CN113682863A - Adjustable coiling mechanism is used in non-woven fabrics production - Google Patents

Abstract

The invention discloses an adjustable winding device for non-woven fabric production, which comprises a main body, a magnetic suspension weight compensation type zero-friction winding device, an ultrasonic water self-hammering type drying device, an all-dimensional covering type porous material type dust cleaning device and a self-returning type non-woven fabric uniform cutting device. The invention belongs to the technical field of adjustable rolling for non-woven fabric production, and particularly relates to an adjustable rolling device for non-woven fabric production; the technical theory of the weight compensation principle (combining a certain object with another object capable of providing lifting force to compensate the weight of the object) is creatively applied to the technical field of adjustable rolling for producing non-woven fabrics.

Description

Adjustable coiling mechanism is used in non-woven fabrics production

Technical Field

The invention belongs to the technical field of adjustable rolling for non-woven fabric production, and particularly relates to an adjustable rolling device for non-woven fabric production.

Background

Nonwoven fabrics, also known as nonwovens, are composed of oriented or random fibers. The non-woven fabric is called as the fabric because of the appearance and certain properties of the fabric, and has the characteristics of moisture resistance, air permeability, flexibility, light weight, no combustion supporting, easy decomposition, no toxicity or irritation, rich color, low price, recycling and the like. For example, the polypropylene (pp material) granules are mostly adopted as raw materials and are produced by a continuous one-step method of high-temperature melting, spinning, laying a line and hot-pressing coiling. The fabric is not interwoven and knitted by yarns one by one, but the fibers are directly bonded together by a physical method, so that when a user takes the fabric into the clothes, the user can find that one thread end cannot be drawn out. The non-woven fabric breaks through the traditional spinning principle and has the characteristics of short process flow, high production rate, high yield, low cost, wide application, multiple raw material sources and the like.

When traditional non-woven fabrics was rolled up, directly roll up the non-woven fabrics, dust impurity and fine hair etc. that the non-woven fabrics surface is infected with influence product quality to the non-woven fabrics that the degree of drying is not high can not preserve for a long time, easily rotten. In the rolling process, can't carry out the self-adaptation when meetting the card material and adjust, lead to the non-woven fabrics atress to pull the deformation, cause unable use, also very loaded down with trivial details in the fixed aspect of wind-up roll moreover. In addition, when the rolling device is in failure and stalls, no corresponding device is provided for ensuring that the non-woven fabric is pulled and scrapped. The non-woven fabrics passes through the coiling of coiling mechanism, and the coiling is cut off to certain thickness thick, the winding up roller of more renewing, and the spool of current non-woven fabrics coiling mechanism is changed process, lapping unloading process and all needs the manual work to go on, and degree of automation is low, and the security is low, and operating efficiency is low. After the non-woven fabrics production, when the clearance dust, because the dust is not concentrated in the dirt cup, and easily adhere to on dirt cup inside and other parts, so all have raise dust and other secondary pollution problems when falling the ash, greatly influence user experience and clean efficiency.

Disclosure of Invention

In order to solve the existing problems, the invention provides a workbench for motor intelligent assembly, which creatively applies the technical theory of weight compensation principle (combining a certain object with another object capable of providing lifting force to compensate the weight of the object) to the technical field of adjustable winding for non-woven fabric production without any supporting device, because a new winding roller is replaced in the non-woven fabric winding process, the reel replacement process and the winding and blanking process of the existing non-woven fabric winding device are manually carried out, the automation degree is low, the safety is low, the operation efficiency is low, the magnetic suspension weight compensation type zero friction winding primary expansion device is utilized to contract, the uniform driving type magnetic suspension weight compensation type zero friction winding tertiary support frame descends, the magnetic suspension weight compensation type zero friction winding secondary expansion device contracts, the magnetic suspension weight compensation type secondary support frame descends, the zero-friction type magnetic suspension reel-changing suspension end beam is in a suspension state under the action of magnetic force, when one end of the zero-friction type magnetic suspension reel-changing operation track is lowered, the zero-friction type magnetic suspension reel-changing suspension end beam moves towards a low position, the zero-friction type magnetic suspension reel-changing suspension end beam moves to drive the magnetic suspension weight compensation type zero-friction winding bracket to move, the magnetic suspension weight compensation type zero-friction winding bracket moves to drive the magnetic suspension weight compensation type zero-friction winding primary winding roller to move, and the magnetic suspension weight compensation type zero-friction winding primary winding roller moves to the magnetic suspension weight compensation type secondary support frame to change reels, so that the technical problems that a reel changing process and a reel blanking process of a non-woven fabric coiling device need to be manually carried out, the automation degree is low, the safety is low, and the operation efficiency is low are solved; the non-woven fabric drying concept is innovatively applied to the technical field of adjustable winding for non-woven fabric production by a mechanical vibration principle (ultrasonic vibration and electromagnetic field coupling), and the ultrasonic moisture self-beating type drying device is utilized, and a moisture self-beating type ultrasonic dryer is used for carrying out ultrasonic drying treatment on the non-woven fabric passing through a rotary friction nondestructive type two-stage conveying roller, so that the efficiency of accelerating the drying of the non-woven fabric is realized, and the problems that the non-woven fabric with low drying degree cannot be stored for a long time and is easy to rot are solved; the technical theory of a precaution principle (adopting an emergency measure prepared in advance and carrying out corresponding compensation on a system to improve the reliability of the system) is creatively applied to the technical field of adjustable winding for producing the non-woven fabric, when the winding device is in fault stall operation, the non-woven fabric is prevented from being pulled and scrapped by the self-adaptive anti-pulling type primary telescopic conveying device, and the problem that when the winding device is in fault stall operation or material jamming, no corresponding device ensures that the non-woven fabric is pulled and scrapped is solved; the technical theory of porous material principle (composite material is used for replacing homogeneous material) is innovatively applied to the technical field of adjustable winding for non-woven fabric production, the air-breathing type porous material type dust adsorption primary cleaning roller and the air-breathing type porous material type dust adsorption secondary cleaning roller are used for adsorbing dust and impurities in the winding process of non-woven fabric, and the problems that when the traditional non-woven fabric is wound, the non-woven fabric is directly wound, and the dust, the impurities, fluff and the like stained on the surface of the non-woven fabric influence the product quality are solved. The technical theory of curved surface and curvature increase (centrifugal force is utilized, and rotary motion replaces linear motion) is innovatively applied to the technical field of adjustable winding for non-woven fabric production, the cyclone circulation dispersing type centrifugal device is utilized, the air flow generated by the centrifugal force is used for rapidly adsorbing the entering dust and impurities on the cyclone circulation dispersing type electrostatic adsorption plate, the dust and the impurities are concentrated after winding is completed, and the problem that the dust flies randomly when a dust box is cleaned is solved.

The technical scheme adopted by the invention is as follows: the invention relates to an adjustable winding device for non-woven fabric production, which comprises a main body, a magnetic suspension weight compensation type zero-friction winding device, an ultrasonic moisture self-hammering type drying device, an all-dimensional covering type porous material type dust cleaning device and a self-returning type non-woven fabric uniform cutting device, wherein the all-dimensional covering type porous material type dust cleaning device is arranged in the middle of the main body; the magnetic suspension weight compensation type zero-friction winding device comprises a magnetic suspension weight compensation type first-level electromagnet, a magnetic suspension weight compensation type second-level electromagnet, a magnetic suspension weight compensation type third-level electromagnet, a magnetic suspension weight compensation type fourth-level electromagnet, a reverse weight compensation type zero-friction first-level coil winding, a reverse weight compensation type zero-friction second-level coil winding, a reverse weight compensation type zero-friction third-level coil winding, a reverse weight compensation type zero-friction fourth-level coil winding, a zero-friction type magnetic suspension coil changing running track, a zero-friction type magnetic suspension coil changing suspension end beam, a magnetic suspension weight compensation type zero-friction winding bracket, a sliding friction lossless type magnetic suspension first-level limiting part, a sliding friction lossless type magnetic suspension second-level limiting part, a friction lossless type first-level bearing, a friction lossless type second-level bearing, a friction lossless type third-level bearing, a friction lossless type fourth-level bearing, a magnetic suspension weight compensation type zero-friction first-level winding roller, a magnetic suspension weight compensation type zero-friction type third-level winding roller, a magnetic suspension weight compensation type zero-friction type magnetic suspension roller, a magnetic suspension type zero-friction type magnetic suspension coil winding roller, a magnetic suspension type magnetic suspension device, a magnetic suspension type magnetic suspension device, a magnetic suspension type magnetic suspension device, a magnetic suspension type magnetic suspension device, a magnetic suspension type magnetic suspension device, a magnetic suspension type magnetic suspension device, a magnetic suspension type magnetic, A magnetic suspension weight compensation type zero friction rolling secondary power roller, a magnetic suspension weight compensation type zero friction rolling primary rolling roller, a wrinkle-proof type gravity compensation type primary auxiliary roller, a wrinkle-proof type gravity compensation type primary limiting spring, a uniform speed driving type magnetic suspension weight compensation type zero friction rolling primary gear, a uniform speed driving type magnetic suspension weight compensation type zero friction rolling secondary gear, a uniform speed driving type magnetic suspension weight compensation type zero friction rolling primary motor, a uniform speed driving type magnetic suspension weight compensation type zero friction rolling primary chain, a wrinkle-proof type gravity compensation type primary support frame, a magnetic suspension wrinkle-proof type gravity compensation type primary support frame downward sliding gap, a magnetic suspension weight compensation type secondary support frame, a magnetic suspension weight compensation type zero friction rolling primary expansion device, a magnetic suspension weight compensation type zero friction rolling secondary expansion device and a uniform speed driving type magnetic suspension weight compensation type zero friction rolling tertiary support frame, the fold-prevention gravity compensation type primary support frame is arranged on the magnetic suspension weight compensation type zero-friction winding device, a magnetic suspension fold-prevention gravity compensation type primary support frame gliding clearance is arranged in the fold-prevention gravity compensation type primary support frame, one end of the fold-prevention gravity compensation type primary limit spring is arranged at the upper end of the magnetic suspension fold-prevention gravity compensation type primary support frame gliding clearance, the friction nondestructive four-stage bearing is arranged at the other end of the fold-prevention gravity compensation type primary limit spring, one end of the fold-prevention gravity compensation type primary auxiliary roller is arranged in the friction nondestructive four-stage bearing, the magnetic suspension weight compensation type zero-friction winding primary expansion device is arranged at the lower end of the magnetic suspension weight compensation type zero-friction winding device, and the uniform-speed magnetic suspension weight compensation type zero-friction winding tertiary support frame is arranged on the magnetic suspension weight compensation type zero-friction winding primary expansion device, the uniform-speed driving type magnetic suspension weight compensation type zero friction winding primary motor is arranged on the uniform-speed driving type magnetic suspension weight compensation type zero friction winding tertiary support frame in a rotating mode, the magnetic suspension weight compensation type zero friction winding secondary power roller is arranged on the uniform-speed driving type magnetic suspension weight compensation type zero friction winding tertiary support frame in a rotating mode, the uniform-speed driving type magnetic suspension weight compensation type zero friction winding primary gear is sleeved on a shaft of the magnetic suspension weight compensation type zero friction winding primary power roller, the uniform-speed driving type magnetic suspension weight compensation type zero friction winding secondary gear is sleeved on a shaft of the magnetic suspension weight compensation type zero friction winding secondary power roller, the uniform-speed driving type magnetic suspension weight compensation type zero friction winding primary motor is arranged on the uniform-speed driving type magnetic suspension weight compensation type zero friction winding tertiary support frame, one end of the magnetic suspension weight compensation type zero friction winding secondary power roller is arranged at the uniform-speed driving type magnetic suspension weight compensation type zero friction winding secondary power roller The output end of a rolling primary motor is wiped, a magnetic suspension weight compensation type zero friction rolling secondary expansion device is arranged at one side of a uniform-speed driving type magnetic suspension weight compensation type zero friction rolling tertiary support frame, the magnetic suspension weight compensation type secondary support frame is arranged on the magnetic suspension weight compensation type zero friction rolling secondary expansion device, a friction lossless type primary bearing is arranged on the side wall of the wrinkle-proof type gravity compensation type primary support frame, a friction lossless type secondary bearing is arranged on the side wall of the magnetic suspension weight compensation type secondary support frame, one end of a zero friction type magnetic suspension roll changing operation track is arranged on the friction lossless type primary bearing, the other end of the zero friction type magnetic suspension roll changing operation track is arranged on the friction lossless type secondary bearing, a sliding friction lossless type magnetic suspension primary limiting piece is arranged on the side wall of the wrinkle-proof type gravity compensation type primary support frame, the sliding friction nondestructive magnetic suspension secondary limiting part is arranged on the side wall of the magnetic suspension weight compensation type secondary supporting frame, the zero friction type magnetic suspension coil changing suspension end beam is arranged on the zero friction type magnetic suspension coil changing running track in a suspension way, the magnetic suspension weight compensation type primary electromagnet is arranged on the zero friction type magnetic suspension coil changing suspension end beam, the magnetic suspension weight compensation type four-level electromagnet is arranged on the zero friction type magnetic suspension coil changing suspension end beam, the magnetic suspension weight compensation type secondary electromagnet is arranged on the zero friction type magnetic suspension coil changing suspension end beam, the magnetic suspension weight compensation type three-level electromagnet is arranged on the zero friction type magnetic suspension coil changing suspension end beam, the reverse weight compensation zero friction type one-level coil winding resistance is arranged on the zero friction type magnetic suspension coil changing running track, and the reverse weight compensation zero friction type four-level coil winding resistance is arranged on the zero friction type magnetic suspension coil changing running track, the reverse weight compensation zero friction secondary coil winding is arranged on a zero friction type magnetic suspension coil-changing running track, the reverse weight compensation zero friction tertiary coil winding is arranged on the zero friction type magnetic suspension coil-changing running track, the magnetic suspension weight compensation type primary electromagnet and the reverse weight compensation zero friction primary coil winding are symmetrical, the magnetic suspension weight compensation type secondary electromagnet and the reverse weight compensation zero friction secondary coil winding are symmetrical, the reverse weight compensation zero friction tertiary coil winding and the magnetic suspension weight compensation type tertiary electromagnet are symmetrical, the magnetic suspension weight compensation type four-stage electromagnet and the reverse weight compensation zero friction four-stage coil winding are symmetrical, the magnetic suspension weight compensation type zero friction winding bracket is arranged on a zero friction type magnetic suspension coil-changing suspension end beam, and the friction lossless type three-stage bearing is detachably arranged on the magnetic suspension weight compensation type zero friction winding bracket, the magnetic suspension weight compensation type zero-friction winding primary winding roller is detachably sleeved in the friction lossless type tertiary bearing, the magnetic suspension weight compensation type zero-friction winding primary expansion device contracts, the uniform speed driving type magnetic suspension weight compensation type zero-friction winding tertiary support frame descends, the magnetic suspension weight compensation type zero-friction winding secondary expansion device contracts, the magnetic suspension weight compensation type secondary support frame descends, the zero-friction type magnetic suspension reel changing suspension end beam is in a suspension state under the action of magnetic force, when one end of the zero-friction type magnetic suspension reel changing operation track is lowered, the zero-friction type magnetic suspension reel changing suspension end beam moves towards the lower part, the zero-friction type magnetic suspension reel changing suspension end beam moves to drive the magnetic suspension weight compensation type zero-friction winding bracket to move, and the magnetic suspension weight compensation type zero-friction winding bracket moves to drive the magnetic suspension weight compensation type zero-friction primary winding roller to move, the magnetic suspension weight compensation type zero-friction winding primary winding roller moves to the magnetic suspension weight compensation type secondary support frame to change a winding, the magnetic suspension weight compensation type zero-friction winding secondary expansion device is started to extend after the winding is changed, the magnetic suspension weight compensation type secondary support frame rises, a new winding shaft moves to an initial position through the zero-friction type magnetic suspension winding changing suspension end beam, one end of the uniform speed drive type magnetic suspension weight compensation type zero-friction winding primary chain is sleeved on the uniform speed drive type magnetic suspension weight compensation type zero-friction winding primary gear, and the other end of the uniform speed drive type magnetic suspension weight compensation type zero-friction winding primary chain is sleeved on the uniform speed drive type magnetic suspension weight compensation type zero-friction winding secondary gear.

Further, the ultrasonic moisture self-beating type drying device comprises an ultrasonic moisture self-beating type drying base, an ultrasonic dryer fixing shaft, an ultrasonic moisture self-beating type drying arch box, a rotary friction lossless type first-level conveying roller, a rotary friction lossless type second-level conveying roller and a moisture self-beating type ultrasonic dryer, wherein the ultrasonic moisture self-beating type drying base is arranged at the lower end of the ultrasonic moisture self-beating type drying device, the ultrasonic moisture self-beating type drying arch box is arranged on the ultrasonic moisture self-beating type drying base, the ultrasonic dryer fixing shaft is arranged in the ultrasonic moisture self-beating type drying arch box, the moisture self-beating type ultrasonic dryer is arranged on the ultrasonic dryer fixing shaft, the rotary friction lossless type first-level conveying roller is rotatably arranged at the inlet of the ultrasonic moisture self-beating type drying arch box, the harmless formula second grade transfer roller of rotational friction rotates and locates ultrasonic wave moisture from beating the formula arch incasement of drying, and moisture carries out ultrasonic drying from beating the non-woven fabrics of beating formula ultrasonic dryer to passing the harmless formula second grade transfer roller of rotational friction and handles.

Further, the all-directional covering type porous material type dust cleaning device comprises an all-directional covering type porous material type dust cleaning box, a self-adaptive pull-proof type first-stage telescopic conveying device, a suction type porous material type dust adsorption first-stage cleaning roller, a suction type porous material type dust adsorption second-stage cleaning roller, a multidirectional attachment type dust first-stage adsorption hole, a multidirectional attachment type dust second-stage adsorption hole, a friction lossless type five-stage bearing, a friction lossless type six-stage bearing, a friction lossless type seven-stage bearing, a friction lossless type eight-stage bearing, an all-directional covering type porous material type dust cleaning first-stage gear, an all-directional covering type porous material type dust cleaning second-stage gear, an all-directional covering type porous material type dust cleaning third-stage gear, an all-directional covering type porous material type dust cleaning second-stage motor, an F-type air flow conveying dust cleaning suction pipe, an F-type air flow conveying dust cleaning first-stage air suction port, An F-shaped airflow conveying dust cleaning secondary air suction port, an F-shaped airflow conveying dust cleaning primary air outlet, an all-round covering type porous material type dust cleaning primary air pump, a cyclone circulating scattering type electrostatic adsorption dust collecting box, a cyclone circulating scattering type centrifugal device, a cyclone circulating scattering type electrostatic adsorption plate, a cyclone circulating scattering type filter screen and a cyclone circulating scattering type air hole, wherein the all-round covering type porous material type dust cleaning box is arranged on the all-round covering type porous material type dust cleaning device, the self-adaptive pulling-proof type primary telescopic conveying device is arranged in the all-round covering type porous material type dust cleaning box, the friction lossless type five-stage bearing is arranged on the inner wall of the all-round covering type porous material type dust cleaning box, the friction lossless type six-stage bearing is arranged on the inner wall of the all-round covering type porous material type dust cleaning box, one end of the air suction type porous material type dust adsorption one-level cleaning roller is arranged on a friction lossless type five-level bearing, one end of the air suction type porous material type dust adsorption two-level cleaning roller is arranged on a friction lossless type six-level bearing, multidirectional attaching type dust one-level adsorption holes are formed in the air suction type porous material type dust adsorption one-level cleaning roller, the multidirectional attaching type dust two-level adsorption holes are formed in the air suction type porous material type dust adsorption two-level cleaning roller, the omnibearing covering type porous material type dust cleaning two-level motor is arranged on the inner wall of the omnibearing covering type porous material type dust cleaning box, the omnibearing covering type porous material type dust cleaning one-level gear is arranged at the output end of the omnibearing covering type porous material type dust cleaning two-level motor, and the omnibearing covering type porous material type dust cleaning two-level gear is sleeved on the shaft of the air suction type porous material type dust adsorption one-level cleaning roller, the all-round cover type porous material type dust cleaning three-level gear is sleeved on a shaft of the air suction type porous material type dust adsorption two-level cleaning roller, the friction lossless type seven-level bearing is penetrated and arranged at the other end of the air suction type porous material type dust adsorption one-level cleaning roller, the friction lossless type eight-level bearing is penetrated and arranged at the other end of the air suction type porous material type dust adsorption two-level cleaning roller, the upper end of the F-shaped air flow conveying dust cleaning suction pipe is penetrated and arranged on the friction lossless type seven-level bearing and the F-shaped air flow conveying dust cleaning two-level suction port, the F-shaped air flow conveying dust cleaning one-level suction port is arranged on the F-shaped air flow conveying dust cleaning suction pipe, the F-shaped air flow conveying dust cleaning one-level air outlet is arranged at the lower end of the F-shaped air flow conveying dust cleaning suction pipe, the omnibearing coverage type porous material type dust cleaning primary air pump is arranged on the F-shaped airflow conveying dust cleaning suction pipe, the cyclone circulation scattering type electrostatic adsorption dust collecting box is arranged at the bottom end of the inner wall of the omnibearing coverage type porous material type dust cleaning box, the F-shaped airflow conveying dust cleaning suction pipe is arranged on the cyclone circulation scattering type electrostatic adsorption dust collecting box in a penetrating way, the cyclone circulation scattering type centrifugal device is arranged at the bottom end of the inner wall of the cyclone circulation scattering type electrostatic adsorption dust collecting box, the cyclone circulation scattering type electrostatic adsorption plate is arranged in the cyclone circulation scattering type electrostatic adsorption dust collecting box, the cyclone circulation scattering type filter screen is arranged in the cyclone circulation scattering type electrostatic adsorption dust collecting box, the cyclone circulation scattering type air hole is arranged on the side wall of the cyclone circulation scattering type electrostatic adsorption dust collecting box, the omnibearing coverage type porous material type dust cleaning primary gear and the omnibearing coverage type porous material type dust cleaning secondary air pump are arranged on the side wall of the cyclone circulation scattering type electrostatic adsorption dust collecting box, and the omnibearing coverage type porous material type dust cleaning secondary air pump is arranged on the side wall of the cyclone circulation scattering type electrostatic adsorption dust collecting box, and the cyclone circulation scattering type dust collecting box is arranged on the side wall of the whole area of the cyclone circulation scattering type dust collecting box, and the whole area of the whole area The stage gears are connected in a meshing rotation mode, the omnibearing cover type porous material type dust cleaning tertiary gear and the omnibearing cover type porous material type dust cleaning secondary gear are connected in a meshing rotation mode, the omnibearing cover type porous material type dust cleaning device is started, the output end of the omnibearing cover type porous material type dust cleaning secondary motor rotates to drive the omnibearing cover type porous material type dust cleaning primary gear to rotate, the omnibearing cover type porous material type dust cleaning primary gear rotates to drive the omnibearing cover type porous material type dust cleaning secondary gear to rotate, the omnibearing cover type porous material type dust cleaning secondary gear rotates to drive the air suction type porous material type dust adsorption primary cleaning roller and the omnibearing cover type porous material type dust cleaning tertiary gear to rotate, the omnibearing cover type porous material type dust cleaning tertiary gear rotates to drive the air suction type porous material type dust adsorption secondary cleaning roller to rotate, starting the omnibearing covering type porous material type dust cleaning primary air pump, sucking dust and impurities on non-woven fabrics into the air suction type porous material type dust adsorption primary cleaning roller through the multidirectional attaching type dust primary adsorption hole, then entering the F-shaped air flow conveying dust cleaning suction pipe, sucking the air suction type porous material type dust adsorption secondary cleaning roller through the multidirectional attaching type dust secondary adsorption hole, then entering the F-shaped air flow conveying dust cleaning suction pipe, finally entering the cyclone circulation scattering type electrostatic adsorption dust collecting box, starting the cyclone circulation scattering type centrifugal device, quickly adsorbing the entered dust and impurities on the cyclone circulation scattering type electrostatic adsorption plate through air flow generated by centrifugal force, and finishing centralized treatment after rolling; the flexible conveyer of type one-level is prevented dragging by self-adaptation includes that the self-adaptation prevents dragging the flexible pipe of type one-level, self-adaptation prevents dragging the flexible pipe of type second grade, self-adaptation prevents dragging type one-level transfer roller and self-adaptation prevents dragging type one-level spring, the self-adaptation prevents dragging the flexible pipe of type one-level and locates on the inner wall of all-round overlay type porous material type dust clean box, the self-adaptation prevents dragging the one end of type one-level spring and locates the self-adaptation and prevent dragging the inner wall bottom that the flexible pipe of type one-level, the self-adaptation prevents dragging the one end that the flexible pipe of type second grade was located the self-adaptation and prevents dragging the other end of type one-level spring, the self-adaptation prevents dragging type one-level transfer roller and rotates and locates the other end that the flexible pipe of type second grade is prevented dragging by self-adaptation.

Further, the self-return non-woven fabric uniform cutting device comprises a self-return non-woven fabric uniform cutting piece, a friction lossless self-return non-woven fabric uniform cutting slide block, a friction lossless self-return non-woven fabric uniform cutting slide rod, a self-return non-woven fabric uniform cutting three-stage motor, a friction lossless self-return non-woven fabric uniform cutting lead screw, a friction lossless nine-stage bearing, a self-return non-woven fabric uniform cutting fixed box body, a rotary friction lossless three-stage conveying roller and a rotary friction lossless four-stage conveying roller, wherein the self-return non-woven fabric uniform cutting fixed box body is arranged in the omnibearing covering type porous material dust cleaning box body, the self-return non-woven fabric uniform cutting three-stage motor is arranged on the outer wall of the self-return non-woven fabric uniform cutting fixed box body, and the friction lossless nine-stage bearing is arranged on the inner wall of the self-return non-woven fabric uniform cutting fixed box body, one end of the friction lossless type uniform cutting lead screw for the self-returning non-woven fabric is arranged at the output end of the three-stage motor for uniformly cutting the self-returning non-woven fabric, the other end of the friction lossless type uniform cutting lead screw for the self-returning non-woven fabric is arranged on a friction lossless type nine-stage bearing, the friction lossless type uniform cutting slide bar for the self-returning non-woven fabric is arranged on the inner wall of the uniformly cutting fixed box body for uniformly cutting the self-returning non-woven fabric, the friction lossless type uniform cutting slide block for the self-returning non-woven fabric is sleeved on the friction lossless type uniform cutting slide bar for the self-returning non-woven fabric and the friction lossless type uniform cutting lead screw for the self-returning non-woven fabric, the friction lossless type uniform cutting slide block for the self-returning non-woven fabric is connected with the uniform cutting lead screw for meshing rotation, and the uniform cutting piece for the self-returning non-woven fabric is arranged on the friction lossless type uniform cutting slide block for cutting the self-returning non-woven fabric, the three-level transfer roller of the lossless formula of rotating friction rotates and is located on the box body of the uniform cutting of the self-returning non-woven fabric, the device for uniformly cutting the self-returning non-woven fabric is started, the output end of the three-level motor of the uniform cutting of the self-returning non-woven fabric rotates and drives the lead screw of the lossless formula of rotating and automatically returning the non-woven fabric to rotate, the lead screw of the lossless formula of rotating and automatically returning the uniform cutting of the non-woven fabric rotates and drives the slider of the lossless formula of automatically returning the non-woven fabric to move, and the non-woven fabric is cut.

The invention with the structure has the following beneficial effects: the invention provides an adjustable winding device for non-woven fabric production, which creatively applies the technical theory of weight compensation principle (combining a certain object with another object capable of providing lifting force to compensate the weight of the object) to the technical field of adjustable winding for non-woven fabric production without any supporting device, because a new winding roller is replaced in the non-woven fabric winding process, the reel replacement process and the winding and blanking process of the existing non-woven fabric winding device are manually carried out, the automation degree is low, the safety is low, and the operation efficiency is low, the magnetic suspension weight compensation type zero-friction winding primary expansion device is utilized to contract, the constant-speed driving type magnetic suspension weight compensation type zero-friction winding tertiary support frame descends, the magnetic suspension weight compensation type zero-friction winding secondary expansion device contracts, the magnetic suspension weight compensation type secondary support frame descends, and the zero-friction type magnetic suspension changing suspension end beam is in a suspension state under the action of magnetic force, when one end of the zero-friction type magnetic suspension reel changing operation track is lowered, the zero-friction type magnetic suspension reel changing suspension end beam moves towards a low position, the zero-friction type magnetic suspension reel changing suspension end beam moves to drive the magnetic suspension weight compensation type zero-friction winding bracket to move, the magnetic suspension weight compensation type zero-friction winding bracket moves to drive the magnetic suspension weight compensation type zero-friction winding primary winding roller to move, and the magnetic suspension weight compensation type zero-friction winding primary winding roller moves to the magnetic suspension weight compensation type secondary support frame to change reels, so that the technical problems that a reel changing process and a reel blanking process of a non-woven fabric coiling device need to be manually carried out, the automation degree is low, the safety is low, and the operation efficiency is low are solved; the non-woven fabric drying concept is innovatively applied to the technical field of adjustable winding for non-woven fabric production by a mechanical vibration principle (ultrasonic vibration and electromagnetic field coupling), and the ultrasonic moisture self-beating type drying device is utilized, and a moisture self-beating type ultrasonic dryer is used for carrying out ultrasonic drying treatment on the non-woven fabric passing through a rotary friction nondestructive type two-stage conveying roller, so that the efficiency of accelerating the drying of the non-woven fabric is realized, and the problems that the non-woven fabric with low drying degree cannot be stored for a long time and is easy to rot are solved; the technical theory of a precaution principle (adopting an emergency measure prepared in advance and carrying out corresponding compensation on a system to improve the reliability of the system) is creatively applied to the technical field of adjustable winding for producing the non-woven fabric, when the winding device is in fault stall operation, the non-woven fabric is prevented from being pulled and scrapped by the self-adaptive anti-pulling type primary telescopic conveying device, and the problem that when the winding device is in fault stall operation or material jamming, no corresponding device ensures that the non-woven fabric is pulled and scrapped is solved; the technical theory of porous material principle (composite material is used for replacing homogeneous material) is innovatively applied to the technical field of adjustable winding for non-woven fabric production, the air-breathing type porous material type dust adsorption primary cleaning roller and the air-breathing type porous material type dust adsorption secondary cleaning roller are used for adsorbing dust and impurities in the winding process of non-woven fabric, and the problems that when the traditional non-woven fabric is wound, the non-woven fabric is directly wound, and the dust, the impurities, fluff and the like stained on the surface of the non-woven fabric influence the product quality are solved. The technical theory of curved surface and curvature increase (centrifugal force is utilized, and rotary motion replaces linear motion) is innovatively applied to the technical field of adjustable winding for non-woven fabric production, the cyclone circulation dispersing type centrifugal device is utilized, the air flow generated by the centrifugal force is used for rapidly adsorbing the entering dust and impurities on the cyclone circulation dispersing type electrostatic adsorption plate, the dust and the impurities are concentrated after winding is completed, and the problem that the dust flies randomly when a dust box is cleaned is solved.

Drawings

The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this specification, illustrate embodiments of the invention and together with the description serve to explain the principles of the invention and not to limit the invention.

FIG. 1 is a front sectional view of an adjustable winding device for non-woven fabric production according to the present invention;

FIG. 2 is a schematic structural diagram I of the magnetic suspension weight compensation type zero-friction winding device in FIG. 1;

FIG. 3 is a schematic structural diagram II of the magnetic levitation weight compensation type zero-friction winding device in FIG. 1;

FIG. 4 is a schematic view showing the internal structure of the dust cleaning apparatus of the all-directional covering type made of porous material in FIG. 1;

FIG. 5 is a schematic view of the self-feeding non-woven fabric uniform cutting device shown in FIG. 1;

FIG. 6 is an enlarged view of a portion A of FIG. 2;

fig. 7 is a partially enlarged view of a portion C in fig. 1.

Wherein, 1, a main body, 2, a magnetic suspension weight compensation type zero friction winding device, 3, an ultrasonic wave moisture self-beating type drying device, 4, an all-dimensional covering type porous material type dust cleaning device, 5, a self-returning type non-woven fabric uniform cutting device, 6, a magnetic suspension weight compensation type primary electromagnet, 7, a magnetic suspension weight compensation type secondary electromagnet, 8, a magnetic suspension weight compensation type tertiary electromagnet, 9, a magnetic suspension weight compensation type four-stage electromagnet, 10, a reverse weight compensation type zero friction primary coil winding, 11, a reverse weight compensation type zero friction secondary coil winding, 12, a reverse weight compensation type zero friction tertiary coil winding, 13, a reverse weight compensation type zero friction four-stage coil winding, 14, a zero friction type magnetic suspension coil changing running track, 15, a zero friction type magnetic suspension coil changing suspension end beam, 16, a magnetic suspension weight compensation type zero friction winding bracket, 17. sliding friction lossless type magnetic suspension first-level limiting part, 18 sliding friction lossless type magnetic suspension second-level limiting part, 19 friction lossless type first-level bearing, 20 friction lossless type second-level bearing, 21 friction lossless type third-level bearing, 22 friction lossless type fourth-level bearing, 23 magnetic suspension weight compensation type zero friction winding first-level power roller, 24 magnetic suspension weight compensation type zero friction winding second-level power roller, 25 magnetic suspension weight compensation type zero friction winding first-level winding roller, 26 wrinkle prevention type gravity compensation type first-level auxiliary roller, 27 wrinkle prevention type gravity compensation type first-level limiting spring, 28 driving type magnetic suspension weight compensation type zero friction winding first-level gear, 29 uniform driving type magnetic suspension weight compensation type zero friction winding second-level gear, 30 uniform driving type magnetic suspension weight compensation type zero friction first-level winding motor, 31. uniform speed driving type magnetic suspension weight compensation type zero friction rolling primary chain, 32, anti-wrinkle type gravity compensation type primary support frame, 33, magnetic suspension anti-wrinkle type gravity compensation type primary support frame gliding clearance, 34, magnetic suspension weight compensation type secondary support frame, 35, magnetic suspension weight compensation type zero friction rolling primary expansion device, 36, magnetic suspension weight compensation type zero friction rolling secondary expansion device, 37, ultrasonic moisture self-beating type drying base, 38, ultrasonic dryer fixing shaft, 39, ultrasonic moisture self-beating type drying arch box, 40, rotary friction lossless type primary conveying roller, 41, rotary friction lossless type secondary conveying roller, 42, moisture self-beating type ultrasonic dryer, 43, omnibearing covering type porous material type dust cleaning box, 44, self-adapting anti-pulling type primary expansion conveying device, 45, air suction type porous material type dust adsorption primary cleaning roller, 46. a suction type porous material type dust adsorption secondary cleaning roller, 47, a multidirectional attaching type dust first-stage adsorption hole, 48, a multidirectional attaching type dust second-stage adsorption hole, 49, a friction lossless type five-stage bearing, 50, a friction lossless type six-stage bearing, 51, a friction lossless type seven-stage bearing, 52, a friction lossless type eight-stage bearing, 53, an all-directional covering type porous material type dust cleaning primary gear, 54, an all-directional covering type porous material type dust cleaning secondary gear, 55, an all-directional covering type porous material type dust cleaning tertiary gear, 56, an all-directional covering type porous material type dust cleaning secondary motor, 57, an F type air flow conveying dust cleaning suction pipe, 58, an F type air flow conveying dust cleaning primary air suction port, 59, an F type air flow conveying dust cleaning secondary air suction port, 60, an F type air flow conveying dust cleaning primary air outlet, 61, An omnibearing covering type porous material type dust cleaning primary air pump 62, a cyclone circulation scattering type electrostatic adsorption dust collecting box 63, a cyclone circulation scattering type centrifugal device 64, a cyclone circulation scattering type electrostatic adsorption plate 65, a cyclone circulation scattering type filter screen 66, a cyclone circulation scattering type air hole 67, an adaptive anti-pulling type primary extension tube 68, an adaptive anti-pulling type secondary extension tube 69, an adaptive anti-pulling type primary transmission roller 70, an adaptive anti-pulling type primary spring 71, a self-returning type non-woven fabric uniform cutting sheet 72, a friction damage-free type self-returning non-woven fabric uniform cutting slide block 73, a friction damage-free type self-returning non-woven fabric uniform cutting slide bar 74, a self-returning type non-woven fabric uniform cutting tertiary motor 75, a friction damage-free type self-returning non-woven fabric uniform cutting lead screw 76, a friction damage-free type nine-level bearing 77, a self-adaptive anti-pulling type non-woven fabric uniform cutting slide bar 68, a friction damage type self-returning non-woven fabric uniform cutting slide bar, The automatic non-woven fabric uniform cutting and fixing box body is characterized by comprising a self-returning non-woven fabric uniform cutting and fixing box body, 78 rotating friction lossless type three-stage conveying rollers, 79 rotating friction lossless type four-stage conveying rollers and 80 constant speed driving type magnetic suspension weight compensation type zero friction winding three-stage supporting frame.

Detailed Description

The technical solutions of the present invention will be further described in detail with reference to specific embodiments, and the technical features or connection relationships described in the present invention are not described in detail in the prior art. The present invention will be described in further detail with reference to the accompanying drawings.

In the description of the present invention, it is to be understood that the terms "upper", "lower", "front", "rear", "left", "right", "top", "bottom", "inner", "outer", and the like, indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, are merely for convenience in describing the present invention and simplifying the description, and do not indicate or imply that the device or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus, should not be construed as limiting the present invention.

As shown in fig. 1, 2, 3 and 6, the invention provides an adjustable winding device for non-woven fabric production, which comprises a main body 1, a magnetic suspension weight compensation type zero friction winding device 2, an ultrasonic moisture self-beating type drying device 3, an all-directional covering type porous material type dust cleaning device 4 and a self-returning type non-woven fabric uniform cutting device 5, wherein the all-directional covering type porous material type dust cleaning device 4 is arranged in the middle of the main body 1, the magnetic suspension weight compensation type zero friction winding device 2 is arranged at one side of the all-directional covering type porous material type dust cleaning device 4, the ultrasonic moisture self-beating type drying device 3 is arranged at the other side of the magnetic suspension weight compensation type zero friction winding device 2, and the self-returning type non-woven fabric uniform cutting device 5 is arranged in the all-directional covering type porous material type dust cleaning device 4; the magnetic suspension weight compensation type zero-friction winding device 2 comprises a magnetic suspension weight compensation type primary electromagnet 6, a magnetic suspension weight compensation type secondary electromagnet 7, a magnetic suspension weight compensation type tertiary electromagnet 8, a magnetic suspension weight compensation type four-stage electromagnet 9, a reverse weight compensation type zero-friction primary coil winding 10, a reverse weight compensation type zero-friction secondary coil winding 11, a reverse weight compensation type zero-friction tertiary coil winding 12, a reverse weight compensation type zero-friction four-stage coil winding 13, a zero-friction type magnetic suspension coil-changing running track 14, a zero-friction type magnetic suspension coil-changing suspension end beam 15, a magnetic suspension weight compensation type zero-friction winding bracket 16, a sliding friction type nondestructive magnetic suspension type primary limiting piece 17, a sliding friction type nondestructive magnetic suspension type secondary limiting piece 18, a friction type primary bearing 19, a friction type nondestructive secondary bearing 20, a friction type nondestructive tertiary bearing 21, a magnetic suspension type nondestructive bearing 21, A friction lossless four-stage bearing 22, a magnetic suspension weight compensation type zero friction winding primary power roller 23, a magnetic suspension weight compensation type zero friction winding secondary power roller 24, a magnetic suspension weight compensation type zero friction winding primary power roller 25, a wrinkle prevention type gravity compensation type primary auxiliary roller 26, a wrinkle prevention type gravity compensation type primary limit spring 27, a uniform speed driving type magnetic suspension weight compensation type zero friction winding primary gear 28, a uniform speed driving type magnetic suspension weight compensation type zero friction winding secondary gear 29, a uniform speed driving type magnetic suspension weight compensation type zero friction winding primary motor 30, a uniform speed driving type magnetic suspension weight compensation type zero friction winding primary chain 31, a wrinkle prevention type gravity compensation type primary support frame 32, a magnetic suspension wrinkle prevention type gravity compensation type primary support frame 32 lower sliding gap 33, a magnetic suspension weight compensation type secondary support frame 34, a magnetic suspension weight compensation type zero friction winding primary expansion device 35, A magnetic suspension weight compensation type zero friction rolling secondary expansion device 36 and a uniform speed driving type magnetic suspension weight compensation type zero friction rolling tertiary support frame 80, wherein a wrinkle-proof gravity compensation type primary support frame 32 is arranged on the magnetic suspension weight compensation type zero friction rolling device 2, a downward sliding gap 33 of the magnetic suspension wrinkle-proof gravity compensation type primary support frame 32 is arranged in the wrinkle-proof gravity compensation type primary support frame 32, one end of a wrinkle-proof gravity compensation type primary limit spring 27 is arranged at the upper end of the downward sliding gap 33 of the magnetic suspension wrinkle-proof gravity compensation type primary support frame 32, a friction lossless type four-stage bearing 22 is arranged at the other end of the wrinkle-proof gravity compensation type primary limit spring 27, one end of a wrinkle-proof gravity compensation type primary auxiliary roller 26 is arranged in the friction type four-stage bearing 22, and the magnetic suspension lossless weight compensation type zero friction primary expansion device 35 is arranged at the lower end of the magnetic suspension weight compensation type zero friction rolling device 2, the uniform-speed drive type magnetic suspension weight compensation type zero-friction winding three-level support frame 80 is arranged on a magnetic suspension weight compensation type zero-friction winding one-level expansion device 35, the magnetic suspension weight compensation type zero-friction winding one-level power roller 23 is rotatably arranged on the uniform-speed drive type magnetic suspension weight compensation type zero-friction winding three-level support frame 80, the magnetic suspension weight compensation type zero-friction winding two-level power roller 24 is rotatably arranged on the uniform-speed drive type magnetic suspension weight compensation type zero-friction winding three-level support frame 80, the uniform-speed drive type magnetic suspension weight compensation type zero-friction winding one-level gear 28 is sleeved on a shaft of the magnetic suspension weight compensation type zero-friction winding one-level power roller 23, the uniform-speed drive type magnetic suspension weight compensation type zero-friction winding two-level gear 29 is sleeved on a shaft of the magnetic suspension weight compensation type zero-friction winding two-level power roller 24, and the uniform-speed drive type magnetic suspension weight compensation type zero-friction winding one-level motor 30 is arranged on a shaft of the uniform-speed drive type magnetic suspension weight compensation type zero-friction winding two-level power roller 80 On the third support frame 80, one end of the magnetic suspension weight compensation type zero friction rolling secondary power roller 24 is arranged at the output end of the constant speed driving type magnetic suspension weight compensation type zero friction rolling primary motor 30, the magnetic suspension weight compensation type zero friction rolling secondary expansion device 36 is arranged at one side of the constant speed driving type magnetic suspension weight compensation type zero friction rolling tertiary support frame 80, the magnetic suspension weight compensation type secondary support frame 34 is arranged on the magnetic suspension weight compensation type zero friction rolling secondary expansion device 36, the friction damage-free type primary bearing 19 is arranged on the side wall of the wrinkle-proof type gravity compensation type primary support frame 32, the friction damage-free type secondary bearing 20 is arranged on the side wall of the magnetic suspension weight compensation type secondary support frame 34, one end of the zero friction type magnetic suspension roll changing operation track 14 is arranged on the friction damage-free type primary bearing 19, the other end of the zero friction type magnetic suspension roll changing operation track 14 is arranged on the friction damage-free type secondary bearing 20, the sliding friction lossless type magnetic suspension primary limiting piece 17 is arranged on the side wall of the wrinkle-proof type gravity compensation type primary supporting frame 32, the sliding friction lossless type magnetic suspension secondary limiting piece 18 is arranged on the side wall of the magnetic suspension weight compensation type secondary supporting frame 34, the zero friction type magnetic suspension reel changing suspension end beam 15 is arranged on the zero friction type magnetic suspension reel changing running track 14 in a suspending way, the magnetic suspension weight compensation type primary electromagnet 6 is arranged on the zero friction type magnetic suspension reel changing suspension end beam 15, the magnetic suspension weight compensation type four-stage electromagnet 9 is arranged on the zero friction type magnetic suspension reel changing suspension end beam 15, the magnetic suspension weight compensation type secondary electromagnet 7 is arranged on the zero friction type magnetic suspension reel changing suspension end beam 15, the magnetic suspension weight compensation type three-stage electromagnet 8 is arranged on the zero friction type magnetic suspension reel changing suspension end beam 15, the reverse weight compensation zero friction type primary coil winding resistance 10 is arranged on the zero friction type magnetic suspension reel changing running track 14, a reverse weight compensation zero friction four-stage coil winding 13 is arranged on a zero friction type magnetic suspension reel change running track 14, a reverse weight compensation zero friction two-stage coil winding 11 is arranged on the zero friction type magnetic suspension reel change running track 14, a reverse weight compensation zero friction three-stage coil winding 12 is arranged on the zero friction type magnetic suspension reel change running track 14, a magnetic suspension weight compensation type one-stage electromagnet 6 is symmetrical to a reverse weight compensation zero friction one-stage coil winding 10, a magnetic suspension weight compensation type two-stage electromagnet 7 is symmetrical to the reverse weight compensation zero friction two-stage coil winding 11, the reverse weight compensation zero friction three-stage coil winding 12 is symmetrical to a magnetic suspension weight compensation type three-stage electromagnet 8, a magnetic suspension weight compensation type four-stage electromagnet 9 is symmetrical to the reverse weight compensation zero friction four-stage coil winding 13, and a magnetic suspension weight compensation zero friction winding bracket 16 is arranged on a zero friction type magnetic suspension reel change suspension end beam 15, the friction lossless type three-stage bearing 21 is detached and arranged on the magnetic suspension weight compensation type zero friction winding bracket 16, the magnetic suspension weight compensation type zero friction winding first-stage winding roller 25 is detached and sleeved in the friction lossless type three-stage bearing 21, one end of the uniform speed driving type magnetic suspension weight compensation type zero friction winding first-stage chain 31 is sleeved and arranged on the uniform speed driving type magnetic suspension weight compensation type zero friction winding first-stage gear 28, and the other end of the uniform speed driving type magnetic suspension weight compensation type zero friction winding first-stage chain 31 is sleeved and arranged on the uniform speed driving type magnetic suspension weight compensation type zero friction winding second-stage gear 29.

As shown in FIGS. 1 and 4, the all-directional covering type porous material type dust cleaning device 4 comprises an all-directional covering type porous material type dust cleaning tank 43, an adaptive pull-proof type primary telescopic conveyor 44, a suction type porous material type dust adsorbing primary cleaning roller 45, a suction type porous material type dust adsorbing secondary cleaning roller 46, a multi-directional fitting type dust primary adsorbing hole 47, a multi-directional fitting type dust secondary adsorbing hole 48, a friction nondestructive five-stage bearing 49, a friction nondestructive six-stage bearing 50, a friction nondestructive seven-stage bearing 51, a friction nondestructive eight-stage bearing 52, an all-directional covering type porous material type dust cleaning primary gear 53, an all-directional covering type porous material type dust cleaning secondary gear 54, an all-directional covering type porous material type dust cleaning tertiary gear 55, an all-directional covering type porous material type dust cleaning secondary motor 56, An F-shaped air flow conveying dust cleaning suction pipe 57, an F-shaped air flow conveying dust cleaning primary air suction port 58, an F-shaped air flow conveying dust cleaning secondary air suction port 59, an F-shaped air flow conveying dust cleaning primary air outlet 60, an all-round covering type porous material dust cleaning primary air pump 61, a cyclone circulation scattering type electrostatic adsorption dust collecting box 62, a cyclone circulation scattering type centrifugal device 63, a cyclone circulation scattering type electrostatic adsorption plate 64, a cyclone circulation scattering type filter screen 65 and a cyclone circulation scattering type air hole 66, wherein the all-round covering type porous material dust cleaning box 43 is arranged on the all-round covering type porous material dust cleaning device 4, the self-adaptive pulling-proof type primary telescopic conveying device 44 is arranged in the all-round covering type porous material dust cleaning box 43, the friction nondestructive five-stage bearing 49 is arranged on the inner wall of the all-round covering type porous material dust cleaning box 43, a friction lossless type six-stage bearing 50 is arranged on the inner wall of the omnibearing covering type porous material type dust cleaning box 43, one end of a suction type porous material type dust adsorption first-stage cleaning roller 45 is arranged on a friction lossless type five-stage bearing 49, one end of a suction type porous material type dust adsorption second-stage cleaning roller 46 is arranged on the friction lossless type six-stage bearing 50, a multidirectional attaching type dust first-stage adsorption hole 47 is arranged on the suction type porous material type dust adsorption first-stage cleaning roller 45, a multidirectional attaching type dust second-stage adsorption hole 48 is arranged on the suction type porous material type dust adsorption second-stage cleaning roller 46, an omnibearing covering type porous material type dust cleaning second-stage motor 56 is arranged on the inner wall of the omnibearing covering type porous material type dust cleaning box 43, an omnibearing covering type porous material type dust cleaning first-stage gear 53 is arranged at the output end of the omnibearing covering type porous material type dust cleaning second-stage motor 56, an omnibearing cover type porous material type dust cleaning secondary gear 54 is sleeved on the shaft of the air suction type porous material type dust adsorption primary cleaning roller 45, an omnibearing cover type porous material type dust cleaning tertiary gear 55 is sleeved on the shaft of the air suction type porous material type dust adsorption secondary cleaning roller 46, a friction lossless type seven-stage bearing 51 is penetrated and arranged at the other end of the air suction type porous material type dust adsorption primary cleaning roller 45, a friction lossless type eight-stage bearing 52 is penetrated and arranged at the other end of the air suction type porous material type dust adsorption secondary cleaning roller 46, the upper end of an F type air flow conveying dust cleaning suction pipe 57 is penetrated and arranged on the friction lossless type seven-stage bearing 51 and an F type air flow conveying dust cleaning secondary suction port 59, the F type air flow conveying dust cleaning primary suction port 58 is arranged on the F type air flow conveying dust cleaning suction pipe 57, the F type air flow conveying dust cleaning secondary suction port 59 is arranged on the F type air flow conveying dust cleaning suction pipe 57, an F-shaped air flow conveying dust cleaning first-stage air outlet 60 is arranged at the lower end of an F-shaped air flow conveying dust cleaning suction pipe 57, an all-round covering type porous material type dust cleaning first-stage air pump 61 is arranged on the F-shaped air flow conveying dust cleaning suction pipe 57, a cyclone circulation dispersion type electrostatic adsorption dust collecting box 62 is arranged at the bottom end of the inner wall of the all-round covering type porous material type dust cleaning box 43, the F-shaped air flow conveying dust cleaning suction pipe 57 is penetratingly arranged on the cyclone circulation dispersion type electrostatic adsorption dust collecting box 62, a cyclone circulation dispersion type centrifugal device 63 is arranged at the bottom end of the inner wall of the cyclone circulation dispersion type electrostatic adsorption dust collecting box 62, a cyclone circulation dispersion type electrostatic adsorption plate 64 is arranged in the cyclone dispersion type electrostatic adsorption dust collecting box 62, a cyclone circulation dispersion type filter screen 65 is arranged in the cyclone circulation dispersion type electrostatic adsorption dust collecting box 62, and a cyclone circulation dispersion type air hole 66 is arranged on the side wall of the cyclone circulation dispersion type electrostatic adsorption dust collecting box 62, the omnibearing cover type porous material type dust cleaning primary gear 53 and the omnibearing cover type porous material type dust cleaning secondary gear 54 are in meshed rotary connection, and the omnibearing cover type porous material type dust cleaning tertiary gear 55 and the omnibearing cover type porous material type dust cleaning secondary gear 54 are in meshed rotary connection; the flexible conveyer 44 of type one-level is prevented dragging by self-adaptation includes that the flexible pipe 67 of type one-level is prevented dragging by self-adaptation, the flexible pipe 68 of type second grade is prevented dragging by self-adaptation, type one-level transfer roller 69 is prevented dragging by self-adaptation and type one-level spring 70 is prevented dragging by self-adaptation, the flexible pipe 67 of type one-level is prevented dragging by self-adaptation is located on the inner wall of all-round overlay type porous material type dust clean box 43, the flexible pipe 67's of type one-level inner wall bottom is prevented dragging by self-adaptation is located to the one end of type one-level spring 70 is prevented dragging by self-adaptation, the other end of type one-level spring 70 is prevented dragging by self-adaptation is located to the flexible pipe 68's of type second grade of self-adaptation one-level transfer roller 69 rotation is prevented dragging by self-adaptation.

As shown in fig. 1, 5 and 7, the self-returning non-woven fabric uniform cutting device 5 comprises a self-returning non-woven fabric uniform cutting blade 71, a friction non-destructive self-returning non-woven fabric uniform cutting slider 72, a friction non-destructive self-returning non-woven fabric uniform cutting slider 73, a self-returning non-woven fabric uniform cutting three-stage motor 74, a friction non-destructive self-returning non-woven fabric uniform cutting lead screw 75, a friction non-destructive nine-stage bearing 76, a self-returning non-woven fabric uniform cutting fixed box 77, a rotary friction non-destructive three-stage transport roller 78 and a rotary friction non-destructive four-stage transport roller 79, wherein the self-returning non-woven fabric uniform cutting fixed box 77 is arranged in the omnibearing covering type porous material dust cleaning box 43, the self-returning non-woven fabric uniform cutting three-stage motor 74 is arranged on the outer wall of the self-returning non-woven fabric uniform cutting fixed box 77, the friction non-destructive nine-stage bearing 76 is arranged on the inner wall of the self-returning non-woven fabric uniform cutting fixed box 77, one end of a friction lossless type uniform cutting lead screw 75 for the self-returning non-woven fabric is arranged at the output end of a three-stage motor 74 for uniformly cutting the self-returning non-woven fabric, the other end of the friction lossless type uniform cutting lead screw 75 for the self-returning non-woven fabric is arranged on a friction lossless type nine-stage bearing 76, a friction lossless type uniform cutting slide bar 73 for the self-returning non-woven fabric is arranged on the inner wall of a fixed box 77 for uniformly cutting the self-returning non-woven fabric, a friction lossless type uniform cutting slide block 72 for the self-returning non-woven fabric is sleeved on the slide bar 73 for uniformly cutting the self-returning non-woven fabric and the slide screw 75 for uniformly cutting the self-returning non-woven fabric, the friction lossless type uniform cutting slide block 72 for uniformly cutting the self-returning non-woven fabric is connected with the slide screw 75 for meshing rotation, and a uniform cutting piece 71 for cutting the self-returning non-woven fabric is arranged on the friction lossless type uniform cutting slide block 72 for uniformly cutting the self-returning non-woven fabric, the third-stage conveying roller 78 with lossless rotation friction is rotatably arranged on the box 77 for uniformly cutting the self-returning non-woven fabric, and the fourth-stage conveying roller 79 with lossless rotation friction is rotatably arranged on the box 77 for uniformly cutting the self-returning non-woven fabric.

As shown in fig. 1, the ultrasonic moisture self-hammering type drying apparatus 3 comprises an ultrasonic moisture self-hammering type drying base 37, an ultrasonic dryer fixing shaft 38, an ultrasonic moisture self-hammering type drying arch case 39, a rotary friction lossless type primary conveying roller 40, a rotary friction lossless type secondary conveying roller 41 and a moisture self-hammering type ultrasonic dryer 42, the ultrasonic moisture self-hammering type drying base 37 is provided at the lower end of the ultrasonic moisture self-hammering type drying apparatus 3, the ultrasonic moisture self-hammering type drying arch case 39 is provided on the ultrasonic moisture self-hammering type drying base 37, the ultrasonic dryer fixing shaft 38 is provided in the ultrasonic moisture self-hammering type drying arch case 39, the moisture self-hammering type ultrasonic dryer 42 is provided on the ultrasonic dryer fixing shaft 38, the rotary friction lossless type primary conveying roller 40 is rotatably provided at the inlet of the ultrasonic moisture self-hammering type drying arch case 39, the rotary friction nondestructive type second-stage conveying roller 41 is rotatably arranged in the ultrasonic moisture self-hammering drying arch-shaped box 39.

When the device is used, firstly, non-woven fabrics enter an ultrasonic moisture self-hammering type drying device 3 through a rotary friction lossless type first-stage conveying roller 40, pass through an all-directional covering type porous material type dust cleaning device 4, finally reach a magnetic suspension weight compensation type zero friction winding first-stage winding roller 25 of a magnetic suspension weight compensation type zero friction winding device 2, a constant-speed driving type magnetic suspension weight compensation type zero friction winding first-stage motor 30 is started, the output end of the constant-speed driving type magnetic suspension weight compensation type zero friction winding first-stage motor 30 rotates to drive a magnetic suspension weight compensation type zero friction winding second-stage power roller 24 to rotate, the magnetic suspension weight compensation type zero friction winding second-stage power roller 24 rotates to drive a constant-speed driving type magnetic suspension weight compensation type zero friction winding second-stage gear 29 to rotate, the constant-speed driving type magnetic suspension weight compensation type zero friction winding second-stage gear 29 rotates to drive a constant-speed driving type magnetic suspension weight compensation type zero friction winding first-stage chain 31 to rotate, the uniform-speed driving type magnetic suspension weight compensation type zero friction winding primary chain 31 rotates to drive the uniform-speed driving type magnetic suspension weight compensation type zero friction winding primary gear 28 to rotate, the uniform-speed driving type magnetic suspension weight compensation type zero friction winding primary gear 28 rotates to drive the magnetic suspension weight compensation type zero friction winding primary power roller 23 to rotate, the magnetic suspension weight compensation type zero friction winding primary power roller 23 rotates and the magnetic suspension weight compensation type zero friction winding secondary power roller 24 rotates to drive the magnetic suspension weight compensation type zero friction winding primary power roller 25 to rotate, the magnetic suspension weight compensation type zero friction winding primary telescoping device 35 is used for adjusting the height of the uniform-speed driving type magnetic suspension weight compensation type zero friction winding tertiary support frame 80, and the wrinkle-proof type gravity compensation type primary auxiliary roller 26 rotates at the upper end of the magnetic suspension weight compensation type zero friction winding primary power roller 25 to prevent the magnetic suspension weight compensation type zero friction winding primary power roller 25 from generating wrinkles during winding, starting the ultrasonic moisture self-beating type drying device 3 in the rolling process, carrying out ultrasonic drying treatment on the non-woven fabric passing through the rotary friction lossless type secondary conveying roller 41 by the moisture self-beating type ultrasonic dryer 42, enabling the dried non-woven fabric to enter the omnibearing covering type porous material type dust cleaning box 43, carrying out self-adaptive tensioning adjustment on the non-woven fabric by the self-adaptive pulling type primary telescopic conveying device 44, starting the omnibearing covering type porous material type dust cleaning device 4, driving the omnibearing covering type porous material type dust cleaning primary gear 53 to rotate by the output end of the omnibearing covering type porous material type dust cleaning secondary motor 56, driving the omnibearing covering type porous material type dust cleaning primary gear 53 to rotate, driving the omnibearing covering type porous material type dust cleaning secondary gear 54 to rotate, driving the air suction type porous material type dust adsorption primary cleaning roller 45 and the full-beating type porous material type dust cleaning primary roller 45 The azimuth covering type porous material type dust cleaning tertiary gear 55 rotates, the omnibearing covering type porous material type dust cleaning tertiary gear 55 rotates to drive the air suction type porous material type dust adsorption secondary cleaning roller 46 to rotate, the omnibearing covering type porous material type dust cleaning primary air pump 61 is started to suck dust and impurities on non-woven fabrics into the air suction type porous material type dust adsorption primary cleaning roller 45 through the multidirectional attaching type dust primary adsorption hole 47 to enter the F-shaped airflow transmission dust cleaning suction pipe 57, the air suction type porous material type dust adsorption secondary cleaning roller 46 through the multidirectional attaching type dust secondary adsorption hole 48 to enter the F-shaped airflow transmission dust cleaning suction pipe 57 and finally enter the cyclone circulation scattering type electrostatic adsorption dust collecting box 62, the cyclone circulation scattering type centrifugal device 63 is started, the entering dust and impurities are quickly adsorbed on the cyclone circulation scattering type electrostatic adsorption plate 64 through airflow generated by centrifugal force, centralized processing is carried out after the rolling is finished, when the roll needs to be changed, the self-returning non-woven fabric uniform cutting device 5 is started, the output end of the self-returning non-woven fabric uniform cutting three-level motor 74 rotates to drive the friction lossless self-returning non-woven fabric uniform cutting screw 75 to rotate, the friction lossless self-returning non-woven fabric uniform cutting screw 75 rotates to drive the friction lossless self-returning non-woven fabric uniform cutting slider 72 to move, the friction lossless self-returning non-woven fabric uniform cutting slider 72 moves to drive the self-returning non-woven fabric uniform cutting piece 71 to move to cut the non-woven fabric, the magnetic suspension weight compensation type zero friction rolling primary expansion device 35 contracts, the uniform speed driving type magnetic suspension weight compensation type zero friction rolling tertiary support frame 80 descends, the magnetic suspension weight compensation type zero friction rolling secondary expansion device 36 contracts, and the magnetic suspension weight compensation type secondary support frame 34 descends, the zero-friction type magnetic suspension coil changing suspension end beam 15 is in a suspension state under the action of magnetic force, when one end of the zero-friction type magnetic suspension coil changing running track 14 is lowered, the zero-friction type magnetic suspension coil changing suspension end beam 15 moves towards a lower position, the zero-friction type magnetic suspension coil changing suspension end beam 15 moves to drive the magnetic suspension weight compensation type zero-friction winding bracket 16 to move, the magnetic suspension weight compensation type zero-friction winding bracket 16 moves to drive the magnetic suspension weight compensation type zero-friction winding primary winding roller 25 to move, the magnetic suspension weight compensation type zero-friction winding primary winding roller 25 moves to the magnetic suspension weight compensation type secondary support frame 34 to change coils, the magnetic suspension weight compensation type zero-friction winding secondary expansion device 36 is started to extend after coil changing, the magnetic suspension weight compensation type secondary support frame 34 is lifted, a new reel moves to an initial position through the zero-friction type magnetic suspension coil changing suspension end beam 15, the above is the overall working process of the invention, and the steps are repeated when the device is used next time.

It is noted that, herein, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

The present invention and its embodiments have been described above, and the description is not intended to be limiting, and the drawings are only one embodiment of the present invention, and the actual structure is not limited thereto. In summary, those skilled in the art should appreciate that they can readily use the disclosed conception and specific embodiments as a basis for designing or modifying other structures for carrying out the same purposes of the present invention without departing from the spirit and scope of the invention as defined by the appended claims.

Claims (4)

1. The utility model provides an adjustable coiling mechanism is used in non-woven fabrics production which characterized in that: the device comprises a main body, a magnetic suspension weight compensation type zero-friction winding device, an ultrasonic moisture self-beating type drying device, an all-dimensional covering type porous material type dust cleaning device and a self-returning type non-woven fabric uniform cutting device, wherein the all-dimensional covering type porous material type dust cleaning device is arranged in the middle of the main body; the magnetic suspension weight compensation type zero-friction winding device comprises a magnetic suspension weight compensation type first-level electromagnet, a magnetic suspension weight compensation type second-level electromagnet, a magnetic suspension weight compensation type third-level electromagnet, a magnetic suspension weight compensation type fourth-level electromagnet, a reverse weight compensation type zero-friction first-level coil winding, a reverse weight compensation type zero-friction second-level coil winding, a reverse weight compensation type zero-friction third-level coil winding, a reverse weight compensation type zero-friction fourth-level coil winding, a zero-friction type magnetic suspension coil changing running track, a zero-friction type magnetic suspension coil changing suspension end beam, a magnetic suspension weight compensation type zero-friction winding bracket, a sliding friction lossless type magnetic suspension first-level limiting part, a sliding friction lossless type magnetic suspension second-level limiting part, a friction lossless type first-level bearing, a friction lossless type second-level bearing, a friction lossless type third-level bearing, a friction lossless type fourth-level bearing, a magnetic suspension weight compensation type zero-friction first-level winding roller, a magnetic suspension weight compensation type zero-friction type third-level winding roller, a magnetic suspension weight compensation type zero-friction type magnetic suspension roller, a magnetic suspension type zero-friction type magnetic suspension coil winding roller, a magnetic suspension type magnetic suspension device, a magnetic suspension type magnetic suspension device, a magnetic suspension type magnetic suspension device, a magnetic suspension type magnetic suspension device, a magnetic suspension type magnetic suspension device, a magnetic suspension type magnetic suspension device, a magnetic suspension type magnetic, A magnetic suspension weight compensation type zero friction rolling secondary power roller, a magnetic suspension weight compensation type zero friction rolling primary rolling roller, a wrinkle-proof type gravity compensation type primary auxiliary roller, a wrinkle-proof type gravity compensation type primary limiting spring, a uniform speed driving type magnetic suspension weight compensation type zero friction rolling primary gear, a uniform speed driving type magnetic suspension weight compensation type zero friction rolling secondary gear, a uniform speed driving type magnetic suspension weight compensation type zero friction rolling primary motor, a uniform speed driving type magnetic suspension weight compensation type zero friction rolling primary chain, a wrinkle-proof type gravity compensation type primary support frame, a magnetic suspension wrinkle-proof type gravity compensation type primary support frame downward sliding gap, a magnetic suspension weight compensation type secondary support frame, a magnetic suspension weight compensation type zero friction rolling primary expansion device, a magnetic suspension weight compensation type zero friction rolling secondary expansion device and a uniform speed driving type magnetic suspension weight compensation type zero friction rolling tertiary support frame, the fold-prevention gravity compensation type primary support frame is arranged on the magnetic suspension weight compensation type zero-friction winding device, a magnetic suspension fold-prevention gravity compensation type primary support frame gliding clearance is arranged in the fold-prevention gravity compensation type primary support frame, one end of the fold-prevention gravity compensation type primary limit spring is arranged at the upper end of the magnetic suspension fold-prevention gravity compensation type primary support frame gliding clearance, the friction nondestructive four-stage bearing is arranged at the other end of the fold-prevention gravity compensation type primary limit spring, one end of the fold-prevention gravity compensation type primary auxiliary roller is arranged in the friction nondestructive four-stage bearing, the magnetic suspension weight compensation type zero-friction winding primary expansion device is arranged at the lower end of the magnetic suspension weight compensation type zero-friction winding device, and the uniform-speed magnetic suspension weight compensation type zero-friction winding tertiary support frame is arranged on the magnetic suspension weight compensation type zero-friction winding primary expansion device, the uniform-speed driving type magnetic suspension weight compensation type zero friction winding primary motor is arranged on the uniform-speed driving type magnetic suspension weight compensation type zero friction winding tertiary support frame in a rotating mode, the magnetic suspension weight compensation type zero friction winding secondary power roller is arranged on the uniform-speed driving type magnetic suspension weight compensation type zero friction winding tertiary support frame in a rotating mode, the uniform-speed driving type magnetic suspension weight compensation type zero friction winding primary gear is sleeved on a shaft of the magnetic suspension weight compensation type zero friction winding primary power roller, the uniform-speed driving type magnetic suspension weight compensation type zero friction winding secondary gear is sleeved on a shaft of the magnetic suspension weight compensation type zero friction winding secondary power roller, the uniform-speed driving type magnetic suspension weight compensation type zero friction winding primary motor is arranged on the uniform-speed driving type magnetic suspension weight compensation type zero friction winding tertiary support frame, one end of the magnetic suspension weight compensation type zero friction winding secondary power roller is arranged at the uniform-speed driving type magnetic suspension weight compensation type zero friction winding secondary power roller The output end of a rolling primary motor is wiped, a magnetic suspension weight compensation type zero friction rolling secondary expansion device is arranged at one side of a uniform-speed driving type magnetic suspension weight compensation type zero friction rolling tertiary support frame, the magnetic suspension weight compensation type secondary support frame is arranged on the magnetic suspension weight compensation type zero friction rolling secondary expansion device, a friction lossless type primary bearing is arranged on the side wall of the wrinkle-proof type gravity compensation type primary support frame, a friction lossless type secondary bearing is arranged on the side wall of the magnetic suspension weight compensation type secondary support frame, one end of a zero friction type magnetic suspension roll changing operation track is arranged on the friction lossless type primary bearing, the other end of the zero friction type magnetic suspension roll changing operation track is arranged on the friction lossless type secondary bearing, a sliding friction lossless type magnetic suspension primary limiting piece is arranged on the side wall of the wrinkle-proof type gravity compensation type primary support frame, the sliding friction nondestructive magnetic suspension secondary limiting part is arranged on the side wall of the magnetic suspension weight compensation type secondary supporting frame, the zero friction type magnetic suspension coil changing suspension end beam is arranged on the zero friction type magnetic suspension coil changing running track in a suspension way, the magnetic suspension weight compensation type primary electromagnet is arranged on the zero friction type magnetic suspension coil changing suspension end beam, the magnetic suspension weight compensation type four-level electromagnet is arranged on the zero friction type magnetic suspension coil changing suspension end beam, the magnetic suspension weight compensation type secondary electromagnet is arranged on the zero friction type magnetic suspension coil changing suspension end beam, the magnetic suspension weight compensation type three-level electromagnet is arranged on the zero friction type magnetic suspension coil changing suspension end beam, the reverse weight compensation zero friction type one-level coil winding resistance is arranged on the zero friction type magnetic suspension coil changing running track, and the reverse weight compensation zero friction type four-level coil winding resistance is arranged on the zero friction type magnetic suspension coil changing running track, the reverse weight compensation zero friction secondary coil winding is arranged on a zero friction type magnetic suspension coil-changing running track, the reverse weight compensation zero friction tertiary coil winding is arranged on the zero friction type magnetic suspension coil-changing running track, the magnetic suspension weight compensation type primary electromagnet and the reverse weight compensation zero friction primary coil winding are symmetrical, the magnetic suspension weight compensation type secondary electromagnet and the reverse weight compensation zero friction secondary coil winding are symmetrical, the reverse weight compensation zero friction tertiary coil winding and the magnetic suspension weight compensation type tertiary electromagnet are symmetrical, the magnetic suspension weight compensation type four-stage electromagnet and the reverse weight compensation zero friction four-stage coil winding are symmetrical, the magnetic suspension weight compensation type zero friction winding bracket is arranged on a zero friction type magnetic suspension coil-changing suspension end beam, and the friction lossless type three-stage bearing is detachably arranged on the magnetic suspension weight compensation type zero friction winding bracket, the constant-speed driving type magnetic suspension weight compensation type zero-friction winding primary chain is sleeved on the constant-speed driving type magnetic suspension weight compensation type zero-friction winding primary gear, and the other end of the constant-speed driving type magnetic suspension weight compensation type zero-friction winding primary chain is sleeved on the constant-speed driving type magnetic suspension weight compensation type zero-friction winding secondary gear.

2. The adjustable winding device for non-woven fabric production according to claim 1, characterized in that: ultrasonic wave moisture is from beating formula stoving base, ultrasonic wave drier fixed axle, ultrasonic wave moisture from beating formula stoving arch case, the harmless formula one-level transfer roller of rotation friction, the harmless formula second grade transfer roller of rotation friction and the formula ultrasonic wave drier of beating of ultrasonic wave moisture, ultrasonic wave moisture is located ultrasonic wave moisture from beating formula stoving base and is beaten the lower extreme of formula drying device from beating formula stoving base, ultrasonic wave moisture is located ultrasonic wave moisture from beating formula stoving arch case and is dried on the base, ultrasonic wave moisture is located from beating formula stoving arch incasement from beating to the ultrasonic wave drier fixed axle, moisture is located on the ultrasonic wave drier fixed axle from beating formula ultrasonic wave drier, the harmless formula one-level transfer roller of rotation friction is located ultrasonic wave moisture from the entrance of beating formula stoving arch case, the harmless formula second grade transfer roller of rotation friction is located ultrasonic wave moisture from beating formula stoving arch incasement.

3. The adjustable winding device for non-woven fabric production according to claim 2, characterized in that: the all-round covering type porous material dust cleaning device comprises an all-round covering type porous material dust cleaning box, a self-adaptive pull-proof type one-level telescopic conveying device, a suction type porous material dust adsorption one-level cleaning roller, a suction type porous material dust adsorption second-level cleaning roller, a multidirectional attaching type dust one-level adsorption hole, a multidirectional attaching type dust second-level adsorption hole, a friction lossless type five-level bearing, a friction lossless type six-level bearing, a friction lossless type seven-level bearing, a friction lossless type eight-level bearing, an all-round covering type porous material dust cleaning one-level gear, an all-round covering type porous material dust cleaning second-level gear, an all-round covering type porous material dust cleaning third-level gear, an all-round covering type porous material dust cleaning second-level motor, an F-shaped air flow conveying dust cleaning suction pipe, an F-shaped air flow conveying dust cleaning one-level suction port, An F-shaped airflow conveying dust cleaning secondary air suction port, an F-shaped airflow conveying dust cleaning primary air outlet, an all-round covering type porous material type dust cleaning primary air pump, a cyclone circulating scattering type electrostatic adsorption dust collecting box, a cyclone circulating scattering type centrifugal device, a cyclone circulating scattering type electrostatic adsorption plate, a cyclone circulating scattering type filter screen and a cyclone circulating scattering type air hole, wherein the all-round covering type porous material type dust cleaning box is arranged on the all-round covering type porous material type dust cleaning device, the self-adaptive pulling-proof type primary telescopic conveying device is arranged in the all-round covering type porous material type dust cleaning box, the friction lossless type five-stage bearing is arranged on the inner wall of the all-round covering type porous material type dust cleaning box, the friction lossless type six-stage bearing is arranged on the inner wall of the all-round covering type porous material type dust cleaning box, one end of the air suction type porous material type dust adsorption one-level cleaning roller is arranged on a friction lossless type five-level bearing, one end of the air suction type porous material type dust adsorption two-level cleaning roller is arranged on a friction lossless type six-level bearing, multidirectional attaching type dust one-level adsorption holes are formed in the air suction type porous material type dust adsorption one-level cleaning roller, the multidirectional attaching type dust two-level adsorption holes are formed in the air suction type porous material type dust adsorption two-level cleaning roller, the omnibearing covering type porous material type dust cleaning two-level motor is arranged on the inner wall of the omnibearing covering type porous material type dust cleaning box, the omnibearing covering type porous material type dust cleaning one-level gear is arranged at the output end of the omnibearing covering type porous material type dust cleaning two-level motor, and the omnibearing covering type porous material type dust cleaning two-level gear is sleeved on the shaft of the air suction type porous material type dust adsorption one-level cleaning roller, the all-round cover type porous material type dust cleaning three-level gear is sleeved on a shaft of the air suction type porous material type dust adsorption two-level cleaning roller, the friction lossless type seven-level bearing is penetrated and arranged at the other end of the air suction type porous material type dust adsorption one-level cleaning roller, the friction lossless type eight-level bearing is penetrated and arranged at the other end of the air suction type porous material type dust adsorption two-level cleaning roller, the upper end of the F-shaped air flow conveying dust cleaning suction pipe is penetrated and arranged on the friction lossless type seven-level bearing and the F-shaped air flow conveying dust cleaning two-level suction port, the F-shaped air flow conveying dust cleaning one-level suction port is arranged on the F-shaped air flow conveying dust cleaning suction pipe, the F-shaped air flow conveying dust cleaning one-level air outlet is arranged at the lower end of the F-shaped air flow conveying dust cleaning suction pipe, the omnibearing coverage type porous material type dust cleaning primary air pump is arranged on the F-shaped airflow conveying dust cleaning suction pipe, the cyclone circulation scattering type electrostatic adsorption dust collecting box is arranged at the bottom end of the inner wall of the omnibearing coverage type porous material type dust cleaning box, the F-shaped airflow conveying dust cleaning suction pipe is arranged on the cyclone circulation scattering type electrostatic adsorption dust collecting box in a penetrating way, the cyclone circulation scattering type centrifugal device is arranged at the bottom end of the inner wall of the cyclone circulation scattering type electrostatic adsorption dust collecting box, the cyclone circulation scattering type electrostatic adsorption plate is arranged in the cyclone circulation scattering type electrostatic adsorption dust collecting box, the cyclone circulation scattering type filter screen is arranged in the cyclone circulation scattering type electrostatic adsorption dust collecting box, the cyclone circulation scattering type air hole is arranged on the side wall of the cyclone circulation scattering type electrostatic adsorption dust collecting box, the omnibearing coverage type porous material type dust cleaning primary gear and the omnibearing coverage type porous material type dust cleaning secondary air pump are arranged on the side wall of the cyclone circulation scattering type electrostatic adsorption dust collecting box, and the omnibearing coverage type porous material type dust cleaning secondary air pump is arranged on the side wall of the cyclone circulation scattering type electrostatic adsorption dust collecting box, and the cyclone circulation scattering type dust collecting box is arranged on the side wall of the whole area of the cyclone circulation scattering type dust collecting box, and the whole area of the whole area The stage gears are in meshed rotary connection, and the omnibearing covering type porous material type dust cleaning third stage gear and the omnibearing covering type porous material type dust cleaning second stage gear are in meshed rotary connection; the flexible conveyer of type one-level is prevented dragging by self-adaptation includes that the self-adaptation prevents dragging the flexible pipe of type one-level, self-adaptation prevents dragging the flexible pipe of type second grade, self-adaptation prevents dragging type one-level transfer roller and self-adaptation prevents dragging type one-level spring, the self-adaptation prevents dragging the flexible pipe of type one-level and locates on the inner wall of all-round overlay type porous material type dust clean box, the self-adaptation prevents dragging the one end of type one-level spring and locates the self-adaptation and prevent dragging the inner wall bottom that the flexible pipe of type one-level, the self-adaptation prevents dragging the one end that the flexible pipe of type second grade was located the self-adaptation and prevents dragging the other end of type one-level spring, the self-adaptation prevents dragging type one-level transfer roller and rotates and locates the other end that the flexible pipe of type second grade is prevented dragging by self-adaptation.

4. The adjustable winding device for non-woven fabric production according to claim 3, characterized in that: the self-return non-woven fabric uniform cutting device comprises a self-return non-woven fabric uniform cutting piece, a friction lossless self-return non-woven fabric uniform cutting slide block, a friction lossless self-return non-woven fabric uniform cutting slide rod, a self-return non-woven fabric uniform cutting three-stage motor, a friction lossless self-return non-woven fabric uniform cutting lead screw, a friction lossless nine-stage bearing, a self-return non-woven fabric uniform cutting fixed box body, a rotation friction lossless three-stage conveying roller and a rotation friction lossless four-stage conveying roller, wherein the self-return non-woven fabric uniform cutting fixed box body is arranged in an omnibearing covering type porous material dust cleaning box body, the self-return non-woven fabric uniform cutting three-stage motor is arranged on the outer wall of the self-return non-woven fabric uniform cutting fixed box body, and the friction lossless nine-stage bearing is arranged on the inner wall of the self-return non-woven fabric uniform cutting fixed box body, one end of the friction lossless type uniform cutting lead screw for the self-returning non-woven fabric is arranged at the output end of the three-stage motor for uniformly cutting the self-returning non-woven fabric, the other end of the friction lossless type uniform cutting lead screw for the self-returning non-woven fabric is arranged on a friction lossless type nine-stage bearing, the friction lossless type uniform cutting slide bar for the self-returning non-woven fabric is arranged on the inner wall of the uniformly cutting fixed box body for uniformly cutting the self-returning non-woven fabric, the friction lossless type uniform cutting slide block for the self-returning non-woven fabric is sleeved on the friction lossless type uniform cutting slide bar for the self-returning non-woven fabric and the friction lossless type uniform cutting lead screw for the self-returning non-woven fabric, the friction lossless type uniform cutting slide block for the self-returning non-woven fabric is connected with the uniform cutting lead screw for meshing rotation, and the uniform cutting piece for the self-returning non-woven fabric is arranged on the friction lossless type uniform cutting slide block for cutting the self-returning non-woven fabric, the three-level conveying roller with the lossless rotation friction is rotatably arranged on the box body for uniformly cutting the self-returning non-woven fabric, and the four-level conveying roller with the lossless rotation friction is rotatably arranged on the box body for uniformly cutting the self-returning non-woven fabric.

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