CN115107208B - Realize spun-bond and drench membrane one-step method on-line quick production with chromed optical axis - Google Patents

Abstract

The invention discloses a chromeplated optical axis for realizing on-line rapid production of a spunbond film coating one-step method, and relates to the technical field of intelligent equipment. The invention comprises a base, wherein the base is fixedly provided with a rubber roller assembly, a movable assembly and a winding assembly from left to right, the movable assembly is movably provided with two groups of composite assemblies, and each group of composite assemblies is movably provided with a compacting assembly; the composite assembly comprises mounting blocks, driving gears, shaft bodies, energizing coils and iron sheets, wherein four mounting blocks of the two groups of composite assemblies are respectively movably arranged at two ends of two movable rods, one end of each mounting block is movably provided with a driving gear, every two driving gears are fixedly connected with each other through the shaft bodies, the circumferential side surfaces of the shaft bodies are fixedly connected with the energizing coils, and the circumferential side surfaces of the energizing coils are fixedly connected with the iron sheets. According to the invention, the mode of conveying the film coating cloth through the two chromed optical axes can continuously carry out film coating operation on the non-woven fabric without gaps.

Description

Realize spun-bond and drench membrane one-step method on-line quick production with chromed optical axis

Technical Field

The invention belongs to the technical field of intelligent equipment, and particularly relates to a chromeplated optical axis for realizing on-line rapid production of a spunbond film coating one-step method.

Background

The non-woven fabric is made up by using polypropylene resin as main raw material, its specific weight is only 0.9, only three fifths of that of cotton, and its bulkiness and hand feeling are good, and is a fabric formed from non-woven fabric, and is formed from woven short fibre or filament which is formed from directional or random arrangement, and adopts mechanical, thermal or chemical method to implement reinforcement.

In the patent number CN 105252855A non-woven fabric forming and laminating equipment and a processing method for producing laminated non-woven fabrics, the problem that the existing machine cannot directly process the laminated non-woven fabrics is solved, the non-woven fabrics which are processed are conveyed to a rubber roll device, laminated cloth on a discharging device is pulled to the rubber roll device, sticky laminated liquid drops fall on the non-woven fabrics and the laminated cloth, the non-woven fabrics and the laminated cloth are compounded into the laminated non-woven fabrics after passing through the rubber roll device, the spun-bonded laminated is completed in one step, and the laminated non-woven fabrics are processed, however, when the laminated cloth on a mounting shaft is used up, the laminated cloth is cut off by a shearing device, the other mounting shaft is driven by an electric appliance to synchronously rotate with the mounting shaft which is used at present, so that the laminated cloth on the other mounting shaft is connected to the laminated cloth which is cut off by the shearing device, the machine is required to stop running in the process, the laminated cloth is placed inside the rubber roll device through a manual operation mode, the laminated cloth can be restarted, the laminated cloth can be temporarily stopped in the machine after the machine is restarted, the service life of the machine is required to be influenced, and the machine is required to be temporarily stopped, and the machine life is required to be stopped.

The existing non-woven fabric film spraying process cannot produce non-woven fabrics and perform film spraying operation in one step, meanwhile, the non-woven fabrics need to be stopped when the film spraying cloth is replaced, the service life of the machine is influenced, and the non-woven fabrics are sprayed with film through manual feeding in the stopping process, so that the non-woven fabric film spraying efficiency is reduced, and the chromium plating optical axis for realizing the on-line rapid production of the spun-bond film spraying one-step method is provided.

Disclosure of Invention

The invention aims to provide a chromeplated optical axis for realizing on-line rapid production of a spun-bonded film coating one-step method, which solves the problems that the existing non-woven film coating process can not produce non-woven fabrics and carry out film coating operation in one step, meanwhile, when the non-woven fabrics are used for replacing film coating cloth, the non-woven fabrics need to stop machines to influence the service life of the machines, and the non-woven fabrics are coated by manual feeding in the stopping process, so that the non-woven fabrics film coating efficiency is reduced.

In order to solve the technical problems, the invention is realized by the following technical scheme:

the invention relates to a chromium plating optical axis for realizing one-step on-line rapid production of a spunbond laminated film, which comprises a base, wherein a rubber roller assembly, a movable assembly and a winding assembly are fixedly arranged on the base from left to right, two groups of composite assemblies are movably arranged on the movable assembly, and a pressing assembly is movably arranged on each group of composite assemblies; two support rods are fixedly connected to one side of the top of the base, guide shafts are movably arranged between the two support rods, and the guide shafts are close to the rubber roller assembly.

The rubber roll assembly comprises a mounting frame and a discharging roll, the mounting frame is fixedly connected to the top of the base, and two ends of the discharging roll are respectively and movably arranged on the inner walls of two opposite sides of the mounting frame; the rubber roll assembly further comprises a limiting roll, a transmission element and a first motor, wherein two ends of the limiting roll are movably arranged on inner walls of two opposite sides of the mounting frame, the limiting roll is located right above the discharging roll, one end of the discharging roll penetrates through one side wall of the mounting frame and is fixedly connected with one end of the transmission element, the other end of the transmission element is fixedly connected with the output end of the first motor, and the first motor is fixedly connected to the top of the base.

Preferably, the rubber roll subassembly top is fixed to be provided with and drenches the membrane subassembly, it includes the feeder hopper, drenches membrane machine and drenches the membrane head to drenches the membrane subassembly, drenches membrane machine fixed connection at the mounting bracket top, just drenches membrane machine top and feeder hopper fixed connection, drenches membrane machine bottom and drenches membrane head top fixed connection, it is located the blowing roller top to drench the membrane head.

The movable assembly comprises a movable rod, and the movable rod is movably arranged in the mounting frame and is close to the discharging roller; the movable assembly further comprises a second motor and a connecting shaft, the two connecting shafts are fixedly connected to the middle section of the movable rod respectively and movably arranged on the inner walls of the two opposite sides of the mounting frame, one connecting shaft penetrates through one side face of the mounting frame and is fixedly connected with the output end of the second motor, and the second motor is fixedly connected to the outer wall of the mounting frame.

The composite assembly comprises mounting blocks, driving gears, shaft bodies, energizing coils and iron sheets, wherein the four mounting blocks of the two groups of composite assemblies are respectively and movably arranged at two ends of two movable rods, one end of each mounting block is movably provided with a driving gear, every two driving gears are fixedly connected through a shaft body, the energizing coils are fixedly connected to the peripheral side surfaces of the shaft bodies, and the iron sheets are fixedly connected to the peripheral side surfaces of the energizing coils; the composite assembly further comprises a driver and a chromium coating, wherein the driver is fixedly connected to one end of the shaft body; the peripheral side surface of the iron sheet layer is coated with a chromium plating layer.

The pressing assembly comprises driven gears, pressing shafts, fixing blocks, telescopic columns, springs and electromagnet blocks, wherein two ends of the pressing shafts are movably connected to different mounting blocks, the pressing shafts are located right above the shafts, the driven gears are fixedly connected to the two ends of the pressing shafts, the driven gears are movably arranged at the other ends of the mounting blocks, mounting grooves are formed in the two ends of the pressing shafts, the bottoms of the mounting grooves are fixedly connected with the telescopic columns, a plurality of telescopic columns are fixedly connected to the peripheral side surfaces of the telescopic columns, springs are movably arranged on each telescopic column, one ends of the telescopic columns are fixedly connected with the electromagnet blocks, and the electromagnet blocks penetrate through the pressing shafts to the outer parts of the pressing shafts; the fixed block is a quadrangular prism, each side face of the fixed block is fixedly provided with a telescopic column, and the number of the telescopic columns, the springs and the electromagnet blocks is 16.

The winding assembly comprises winding frames and placing shafts, wherein two placing shafts are arranged above the winding frames; the winding assembly further comprises a winding frame, the winding frame is fixedly connected to one side surface of the opposite supporting rod at the top of the base, two ends of the winding roller are movably arranged on the inner walls of the two opposite sides of the winding frame, one end of the winding roller penetrates through one side surface of the winding frame to the outside of the winding roller and is fixedly connected with the output end of a third motor, and the third motor is fixedly connected to the outer wall of the winding frame; a fourth motor is fixedly connected on the outer wall of one side surface of the winding frame, the output end of the fourth motor penetrates through one side surface of the winding frame to the inside thereof and is fixedly connected with one end of the main stay bar, the other end of the main stay bar is movably arranged on the inner wall of the other side of the winding frame, two ends of the main stay bar are fixedly connected with swing arms, and the two swing arms are fixedly connected through two placement shafts.

The invention has the following beneficial effects:

1. according to the invention, through arranging two chromeplate optical axes capable of alternately conveying the chromeplate cloth and two An Fangzhou for placing the chromeplate cloth, the chromeplate cloth on two rolls of the chromeplate optical axes is placed on two groups of chromeplate optical axes, one of the chromeplate optical axes conveys one roll of the chromeplate cloth to the rubber roll component to be compounded with the non-woven fabric to form the chromeplate non-woven fabric, when the roll of chromeplate cloth is about to run out, the rotating movable rod drives the chromeplate optical axis to rotate anticlockwise by 180 degrees, and the other chromeplate optical axis is continuously compounded with the non-woven fabric on the discharging roll to form the chromeplate non-woven fabric continuously. The mode of conveying the film coating cloth through the two chromeplated optical axes can continuously carry out film coating operation on the non-woven fabric without gaps.

2. According to the invention, the pressing shaft is arranged above each chromium plating optical axis, the telescopic electromagnet blocks are arranged in the pressing shafts, the iron sheet layer and the electromagnetic coil are arranged in the chromium plating optical axes in advance, and when the electromagnetic coil is electrified, the iron sheet layer has electromagnetic attraction force, so that the electromagnet blocks in the pressing shafts are adsorbed to the surfaces of the electromagnet blocks, the to-be-used laminating cloth is clamped, the possibility of falling off of the laminating cloth is avoided, and meanwhile, the step of manually penetrating the laminating cloth through a composite component is not required, the labor consumption is reduced, and the operation of automatically producing the laminating non-woven fabric by one-step method is completed.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings that are needed for the description of the embodiments will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and that other drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

FIG. 1 is a schematic diagram of the overall structure of a chromed optical axis for realizing the one-step on-line rapid production of a spunbond film;

FIG. 2 is a schematic diagram of the internal structure of a chromed optical axis for realizing the one-step on-line rapid production of a spunbond film;

FIG. 3 is an enlarged view of the invention at A in FIG. 2;

FIG. 4 is a schematic diagram of a cross-sectional structure of a composite component and a compacting component for realizing chrome plating optical axis for on-line rapid production of a spunbond laminated film by one-step method;

FIG. 5 is an enlarged view of the invention at B in FIG. 1;

FIG. 6 is a schematic diagram of a front view structure of a chromed optical axis for realizing on-line rapid production of a spunbond laminated film by one-step method;

fig. 7 is an enlarged view of fig. 2 at C in accordance with the present invention.

In the drawings, the list of components represented by the various numbers is as follows:

1. a base; 2. a support rod; 3. a guide shaft; 4. a mounting frame; 5. a feed hopper; 6. a film coating machine; 7. a film spraying head; 8. a discharging roller; 9. a limit roller; 10. a transmission element; 11. a first motor; 12. a second motor; 13. a connecting shaft; 14. a movable rod; 15. a mounting block; 16. a driver; 17. a drive gear; 18. a shaft body; 19. a power-on coil; 20. an iron skin layer; 21. a chromium plating layer; 22. a driven gear; 23. a compression shaft; 24. a fixed block; 25. a telescopic column; 26. a spring; 27. an electromagnet block; 28. a winding frame; 29. a third motor; 30. a wind-up roll; 31. a fourth motor; 32. a main stay bar; 33. swing arms; 34. an Fangzhou.

Detailed Description

The invention is further described in connection with the following detailed description, in order to make the technical means, the creation characteristics, the achievement of the purpose and the effect of the invention easy to understand.

In the description of the present invention, it should be noted that the directions or positional relationships indicated by the terms "upper", "lower", "inner", "outer", "front", "rear", "both ends", "one end", "the other end", etc. are based on the directions or positional relationships shown in the drawings, are merely for convenience of describing the present invention and simplifying the description, and do not indicate or imply that the devices or elements referred to must have a specific direction, be configured and operated in the specific direction, and thus should not be construed as limiting the present invention. Furthermore, the terms "first," "second," and the like, 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 explicitly specified and limited otherwise, the terms "mounted," "provided," "connected," and the like are to be construed broadly, and may be fixedly connected, detachably connected, or integrally connected, for example; can be mechanically or electrically connected; can be directly connected or indirectly connected through an intermediate medium, and can be communication between two elements. The specific meaning of the above terms in the present invention will be understood in specific cases by those of ordinary skill in the art.

Fig. 1 is a schematic diagram of the overall structure of a chromeplated optical axis for realizing the one-step online rapid production of a spunbond film, and fig. 2 is a schematic diagram of the internal structure of the chromeplated optical axis for realizing the one-step online rapid production of the spunbond film, as shown in fig. 1 and 2, the chromeplated optical axis for realizing the one-step online rapid production of the spunbond film, provided by the invention, comprises a base 1, wherein a rubber roller assembly, a movable assembly and a winding assembly are fixedly arranged on the base 1 from left to right, two groups of composite assemblies are movably arranged on the movable assembly, and a compression assembly is movably arranged on each group of composite assemblies; two support rods 2 are fixedly connected to one side of the top of the base 1, a guide shaft 3 is movably arranged between the two support rods 2, and the guide shaft 3 is close to the rubber roller assembly. The rubber roll assembly comprises a mounting frame 4 and a discharging roll 8, the mounting frame 4 is fixedly connected to the top of the base 1, and two ends of the discharging roll 8 are respectively and movably arranged on the inner walls of two opposite sides of the mounting frame 4; the rubber roll assembly further comprises a limiting roll 9, a transmission element 10 and a first motor 11, two ends of the limiting roll 9 are movably arranged on inner walls of two opposite sides of the mounting frame 4, the limiting roll 9 is located right above the discharging roll 8, one end of the discharging roll 8 penetrates through one side wall of the mounting frame 4 and is fixedly connected with one end of the transmission element 10, the other end of the transmission element 10 is fixedly connected with the output end of the first motor 11, and the first motor 11 is fixedly connected with the top of the base 1. The rubber roll subassembly top is fixed to be provided with and drenches the membrane subassembly, drenches the membrane subassembly and includes feeder hopper 5, drenches membrane machine 6 and drenches membrane head 7, drenches membrane machine 6 fixed connection at the mounting bracket 4 top, and drenches membrane machine 6 top and feeder hopper 5 fixed connection, drenches membrane machine 6 bottom and drenches membrane head 7 top fixed connection, drenches membrane head 7 and is located blowing roller 8 top. The movable assembly comprises a movable rod 14, and the movable rod 14 is movably arranged in the mounting frame 4 and is adjacent to the discharging roller 8; the movable assembly further comprises a second motor 12 and a connecting shaft 13, the connecting shafts 13 are fixedly connected to the middle sections of the two movable rods 14, the two connecting shafts 13 are respectively and movably arranged on the inner walls of the two opposite sides of the mounting frame 4, one connecting shaft 13 penetrates through one side surface of the mounting frame 4 and is fixedly connected with the output end of the second motor 12, and the second motor 12 is fixedly connected to the outer wall of the mounting frame 4; the base 1 is used as a main body part of the invention and is used for supporting and bearing other components, the supporting rod 2 is used for fixing the guide shaft 3, the guide shaft 3 is used for conveying the processed non-woven fabric, the non-woven fabric is conveyed to the inside of the rubber roller assembly through the guide shaft 3, the inside of the mounting frame 4 is used for fixing the film spraying assembly, the rubber roller assembly and the movable assembly, the feeding hopper 5 is used for throwing polyethylene particles into the inside of the non-woven fabric, the inside of the film spraying machine 6 is used as a main material of film spraying, the thrown polyethylene particles are heated and melted and finally discharged from the film spraying head 7, the film spraying head 7 is positioned above between the discharging roller 8 and the shaft body 18, when the film spraying head 7 discharges polyethylene solution, the polyethylene solution just drops between the non-woven fabric and the film spraying cloth, so that the non-woven fabric is compounded, the non-woven fabric is conveyed by the discharging roller 8 and the shaft body 18, the non-woven fabric is subjected to film spraying operation by compounding extrusion, the limiting roller 9 is used for pressing the non-woven fabric, wrinkles or twists are avoided, the transmission element 10 is used for driving the discharging roller 8, and the first motor 11 is used for driving the discharging roller 8 to rotate.

Fig. 3 is an enlarged view of a position a in fig. 2, fig. 4 is a schematic cross-sectional structure of a composite component and a compacting component for realizing a chromeplated optical axis for one-step on-line rapid production of a spunbond film, and fig. 5 is an enlarged view of a position B in fig. 1, as shown in fig. 3,4 and 5, the composite component comprises mounting blocks 15, driving gears 17, a shaft body 18, a power-on coil 19 and an iron sheet layer 20, four mounting blocks 15 of two groups of composite components are respectively and movably arranged at two ends of two movable rods 14, one end of each mounting block 15 is movably provided with a driving gear 17, each two opposite driving gears 17 are fixedly connected through the shaft body 18, the circumferential side surface of the shaft body 18 is fixedly connected with the power-on coil 19, and the circumferential side surface of the power-on coil 19 is fixedly connected with the iron sheet layer 20; the composite assembly further comprises a driver 16 and a chromium coating 21, wherein the driver 16 is fixedly connected to one end of the shaft body 18; the peripheral side surface of the iron skin layer 20 is coated with a chromium plating layer 21. The compression assembly comprises a driven gear 22, a compression shaft 23, a fixed block 24, telescopic columns 25, springs 26 and electromagnet blocks 27, wherein two ends of the compression shaft 23 are movably connected to different mounting blocks 15, the compression shaft 23 is positioned right above the shaft body 18, the two ends of the compression shaft 23 are fixedly connected with the driven gear 22, the driven gear 22 is movably arranged at the other end of the mounting block 15, mounting grooves are formed in the two ends of the compression shaft 23, the bottoms of the mounting grooves are fixedly connected with the telescopic columns 25, a plurality of telescopic columns 25 are fixedly connected to the peripheral side surfaces of the telescopic columns 25, the springs 26 are movably arranged on each telescopic column 25, one end of each telescopic column 25 is fixedly connected with the electromagnet block 27, and the electromagnet blocks 27 penetrate through the compression shaft 23 to the outside; the fixed block 24 is a quadrangular prism, and the number of telescopic columns 25, springs 26 and electromagnet blocks 27 are 16 on each side face of the fixed block, the installation block 15 is used for installing a composite component on a movable component, the driver 16 is used for driving the shaft body 18 to rotate, the driving gear 17 is meshed with the driven gear 22 in a direction and used for driving the driven gear 22 to rotate, the shaft body 18 is used for processing the laminated non-woven fabrics by a one-step method as a main body part of a chromed optical axis, the energizing coil 19 is energized to enable the iron sheet layer 20 to generate magnetic force, so that attractive force is generated on the electromagnet blocks 27, the chromed layer 21 is used for being coated outside the iron sheet layer 20 to play a protective role, the driven gear 22 is fixed on the compression shaft 23 and rotates through the driving gear 17, so as to drive the compression shaft 23 to rotate, the fixed block 24 is used for fixedly connecting the telescopic columns 25, the telescopic columns 25 drive the electromagnet blocks 27 to move in a telescopic process, the springs 26 are in a normal state in a non-energized process, when the energizing coil 19 is energized, the springs 26 are stretched, the telescopic columns 25 drive the electromagnet blocks 27 to be close to the iron sheet layer 27 to the iron sheet layer 20, and the electromagnet blocks 20 are used for preventing the film from falling in a film exchange process.

Fig. 6 is a schematic front view of a chromed optical axis for implementing the one-step on-line rapid production of a spunbond film, and fig. 7 is an enlarged view of a position C in fig. 2, as shown in fig. 6 and 7, a winding assembly comprises a winding frame 28 and two mounting shafts 34, and the two mounting shafts 34 are positioned above the winding frame 28; the winding assembly further comprises a winding frame 28, the winding frame 28 is fixedly connected to one side surface of the top of the base 1 opposite to the supporting rod 2, two ends of a winding roller 30 are movably arranged on the inner walls of the two opposite sides of the winding frame 28, one end of the winding roller 30 penetrates through one side surface of the winding frame 28 to the outside thereof and is fixedly connected with the output end of a third motor 29, and the third motor 29 is fixedly connected to the outer wall of the winding frame 28; the rolling frame 28 is fixedly connected with a fourth motor 31 on the outer wall of one side surface, the output end of the fourth motor 31 penetrates through one side surface of the rolling frame 28 to the inside of the rolling frame 28 and is fixedly connected with one end of a main supporting rod 32, the other end of the main supporting rod 32 is movably arranged on the inner wall of the other side of the rolling frame 28, two ends of the main supporting rod 32 are fixedly connected with swing arms 33, two swing arms 33 are fixedly connected through two placing shafts 34, the rolling frame 28 is used for fixing each rolling element in the rolling frame, a third motor 29 is used for driving a rolling roller 30 to rotate, the rolling roller 30 rolls the processed laminated non-woven fabric, the fourth motor 31 is used for driving the main supporting rod 32 to rotate, the swing arms 33 on the main supporting rod 32 are driven to rotate, the swing arms 33 are used for fixing two placing shafts 34, and the two placing shafts 34 can timely replace the laminated non-woven fabric.

When a person uses the device, the device is arranged at the outlet position of a non-woven fabric processing machine, the non-woven fabric is conveyed to the position of a discharging roller 8 through a guide shaft 3 at the first time when the non-woven fabric is processed, at the moment, a fourth motor 31 is started, a placing shaft 34 with the laminated fabric is moved to the position of one group of composite components, one end of the laminated fabric passes through the space between the composite components and a compacting component, an electrified coil 19 is electrified, so that an electromagnetic attraction force is generated by an iron sheet layer 20, an electromagnet 27 in the compacting shaft 23 is sucked and led out, the electromagnet 27 is used for compacting the laminated fabric, the laminated fabric is prevented from falling off, a second motor 12 is started to drive a movable rod 14 to rotate, a group of composite components with the laminated fabric clamped by the movable rod 14 is rotated to the position near the discharging roller 8, at the moment, the electrified coil 19 is disconnected, the electromagnet 27 loses attraction force to the inside of the compacting shaft 23, the laminated fabric is not clamped any more, and the shaft 18 is driven by a driver 16 to rotate, and the laminated fabric is conveyed forwards from the container; simultaneously, polyethylene particles are put into the film coating machine 6 through the feed hopper 5, the polyethylene particles are fused into a liquid state through the heating of the film coating machine 6, when the non-woven fabric on the discharging roller 8 is contacted with the film coating cloth on the shaft body 18, the film coating head 7 discharges polyethylene liquid and drops on the non-woven fabric and the film coating cloth, so that the non-woven fabric and the film coating cloth are compounded to form film coating non-woven fabric, and the processed film coating non-woven fabric is wound by the winding roller 30; in the film coating processing process, when one of the film coating cloth blocks on the mounting shaft 34 is used up, the swing arm 33 is rotated anticlockwise, so that the mounting shaft 34 is positioned below the other mounting shaft 34, the current film coating cloth conveying operation of the mounting shaft 34 is not influenced, the film coating cloth on the other mounting shaft 34 passes through the space between the idle composite component and the compressing component, the film coating cloth is clamped in the steps, and when the conveyed film coating cloth is used up, the film coating cloth is rotated to be continuously used, so that the machine is not stopped, and the film coating operation can be continuously performed.

The foregoing has shown and described the basic principles and main features of the present invention and the advantages of the present invention. It will be understood by those skilled in the art that the present invention is not limited to the embodiments described above, and that the above embodiments and descriptions are merely illustrative of the principles of the present invention, and various changes and modifications may be made without departing from the spirit and scope of the invention, which is defined in the appended claims. The scope of the invention is defined by the appended claims and equivalents thereof.

Claims (9)

1. Realize that spunbond drenches online quick production of membrane one-step method and use chromed optical axis, including base (1), its characterized in that: the base (1) is fixedly provided with a rubber roller assembly, a movable assembly and a winding assembly from left to right, the movable assembly is movably provided with two groups of composite assemblies, and each group of composite assemblies is movably provided with a compression assembly;

the rubber roll assembly comprises a mounting frame (4) and a discharging roll (8), wherein the mounting frame (4) is fixedly connected to the top of the base (1), and two ends of the discharging roll (8) are respectively and movably arranged on the inner walls of two opposite sides of the mounting frame (4);

the movable assembly comprises a movable rod (14), and the movable rod (14) is movably arranged in the mounting frame (4) and is adjacent to the discharging roller (8);

the combined assembly comprises mounting blocks (15), driving gears (17), shaft bodies (18), energizing coils (19) and iron sheet layers (20), wherein four mounting blocks (15) of two groups of combined assemblies are respectively and movably arranged at two ends of two movable rods (14), one end of each mounting block (15) is movably provided with a driving gear (17), every two driving gears (17) are fixedly connected with each other through a shaft body (18), the energizing coils (19) are fixedly connected to the peripheral side surfaces of the shaft bodies (18), and the iron sheet layers (20) are fixedly connected to the peripheral side surfaces of the energizing coils (19);

the pressing assembly comprises a driven gear (22), a pressing shaft (23), fixed blocks (24), telescopic columns (25), springs (26) and electromagnet blocks (27), two ends of the pressing shaft (23) are movably connected to different mounting blocks (15), the pressing shaft (23) is located right above a shaft body (18), the driven gear (22) is fixedly connected to two ends of the pressing shaft (23), the driven gear (22) is movably arranged at the other end of the mounting block (15), mounting grooves are formed in two ends of the pressing shaft (23), the bottoms of the mounting grooves are fixedly connected with the telescopic columns (25), a plurality of telescopic columns (25) are fixedly connected to the peripheral side faces of the telescopic columns (25), the springs (26) are movably arranged on each telescopic column (25), one end of each telescopic column (25) is fixedly connected with the electromagnet block (27), and the electromagnet blocks (27) penetrate through the pressing shaft (23) to the outer parts of the pressing shaft;

the winding assembly comprises winding frames (28) and placement shafts (34), and two placement shafts (34) are arranged above the winding frames (28).

2. The optical axis for realizing the on-line rapid production of the spun-bonded laminated films by the one-step method according to claim 1 is characterized in that two support rods (2) are fixedly connected to one side of the top of the base (1), a guide shaft (3) is movably arranged between the two support rods (2), and the guide shaft (3) is close to a rubber roller assembly.

3. The one-step on-line quick production of the spun-bonded laminated film is realized according to claim 2 and is characterized in that a laminated film component is fixedly arranged at the top of the rubber roller component, the laminated film component comprises a feeding hopper (5), a laminated film machine (6) and a laminated film head (7), the laminated film machine (6) is fixedly connected at the top of the mounting frame (4), the top of the laminated film machine (6) is fixedly connected with the feeding hopper (5), the bottom of the laminated film machine (6) is fixedly connected with the top of the laminated film head (7), and the laminated film head (7) is positioned above the discharging roller (8).

4. The chrome plating optical axis for realizing on-line rapid production of a spun-bonded laminated film by one-step method according to claim 3, wherein the rubber roller assembly further comprises a limiting roller (9), a transmission element (10) and a first motor (11), two ends of the limiting roller (9) are movably arranged on inner walls of two opposite sides of the mounting frame (4), the limiting roller (9) is positioned right above the discharging roller (8), one end of the discharging roller (8) penetrates through one side wall of the mounting frame (4) and is fixedly connected with one end of the transmission element (10), the other end of the transmission element (10) is fixedly connected with the output end of the first motor (11), and the first motor (11) is fixedly connected with the top of the base (1).

5. The one-step method for realizing the on-line rapid production of the spun-bonded laminated film is characterized in that the movable assembly further comprises a second motor (12) and a connecting shaft (13), the connecting shafts (13) are fixedly connected to the middle sections of the two movable rods (14), the two connecting shafts (13) are respectively and movably arranged on the inner walls of the two opposite sides of the mounting frame (4), one connecting shaft (13) penetrates through one side surface of the mounting frame (4) and is fixedly connected with the output end of the second motor (12), and the second motor (12) is fixedly connected to the outer wall of the mounting frame (4).

6. The chrome-plated optical axis for realizing the one-step on-line rapid production of the spunbond laminated film according to claim 5, wherein the composite assembly further comprises a driver (16) and a chrome-plated layer (21), and the driver (16) is fixedly connected to one end of the shaft body (18); the peripheral side surface of the iron sheet layer (20) is coated with a chromium plating layer (21).

7. The chromed optical axis for realizing the one-step on-line rapid production of the spunbond laminated film according to claim 6, wherein the fixing block (24) is a quadrangular prism, each side surface of the fixing block is fixedly provided with a telescopic column (25), and the number of the telescopic columns (25), the springs (26) and the electromagnet blocks (27) is 16.

8. The one-step on-line rapid production of the spun-bonded laminated film according to claim 7, wherein the winding assembly further comprises a winding frame (28), the winding frame (28) is fixedly connected to one side surface of the opposite supporting rod (2) at the top of the base (1), two ends of the winding roller (30) are movably arranged on the inner walls of the two opposite sides of the winding frame (28), one end of the winding roller (30) penetrates through one side surface of the winding frame (28) to the outside thereof and is fixedly connected with the output end of a third motor (29), and the third motor (29) is fixedly connected to the outer wall of the winding frame (28).

9. The one-step method for realizing the on-line rapid production of the spun-bonded laminated film according to claim 8, wherein a fourth motor (31) is fixedly connected to the outer wall of one side surface of the winding frame (28), the output end of the fourth motor (31) penetrates through one side surface of the winding frame (28) to the inside of the winding frame and is fixedly connected with one end of a main supporting rod (32), the other end of the main supporting rod (32) is movably arranged on the inner wall of the other side of the winding frame (28), two ends of the main supporting rod (32) are fixedly connected with swing arms (33), and two swing arms (33) are fixedly connected through two placing shafts (34).