CN115323745A

CN115323745A - Processing and generating system for melt-blown non-woven fabric

Info

Publication number: CN115323745A
Application number: CN202210906657.9A
Authority: CN
Inventors: 胡婷婷
Original assignee: Individual
Current assignee: Individual
Priority date: 2022-07-29
Filing date: 2022-07-29
Publication date: 2022-11-11

Abstract

The invention relates to the technical field of non-woven fabric production, in particular to a processing and generating system for melt-blown non-woven fabric; the non-woven fabric pressing device comprises three flattening parts arranged on the same straight line, a shaking part used for driving the flattening part located in the middle to move up and down, and a filtering part arranged on the shaking part, wherein after the non-woven fabric sequentially penetrates through the three flattening parts, the shaking part can drive the flattening part located in the middle to circularly move up and down; the shaking part comprises a frame, a sliding rod fixed on the frame and a sliding beam sliding on the sliding rod, and a sliding seat in the middle flattening part is fixed on the sliding beam; a bracket is fixed on the frame, a push rod is rotated on the bracket, and the end part of the push rod slides in a groove arranged on the sliding beam; individual fibers can be cleaned during the nonwoven manufacturing process.

Description

Processing and generating system for melt-blown non-woven fabric

Technical Field

The invention relates to the technical field of non-woven fabric production, in particular to a processing and generating system for melt-blown non-woven fabric.

Background

The non-woven fabric is also called non-woven fabric, needle-punched cotton, needle-punched non-woven fabric and the like, is produced by adopting polyester fiber and polyester fiber materials and is manufactured by a needle-punching process, different thicknesses, handfeel, hardness and the like can be manufactured, the non-woven fabric has no warp and weft, is very convenient to cut and sew, is light in weight and easy to set, and the conventional melt-blown non-woven fabric needs to be produced by the steps of polymer input, melt extrusion, fiber formation, fiber cooling, net forming, cloth reinforcement and the like; however, in such a production process, since the fibers are interlaced and intertwined by the needle punching process to form a net structure, the fibers in one step are not intertwined with other fibers in the process, so that individual fibers are generated, and the individual fibers are easy to fall off during use and prick on the skin to cause itching after being made into clothes; the present application is therefore proposed to solve the above problems.

Disclosure of Invention

In order to overcome the defects of the prior art, the invention provides a processing and generating system of melt-blown non-woven fabric, which can clean single fibers in the manufacturing process of the non-woven fabric.

The technical scheme adopted by the invention for solving the technical problems is as follows:

the utility model provides a melt-blown non-woven fabrics processing generation system, is including setting up three flattening portion on same straight line, and is used for driving the shaking portion that the flattening portion that is located the centre reciprocated, and installs the filter house in shaking portion, and shaking portion can drive the flattening portion upper and lower cyclic movement that is located the centre after the non-woven fabrics passes three flattening portion in proper order, realizes the upper and lower shake to the non-woven fabrics.

The flattening part comprises a sliding seat which is provided with a screw rod A in a rotating mode, and two rotating rollers which are respectively arranged on two sliding blocks in a rotating mode, the two sliding blocks are respectively connected to the upper side and the lower side of the screw rod A, and the rotating directions of threads on the upper side and the lower side of the screw rod A are opposite.

The roller on be connected with a plurality of lantern rings through the bolt is dismantled, a plurality of lantern rings of two on the roller in each flattening portion are staggered arrangement each other.

The shaking part comprises a frame, a sliding rod fixed on the frame and a sliding beam sliding on the sliding rod, and a sliding seat in the middle pressing part is fixed on the sliding beam.

A bracket is fixed on the frame, a push rod is rotatably arranged on the bracket, and the end part of the push rod slides in a groove arranged on the sliding beam.

Drawings

The invention is described in further detail below with reference to the accompanying drawings and specific embodiments.

FIG. 1 is a schematic structural diagram of a processing and generating system of a melt-blown nonwoven fabric in the invention;

FIG. 2 is a schematic structural view of a processing and forming system of a melt-blown non-woven fabric in another direction;

FIG. 3 is a schematic structural view of a rotary roller, a slide block, a screw rod A and a slide seat in the invention;

FIG. 4 is a schematic view of the construction of the rolls and collars of the present invention;

FIG. 5 is a schematic view of the structure of the frame and the lead screw B of the present invention

FIG. 6 is a schematic view of the structure of the slide, slide bar and cross beam 1 of the present invention;

FIG. 7 is a schematic view of a partial structure of the shelf of the present invention;

FIG. 8 is a schematic view of the structure of the bracket and the push rod of the present invention;

FIG. 9 is a schematic view of the construction of a slider beam according to the present invention;

FIG. 10 is a schematic view of the structure of the screen and slot of the present invention;

fig. 11 is a schematic structural view of a long brush according to the present invention.

Detailed Description

By observing fig. 1 and 2, one exemplary operation that can be achieved to clean the excess fibers from the nonwoven fabric is shown in the figures as:

the melt-blown non-woven fabric processing and generating system comprises three flattening parts arranged on the same straight line, a shaking part used for driving the flattening part in the middle to move up and down, and a filtering part arranged on the shaking part, wherein the shaking part can drive the flattening part in the middle to circularly move up and down after the non-woven fabric sequentially passes through the three flattening parts, so that the flattening part in the middle drives the non-woven fabric to shake up and down, fibers which are not wound with other fibers together in the processing process of the non-woven fabric are not shaken off, and the phenomenon that the single fiber drops or is pricked on the skin to generate pruritus after the non-woven fabric is made into clothes is avoided; and the filter house can be collected the single fibre that the shake got off, avoids single fibre to float and pollutes operational environment in the air, can be convenient for reuse after collecting single fibre simultaneously, avoids extravagant.

By observing fig. 1 to 3, one exemplary process by which a compacted nonwoven can be conveyed according to the figures shown in the drawings is:

the portion of flattening include slide 04, it is connected with lead screw A03 to rotate in slide 04's the vertical direction, the screw thread of both sides is rotated to opposite on the lead screw A03, threaded hole has all been seted up on two sliders 02, two sliders 02 connect respectively in the upper and lower both sides of lead screw A03 through the threaded hole, it is connected with a commentaries on classics roller 01 to rotate respectively on two sliders 02, two slider 02 face contact is on slide 04, in-process when using, at first make two sliders 02 the upper and lower both sides of slide 04, two sliders 02 drive two commentaries on classics rollers 01 and be in the farthest state this moment, interval between two commentaries on classics rollers 01 is the biggest, then pass two commentaries on classics between the roller 01 with the non-woven fabrics, rethread rotation lead screw A03, make lead screw A03 drive two sliders 02 and slide 04 and slide and be close to, thereby realize two sliders 02 drive two commentaries on classics roller 01 and press from the tight non-woven fabrics, when non-woven fabrics equipment drives non-woven fabrics unidirectional movement, alright make two commentaries on classics roller 01 rotatory roller 01 of non-woven fabrics get up and make two commentaries on classics roller 01 rotate the surface and make two commentaries on classics roller 01 flatten the upper and flatten the non-woven fabrics, thereby it is even more even after the non-woven fabrics to utilize two changes the non-woven fabrics to flatten.

By observing fig. 3 and 4, one exemplary process by which the nonwoven fabric can be cut into strips as shown in the figures is:

the rotary rollers 01 are detachably connected with a plurality of lantern rings 05 through bolts, the lantern rings 05 on the two rotary rollers 01 in each flattening part are mutually staggered, and the side surfaces of the two staggered and adjacent lantern rings 05 are in surface contact; when needs cut into the strip with the non-woven fabrics, alright with install a plurality of lantern rings 05 on changeing the roller 01 through the bolt to when the non-woven fabrics passes two changeing between the roller 01, utilize every two adjacent lantern rings 05 of crisscross each other from top to bottom to cut into the strip with the non-woven fabrics, alright with the in-process that non-woven fabrics unidirectional movement cuts into the strip that a plurality of widths are the same.

By observing fig. 1 to 9, one exemplary operation that can be obtained from the nonwoven fabric that is shaken is as follows:

the shaking part comprises a frame 06, a sliding rod 09 is fixedly connected to the middle of the frame 06 in the vertical direction, a sliding beam 14 is connected to the sliding rod 09 in a sliding manner, and a sliding seat 04 in the middle flattening part is fixedly connected to the sliding beam 14; when using, only need two in the flattening of centre turn round roller 01 after pressing from both sides tight non-woven fabrics, make the length control of the non-woven fabrics that lies in between two flattening of both sides make the surplus, alright reciprocate on slide bar 09 through driving smooth roof beam 14, alright shake the non-woven fabrics from top to bottom when pressing from both sides tight non-woven fabrics through two commentaries on classics roller 01 of slide 04 drive to do not shake down with the single fibre of other fibre twines together on the non-woven fabrics.

By observing fig. 1 to 9, one exemplary operation that can be obtained from the self-oscillating nonwoven fabric shown in the figures is:

a bracket 12 is fixedly connected to the frame 06, a push rod 13 is rotatably arranged on the bracket 12, a speed reducing motor is arranged on the bracket 12, an output shaft of the speed reducing motor is fixedly connected to the push rod 13, a convex shaft is formed at the end part of the push rod 13, and the convex shaft slides in a groove formed in a sliding beam 14; when the non-woven fabric is automatically shaken, only the speed reducing motor needs to be turned on, so that the push rod 13 can be driven by the speed reducing motor to rotate around the output shaft of the speed reducing motor, the convex shaft on the end part of the push rod 13 slides in the groove, and the sliding beam 14 is driven to slide on the sliding rod 09 in a reciprocating manner up and down, so that the non-woven fabric is driven to shake up and down at the flattening part in the middle;

meanwhile, the falling fibers generated at the cutting position can be shaken off when the non-woven fabric is cut into strips, so that the fibers which may fall off at any time are prevented from being fully distributed at the cutting position; and can avoid the non-woven fabrics cut into strips from winding together through shaking.

By observing fig. 1 to 9, an exemplary operation process for adjusting the nonwoven fabric flutter range in the length direction can be obtained according to the illustration in the figure:

the shaking part also comprises two lead screws B07 which are rotatably connected to two sides of the frame 06 in a horizontal state, two slide ways 08 are arranged on two sides of the frame 06 in the horizontal direction, the two slide ways 08 correspond to the two lead screws B07, two slide seats 04 in the other two flattening parts are respectively provided with a threaded hole, the two slide seats 04 are respectively connected to the two lead screws B07 through the threaded holes, and the two slide seats 04 respectively slide in the two slide ways 08; when flattening portion in the middle of when driving the non-woven fabrics and shake from top to bottom, can be through rotating two lead screws B07, make lead screw B07 drive two slide bases 04 respectively and slide in two slides 08 and be close to or keep away from, thereby change the interval between two flattening portions that are located both sides, thereby change the scope of non-woven fabrics in the length direction of shake in-process, the bending degree that can make the non-woven fabrics shake in the in-process of shake under the less circumstances of interval between two flattening portions is bigger, the angle of non-woven fabrics surface slope is bigger, when the interval between two flattening portions is bigger, the bending degree that the non-woven fabrics trembles is littleer, the angle of non-woven fabrics surface slope is littleer, thereby can change the power that the non-woven fabrics produced to single fibre during shake, so as to ensure that all, singleness, do not shake down with the fibre that other fibre twines together.

By observing fig. 1-9, one exemplary operation that can be obtained from the graphs to make the shaken fibers move in one direction is:

the shaking part also comprises two cross beams 10 fixedly connected to the rack 06, and a plurality of fans 11 are fixedly connected to the rack 06 through bolts; a plurality of fans 11 can be opened at the in-process that the non-woven fabrics was shaken, makes a plurality of fans 11 drive the fibre that the air flow will shake down take away, realizes fibrous one-way movement, avoids the fibre to float to operational environment.

By observing fig. 1-10, one exemplary operation that can be achieved from the centrally dithered fibers shown in the figures is:

the filtering part comprises a filter screen 15 of which the lower end is rotated on the cross beam 10 positioned below, and the upper end of the filter screen 15 can be detachably connected on the cross beam 10 positioned above through a bolt; in the use, when the wind that the fan produced blows the fibre that comes down to filter screen 15, filter screen 15 can stop the fibre, avoids the fibre to be blown to other places to the realization carries out the effect of concentrating with the fibre, after finishing using, alright with twist off the bolt and make filter screen 15 rotate downwards open, alright with collect the fibre of concentrating on filter screen 15 and be convenient for reuse.

By observing fig. 1-10, one exemplary process that can be derived from the figures to avoid fiber wandering is:

the inboard fixedly connected with of filter screen 15 soaks the gauze, can utilize water to "glue" the fibre on soaked gauze when the fibre contacts on soaked gauze, avoid the fibre to waft to other places, improve filter screen 15 and block the ability concentrated to the fibre.

By observing fig. 1-11, one exemplary process by which rapid collection of fibers can be achieved is as follows:

the filter screen 15 about both ends seted up slot hole 16, long brush 17 about both ends slide respectively in two slot holes 16, long brush 17 contact is on the gauze, after the use, can remove the in-process of one side in the other side from filter screen 15 through driving long brush 17, make long brush 17 promote the fibre of collecting in with filter screen 15 together, be convenient for take out the fibre, improved the fibrous efficiency of collection, also can clear up filter screen 15 and gauze through long brush 17.

Claims

1. A melt-blown non-woven fabric processing and generating system is characterized in that: including setting up three flattening portion on same straight line, and be used for driving the shaking portion that the flattening portion that is located the centre reciprocated, and install the filter house in shaking portion, shake portion can drive the flattening portion that is located the centre and circulate from top to bottom and remove after the non-woven fabrics passes three flattening portion in proper order, realizes the upper and lower shake to the non-woven fabrics.

2. The system of claim 1, wherein: the flattening part comprises a sliding seat (04) which rotates a screw rod A (03), and two rotating rollers (01) which rotate on two sliding blocks (02) respectively, the two sliding blocks (02) are connected to the upper side and the lower side of the screw rod A (03) respectively, and the thread turning directions of the upper side and the lower side of the screw rod A (03) are opposite.

3. The system of claim 2, wherein: the roller (01) is detachably connected with a plurality of lantern rings (05) through bolts, and the lantern rings (05) on the two roller (01) in each flattening part are arranged in a staggered mode.

4. The system according to claim 2 or 1, characterized in that: the shaking part comprises a frame (06), a sliding rod (09) fixed on the frame (06), a sliding beam (14) sliding on the sliding rod (09), and a sliding seat (04) positioned in the middle flattening part is fixed on the sliding beam (14).

5. The system of claim 4, wherein: a support (12) is fixed on the frame (06), a push rod (13) is rotatably arranged on the support (12), and the end part of the push rod (13) slides in a groove formed in the sliding beam (14).

6. The system of claim 5, wherein: the shaking part further comprises two lead screws B (07) which are arranged on two sides of the frame (06) in a rotating mode, two slideways (08) which are arranged on two sides of the frame (06) and correspond to the two lead screws B (07), and two sliding seats (04) in the rest two flattening parts are respectively connected to the two lead screws B (07) and slide in the two slideways (08).

7. The system of claim 6, wherein: the shaking part also comprises two cross beams (10) fixed on the frame (06) and a plurality of fans (11) fixed on the frame (06).

8. The system of claim 7, wherein: the filter part comprises a filter screen (15) with the lower end rotating on a cross beam (10) positioned below, and the upper end of the filter screen (15) can be detachably connected to the cross beam (10) positioned above through bolts.

9. The system of claim 8, wherein: the inner side of the filter screen (15) is fixedly connected with a wetted gauze.

10. The system of claim 9, wherein: slotted holes (16) are formed in the upper end and the lower end of the filter screen (15), the upper end and the lower end of the long brush (17) slide in the two slotted holes (16) respectively, and the long brush (17) is in contact with the screen.