensor 441 is used for detecting the height change of the glass fiber strip above, and the unreeling speed is controlled through the detection result of the high-low sensor to control the buffering amount.

The material receiving mechanism 5 includes a first material receiving sub-mechanism 51 and a second material receiving sub-mechanism 52 arranged in sequence. The first material receiving mechanism 51 comprises a plurality of first guide wheels 511, a first cutter driving wheel 512, a cutter assembly 513, a sheet material receiving bin 514 and a first rolling inflatable shaft 515, wherein the sheet material receiving bin 514 is arranged at one side of the cutter assembly 513. The second material receiving mechanism 52 includes a second cutter driving wheel 521, a hob component 522, a second rolling air expansion shaft 523 and a third rolling air expansion shaft 524, and the position of the second rolling air expansion shaft 523 corresponds to the position of the third rolling air expansion shaft 524. The receiving mechanism 5 combines the first receiving mechanism 51 and the second receiving mechanism 52 to receive the glass fibers in three ways, so as to obtain 3 different types of semi-finished glass fibers for subsequent processing.

The first method comprises the following steps: after the glass fiber strip is led out from the first guide wheel 511, the glass fiber strip is conveyed for a fixed length distance through the first cutter driving wheel 512, then the cutter assembly 513 cuts the glass fiber strip through the cutter, and the sheet produced by cutting falls into the sheet collecting bin 514, so as to obtain the semi-finished glass fiber in the form of the sheet.

And the second method comprises the following steps: after the glass fiber strip is led out from the first guide wheel 511, the cutter assembly 513 does not work, and the glass fiber strip is directly rolled by the first rolling air expansion shaft 515 to obtain a semi-finished glass fiber in a wide roll form.

And the third is that: the first material receiving mechanism 51 does not work, and after the glass fiber strip enters the second material receiving mechanism 52, the glass fiber strip is cut into two parts (for example, a 300mm wide product is cut into two 150mm wide products) by the hob assembly 522, one part is wound by the second winding air expanding shaft 523 at the upper part, and the other part is wound by the third winding air expanding shaft 524 at the lower part, so as to obtain a semi-finished glass fiber in a narrow-winding form.

The three receiving modes can not be carried out simultaneously, and the other two receiving modes stop when one receiving mode is carried out.

One side of the first winding air expansion shaft 515 is provided with a guide component 516, the guide component 516 comprises 3 guide rods 5161 which are arranged in a shape like a Chinese character pin, and the guide rods 5161 are parallel to the first winding air expansion shaft 515. Two limiting blocks 5162 are arranged on the guide rod 5161, the limiting blocks 5162 are slidably connected to the guide rod 5161, and the limiting blocks 5162 can be fixed on the guide rod 5161 by bonding or other methods. The glass fiber strip is wound on the first winding air inflation shaft 515 after sequentially bypassing 3 guide rods 5161 of the guide assembly 516, and the limiting block 5162 is fixed after sliding to adjust the position, so that the position of the glass fiber strip bypassing the guide rods 5161 is limited, the deviation rectification of the glass fiber strip can be realized, and the winding effect of the glass fiber strip is ensured.

The working principle is as follows: during glass fiber pretreatment, the glass fiber material roll 6 is firstly sleeved on the unwinding air expansion shaft 12, a glass fiber strip generated by unwinding of the glass fiber material roll 6 enters the infiltration mechanism 2 after bypassing the first guide roller 131, the glass fiber strip is led out from the discharge port after bypassing the pinch roller 25 during infiltration, then enters the oven for drying, products between the unwinding mechanism 1 and the driving wheel mechanism 4 are all pulled by the driving wheel 432, and the glass fiber material roll 6 is led out of the driving wheel mechanism 4 and then is received by the receiving mechanism 5.

The roll-type incoming material in the intelligent drying tunnel device is directly processed without transferring, and time and labor are saved. The intelligent drying tunnel device adopts the form of servo drive and cache adjustment to realize the unreeling and the reeling of materials, and ensures that the materials can not be broken when the walking speed is stable under the high-speed condition. In the infiltration process, a peristaltic pump accurately discharges liquid, the running speed of the product is controlled by a servo system, the content consistency of the solution per square centimeter of the product is ensured, and the product quality is improved. The hot air after the drying oven part adopts the steam to change the ability dehumidification is as admitting air, can effectually take away the moisture of product to can recycle again behind the return air, when having guaranteed the stoving effect, play energy-conserving effect. The equipment is designed with a plurality of receiving possibilities, thereby ensuring the continuation of the prior slicing process and the later change into a full roll type process.

The above description is only for the preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art should be considered as the technical solutions and the inventive concepts of the present invention within the technical scope of the present invention.

Claims (6)

1. The utility model provides a fine preliminary treatment's of colloidal gold side direction chromatography test paper strip intelligence drying tunnel device of glass, its characterized in that, including unwinding mechanism (1), infiltration mechanism (2), drying mechanism (3), drive wheel mechanism (4) and receiving agencies (5) that arrange in proper order, unwinding mechanism (1) includes first frame (11), unreels physiosis axle (12) and first subassembly (13) of rectifying, unreel that physiosis axle (12) is rotatable install on first frame (11), fine material of glass book (6) suit is in unreeling physiosis axle (12), first subassembly (13) of rectifying includes two first deflector rolls (131), fine material of glass book (6) unreel the production is walked around enter behind first deflector roll (131) infiltration mechanism (2), infiltration mechanism (2) includes second frame (21), peristaltic solution groove (22), inlet pump (23), goes out liquid pump (24) and pinch roller (25), second frame (21) one side is provided with the feed inlet, the opposite side is provided with the discharge gate, peristaltic solution groove (22), be provided with the peristaltic pump (22) in the peristaltic pump (22), inlet pump (22) connect the solution tank (22) the inlet solution pump (22) goes into liquid pump (25), the glass fiber strip is led out from the discharge hole after bypassing the pinch roller (25), the drying mechanism (3) comprises three drying ovens (31) which are sequentially arranged along a straight line, the top of the oven (31) is provided with an air inlet (311) and an air outlet (312), the glass fiber strip sequentially passes through the three drying ovens (31) and then enters the driving wheel mechanism (4), the driving wheel mechanism (4) comprises a third frame (41), a second deviation rectifying component (42) and a driving component (43), the second deviation rectifying component (42) comprises two second guide rollers (421), the glass fiber strip is led out from the second deviation rectifying component (42) and then enters the driving component (43), the driving assembly (43) comprises a supporting frame (431), a driving wheel (432), a driven wheel (433), a mounting frame (434) and a pressing cylinder (435), the driving wheel (432) is rotatably arranged on the supporting frame (431), the driven wheel (433) is rotatably arranged on the mounting frame (434), the mounting rack (434) is connected on the supporting frame (431) in a sliding way, the pressing air cylinder (435) is fixedly arranged on the supporting frame (431), the cylinder rod of the pressing cylinder (435) is connected with the mounting frame (434), the glass fiber strip is led out from the driving assembly (43) and then enters the material receiving mechanism (5);

the material receiving mechanism (5) comprises a first material receiving mechanism (51) and a second material receiving mechanism (52) which are sequentially arranged;

the first material receiving mechanism (51) comprises a plurality of first guide wheels (511), a first cutter driving wheel (512), a cutter assembly (513), a sheet material receiving bin (514) and a first winding air expansion shaft (515), and the sheet material receiving bin (514) is arranged on one side of the cutter assembly (513);

the second material receiving mechanism (52) comprises a second cutter driving wheel (521), a hob assembly (522), a second rolling air expansion shaft (523) and a third rolling air expansion shaft (524), and the position of the second rolling air expansion shaft (523) corresponds to the position of the device above the third rolling air expansion shaft (524).

2. The intelligent drying tunnel device for glass fiber pretreatment in the colloidal gold lateral chromatography test paper strip according to claim 1, wherein the unreeling mechanism (1) further comprises a magnetic powder brake (14), and the magnetic powder brake (14) is fixedly installed at one end of the unreeling air-expanding shaft (12).

3. The intelligent drying tunnel device for pretreating glass fibers in the colloidal gold lateral chromatography test strip according to claim 1, wherein the cross-sectional area of the air inlet (311) is larger than the cross-sectional area of the air outlet (312).

4. The intelligent drying tunnel device for pretreating glass fibers in colloidal gold lateral chromatography test strips according to claim 1, wherein a buffer table (44) is arranged between the third rack (41) and the material receiving mechanism (5), and at least one high-low sensor (441) is arranged on the buffer table (44).

5. The intelligent drying tunnel device for pretreating glass fibers in a colloidal gold lateral chromatography test strip according to claim 1, wherein a guide component (516) is arranged on one side of the first rolling physiosis shaft (515), the guide component (516) comprises 3 guide rods (5161) arranged in a shape like a Chinese character pin, and the guide rods (5161) are parallel to the first rolling physiosis shaft (515).

6. The intelligent drying tunnel device for pretreating glass fibers in a colloidal gold lateral chromatography test strip according to claim 5, wherein two limiting blocks (5162) are arranged on the guide rod (5161), and the limiting blocks (5162) are slidably connected to the guide rod (5161).

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