CN113758212A

CN113758212A - Drying device is used in textile fiber processing

Info

Publication number: CN113758212A
Application number: CN202110864132.9A
Authority: CN
Inventors: 王慧明
Original assignee: Individual
Current assignee: Zhejiang Guozhi School Uniform Co ltd
Priority date: 2021-07-29
Filing date: 2021-07-29
Publication date: 2021-12-07
Anticipated expiration: 2041-07-29
Also published as: CN113758212B

Abstract

The invention discloses a drying device for processing textile fibers, which belongs to the technical field of fiber material drying, wherein two drying cylinders which are sequentially arranged from top to bottom are arranged on one side of a drying box, a fiber driving roller which is in traction contact with the textile fibers is arranged on each drying cylinder, an air supply mechanism is utilized to supply air flow to the insides of the two drying cylinders, the textile fibers are rubbed with the fiber driving rollers in the traction process, and the heated fiber driving rollers are pulled to rotate clockwise, so that the dynamic water absorption and drying effects are achieved, the drying effect is improved, the direct supply of hot air is avoided, and the fibers are not easy to cause hot melt fracture.

Description

Drying device is used in textile fiber processing

Technical Field

The invention relates to the technical field of fiber material drying, in particular to a drying device for textile fiber processing.

Background

Textile fibers are classified into both natural fibers and chemical fibers. Flax, cotton yarn, hemp rope, etc. are obtained from plants and belong to natural fibers, wool and silk are from animals and also natural fibers. There are many types of chemical fibers such as nylon, rayon, fiberglass, and the like.

After the textile fibers are cleaned by printing, they need to be dried. Traditional drying method is the leading-in drying cabinet of dry wind through the heating, and textile fiber passes from the box to the realization is dried textile fiber's surface, adopts hot-blast drying, is difficult to guarantee that the box is interior everywhere temperature is even, and because textile fiber is frivolous, if the heating is inhomogeneous, when certain overweight heating promptly, causes textile fiber's hot melt fracture easily, influences textile fiber's drying quality.

Therefore, the drying device for textile fiber processing is provided to effectively solve the problems in the prior art.

Disclosure of Invention

1. Technical problem to be solved

Aiming at the problems in the prior art, the invention aims to provide a drying device for processing textile fibers, which utilizes an air supply mechanism to supply air flow to the insides of two drying cylinders, and the textile fibers are rubbed with a fiber driving roller in the traction process to play a dynamic water absorption and drying role, improve the drying effect, avoid the direct supply of hot air and avoid the hot melt fracture of the fibers.

2. Technical scheme

In order to solve the above problems, the present invention adopts the following technical solutions.

A drying device for textile fiber processing comprises a drying box, wherein two drying cylinders are embedded on the outer end wall of the drying box, the inner ends of the two drying cylinders extend to the inner side of the drying box, fiber driving rollers are rotatably arranged on the outer end walls of the two drying cylinders, the outer end of the fiber driving roller extends outwards, the end walls of the two drying cylinders positioned at the inner side of the drying box are respectively embedded with an air inlet pipe and an air outlet pipe, a circulating air supply mechanism is arranged in the drying box, an air supply pipe connected with the circulating air supply mechanism is arranged at the outer end of the drying box, the circulation air feed mechanism is connected with a pair of intake pipe, blast pipe and sets up, the drying cabinet one end outside is equipped with the guide roll of a plurality of interval distributions between the fibre driving roller, is equipped with flexible heat-conducting piece between two adjacent guide rolls, flexible heat-conducting piece corresponds the setting with fibre driving roller position.

Further, air feed mechanism includes heating cabinet, communicating pipe, gas storage pipe and back flow, the heating cabinet is installed in the drying cabinet and is connected with the air supply pipe, the heating cabinet inner is connected with the intake pipe that is located the top drying cylinder through a plurality of first air inlet hose, the gas storage pipe is connected with the blast pipe that is located the top drying cylinder through communicating pipe, the gas storage pipe is connected with the intake pipe that is located the below drying cylinder through a plurality of second air inlet hose, and the blast pipe that is located the below drying cylinder is connected with the back flow, the back flow is connected with the intake pipe.

Furthermore, the exhaust ports are formed in the exhaust pipes, the air inlet pipes are provided with a plurality of air nozzles, and the jet ports of the air nozzles are obliquely arranged towards one side of the fiber driving roller.

Further, two inside arc water conservancy diversion pieces that all are equipped with of dryer, arc water conservancy diversion piece bottom is connected on the dryer inner wall that is located between intake pipe, blast pipe, arc water conservancy diversion piece upper end and dryer top end wall form the water conservancy diversion mouth.

Further, arc water conservancy diversion piece sets up to fibre driving roller one side arc protrusion, is favorable to locating leading-in gas from the intake pipe to the drainage motion that makes progress on one side of the fibre driving roller, and drainage upward movement's steam not only plays the intensification effect to the fibre driving roller, still does benefit to and plays clockwise operation effect to the fibre driving roller to be favorable to textile fiber to pull downwards.

Furthermore, the fiber driving roller is of a hollow cylindrical structure, and the outer end wall of the fiber driving roller is coated with a water-absorbing fiber cotton layer.

Further, a drying cylinder, an arc-shaped flow deflector and a fiber driving roller are all made of heat conducting materials, a plurality of graphite heat conducting particles are filled in the fiber driving roller, and a heat insulating layer is coated on the end wall of the drying cylinder, which is located on the inner side of the drying box.

Furthermore, flexible heat-conducting piece is including connecting the heat-conducting plate between a pair of guide roll, the upper and lower both ends of heat-conducting plate set up to the upper and lower direction slope of fibre driving roller respectively, and equally divide on the upper and lower end wall of heat-conducting plate and distribute a plurality of flexible arcs, and is a plurality of the tip of flexible arcs all distributes and has a plurality of fibre velvet ribbon.

Furthermore, a liquid storage cavity is formed in the inner portion of the flexible arc-shaped sheet, antistatic paint is filled in the liquid storage cavity, and the inner end of the fiber velvet ribbon is soaked at the bottom of the liquid storage cavity.

Furthermore, the fiber velvet belt is made of high water absorption and permeation materials, and the inner end of the fiber velvet belt extends to the bottom in the liquid storage cavity.

3. Advantageous effects

Compared with the prior art, the invention has the advantages that:

(1) this scheme is through setting up the drying cylinder that sets gradually from top to bottom in drying cabinet one side, be equipped with the fibre driving roller that draws the contact with textile fiber on the drying cylinder, utilize air feed mechanism to carry out the air current to two drying cylinder insides and supply with, textile fiber is in the in-process of drawing, with the friction of fibre driving roller, fibre driving roller after the heating is drawn clockwise rotation, thereby play the dry effect of dynamic water absorption, improve drying effect, and avoid hot-blast direct supply, be difficult for causing fibrous hot melt fracture, in addition, set up flexible heat-conducting piece outside a pair of drying cylinder, textile fiber draws in-process and flexible heat-conducting piece terminal surface friction contact, the moisture absorption drying effect to textile fiber has both further been improved, play flexible carding effect to textile fiber again, improve drying quality.

(2) The air feed mechanism of this scheme is by the heating cabinet, communicating pipe, hold trachea and back flow and constitute, utilize the heating cabinet to heat gas, gas after the heating passes through the intake pipe and guides into to the drying cylinder of top in, the drying cylinder of top carries out preliminary drying to the textile fabric of pulling the in-process, gas by this drying cylinder derivation passes through the blast pipe, in the leading-in trachea that holds of communicating pipe, and in leading-in below drying cylinder by holding trachea, gas after the dry use of below is guided back again in the air feed pipe by the back flow again, realize gaseous circulation and flow, and in the leading-in below drying cylinder of gas after the moderate degree cooling, textile fabric after preliminary drying carries out secondary drying, effectively avoid causing textile fabric's hot melt fracture because of higher temperature.

(3) Inside arc water conservancy diversion piece that all is equipped with of two dryer drums, the connection of arc water conservancy diversion piece bottom is located the intake pipe, on the dryer inner wall between the blast pipe, arc water conservancy diversion piece upper end and dryer top end wall form the water conservancy diversion mouth, the arc water conservancy diversion piece sets up to fibre driving roller one side arc protrusion, be favorable to locating leading-in gas from the intake pipe to the upwards drainage motion of fibre driving roller one side, the steam of drainage upward movement not only plays the intensification effect to fibre driving roller, still be favorable to playing clockwise operation effect to fibre driving roller, thereby be favorable to textile fiber to pull downwards, the space that the water conservancy diversion mouth formed, a derivation for the guide gas that makes progress.

(4) The fibre driving roller is cavity tubular structure, the cladding has the cotton layer of fibre that absorbs water on the outer end wall of fibre driving roller, textile fiber from top to bottom pulls through two fibre driving rollers, the cotton layer of fibre that absorbs water adsorbs the moisture on the textile fiber, and pull the in-process, because frictional force between the two makes fibre driving roller clockwise rotation, thereby play the dry effect of developments absorbing water, improve drying effect, and avoid hot-blast direct supply, be difficult for causing fibrous hot melt fracture.

(5) A drying cylinder, arc water conservancy diversion piece and fibre driving roller all adopt the heat conduction material to make, and fibre driving roller is inside to be filled has a plurality of graphite heat conduction particles, and the cladding has the insulating layer on the end wall that the drying cylinder is located the drying cabinet inboard, has both improved heat transfer efficiency, prevents again that the heat from scattering and disappearing.

(6) Flexible heat-conducting piece is including connecting the heat-conducting plate between a pair of guide roll, the upper and lower both ends of heat-conducting plate set up to the upper and lower direction slope of fibre driving roller respectively, and it has a plurality of flexible arcs to divide cloth equally on the upper and lower end wall of heat-conducting plate, the tip of a plurality of flexible arcs all distributes and has a plurality of fibre pile belts, the upper and lower both ends of heat-conducting plate set up along textile fabric's direction of traction, textile fabric is in traction in-process and the fibre pile belt frictional contact on the flexible arcs, improve the moisture absorption drying process effect to textile fabric, and play the carding effect to textile fabric.

(7) The stock solution chamber has been seted up to flexible arc piece inside, and stock solution intracavity portion is filled has antistatic coating, and the inner flooding in stock solution chamber bottom in the fibre fine hair area, and the fibre fine hair area adopts the high permeable material that absorbs water to make, and fibre fine hair area the inner bottom of extending to the stock solution intracavity, and textile fiber is when drawing in-process and fibre fine hair area frictional contact, is favorable to coating antistatic coating on textile fiber, effectively improves textile fiber's antistatic properties.

Drawings

FIG. 1 is a perspective view of the present invention;

FIG. 2 is a partial internal cross-sectional view of the present invention;

FIG. 3 is a partial internal cross-sectional view of the second embodiment of the present invention;

FIG. 4 is a cross-sectional view of the interior of the dryer cartridge of the present invention;

FIG. 5 is an internal schematic view of the present invention;

FIG. 6 is a schematic view of the flexible heat-conducting member of the present invention shown disengaged from the drying cylinder;

FIG. 7 is a first external view of the present invention in operation;

FIG. 8 is a second external view of the present invention in operation;

FIG. 9 is a schematic view of the structure at the flexible heat-conducting member of the present invention;

fig. 10 is an enlarged view of a portion of a flexible arcuate sheet of the present invention.

The reference numbers in the figures illustrate:

the drying device comprises a drying box 1, a drying cylinder 2, a fiber driving roller 3, an arc-shaped flow deflector 4, a heating box 5, an air inlet pipe 6, an air nozzle 601, an air exhaust pipe 7, an air exhaust port 701, a communicating pipe 8, an air storage pipe 9, a return pipe 10, a guide roller 11, a flexible heat conducting part 12, a heat conducting plate 121, a flexible arc-shaped sheet 122 and a fiber velvet ribbon 123.

Detailed Description

The drawings in the embodiments of the invention will be combined; the technical scheme in the embodiment of the invention is clearly and completely described; obviously; the described embodiments are only some of the embodiments of the invention; but not all embodiments, are based on the embodiments of the invention; all other embodiments obtained by a person skilled in the art without making any inventive step; all fall within the scope of protection of the present invention.

In the description of the present invention, it should be noted that the terms "upper", "lower", "inner", "outer", "top/bottom", and the like indicate orientations or positional relationships based on those shown in the drawings, and are only for convenience of description and simplification of description, but do not indicate or imply that the referred device or element must have a specific orientation, be constructed in a specific orientation, and be operated, and thus should not be construed as limiting the present invention. Furthermore, the terms "first" and "second" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

In the description of the present invention, it should be noted that, unless otherwise explicitly specified or limited, the terms "mounted," "disposed," "sleeved/connected," "connected," and the like are to be construed broadly, e.g., "connected," which may be fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meanings of the above terms in the present invention can be understood in specific cases to those skilled in the art.

Example 1:

referring to fig. 1-3, a drying device for textile fiber processing comprises a drying box 1, two drying cylinders 2 are embedded and installed on the outer end wall of the drying box 1, the inner ends of the two drying cylinders 2 extend to the inner side of the drying box 1, fiber driving rollers 3 are installed on the outer end walls of the two drying cylinders 2 in a rotating mode, the outer ends of the fiber driving rollers 3 extend outwards, air inlet pipes 6 and exhaust pipes 7 are respectively embedded on the end walls, located on the inner side of the drying box 1, of the two drying cylinders 2, a circulating air supply mechanism is installed inside the drying box 1, an air supply pipe connected with the circulating air supply mechanism is arranged at the outer end of the drying box 1, and the circulating air supply mechanism is connected with the air inlet pipes 6 and the exhaust pipes 7.

The gas supply mechanism comprises a heating box 5, a communicating pipe 8, a gas storage pipe 9 and a return pipe 10, the heating box 5 is arranged in the drying box 1 and is connected with the gas supply pipe, the gas supply pipe is communicated with an external gas inlet source, the inner end of the heating box 5 is connected with a gas inlet pipe 6 positioned on the upper drying cylinder 2 through a plurality of first gas inlet hoses, the gas storage pipe 9 is connected with a gas outlet pipe 7 positioned on the upper drying cylinder 2 through the communicating pipe 8, the gas storage pipe 9 is connected with a gas inlet pipe 6 positioned on the lower drying cylinder 2 through a plurality of second gas inlet hoses, the gas outlet pipe 7 positioned on the lower drying cylinder 2 is connected with the return pipe 10, the return pipe 10 is connected with the gas inlet pipe, the gas is heated by the heating box 5, the heated gas is guided into the upper drying cylinder 2 through the gas inlet pipe 6, the gas guided out from the drying cylinder 2 is guided into the gas storage pipe 9 through the gas outlet pipe 7 and the communicating pipe 8, and the gas is guided into the drying cylinder 2 below by the gas storage pipe 9, the gas behind the drying cylinder 2 below is guided back into the gas supply pipe again by the return pipe 10, the circular flow of the gas is realized, the gas after moderate cooling is guided into the drying cylinder 2 below, the fiber driving roller 3 at the drying cylinder 2 below performs secondary drying on the textile fiber after primary drying, and the hot melting fracture of the textile fiber caused by higher temperature is effectively avoided.

Referring to fig. 4-5, a pair of exhaust pipes 7 are respectively provided with an exhaust port 701, a pair of intake pipes 6 are respectively provided with a plurality of air nozzles 601, and the jet ports of the air nozzles 601 are obliquely arranged towards one side of the fiber driving roller 3, the two drying cylinders 2 are respectively provided with an arc-shaped deflector 4 inside, the bottom end of the arc-shaped deflector 4 is connected to the inner wall of the drying cylinder 2 between the intake pipe 6 and the exhaust pipe 7, the upper end of the arc-shaped deflector 4 and the top end wall of the drying cylinder 2 form a deflector port, the arc-shaped deflector 4 is convexly arranged towards one side of the fiber driving roller 3, so as to facilitate the upward flow guiding movement of the air introduced from the intake pipe 6 to one side of the fiber driving roller 3, the hot air of the upward flow guiding movement not only has the function of heating and drying to the fiber driving roller 3, but also is beneficial to the clockwise operation to the fiber driving roller 3, thereby facilitating the downward traction of the textile fibers, the wetted end of the fiber driving roller 3 rotates to the inner side of the drying cylinder 2 to receive the hot air for drying, the drying speed of the fiber driving roller 3 is improved by the circulation.

The fiber driving roller 3 is of a hollow tubular structure, the outer end wall of the fiber driving roller 3 is coated with a water-absorbing fiber cotton layer, textile fibers are pulled by the two fiber driving rollers 3 from top to bottom, the water-absorbing fiber cotton layer absorbs water on the textile fibers, and in the pulling process, the fiber driving roller 3 rotates clockwise due to friction force between the water-absorbing fiber cotton layer and the textile fibers, so that dynamic water-absorbing and drying effects are achieved, the drying effect is improved, direct supply of hot air is avoided, hot melt fracture of the fibers is not easily caused, the drying cylinder 2, the arc-shaped flow deflector 4 and the fiber driving roller 3 are made of heat conduction materials, the fiber driving roller 3 is filled with a plurality of graphite heat conduction particles, the end wall of the drying cylinder 2, which is positioned on the inner side of the drying box 1, is coated with a heat insulation layer, heat is easily transferred to the air at the outer side of the drying cylinder 2 through the drying cylinder 2, and heat is effectively prevented from gathering in the drying box 1, not only improves the heat transfer efficiency, but also prevents the heat loss.

Referring to fig. 5-9, a plurality of guide rollers 11 are disposed at an outer side of one end of the drying box 1 and are spaced apart from each other between the fiber driving rollers 3, the plurality of guide rollers 11 are used for guiding and drawing the textile fiber to be guided along the two drying cylinders 2, a flexible heat conducting member 12 is disposed between two adjacent guide rollers 11, the flexible heat conducting member 12 is disposed corresponding to the fiber driving rollers 3, the flexible heat conducting member 12 includes a heat conducting plate 121 connected between the pair of guide rollers 11, upper and lower ends of the heat conducting plate 121 are respectively inclined toward the upper and lower directions of the fiber driving rollers 3, and upper and lower end walls of the heat conducting plate 121 are uniformly distributed with a plurality of flexible arc-shaped pieces 122, end portions of the plurality of flexible arc-shaped pieces 122 are uniformly distributed with a plurality of fiber velvet ribbons 123, upper and lower ends of the heat conducting plate 121 are disposed along a drawing direction of the textile fiber, the textile fiber is in frictional contact with the fiber velvet ribbons 123 on the flexible arc-shaped pieces 122 during the drawing process, the moisture absorption and drying treatment effect on the textile fibers is improved, and the carding function on the textile fibers is achieved.

Referring to fig. 10, it is to be added that a liquid storage cavity is formed inside the flexible arc-shaped piece 122, an antistatic coating is filled inside the liquid storage cavity, the inner end of the fiber velvet ribbon 123 is dipped at the bottom of the liquid storage cavity, the fiber velvet ribbon 123 is made of a high water-absorption permeable material, the inner end of the fiber velvet ribbon 123 extends to the bottom of the liquid storage cavity, and when the textile fiber is in frictional contact with the fiber velvet ribbon 123 in the traction process, the antistatic coating is favorably coated on the textile fiber, so that the antistatic property of the textile fiber is effectively improved.

Compared with the drying device for textile fibers in the prior art, the drying device for textile fibers has the advantages that the two drying cylinders 2 which are sequentially arranged from top to bottom are arranged on one side of the drying box 1, the fiber driving rollers 3 which are in traction contact with the textile fibers are arranged on the drying cylinders 2, air flow is supplied to the insides of the two drying cylinders 2 by the aid of the air supply mechanism, the textile fibers rub the fiber driving rollers 3 in the traction process, the heated fiber driving rollers 3 are pulled to rotate clockwise, dynamic water absorption and drying effects are achieved, drying effects are improved, hot air is prevented from being directly supplied, and hot melt fracture of the fibers is avoided.

The components used in the present invention are all standard components or components known to those skilled in the art, and the structure and principle thereof can be known to those skilled in the art through technical manuals or through routine experiments.

The above; but are merely preferred embodiments of the invention; the scope of the invention is not limited thereto; any person skilled in the art is within the technical scope of the present disclosure; the technical scheme and the improved concept of the invention are equally replaced or changed; are intended to be covered by the scope of the present invention.

Claims

1. The utility model provides a drying device is used in textile fiber processing, includes drying cabinet (1), its characterized in that: the drying box is characterized in that two drying cylinders (2) are embedded on the outer end wall of the drying box (1), the inner ends of the drying cylinders (2) extend to the inner side of the drying box (1), the outer end wall of the drying cylinders (2) is rotated to be provided with fiber transmission rollers (3), the outer ends of the fiber transmission rollers (3) extend outwards, the two drying cylinders (2) are located on the inner end wall of the drying box (1) and are respectively embedded with an air inlet pipe (6) and an exhaust pipe (7), a circulating air supply mechanism is installed inside the drying box (1), an air supply pipe connected with the circulating air supply mechanism is arranged at the outer end of the drying box (1), and the circulating air supply mechanism is connected with a pair of air inlet pipes (6) and the exhaust pipe (7);

the drying cabinet is characterized in that a plurality of guide rollers (11) distributed between the fiber driving rollers (3) at intervals are arranged on the outer side of one end of the drying cabinet (1), a flexible heat conducting piece (12) is arranged between every two adjacent guide rollers (11), and the flexible heat conducting piece (12) corresponds to the position of the fiber driving rollers (3).

2. A drying apparatus for textile fibre processing according to claim 1, characterised in that: air feed mechanism includes heating cabinet (5), communicating pipe (8), holds trachea (9) and back flow (10), heating cabinet (5) are installed in drying cabinet (1) and are connected with the air supply pipe, heating cabinet (5) inner is connected with intake pipe (6) that are located on top drying cylinder (2) through a plurality of first air inlet hose, hold trachea (9) and be connected with blast pipe (7) that are located on top drying cylinder (2) through communicating pipe (8), hold trachea (9) and be connected with intake pipe (6) that are located below drying cylinder (2) through a plurality of second air inlet hose, and blast pipe (7) that are located below drying cylinder (2) are connected with back flow (10), back flow (10) are connected with the intake pipe.

3. A drying apparatus for textile fibre processing according to claim 1, characterised in that: the exhaust ports (701) are formed in the exhaust pipes (7), the air inlet pipes (6) are provided with a plurality of air nozzles (601), and jet ports of the air nozzles (601) are arranged in an inclined mode towards one side of the fiber driving roller (3).

4. A drying apparatus for textile fibre processing according to claim 3, characterised in that: two inside arc water conservancy diversion piece (4) that all is equipped with of dryer (2), arc water conservancy diversion piece (4) bottom is connected on dryer (2) inner wall that is located between intake pipe (6), blast pipe (7), arc water conservancy diversion piece (4) upper end and dryer (2) top wall form the water conservancy diversion mouth.

5. A drying apparatus for textile fibre processing according to claim 4, characterised in that: the arc-shaped guide vanes (4) are arranged in an arc-shaped protruding mode towards one side of the fiber driving roller (3).

6. A drying apparatus for textile fibre processing according to claim 5, characterised in that: the fiber driving roller (3) is of a hollow cylindrical structure, and the outer end wall of the fiber driving roller (3) is coated with a water-absorbing fiber cotton layer.

7. A drying apparatus for textile fibre processing according to claim 6, characterised in that: the drying cylinder (2), the arc-shaped flow deflector (4) and the fiber driving roller (3) are all made of heat conducting materials.

8. A drying apparatus for textile fibre processing according to claim 1, characterised in that: flexible heat-conducting piece (12) are including connecting heat-conducting plate (121) between a pair of guide roll (11), the upper and lower both ends of heat-conducting plate (121) set up to the upper and lower direction slope of fibre driving roller (3) respectively, and equally divide on the upper and lower end wall of heat-conducting plate (121) and distribute a plurality of flexible arcs piece (122), and is a plurality of the tip of flexible arcs piece (122) all distributes and has a plurality of fibre velvet ribbon (123).

9. A drying apparatus for textile fibre processing according to claim 8, characterised in that: a liquid storage cavity is formed in the flexible arc-shaped piece (122), antistatic paint is filled in the liquid storage cavity, and the inner end of the fiber velvet ribbon (123) is soaked at the bottom of the liquid storage cavity.

10. A drying apparatus for textile fibre processing according to claim 9, characterised in that: the fiber velvet ribbon (123) is made of high water absorption and permeation materials, and the inner end of the fiber velvet ribbon (123) extends to the bottom in the liquid storage cavity.