CN111893646B - Non-woven fabric production and setting equipment - Google Patents

Abstract

The invention discloses a non-woven fabric production setting device, which structurally comprises a setting bin, a control electric box, a base, a motor and a conveying table, wherein the control electric box is electrically connected with the base, the motor is arranged at the front end of the base, the conveying table is embedded in the inner position of the base, the setting bin is welded at the upper end position of the conveying table, fibers conveyed to the bottom of the setting bin can be rolled by a heated setting press roller, thermoplastic fibers are quickly softened while rolling, so that the natural fibers and the thermoplastic fibers can be quickly set together by the pressure generated by the setting press roller, and the condition that heat generated by heat conducting oil above the top surface is directly guided into the bottom block can be avoided through a gap generated between the top surface and the bottom block on a heat dissipation mechanism, so that the heat generated by the bottom of a heating inner container after long-time use can be prevented from directly influencing the bottom of the outer container, the temperature at the bottom of the outer cylinder is greatly increased.

Description

Non-woven fabric production and setting equipment

Technical Field

The invention relates to the field of non-woven fabric equipment, in particular to non-woven fabric production and shaping equipment.

Background

The non-woven fabrics forming machine mainly used heats the equipment that bonds the design to the fibre that thermoplasticity is strong, mainly be through the transmission warm table in the conduction oil heat setting machine, then heat thermoplastic fiber, after thermoplasticity reaches the uniform temperature, use inside design compression roller to roll the design to the fibre after the heating, because the production needs, there are some non-woven fabrics inside to add natural fiber cotton, the ramie etc. to make the non-woven fabrics of producing have good moisturizing, characteristics such as warmth retention, often be used for articles for daily use processing such as various cushions, based on the discovery of the inventor of the above-mentioned description, a current non-woven fabrics production forming machine mainly has following not enoughly, for example:

as is known, natural fibers such as cotton, hemp and the like belong to non-thermoplastic fibers and are not high-temperature resistant, the traditional manufacturing method is to mix partial natural fibers in the upper layer of the thermoplastic fibers, so that the thermoplastic fibers can be adhered to the natural fibers after being heated, the natural fibers and the thermoplastic fibers are compacted together through a shaping press roll, and if partial natural fibers are adhered to the surface of a transmission heating table with a long transmission length through gaps among the thermoplastic fibers, the natural fibers are excessively heated and scorched.

Disclosure of Invention

Aiming at the problems, the invention provides non-woven fabric production and shaping equipment.

In order to achieve the purpose, the invention is realized by the following technical scheme: a non-woven fabric production shaping device structurally comprises a shaping bin, a control electric box, a base, a motor and a conveying table, wherein the control electric box is electrically connected with the base; the shaping bin comprises an outer frame, a pressing end and a shaping compression roller, wherein one end of the pressing end is fixedly embedded and connected with the upper end of the inner wall of the outer frame, and the other end of the pressing end is connected with the shaping compression roller.

As a further optimization of the invention, the pressure applying end comprises a pushing strip, a guide frame and a lower pressure rod, the pushing strip is arranged between the guide frame and the lower pressure rod, the lower pressure rod is in clearance fit with the guide frame, and the lower pressure rod can be pushed by the guide frame to press an object connected with the lower pressure rod downwards.

As a further optimization of the invention, the shaping press roller comprises an outer cylinder, a joining block, a heating inner container and a heat conduction layer, wherein the outer cylinder and the joining block are of an integrated structure, the heating inner container is in clearance fit with the outer cylinder, the heat conduction layer is embedded between the outer cylinder and the heating inner container, and the heat conduction layer is of a continuous triangular structure made of aluminum with high heat conductivity.

As a further optimization of the invention, the outer cylinder comprises a caking ring and heat equalizing blocks, the heat equalizing blocks are fixedly embedded with the caking ring, twenty-four heat equalizing blocks are arranged, and the outer surfaces of the caking rings are uniformly distributed in a circular manner.

As a further optimization of the invention, the soaking block comprises a block body, a heat transfer sheet, a movable plate and a rebound ring, the heat transfer sheet is arranged between the movable plate and the block body, the movable plate is hinged with the block body through the rebound ring, and the heat transfer sheet is of a wave-shaped sheet structure made of copper materials with high thermal conductivity.

As a further optimization of the invention, the heating liner comprises a shell, partition plates and heat dissipation mechanisms, the connecting blocks are fixedly embedded in the upper end and the lower end of the inner wall of the shell, the heat dissipation mechanisms are arranged between two adjacent partition plates, and eleven partition plates are uniformly distributed on the inner wall of the shell in parallel.

As a further optimization of the invention, the heat dissipation mechanism comprises a top surface, four support frames and a bottom block, wherein the top surface is arranged at the upper end position of the bottom block, the four support frames are embedded between the top surface and the bottom block, and the four support frames are uniformly distributed between the top surface and the bottom block in a fan shape.

As a further optimization of the invention, the bottom block comprises an upper plate, a linkage piece, a frame, heat collection blocks, a lower plate, a swing plate, an elastic strip, a ventilation port and a heated plate, wherein the linkage piece is embedded and fixed at the bottom of the upper plate, the frame is connected with the lower plate through the heat collection blocks, the swing plate is movably clamped with the heated plate, the elastic strip is arranged between the inner wall of the heated plate and the swing plate, the ventilation port and the lower plate are of an integrated structure, the heated plate is fixed between the two heat collection blocks, and the outer surface of the frame is of an arc concave structure.

The invention has the following beneficial effects:

1. convey thermoplastic fiber and natural fiber inside the design storehouse through conveying the platform to make the design compression roller after the heating can roll the fibre that conveys its bottom, make thermoplastic fiber soften fast when rolling, thereby make design compression roller produce pressure can be in the same place natural fiber and thermoplastic fiber fast design, the effectual traditional mode that heats through conveying the platform that has avoided makes the natural fiber who falls into the bottom appear the condition of scorching.

2. The heating speed of the heating inner container to the internal heat conduction oil can be enhanced through the partition plate on the heating inner container, and the space generated between the top surface on the heat dissipation mechanism and the bottom block can be used for avoiding the situation that the heat generated by the heat conduction oil above the top surface is directly led into the inside of the bottom block, so that the heat generated by the bottom of the heating inner container in long-time use can be prevented, the influence on the bottom of the outer container is directly caused, and the temperature at the bottom of the outer container is greatly increased.

Drawings

FIG. 1 is a schematic structural diagram of a non-woven fabric production and setting device of the present invention.

FIG. 2 is a schematic structural view of the interior of the sizing bin of the present invention.

FIG. 3 is a front half-section schematic view of the sizing roller of the present invention.

FIG. 4 is a schematic side view of the sizing roller according to the present invention.

FIG. 5 is a schematic structural diagram of the outer cylinder of the present invention in a side view.

FIG. 6 is a side view of the thermal block of the present invention.

Fig. 7 is a schematic structural view of a front half section of the heating liner of the present invention.

Fig. 8 is a schematic structural diagram of a front cross-sectional device of a heat dissipation mechanism according to the present invention.

FIG. 9 is a schematic view of a bottom block in half section according to the present invention.

In the figure: shaping bin-1, control electric box-2, base-3, motor-4, transfer table-5, outer frame-11, pressure applying end-12, shaping press roller-13, pushing strip-121, guide frame-122, lower press rod-123, outer cylinder-a 1, connecting block-a 2, heating inner container-a 3, heat conducting layer-a 4, caking ring-a 11, soaking block-a 12, block-b 1, heat conducting sheet-b 2, movable plate-b 3, rebounding ring-b 4, shell-c 1, partition-c 2, heat radiating mechanism-c 3, top surface-c 31, support frame-c 32, bottom block-c 33, upper plate-d 1, linkage sheet-d 2, frame-d 3, heat collecting block-d 4, lower plate-d 5, swinging plate-d 6, Elastic strip-d 7, air vent-d 8 and heated plate-d 9.

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.

Example 1

As shown in fig. 1-6:

the invention provides non-woven fabric production and shaping equipment which structurally comprises a shaping bin 1, a control electric box 2, a base 3, a motor 4 and a conveying table 5, wherein the control electric box 2 is electrically connected with the base 3, the motor 4 is arranged at the front end of the base 3, the conveying table 5 is embedded in the inner position of the base 3, and the shaping bin 1 is welded at the upper end of the conveying table 5; the shaping bin 1 comprises an outer frame 11, a pressing end 12 and a shaping press roller 13, wherein one end of the pressing end 12 is fixedly connected with the upper end of the inner wall of the outer frame 11 in an embedded mode, and the other end of the pressing end 12 is connected with the shaping press roller 13.

The pressing end 12 includes a pushing bar 121, a guide frame 122, and a pressing rod 123, the pushing bar 121 is installed between the guide frame 122 and the pressing rod 123, the pressing rod 123 is in clearance fit with the guide frame 122, and the pressing rod 123 can be pushed by the guide frame 122 to press the object connected to the pressing rod 123 downward, so that the object can be tightly attached to the surface of the fiber under the pressing and pressing action of the pressing rod 123.

The shaping press roller 13 comprises an outer cylinder a1, a connecting block a2, a heating inner container a3 and a heat conducting layer a4, the outer cylinder a1 and the connecting block a2 are of an integrated structure, the heating inner container a3 is in clearance fit with the outer cylinder a1, the heat conducting layer a4 is embedded between an outer cylinder a1 and a heating inner container a3, the left end and the right end of the heating inner container a3 are separately connected with an object, so that the heating inner container a3 is fixed inside the outer cylinder a1, the outer cylinder a1 rotates around the heating inner container a3, heat conducting oil is filled inside the heating inner container a3, and the heat conducting layer a4 is of a continuous triangular structure made of aluminum materials with high heat conductivity, so that heat generated inside the heating inner container a3 can be rapidly conducted to an outer cylinder a 1.

The outer cylinder a1 comprises a caking ring a11 and soaking blocks a12, the soaking blocks a12 are fixedly connected with the caking ring a11 in an embedded mode, twenty-four soaking blocks a12 are arranged, the outer surface of the caking ring a11 is uniformly distributed in a circular mode, and gaps exist between two adjacent soaking blocks a12, so that heat received by the caking ring a11 can be uniformly introduced into each soaking block a 12.

The heat-equalizing block a12 comprises a block body b1, a heat transfer sheet b2, a movable plate b3 and a rebound ring b4, wherein the heat transfer sheet b2 is installed between the movable plate b3 and the block body b1, the movable plate b3 is hinged with the block body b1 through the rebound ring b4, the heat transfer sheet b2 is of a wavy sheet structure which is made of copper materials with high thermal conductivity, and the heat transfer sheet b2 can continuously guide heat on the block body b1 to the movable plate b3 while zooming along with the swinging of the movable plate b 3.

The detailed use method and action of the embodiment are as follows:

in the invention, as the traditional method for manufacturing the warm-keeping non-woven fabric is to mix partial natural fibers in the upper layer of the thermoplastic fibers, the thermoplastic fibers can be adhered to the natural fibers after being heated, the thermoplastic fibers and the natural fibers are compacted together by the shaping press roller 13, if partial natural fibers are adhered to the surface of the conveying table 5 with longer conveying length through gaps between the thermoplastic fibers, the natural fibers are excessively heated and scorched, the problems can be effectively solved through the matching of the pressing end 12 on the shaping bin 1 and the shaping press roller 13, the heat conduction oil in the shaping press roller 13 can be heated by the heating inner container a3, the thermoplastic fibers and the natural fibers are conveyed into the shaping bin 1 by the conveying table 5, the lower press rod 123 can be pushed downwards by the pushing strip 121 on the pressing end 12, and the lower press rod 123 can generate downward pressure on the heating inner container a3 connected with the lower press rod, therefore, the outer cylinder a1 can be tightly attached to the fiber material on the conveying table 5, the heating inner liner a3 and the lower pressing rod 123 are connected inside the shaping pressing roller 13 and are in a fixed state, so that the outer cylinder a1 can rotate around the heating inner liner a3 along with the driving of the fibers on the conveying table 5, the heat conduction layer a4 between the outer cylinder a1 and the heat conduction layer a4 can guide the heat generated inside the heating inner liner a3 into the upper half part of the outer cylinder a1 until the outer cylinder a1 can rotate the part containing the heat downwards to heat and roll the fibers at the bottom, the natural fibers can be prevented from directly contacting with the heating inner liner a3 with high heat, the fibers conveyed to the bottom of the outer cylinder a1 can be rolled through the bottom of the outer cylinder a1, the thermoplastic fibers are quickly softened while rolling, and the shaping pressing roller 13 can generate pressure to quickly shape the natural fibers and the thermoplastic fibers together, the situation that natural fibers falling into the bottom are burnt in a traditional heating mode through the conveying table 5 is effectively avoided, then the heat equalizing block a12 on the outer cylinder a1 can evenly distribute the heat conducted by the heating inner container a3, the situation that the rolled non-woven fabric is uneven in surface due to the fact that the local temperature of the outer cylinder a1 is too high is effectively avoided, and the movable plate b3 can swing upwards along the rebound ring b4 when the fiber is rolled by the heat equalizing block a12, so that the movable plate b3 can be reset quickly through the rebound ring b4 when the heat equalizing block a12 leaves the fiber surface, and the movable plate b3 can bounce natural fiber cotton wool adhered to the surface of the movable plate b3, and the situation that the natural fibers stay for a long time due to the fact that the heat equalizing block a12 is adhered to the surface of the movable plate b4 is effectively avoided.

Example 2

As shown in fig. 7-9:

the heating inner container a3 comprises a shell c1, partition plates c2 and a heat dissipation mechanism c3, wherein the connection block a2 is embedded in the upper end and the lower end of the inner wall of the shell c1, the heat dissipation mechanism c3 is installed between the two adjacent partition plates c2, eleven partition plates c2 are arranged, the inner walls of the shell c1 are uniformly distributed in parallel, and the heating speed of heat conduction oil inside the shell c1 by the mechanism can be increased.

The heat dissipation mechanism c3 includes top surface c31, support frame c32, bottom block c33, top surface c31 installs in the upper end position of bottom block c33, support frame c32 inlays between top surface c31 and bottom block c33, support frame c32 is equipped with four, and even be fan-shaped distribution between top surface c31 and bottom block c33 to be the fretwork state between top surface c31 and bottom block c33, avoided the direct leading-in inside condition of bottom block c33 of heat above top surface c 31.

Wherein the bottom block c33 comprises an upper plate d1, a linkage sheet d2, a frame d3, a heat collecting block d4, a lower plate d5, a swinging plate d6, an elastic strip d7, an air vent d8 and a heated plate d9, the linkage sheet d2 is fixedly embedded at the bottom position of the upper plate d1, the frame d3 is connected with the lower plate d5 through a heat collecting block d4, the swinging plate d6 is movably clamped with the heated plate d9, the elastic strip d7 is installed between the inner wall of the heated plate d9 and the swinging plate d6, the air vent d8 and the lower heat conducting plate d5 are of an integrated structure, the heated plate d9 is fixed between the two heat collecting blocks d4, the linkage sheet d2 is of a sheet-shaped structure made of a spring steel with stronger elasticity, and can swing back and forth through blowing of air flow, the surface of the frame d3 is of an arc-shaped structure, thereby avoiding contact with the external surface of the heat collecting block d4 a, reducing the heat conduction structure of the object directly, the heat transferred by the frame d3 can be intensively led into the heated plate d9, the swinging plates d6 are provided with five swinging plates which are uniformly distributed on the heated plate d9 in an arc shape, the swinging plates can be pushed by external air flow to swing back and forth through the cooperation of the elastic strips d7, the ventilation ports d8 are of a vertically through structure, and part of air flow generated by rotation is led into an object through the rotation of the mechanism.

The detailed use method and action of the embodiment are as follows:

in the invention, because the heat conducting oil in the heating inner container a3 is always vertically downward when the outer cylinder a1 rotates, so that after the shaping press roller 13 is used for a long time, the heat of the heat conducting oil in the heating inner container a3 can be gradually and continuously transferred to the bottom of the outer cylinder a1 through the air between the outer cylinder a1 and the heating inner container a3, and the bottom temperature of the outer cylinder a1 is overhigh, the problem can be effectively solved by heating the heat dissipation mechanism c3 on the inner container a3, the heating speed of the heating inner container a3 on the heat conducting oil in the heating inner container a3 can be enhanced by heating the partition plate c2 on the inner container a3, so as to improve the shaping efficiency of the shaping press roller 13 on fibers, and the condition that the heat generated above the top surface c31 is directly transferred into the bottom block c33 through the gap generated between the heat conducting oil c31 on the heat dissipation mechanism c3 and the bottom block c33 can be avoided, so that the heating speed of the bottom block c33 can be slowed down to a certain degree, the frame d3 of the bottom block c33 can prevent the heat dissipation mechanism c3 from directly contacting the partition plate c2, so that the heating speed of a33 can be further reduced, the heat collected by the heat collection block d4 can concentrate the heat led in the frame d3 on the heated plate d9, the air flow generated by the rotation of the outer cylinder a1 around the heating liner a3 can enter the bottom block c33 through the air vent d8 on the bottom block c33, so that the led air flow can push the swinging plate d6 on the heated plate d9, the swinging plate d6 can swing back and forth under the coordination of the heated plate d9, and the stronger air flow generated by swinging can be matched with the external air flow to dissipate the heat on the heated plate d9, and the air flow generated by the swinging plate d6 in the swinging of the upper end can affect the linkage sheet d2, so that the linkage sheet d2 swings, and the linkage sheet d2 generates the swinging air flow, the heat on the upper plate d1 can be dissipated, the shaping press roller 13 is effectively prevented from being used for a long time, and the heat on the heating inner container a3 is led into the bottom of the outer cylinder a1 in a large quantity, so that the temperature of the bottom of the outer cylinder a1 is too high, and the natural fibers are easily burnt.

The technical solutions of the present invention or similar technical solutions designed by those skilled in the art based on the teachings of the technical solutions of the present invention are all within the scope of the present invention to achieve the above technical effects.

Claims (1)

1. The utility model provides a non-woven fabrics production modular system, its structure is including design storehouse (1), control electronic box (2), base (3), motor (4), conveying platform (5), control electronic box (2) are connected with base (3) electricity, install in the front end position of base (3) motor (4), conveying platform (5) imbed in the inside position of base (3), its characterized in that: the shaping bin (1) is welded at the upper end of the conveying table (5);

the shaping bin (1) comprises an outer frame (11), a pressing end (12) and a shaping press roller (13), wherein one end of the pressing end (12) is fixedly connected with the upper end of the inner wall of the outer frame (11), and the other end of the pressing end (12) is connected with the shaping press roller (13);

the pressing end (12) comprises a pushing strip (121), a guide frame (122) and a lower pressing rod (123), the pushing strip (121) is installed between the guide frame (122) and the lower pressing rod (123), and the lower pressing rod (123) is in clearance fit with the guide frame (122);

the shaping press roller (13) comprises an outer cylinder (a1), a joining block (a2), a heating inner container (a3) and a heat conduction layer (a4), wherein the outer cylinder (a1) and the joining block (a2) are of an integrated structure, the heating inner container (a3) is in clearance fit with the outer cylinder (a1), and the heat conduction layer (a4) is embedded between the outer cylinder (a1) and the heating inner container (a 3);

the outer cylinder (a1) comprises a knot ring (a11) and a soaking block (a12), and the soaking block (a12) is fixedly connected with the knot ring (a 11);

the heat equalizing block (a12) comprises a block body (b1), a heat transfer plate (b2), a movable plate (b3) and a rebound ring (b4), wherein the heat transfer plate (b2) is mounted between the movable plate (b3) and the block body (b1), and the movable plate (b3) is hinged with the block body (b1) through the rebound ring (b 4);

the heating inner container (a3) comprises a shell (c1), partition plates (c2) and a heat dissipation mechanism (c3), wherein the connecting block (a2) is embedded in the upper end and the lower end of the inner wall of the shell (c1), and the heat dissipation mechanism (c3) is installed between every two adjacent partition plates (c 2);

the heat dissipation mechanism (c3) comprises a top surface (c31), a support frame (c32) and a bottom block (c33), wherein the top surface (c31) is installed at the upper end position of the bottom block (c33), and the support frame (c32) is embedded between the top surface (c31) and the bottom block (c 33);

the bottom block (c33) comprises an upper plate (d1), a linkage piece (d2), a frame (d3), a heat collection block (d4), a lower plate (d5), a swinging plate (d6), an elastic strip (d7), an air vent (d8) and a heat receiving plate (d9), wherein the linkage piece (d2) is fixedly embedded at the bottom of the upper plate (d1), the frame (d3) is connected with the lower plate (d5) through the heat collection block (d4), the swinging plate (d6) is movably clamped with the heat receiving plate (d9), the elastic strip (d7) is installed between the inner wall of the heat receiving plate (d9) and the swinging plate (d6), the air vent (d8) and the lower plate (d5) are of an integrated structure, and the heat receiving plate (d9) is fixed between the two heat collection blocks (d 4).

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