CN114274647A - Method for manufacturing carbon-loaded cloth - Google Patents

Abstract

The invention discloses a method for manufacturing carbon-loaded cloth, which comprises the following steps: obtaining activated carbon particles and plastic particles; mixing and heating the activated carbon particles and the plastic particles to obtain a fluid mixture; granulating the fluid mixture to obtain carbon-carrying granules; carrying out softening spinning on the carbon-carrying particles to obtain carbon-carrying short fibers; heating and softening the plastic particles, uniformly mixing the plastic particles with the activated carbon particles to form the fluid mixture, granulating the fluid mixture to obtain the carbon-carrying particles, uniformly distributing the activated carbon in the carbon-carrying particles, performing softening spinning on the carbon-carrying particles to ensure that the spinning step is performed smoothly, and finally bonding the base cloth and the carbon-carrying fibers to obtain the carbon-carrying cloth; and obtaining base cloth, and bonding the base cloth and the carbon-loaded short fibers to obtain the carbon-loaded cloth. The whole steps are simple and easy to operate, the equipment investment is low, the carbon emission is low, the energy consumption is low, and the economic benefit is high.

Description

Method for manufacturing carbon-loaded cloth

Technical Field

The invention relates to the technical field of activated carbon fiber felt cloth, in particular to a method for manufacturing carbon-loaded cloth.

Background

The activated carbon fiber is a new generation of high-efficiency active adsorption material and an environment-friendly functional material, has the characteristics of large specific area, narrow pore size distribution, high adsorption and desorption speeds and large adsorption capacity, and can be widely used for purifying water and air, recovering air agents, removing fishy smell, preventing toxicity, battery motors and the like.

The prior activated carbon fiber felt cloth is prepared by soaking a fire retardant and then carbonizing and activating by high-temperature steam. The whole production process can form waste water, high-temperature steam is needed, the energy consumption is undoubtedly high, equipment is added for treating waste water and waste gas, and the cost is high.

Disclosure of Invention

The invention mainly aims to provide a method for manufacturing carbon-loaded cloth, and aims to solve the problems that the existing activated carbon fiber felt cloth is complex in production steps, large in pollution and high in cost.

In order to achieve the purpose, the invention provides a method for manufacturing carbon-carrying cloth, which comprises the following steps:

obtaining activated carbon particles and plastic particles;

mixing and heating the activated carbon particles and the plastic particles to obtain a fluid mixture;

granulating the fluid mixture to obtain carbon-carrying granules;

carrying out softening spinning on the carbon-carrying particles to obtain carbon-carrying short fibers;

and obtaining base cloth, and bonding the base cloth and the carbon-loaded short fibers to obtain the carbon-loaded cloth.

Optionally, the step of obtaining a base fabric and bonding the base fabric and the carbon-loaded short fibers to obtain the carbon-loaded fabric comprises:

obtaining at least two base fabrics, and placing the carbon-loaded short fibers between the two base fabrics to obtain middle carbon-loaded cloth;

and bonding the carbon-carrying short fibers of the middle carbon-carrying cloth with the two base cloths to obtain the carbon-carrying cloth.

Optionally, the step of bonding the carbon-loaded short fibers of the middle carbon-loaded cloth with the two base cloths to obtain the carbon-loaded cloth comprises:

pre-pressing the middle carbon-loaded cloth at normal temperature;

and carrying out hot pressing on the pre-pressed middle carbon-carrying cloth to obtain the carbon-carrying cloth.

Optionally, the step of bonding the carbon-loaded short fibers of the middle carbon-loaded cloth and the two base cloths to obtain the carbon-loaded cloth comprises:

obtaining a flat pressing mechanism and a hot pressing mechanism;

adjusting the distance between two flat pressing rollers in the flat pressing mechanism to a first set value;

and adjusting the distance between two hot pressing rollers in the hot pressing mechanism to a second set value.

Optionally, the step of obtaining at least two base fabrics and placing the carbon-loaded short fibers between the two base fabrics to obtain an intermediate carbon-loaded fabric comprises:

obtaining at least three conveying devices, wherein the three conveying devices are respectively used for conveying the two base cloths and the carbon-carrying fibers, and the discharge end of the conveying device for conveying the carbon-carrying fibers is positioned between the two base cloths;

acquiring working parameters of the three conveying devices;

when the working parameters of the three conveying devices meet preset conditions, the two conveying devices for conveying the two base fabrics are controlled to start, then the discharge ends of the conveying devices for conveying the carbon-carrying fibers are controlled to uniformly discharge, and the middle carbon-carrying fabric is obtained.

Optionally, the step of mixing and heating the activated carbon particles and the plastic particles to obtain a fluid mixture comprises:

obtaining a heating and mixing device;

putting the activated carbon particles and the plastic particles into the heating and mixing device according to a preset proportion, controlling the heating and mixing device to heat at the temperature of 120-170 ℃, and stirring and mixing for 20-30 minutes to obtain the fluid mixture.

Optionally, the step of granulating the fluid mixture to obtain carbon-loaded granules comprises:

obtaining an extruder, an air outlet device and a cutter, wherein an air outlet of the air outlet device is over against an extrusion opening of the extruder, and the cutter is arranged at the extrusion opening;

controlling the air outlet to output cold air to solidify the extruded fluid mixture when the fluid mixture extruded by the extruder is sensed to be extruded;

cutting the solidified fluid mixture by using the cutter to obtain the carbon-carrying granules.

Optionally, the particle size of the carbon-carrying particle is 3-5 mm.

Optionally, the particle size of the activated carbon particles is not less than 400 mesh.

Optionally, the base fabric is provided as a non-woven fabric.

According to the technical scheme, active carbon particles and plastic particles are obtained, and the active carbon particles and the plastic particles are mixed and heated to obtain a fluid mixture; granulating the fluid mixture to obtain carbon-carrying granules; carrying out softening spinning on the carbon-carrying particles to obtain carbon-carrying short fibers; obtaining base cloth, and bonding the base cloth and the carbon-loaded short fibers to obtain carbon-loaded cloth; mixing and heating the activated carbon particles and the plastic particles, heating and softening the plastic particles, uniformly mixing the plastic particles with the activated carbon particles to form a fluid mixture, granulating the fluid mixture to obtain carbon-carrying particles, uniformly distributing the activated carbon in the carbon-carrying particles, softening and spinning the carbon-carrying particles to ensure that the spinning step is smoother, and finally bonding the base fabric and the carbon-carrying fibers to obtain the carbon-carrying fabric; the whole steps are simple and easy to operate, the equipment investment is low, the carbon emission is low, the energy consumption is low, and the economic benefit is high.

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 the structures shown in the drawings without creative efforts.

Fig. 1 is a schematic flow chart of a method for manufacturing a carbon-loaded cloth according to an embodiment of the present invention;

fig. 2 is a schematic structural diagram of the pressing of the flat pressing roller and the hot pressing roller on the middle carbon-carrying cloth.

The reference numbers illustrate:

reference numerals	Name (R)	Reference numerals	Name (R)
				100	Carbon-carrying cloth	210	Flat-press roller
101	Middle carbon-loaded cloth	300	Hot-pressing mechanism
				1011	Base cloth	310	Hot-pressing roller
200	Flat pressing mechanism

The implementation, functional features and advantages of the objects of the present invention will be further explained with reference to the accompanying drawings.

Detailed Description

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 only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

It should be noted that, if directional indications (such as up, down, left, right, front, and back … …) are involved in the embodiment of the present invention, the directional indications are only used to explain the relative positional relationship between the components, the movement situation, and the like in a specific posture (as shown in the drawing), and if the specific posture is changed, the directional indications are changed accordingly.

In addition, if there is a description of "first", "second", etc. in an embodiment of the present invention, the description of "first", "second", etc. is for descriptive purposes only and is not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include at least one such feature. In addition, the meaning of "and/or" appearing throughout includes three juxtapositions, exemplified by "A and/or B" including either A or B or both A and B. In addition, technical solutions between various embodiments may be combined with each other, but must be realized by a person skilled in the art, and when the technical solutions are contradictory or cannot be realized, such a combination should not be considered to exist, and is not within the protection scope of the present invention.

The activated carbon fiber is a new generation of high-efficiency active adsorption material and an environment-friendly functional material, has the characteristics of large specific area, narrow pore size distribution, high adsorption and desorption speeds and large adsorption capacity, and can be widely used for purifying water and air, recovering air agents, removing fishy smell, preventing toxicity, battery motors and the like.

The prior activated carbon fiber felt cloth is prepared by soaking a fire retardant and then carbonizing and activating by high-temperature steam. The whole production process can form waste water, high-temperature steam is needed, the energy consumption is undoubtedly high, equipment is added for treating waste water and waste gas, and the cost is high.

In view of this, the present invention provides a method for manufacturing a carbon-loaded cloth, and fig. 1 is an embodiment of the method for manufacturing a carbon-loaded cloth according to the present invention.

The manufacturing method of the carbon-carrying cloth adopts a heating and mixing device for mixing and heating the activated carbon particles and the plastic particles, an extruder for extruding the fluid mixture, an air outlet device for discharging cold air, a cutter for cutting the solidified fluid mixture, at least three conveying devices for conveying the carbon-carrying fibers and the base cloth 1011, a flat pressing mechanism 200 for pressing the middle carbon-carrying cloth 101, and a hot pressing mechanism 300; the extruder comprises an extrusion port for extruding the fluid mixture, an air outlet of the air outlet device is opposite to the extrusion port and used for solidifying the fluid mixture extruded from the extrusion port, and the cutter is arranged at the extrusion port; referring to fig. 2, the platen mechanism 200 and the hot press mechanism 300 are disposed at an interval, the platen mechanism 200 includes two platen rollers 210 disposed oppositely, and the hot press mechanism 300 includes two hot press rollers 310 disposed oppositely.

Based on the above structure, the present invention provides a method for manufacturing a carbon-loaded cloth, and referring to fig. 1, the method for manufacturing a carbon-loaded cloth includes the following steps:

s10, obtaining activated carbon particles and plastic particles;

s20, mixing and heating the activated carbon particles and the plastic particles to obtain a fluid mixture;

s30, granulating the fluid mixture to obtain carbon-carrying granules;

s40, carrying out softening spinning on the carbon-carrying particles to obtain carbon-carrying short fibers;

s50, obtaining a base cloth 1011, and bonding the base cloth 1011 and the carbon-carrying short fibers to obtain the carbon-carrying cloth 100.

According to the technical scheme, active carbon particles and plastic particles are obtained, and the active carbon particles and the plastic particles are mixed and heated to obtain a fluid mixture; granulating the fluid mixture to obtain carbon-carrying granules; carrying out softening spinning on the carbon-carrying particles to obtain carbon-carrying short fibers; obtaining a base cloth 1011, and bonding the base cloth 1011 and the carbon-loaded short fibers to obtain the carbon-loaded cloth 100; mixing and heating the activated carbon particles and the plastic particles, heating and softening the plastic particles, uniformly mixing the plastic particles with the activated carbon particles to form a fluid mixture, granulating the fluid mixture to obtain carbon-carrying particles, uniformly distributing the activated carbon in the carbon-carrying particles, softening and spinning the carbon-carrying particles to ensure that the spinning step is performed smoothly, and finally bonding the base fabric 1011 and the carbon-carrying fibers to obtain the carbon-carrying cloth 100; the whole steps are simple and easy to operate, the equipment investment is low, the carbon emission is low, the energy consumption is low, and the economic benefit is high.

Specifically, the step S50 includes:

s51, obtaining at least two base fabrics 1011, and placing the carbon-loaded short fibers between the two base fabrics 1011 to obtain a middle carbon-loaded fabric 101;

s52, the carbon-carrying short fibers of the middle carbon-carrying cloth 101 are bonded with the two base cloths 1011 to obtain the carbon-carrying cloth 100.

In this embodiment, in order to manufacture the carbon-loaded short fibers into the carbon-loaded cloth 100, two base cloths 1011 need to be provided because the carbon-loaded short fibers are softened by heating, a plurality of carbon-loaded fibers are placed between the two base cloths 1011 to obtain the middle carbon-loaded cloth 101, and then the plurality of carbon-loaded short fibers of the middle carbon-loaded cloth 101 are bonded to the two base cloths 1011 to obtain the carbon-loaded cloth 100.

More specifically, the step S52 includes:

s521, pre-pressing the middle carbon-loaded cloth 101 at normal temperature;

and S522, carrying out hot pressing on the intermediate carbon-carrying cloth 101 subjected to the pre-pressing to obtain the carbon-carrying cloth 100.

In this embodiment, a plurality of carbon-carrying fibers are disposed in two of the base fabrics 1011, and since a plurality of carbon-carrying fibers are disposed in two of the base fabrics 1011, a certain height is formed between the two base fabrics 1011, and the certain height is related to the volume of the plurality of carbon-carrying fibers, the middle carbon-carrying fabric 101 is pre-pressed at normal temperature, the middle carbon-carrying fabric 101 is pressed tightly by passing the middle carbon-carrying fabric 101 through the two platen rollers 210, and then the pre-pressed middle carbon-carrying fabric 101 is pressed tightly by passing the two platen rollers 310 to obtain the carbon-carrying fabric 100, thereby ensuring that the middle carbon-carrying fabric 101 can be pressed into the more uniform carbon-carrying fabric 100 after being pressed.

The step S52 is preceded by:

s50a, obtaining the flat pressing mechanism 200 and the hot pressing mechanism 300;

s50b, adjusting the distance between two flat pressing rollers 210 in the flat pressing mechanism 200 to a first set value;

s50c, adjusting the distance between the two hot press rollers 310 in the hot press mechanism 300 to a second set value.

The flat pressing mechanism 200 comprises two flat pressing rollers 210 which are oppositely arranged, and the hot pressing mechanism 300 comprises two hot pressing rollers 310 which are oppositely arranged; the distance between the two flat pressing rollers 210 is not less than the distance between the two hot pressing rollers 310; adjusting the distance between two flat pressing rollers 210 in the flat pressing mechanism 200 to a first set value, and adjusting the distance between two hot pressing rollers 310 in the hot pressing mechanism 300 to a second set value, so that the middle carbon-loaded cloth 101 sequentially passes through the two flat pressing rollers 210 and the two hot pressing rollers 310, and the hot pressing rollers 310 soften the carbon-loaded fibers due to heat and bond the carbon-loaded fibers with the two base cloths 1011; it should be noted that the first set value and the second set value are confirmed by an operator according to different production requirements, and are not limited herein, when the carbon-loaded cloth 100 with a smaller thickness needs to be produced, the first set value and the second set value may be reduced to produce the carbon-loaded cloth 100 with a smaller thickness, and the density is higher; similarly, when the carbon-loaded cloth 100 with a larger thickness needs to be produced, the first set value and the second set value are increased to produce the carbon-loaded cloth 100 with a larger thickness and lower density; and when the first set value and the second set value are adjusted, the first set value is increased or decreased by a certain amount, and the second set value is also increased or decreased by a corresponding amount.

In order to obtain a more uniform carbon-loaded cloth 100, in this embodiment, the step S51 includes:

s511, obtaining at least three conveying devices, wherein the three conveying devices are respectively used for conveying the two base fabrics 1011 and the carbon-carrying fibers, and the discharge ends of the conveying devices for conveying the carbon-carrying fibers are positioned between the two base fabrics 1011;

in this embodiment, two conveying devices are respectively used for conveying two base fabrics 1011, one conveying device is used for conveying the carbon-carrying fibers, and the conveying direction of the conveying device is the same as that of the two conveying belts used for conveying the base fabrics 1011; the discharge end of the conveying device for conveying the carbon-carrying fibers is arranged between the two base fabrics 1011.

S512, acquiring working parameters of the three conveying devices;

s513, when the working parameters of the three conveying devices meet preset conditions, firstly controlling the two conveying devices for conveying the two base fabrics 1011 to start, and then controlling the discharge ends of the conveying devices for conveying the carbon-loaded fibers to uniformly discharge, so as to obtain the middle carbon-loaded fabric 101;

will two the one end of base cloth 1011 passes two in proper order the concora crush roller 210 and two the compression roller starts to be used for the transmission two base cloth 1011 conveyer, the restart is used for conveying year charcoal fibre conveyer makes a plurality ofly carry the charcoal fibre process the discharge end evenly falls into two in the middle of the base cloth 1011, form the charcoal cloth 101 is carried in the middle, through two concora crush roller 210 and two the hot pressing roller 310 forms carry charcoal cloth 100, so can make carry in the middle a plurality of in the charcoal cloth 101 carry charcoal fibre can distribute more evenly to can accomplish automatic production.

In this embodiment, the step S20 includes:

s21, obtaining a heating and mixing device;

s22, putting the activated carbon particles and the plastic particles into the heating and mixing device according to a preset proportion, controlling the heating and mixing device to heat at the temperature of 120-170 ℃, and stirring and mixing for 20-30 minutes to obtain the fluid mixture;

in this embodiment, the particle size of the activated carbon particles is not less than 400 meshes, the plastic particles are polypropylene particles, and the predetermined ratio of the activated carbon particles to the plastic particles is 7: 3, the gram weight ratio of the activated carbon particles to the plastic particles may be, and in the heating and mixing process, the activated carbon particles and the plastic particles may be uniformly mixed first and then heated, or may be heated first and then mixed, which is not limited herein.

Specifically, the step S30 includes:

s31, obtaining an extruder, an air outlet device and a cutter, wherein an air outlet of the air outlet device is over against an extrusion port of the extruder, and the cutter is arranged at the extrusion port;

s32, controlling the air outlet to output cold air to solidify the extruded fluid mixture when the fluid mixture extruded by the extruder is sensed to be extruded;

s33, cutting the solidified fluid mixture by using the cutter to obtain the carbon-carrying particles;

in this embodiment, the heating and mixing device is communicated with the extruder, the fluid mixture is directly fed into the extruder after being uniformly mixed, the fluid mixture is extruded from the extrusion port of the extruder, cold air is discharged from the air outlet of the air outlet device during extrusion to rapidly solidify the extruded fluid mixture, and at this time, the cutter cuts the solidified fluid mixture into a plurality of carbon-loaded particles along with the extrusion of the solidified fluid mixture; the particle size of the carbon-carrying particles is set to be 3-5 mm; in this way, the carbon-carrying fiber extruded by the extruder is easily softened and formed.

The present invention is not limited to the material of the base fabric 1011, and may be any fabric having a plurality of pores, and in this embodiment, the base fabric 1011 is a nonwoven fabric.

The above description is only a preferred embodiment of the present invention, and is not intended to limit the scope of the present invention, and all modifications and equivalents of the present invention, which are made by the contents of the present specification and the accompanying drawings, or directly/indirectly applied to other related technical fields, are included in the scope of the present invention.

Claims (10)

1. The manufacturing method of the carbon-loaded cloth is characterized by comprising the following steps:

obtaining activated carbon particles and plastic particles;

mixing and heating the activated carbon particles and the plastic particles to obtain a fluid mixture;

granulating the fluid mixture to obtain carbon-carrying granules;

carrying out softening spinning on the carbon-carrying particles to obtain carbon-carrying short fibers;

and obtaining base cloth, and bonding the base cloth and the carbon-loaded short fibers to obtain the carbon-loaded cloth.

2. The method of making a carbon-loaded cloth according to claim 1, wherein the step of obtaining a base cloth and bonding the base cloth and the carbon-loaded staple fibers to obtain the carbon-loaded cloth comprises:

obtaining at least two base fabrics, and placing the carbon-loaded short fibers between the two base fabrics to obtain middle carbon-loaded cloth;

and bonding the carbon-carrying short fibers of the middle carbon-carrying cloth with the two base cloths to obtain the carbon-carrying cloth.

3. The method for manufacturing the carbon-loaded cloth according to claim 2, wherein the step of bonding the carbon-loaded short fibers of the middle carbon-loaded cloth and the two base cloths to obtain the carbon-loaded cloth comprises:

pre-pressing the middle carbon-loaded cloth at normal temperature;

and carrying out hot pressing on the pre-pressed middle carbon-carrying cloth to obtain the carbon-carrying cloth.

4. The method for manufacturing the carbon-loaded cloth according to claim 2, wherein the step of bonding the carbon-loaded short fibers of the middle carbon-loaded cloth and the two base cloths to obtain the carbon-loaded cloth comprises the following steps:

obtaining a flat pressing mechanism and a hot pressing mechanism;

adjusting the distance between two flat pressing rollers in the flat pressing mechanism to a first set value;

and adjusting the distance between two hot pressing rollers in the hot pressing mechanism to a second set value.

5. The method of making a carbon-loaded cloth according to claim 2, wherein the step of obtaining at least two of the base cloths and placing the carbon-loaded staple fibers between the two base cloths to obtain an intermediate carbon-loaded cloth comprises:

obtaining at least three conveying devices, wherein the three conveying devices are respectively used for conveying the two base cloths and the carbon-carrying fibers, and the discharge end of the conveying device for conveying the carbon-carrying fibers is positioned between the two base cloths;

acquiring working parameters of the three conveying devices;

when the working parameters of the three conveying devices meet preset conditions, the two conveying devices for conveying the two base fabrics are controlled to start, then the discharge ends of the conveying devices for conveying the carbon-carrying fibers are controlled to uniformly discharge, and the middle carbon-carrying fabric is obtained.

6. The method of making a carbon-loaded cloth of claim 1, wherein the step of mixing and heating the activated carbon particles and the plastic particles to obtain a fluid mixture comprises:

obtaining a heating and mixing device;

putting the activated carbon particles and the plastic particles into the heating and mixing device according to a preset proportion, controlling the heating and mixing device to heat at the temperature of 120-170 ℃, and stirring and mixing for 20-30 minutes to obtain the fluid mixture.

7. The method of making a carbon-loaded cloth according to claim 1, wherein the step of granulating the fluid mixture to obtain carbon-loaded granules comprises:

obtaining an extruder, an air outlet device and a cutter, wherein an air outlet of the air outlet device is over against an extrusion opening of the extruder, and the cutter is arranged at the extrusion opening;

controlling the air outlet to output cold air to solidify the extruded fluid mixture when the fluid mixture extruded by the extruder is sensed to be extruded;

cutting the solidified fluid mixture by using the cutter to obtain the carbon-carrying granules.

8. The method of manufacturing a carbon-loaded cloth according to claim 1, wherein the particle size of the carbon-loaded particles is 3 to 5 mm.

9. The method of manufacturing a carbon-loaded cloth according to claim 1, wherein the particle size of the activated carbon particles is not less than 400 mesh.

10. The method of manufacturing a carbon-loaded cloth according to claim 1, wherein the base cloth is a non-woven cloth.

Images