CN211171259U

CN211171259U - Modularization after finishing system

Info

Publication number: CN211171259U
Application number: CN201922188880.0U
Authority: CN
Inventors: 宋明泽; 李刚
Original assignee: Zhejiang Hong Sheng Environmental Protection Technology Group Co ltd
Current assignee: Zhejiang Hongsheng New Material Technology Group Co ltd
Priority date: 2019-12-09
Filing date: 2019-12-09
Publication date: 2020-08-04
Anticipated expiration: 2029-12-09

Abstract

The utility model discloses a modularization after-treatment system, this modularization after-treatment system include singeing press polish production line, flooding processing system and tentering design production line. During production, the products sequentially pass through an unreeling device, a front cloth storage rack, a singeing calender and a middle cloth storage rack in a singeing and calendering production line; in the dipping processing system, dipping treatment is carried out on the products conveyed by the middle storage cloth rack through a dipping tank; in the tentering and setting production line, the work in process coming out from the dipping processing system is tentered, set and rolled through the standing processing device, the rear cloth storage rack and the rolling device. The modularized after-finishing system can reduce the production cost of the after-finishing process of the textile products, improve the product quality, improve the production efficiency and reduce the energy consumption through optimized and reasonable equipment configuration.

Description

Modularization after finishing system

Technical Field

The utility model relates to a textile product production technical field, in particular to modularization after-treatment system.

Background

The post-finishing process of textile products is very important and can directly influence the application performance, the aesthetic property and the service life of the products.

The mechanical equipment for finishing the textile products comprises a singeing calender and a tentering setting machine. Wherein: the singeing calender is mainly suitable for singeing and calendering various fabrics and felts, and the products achieve uniform singeing effect in a fully unfolded state, thereby providing guarantee for subsequent processing, product quality improvement and the like; the tentering setting machine is to place various fabrics in a high temperature environment under a certain tension and keep the fabrics for a period of time, and then carry out natural cooling and cooling, and the main function is to ensure that the products have relatively stable size and shape.

In the prior art, the singeing calender and tenter setter are generally two separate devices. When the textile product is subjected to after-finishing processing, the textile product needs to be introduced into a singeing calender for surface singeing through an unreeling mechanism, then is subjected to calendering processing through a high-temperature hot roller, and finally is subjected to rolling and packaging; then the textile product is transferred to a stentering and shaping machine, and the textile product is subjected to post-finishing processing procedures such as dipping, drying, sintering, shaping and the like.

In the whole processing process, the singeing, press polishing and tentering setting processes are respectively operated in a single machine, and at least twice unreeling, twice reeling and multiple carrying work are required. The textile product is repeatedly packaged and carried, so that the labor intensity is high, the packaging material is wasted greatly, the integral production cost is high, and the production efficiency is low.

Therefore, how to reduce the production cost of the textile product post-finishing process and improve the production efficiency is a technical problem to be solved urgently by those skilled in the art at present.

SUMMERY OF THE UTILITY MODEL

In view of this, the utility model aims at providing a modularization after-treatment system can reduce the manufacturing cost of textile product after-treatment process, improve production efficiency.

In order to achieve the above object, the utility model provides a following technical scheme:

a modularization after finishing system, includes singeing press polish production line, impregnation processing system and tentering design production line, wherein:

during production, the processed products sequentially pass through an unreeling device, a front cloth storage rack, a singeing calender and a middle cloth storage rack in the singeing and calendering production line;

in the dipping processing system, dipping treatment is carried out on the products in process conveyed by the middle cloth storage rack through a dipping tank;

in the tentering and setting production line, the work-in-process products coming out of the dipping processing system are tentered, set and rolled through a standing processing device, a rear cloth storage rack and a rolling device.

Preferably, in the modular post-finishing system, a cloth guide roller is arranged on one side of the unwinding device close to the front cloth storage rack;

and/or a cloth pressing roller for pressing the product into the impregnating solution is arranged in the impregnating tank;

and/or a homogenizing device is arranged in the dipping tank, and comprises a circulating pump and/or a stirring mechanism;

and/or a roller for rolling out the redundant impregnating solution in the product is arranged outside the impregnating tank;

and/or the standing treatment device comprises a volatilization device, a drying device and a sintering and shaping device which are sequentially connected along the conveying direction of the product and have gradually increased temperature;

and/or a cooling device is arranged between the rear end of the standing treatment device and the rear cloth storage rack, and the cooling device cools the product by using a refrigerant;

and/or an online monitoring device for monitoring the thickness of the work-in-process is arranged between the rear cloth storage rack and the winding device.

Preferably, in the above modular after-treatment system, a hot air circulation device is arranged in the volatilization device.

Preferably, in the above modular after-treatment system, a blowing direction of the hot air in the hot air circulation device is adjustable.

Preferably, in the above modular after-treatment system, three drying temperature zones with gradually increased temperatures along the conveying direction of the products are arranged in the drying device.

Preferably, in the modularized after-finishing system, the volatilization temperature in the volatilization device is 95-98 ℃, and the volatilization speed is 5-10 m/min;

the three drying temperature zones in the drying device are a first drying temperature zone, a second drying temperature zone and a third drying temperature zone, the temperature of the first drying temperature zone is 220-230 ℃, the temperature of the second drying temperature zone is 270-280 ℃, and the temperature of the third drying temperature zone is 320-330 ℃;

the sintering temperature in the sintering and shaping device is 370-380 ℃.

Preferably, in the above modular finishing system, a gas heating device or a heat conducting oil heating device is respectively disposed in the volatilizing device, the drying device and the sintering and shaping device.

Preferably, in the above modular after-treatment system, an electrically-assisted heat conduction flow device is respectively added to the volatilization device, the drying device and the sintering and shaping device, and the electrically-assisted heat conduction flow device is arranged at an inlet position, and/or an outlet position, and/or a turning dead angle position in the volatilization device, the drying device and the sintering and shaping device.

Preferably, in the above modular finishing system, the work in process gradually rises along a slope as it passes through the volatilizing device, the drying device and the sintering and sizing device, and the work in process gradually falls in height as it passes through the cooling device.

Preferably, in the above modular finishing system, a P L C control system is further included for monitoring, feeding back and adjusting the conveying speed of the work in process when passing through a plurality of speed measurement positions, and for monitoring, feeding back and adjusting the temperature of the work in process when passing through a plurality of temperature measurement positions.

According to the above technical scheme, the utility model provides a modularization after-treatment system through optimization, reasonable equipment configuration, has constituted one set of integration processing lines, can carry out a plurality of manufacturing procedures such as singeing press polish, impregnation treatment, tentering design in succession to the in-process, and its production process is continuous, uninterrupted, avoids carrying the in-process midway, has reduced the circulation process between the manufacturing procedure promptly. Thereby, adopt the embodiment of the utility model provides a modularization after-treatment system can reduce the manufacturing cost of textile product after-treatment process, improve product quality, improve production efficiency, reduce energy consumption.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to these drawings without creative efforts.

Fig. 1 is a schematic structural diagram of a modular finishing system provided by an embodiment of the present invention.

Wherein:

1-singeing and calendaring production line, 2-dipping processing system, 3-stentering and setting production line,

101-unwinding device, 102-cloth guide roller, 103-front cloth storage rack,

104-singeing calender, 105-middle cloth storage rack,

201-impregnation tank, 202-cloth pressing roller, 203-homogenizing device, 204-rolling roller,

301-volatilizing device, 302-drying device, 303-sintering and shaping device, 304-cooling device,

305-rear cloth storage rack, 306-online detection device, 307-winding device, 308-electric auxiliary heat and current conducting device.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Referring to fig. 1, fig. 1 is a schematic structural diagram of a modular finishing system according to an embodiment of the present invention.

The embodiment of the utility model provides a modularization after-treatment system, including singeing press polish production line 1, flooding processing system 2 and tentering design production line 3.

The singeing and calendering production line 1 comprises an unreeling device 101, a front cloth storage rack 103, a singeing and calendering machine 104 and a middle cloth storage rack 105. Wherein:

the unwinding device 101 is used for automatically unwinding and unwinding rolled products (i.e. textile products in the processing process, or filter materials) and then conveying the rolled products to the front cloth storage rack 105 through the cloth guide roller 102;

the front cloth storage rack 105 is not only used for temporarily storing the work-in-process, but also can adjust and control the speed of the work-in-process entering the singeing calender 104 so as to ensure the conveying speed of the work-in-process, ensure the production efficiency and ensure the singeing and calendering processing effect of the work-in-process;

the singeing calender 104 is used for burning the raised hairiness on the surface of the product by high-temperature flame, and then carrying out calendaring treatment by a high-temperature hot roller to ensure that the surface of the product is smooth and flat and improve the filtering and dust removing performance of the product;

the middle storage rack 105 is used for collecting and temporarily storing the work-in-process after singeing and calendaring, and can adjust and control the conveying speed of the work-in-process to enter the subsequent processing procedures.

In addition, in the impregnation processing system 2, the product coming out from the singeing and calendering production line 1 is subjected to impregnation treatment through an impregnation tank 201; in the tenter setting line 3, the processed product coming out of the impregnation processing system 2 is tenter-set and wound by the standing processing device, the rear cloth storage rack 305, and the winding device 307. Wherein, the rear cloth storage rack 305 is used for collecting and temporarily storing the products after finishing processing. The winding device 307 is used for winding and forming the products, making the products into a package meeting the requirements, and then packaging and warehousing the packages for later use.

According to the above technical scheme, the embodiment of the utility model provides a modularization after-treatment system through optimization, reasonable equipment configuration, has constituted one set of integration processing lines, can carry out singeing press polish, impregnation treatment, a plurality of manufacturing procedure such as tentering design in succession to the in-process, and its production process is continuous, uninterrupted, avoids carrying the in-process midway, has reduced the circulation process between the manufacturing procedure promptly. Thereby, adopt the embodiment of the utility model provides a modularization after finishing system is favorable to improving production efficiency.

Specifically, a cloth guide roller 102 is arranged on one side of the unwinding device 101 close to the front cloth storage rack 103.

Specifically, a cloth pressing roller 202 used for pressing the product in the dipping liquid is arranged in the dipping tank 201, and the cloth pressing roller 202 is used for tensioning the product in the dipping tank to enable the dipping liquid to permeate into the product in the dipping tank, so that the dipping effect of the product in the dipping tank is ensured. Preferably, the dipping speed is set to be 5m/min to 10m/min, namely, the conveying speed of the product passing through the dipping tank 201 is set to be 5m/min to 10 m/min;

further, a homogenizing device 203 for uniformly mixing the impregnation fluid is provided in the impregnation tank 201. For example, a circulation pump is employed as the homogenizing apparatus 203, or a stirring mechanism is employed as the homogenizing apparatus 203, or both a circulation pump and a stirring mechanism are employed as the homogenizing apparatus 203.

Specifically, a roller 204 is further disposed outside the dipping tank 201, and is used for rolling out excess dipping solution in the product after dipping processing, so as to facilitate subsequent processes such as volatilization and drying.

Specifically, the standing treatment device comprises a volatilization device 301, a drying device 302 and a sintering and sizing device 303 which are sequentially connected along the conveying direction of the product and have gradually increased temperature. The volatilization device 301 is used for volatilizing the redundant water in the product; the drying device 302 is used for deeply drying the products to avoid the problems of moisture regain and the like in the subsequent processing or storage process and influence on the product quality; the sintering and shaping device 303 is used for sintering Polytetrafluoroethylene (PTFE) resin in the impregnation liquid, so as to form a protective film on the surface of the product, and improve the physical and chemical indexes of the product, such as temperature resistance, corrosion resistance and the like.

Specifically, a heated air circulation device is arranged in the volatilization device 301, the heated air circulation device preferably adopts a bidirectional heated air circulation diversion system, the working principle of the system is similar to that of an air conditioner hanging machine, except that the heated air circulation device is in contact with a device installation surface, the front surface and the two sides of the heated air circulation device are respectively provided with an air outlet, and the air outlet direction can be adjusted up, down, left and right, so that heated air circulation in different directions can be formed according to the actual production requirement (for example, a forward heated air circulation and a reverse heated air circulation are formed on a horizontal plane, and the forward direction and the reverse direction can.

Specifically, a gas heating device or a heat conducting oil heating device is respectively arranged in the volatilizing device 301, the drying device 302 and the sintering and shaping device 303.

The tentering setting machine in the prior art has the problems of large internal temperature difference and large heat consumption. Therefore, the hot air blowing direction of the hot air circulating device in the volatilization device 301 can be adjusted, so that the angle between the hot air blowing direction and the plane of the heated and volatilized product can be adjusted. Furthermore, an electrically-assisted heat conduction device 308 is further provided in each of the volatilizing device 301, the drying device 302, and the sintering and shaping device 303. The electrically-assisted heat conduction flow device 308 can adopt a small electric heating device with smaller structure and smaller power compared with a gas heating device and a heat conduction oil heating device.

Specifically, the electrically-assisted heat flow guiding device 308 is disposed at an inlet position, and/or an outlet position, and/or a turning dead angle position in the volatilizing device 301, the drying device 302, and the sintering and shaping device 303. Because the inlet position, the outlet position and the rotary dead angle position of the middle path often have the conditions of large temperature difference and uneven heating, the electric auxiliary heat flow guiding device 308 is arranged at the position, and the temperature uniformity of each temperature area in the standing treatment device can be ensured by combining the hot air circulation, thereby being beneficial to improving the accurate range of the heating temperature, improving the heat radiation efficiency and improving the processing quality of products.

Preferably, three drying temperature zones with gradually increased temperatures along the conveying direction of the product are arranged in the drying device 302, namely a first drying temperature zone, a second drying temperature zone and a third drying temperature zone.

Specifically, the volatilization temperature in the volatilization device 301 is 95 ℃ to 98 ℃, and the volatilization speed is 5m/min to 10 m/min; in the drying device 302, the temperature of the first drying temperature zone is 220 ℃ to 230 ℃, the temperature of the second drying temperature zone is 270 ℃ to 280 ℃, and the temperature of the third drying temperature zone is 320 ℃ to 330 ℃; the sintering temperature in the sintering and shaping device 303 is 370 ℃ to 380 ℃.

Specifically, a cooling device 304 is arranged between the rear end of the standing treatment device (i.e., the rear end of the sintering and shaping device 303) and the rear cloth storage rack 305, and the cooling device 304 uses a refrigerant to perform powerful cooling on a product after high-temperature sintering and shaping, so that the high-temperature shaping processing effect is ensured, and meanwhile, the subsequent processing is facilitated. The refrigerant is freon or other refrigerants.

Further, the products gradually rise along the inclined surface (for example, the highest point thereof is about 30 meters from the vertical height of the ground) while passing through the volatilizing device 301, the drying device 302 and the sintering and sizing device 303, and then gradually decrease in height while passing through the cooling device 304 until falling back to the rear storage rack 305. Therefore, in the tentering and shaping and cooling processes of the products, the vertical arrangement process of downward feeding and downward discharging is adopted, the occupied space is small, and more importantly, in the process, the products are always in an inclined conveying state, so that the flying flocs are prevented from falling on the surfaces of the products to cause spots. In addition, the vertical finishing process of downward feeding and downward discharging is also beneficial to better combining the residual impregnation liquid in the products. In a word, adopt the vertical finishing process of entering under and going out above-mentioned, can utilize the aerodynamic principle, effectively solve appearance defects such as product surface spot, flying wadding, moreover, through the influence of gravity, be favorable to the better combination of maceration extract to be favorable to improving the product quality.

Specifically, an online monitoring device 306 for monitoring the thickness of the work in process is further arranged between the rear cloth storage rack 305 and the winding device 307, and is used for monitoring the thickness of the work in process in real time, so as to ensure that the thickness deviation of the work in process is stable and reasonable.

Specifically, a P L C (Programmable L organic controller) control system is arranged in the modular finishing system, and the P L C control system can monitor, feed back and adjust the conveying speed of the products passing through a plurality of speed measurement positions, and can monitor, feed back and adjust the temperature of the products passing through a plurality of temperature measurement positions, so as to obtain accurate processing parameters and realize accurate control.

The embodiment of the utility model provides a production process of modularization after-treatment system specifically as follows:

when the products pass through the modularized after-finishing processing system, the products firstly enter a singeing and calendering production line 1. In the process, a product is firstly placed on an automatic unreeling device 101, automatically unreeled, extended and then conveyed to a front cloth storage rack 103 through a cloth guide roller 102; the front cloth storage rack 103 adjusts and controls the speed of the products entering the singeing calender 104, and at the moment, the singeing calender processing effect and the product conveying speed are ensured, so that the production efficiency is improved; the singeing calender 104 burns out the raised hairiness on the surface of the product by high-temperature flame, and then carries out calendaring treatment by a high-temperature hot roller, so that the surface of the product is smooth and flat, and the filtering and dust removing performance of the product is improved; the processed products processed by the singeing calender 104 enter the middle storage rack 105, are temporarily collected by the middle storage rack 105 and are fed into the impregnation processing system 2 at a constant speed.

After being processed by a singeing and calendaring production line 1, the product enters a dipping processing system 2. In the process, the product is put into the dipping tank 201 for dipping treatment, at the moment, the dipping liquid is uniformly mixed in the dipping tank 201 through the homogenizing device 203, and the product is tensioned through the cloth pressing roller 202, so that the dipping liquid permeates into the product, and the dipping effect of the product is ensured (wherein, the dipping speed is 5m/min to 10m/min, namely, the conveying speed of the product is 5m/min to 10m/min when the product passes through the dipping tank 201); the product is then transported out of the impregnation tank 201, and excess impregnation fluid in the product is squeezed out by the rollers 204 to facilitate subsequent volatilization and drying processes.

After the product is processed by the dipping processing system 2, the product enters a tentering and setting production line 3 for processing. In the process, the product firstly enters the volatilization device 301, the excessive moisture in the product is volatilized out through the hot air circulation device by the volatilization device 301, the volatilization temperature is 95-98 ℃, and the volatilization speed is 5-10 m/min; then, the product enters a drying device 302, and is subjected to deep drying sequentially through three different temperature zones of 220 ℃ to 230 ℃, 270 ℃ to 280 ℃ and 320 ℃ to 330 ℃ to ensure the drying quality of the product; then, the product enters a sintering and shaping device 303, and is sintered at a high temperature of 370 ℃ to 380 ℃ through the sintering and shaping device 303, so that a protective film is formed on the surface of the product, and the physical and chemical indexes of the product, such as temperature resistance, corrosion resistance and the like, are improved; then, the products after heat setting enter a cooling device 304 for strong cooling to ensure the processing effect of high-temperature setting; finally, the products are temporarily collected in the storage rack 305 after entering, the thickness of the products is monitored by the online detection device 306, and finally the products are curled and formed by the winding device 307 to be made into a package meeting the requirements, and then the package is packaged and put in storage for later use.

Finally, it should also be noted that, herein, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus. Without further limitation, an element defined by the phrase "comprising an … …" does not exclude the presence of other identical elements in a process, method, article, or apparatus that comprises the element.

The embodiments in the present description are described in a progressive manner, each embodiment focuses on differences from other embodiments, and the same and similar parts among the embodiments are referred to each other.

The previous description of the disclosed embodiments is provided to enable any person skilled in the art to make or use the present invention. Various modifications to these embodiments will be readily apparent to those skilled in the art, and the generic principles defined herein may be applied to other embodiments without departing from the spirit or scope of the invention. Thus, the present invention is not intended to be limited to the embodiments shown herein but is to be accorded the widest scope consistent with the principles and novel features disclosed herein.

Claims

1. A modular finishing system, comprising a singeing calendering line (1), a impregnation processing system (2) and a tentering setting line (3), wherein:

during production, the products sequentially pass through an unreeling device (101), a front cloth storage rack (103), a singeing calender (104) and a middle cloth storage rack (105) in the singeing and calendering production line (1);

in the dipping processing system (2), the products in process conveyed by the middle cloth storage rack (105) are dipped through a dipping tank (201);

in the tentering and setting production line (3), the products coming out of the impregnation processing system (2) are tentered, set and rolled through a standing treatment device, a rear cloth storage rack (305) and a rolling device (307).

2. The modular finishing system according to claim 1, characterized in that a cloth guide roller (102) is arranged on one side of the unwinding device (101) close to the front cloth storage rack (103);

and/or a cloth pressing roller (202) for pressing the product into the impregnating solution is arranged in the impregnating tank (201);

and/or a homogenizing device (203) is arranged in the impregnation tank (201), and the homogenizing device (203) comprises a circulating pump and/or a stirring mechanism;

and/or a roller (204) for rolling out the redundant impregnating liquid in the product is arranged outside the impregnating tank (201);

and/or the standing treatment device comprises a volatilization device (301), a drying device (302) and a sintering and shaping device (303) which are sequentially connected along the conveying direction of the products and have gradually increased temperature;

and/or a cooling device (304) is arranged between the rear end of the standing treatment device and the rear cloth storage rack (305), and the cooling device (304) utilizes a refrigerant to cool the processed product;

and/or an online monitoring device (306) for monitoring the thickness of the work-in-process is arranged between the rear cloth storage rack (305) and the winding device (307).

3. The modular aftertreatment system of claim 2, wherein a heated air circulation device is provided in the volatilization device (301).

4. The modular aftertreatment system of claim 3, wherein a blow-off direction of the heated air in the heated air circulation device is adjustable.

5. The modular aftertreatment system of claim 2, wherein three drying temperature zones are provided in the drying device (302) with increasing temperature in the direction of conveyance of the articles.

6. The modular aftertreatment system of claim 5, wherein the volatilization temperature in the volatilization device (301) is 95 ℃ to 98 ℃ and the volatilization speed is 5m/min to 10 m/min;

the three drying temperature zones in the drying device (302) are a first drying temperature zone, a second drying temperature zone and a third drying temperature zone, the temperature of the first drying temperature zone is 220-230 ℃, the temperature of the second drying temperature zone is 270-280 ℃, and the temperature of the third drying temperature zone is 320-330 ℃;

the sintering temperature in the sintering and shaping device (303) is 370-380 ℃.

7. The modular aftertreatment system of claim 2, wherein a gas heating device or a heat conducting oil heating device is respectively arranged in the volatilizing device (301), the drying device (302) and the sintering and shaping device (303).

8. The modular aftertreatment system according to claim 7, wherein electrically assisted heat conduction flow devices (308) are respectively added to the volatilization device (301), the drying device (302) and the sintering and shaping device (303), and the electrically assisted heat conduction flow devices (308) are arranged at inlet positions, and/or outlet positions, and/or convolution dead corner positions in the volatilization device (301), the drying device (302) and the sintering and shaping device (303).

9. The modular aftertreatment system of claim 2, wherein the articles of manufacture gradually rise along a slope as they pass through the volatilization device (301), the drying device (302), and the sinter sizing device (303), and gradually decrease in height as they pass through the cooling device (304).

10. The modular aftertreatment system of any one of claims 1-9, further comprising a P L C control system for monitoring, feeding back, and adjusting the conveyance speed of the work-in-process as it passes through the plurality of speed measurement locations, and for monitoring, feeding back, and adjusting the temperature of the work-in-process as it passes through the plurality of temperature measurement locations.