CN114436040A

CN114436040A - Double-magnetic-acting-force contact-free type glass fiber yarn winding device for nonmetallic mineral products

Info

Publication number: CN114436040A
Application number: CN202111620920.XA
Authority: CN
Inventors: 何向宁; 陈勇; 赵地杰; 李洪伟; 李彦良; 鹿纯玉
Original assignee: Xuzhou Hesheng Mining Industry Technology Co ltd
Current assignee: Xuzhou Hesheng Mining Industry Technology Co ltd
Priority date: 2021-12-28
Filing date: 2021-12-28
Publication date: 2022-05-06
Anticipated expiration: 2041-12-28
Also published as: CN114436040B

Abstract

The invention discloses a double-magnetic-force contact-free glass fiber yarn winding device for a nonmetallic mineral product, which comprises a bottom plate, a support frame, a multidirectional self-rotating ordering replacement winding mechanism and a contact-free inrush current portable adsorption cleaning mechanism, wherein the support frame is symmetrically arranged at two ends of the upper wall of the bottom plate, the frame is arranged on the upper wall of the support frame, the multidirectional self-rotating ordering replacement winding mechanism is arranged at one end of the frame, and the contact-free inrush current portable adsorption cleaning mechanism is arranged at one end, far away from the multidirectional self-rotating ordering replacement winding mechanism, of the frame. The invention belongs to the technical field of glass fiber yarns, and particularly relates to a double-magnetic-acting-force contact-free type glass fiber yarn winding device for a nonmetallic mineral product; the invention provides a double-magnetic-force contact-free type glass fiber yarn winding device for a nonmetal mineral product, which can realize contact-free cleaning of dust under the action of double magnets and can automatically replace a wound winding drum.

Description

Double-magnetic-acting-force contact-free glass fiber yarn winding device for nonmetal mineral products

Technical Field

The invention belongs to the technical field of glass fiber yarns, and particularly relates to a double-magnetic-force contact-free type glass fiber yarn winding device for a nonmetallic mineral product.

Background

The glass fiber yarn is an inorganic non-metallic material with excellent performance, has various types, has the advantages of good insulativity, strong heat resistance, good corrosion resistance and high mechanical strength, but has the defects of brittle performance and poor wear resistance.

The fine yarn coiling mechanism of present glass has following several problems:

1. the conventional glass fiber yarn winding device simply winds glass fiber yarns on the premise of not pre-treating the glass fiber yarns, so that the glass fiber yarns are cracked during winding;

2. traditional winding drum takes the back down with the winding drum after the rolling is accomplished, goes on laying new winding drum, wastes time and energy like this, very big reduction the rolling efficiency of fine yarn of glass, can not carry out the rolling when changing the winding drum.

Disclosure of Invention

Aiming at the situation and overcoming the defects of the prior art, the scheme provides a double-magnetic-acting-force contact-free type glass fiber yarn winding device for a nonmetal mineral product, aiming at the problem of glass fiber yarn pretreatment, creatively combines an intermediary principle (using the intermediary to realize the required action), a shock wave vibration structure and a multipurpose principle (enabling an object to have a composite function to replace the function of other objects) and applies the glass fiber yarn to the technical field of glass fiber yarn, through the arranged contact-free type surge flow portable adsorption cleaning mechanism, the pretreatment of the glass fiber yarn is realized under the mutual matching of the fluctuation impact mechanism, the surge flow generation mechanism and the ascending air flow filtering mechanism, the cleaning of the surface adsorption dust of the glass fiber yarn and the expansion treatment of the winding tension of the glass fiber yarn are effectively realized, the problem that the prior art is difficult to solve that the glass fiber yarn is contacted to clean (the surface yarn is cleaned through a cleaning brush or a cleaning cloth is solved, the most direct and effective mode) and the cleaning without contacting the glass fiber yarn (the glass fiber yarn has poor wear resistance and is easy to damage the glass fiber yarn when being cleaned by friction).

Meanwhile, the single winding mode of transmission is driven by adopting a rotary replacement mode, so that the glass fiber yarn can be continuously wound while the winding drum is replaced after the winding drum is replaced, and the problem that the traditional glass fiber yarn winding device adopts a single winding drum for winding is solved under the arrangement of a multidirectional self-rotary ordered replacement winding mechanism.

The utility model provides a two magnetism effort contactless type nonmetal mineral products glass fiber yarn coiling mechanism that realizes exempting from contact clearance to the dust under two magnetic actions, and can carry out automatic change to the winding drum after the rolling.

The technical scheme adopted by the scheme is as follows: the proposal provides a double-magnetic acting force non-contact glass fiber yarn winding device for nonmetallic mineral products, which comprises a bottom plate, a supporting frame, a multidirectional self-rotating ordered replacement winding mechanism and a non-contact type inrush current portable adsorption cleaning mechanism, the supporting frames are symmetrically arranged at two ends of the upper wall of the bottom plate, the frame is arranged on the upper wall of the supporting frames, the multidirectional self-rotating ordered replacing and winding mechanism is arranged at one end of the frame, the non-contact type inrush current portable adsorption cleaning mechanism is arranged at one end of the frame far away from the multidirectional self-rotating ordered replacement winding mechanism, the multidirectional self-rotating ordered replacing winding mechanism comprises a steering adjusting mechanism, an adaptive dismounting mechanism and a rotating winding mechanism, the frame lateral wall is located to the adjustment mechanism that turns to, adaptation disassembly body locates the frame and is close to the one end that turns to adjustment mechanism, rotatory winding mechanism locates to turn to adjustment mechanism and keeps away from the one end that adaptation disassembly body constructs.

As a further preferred option in the scheme of the present application, the steering adjustment mechanism includes a rotating electrical machine, a rotating shaft and dividing plates, the rotating electrical machine is disposed on the side wall of the frame, the rotating shaft is rotatably disposed between the inner walls of the frame, the rotating shaft penetrates through the frame and is disposed at the power end of the rotating electrical machine, and the dividing plates are symmetrically disposed at two ends of the rotating shaft; the adaptive disassembling mechanism comprises a threaded hole, a bolt, a spring and a rotating block, the threaded hole array is arranged on the side wall of the dividing plate at one end of the rotating shaft close to the rotating motor, the spring is arranged on one side of the dividing plate far away from the rotating motor, the spring is arranged on the side wall of the dividing plate outside the threaded hole, the bolt penetrates through the spring and is arranged in the threaded hole, the bolt is in threaded connection with the threaded hole, the rotating block is arranged on one side of the spring far away from the dividing plate, and one side of the bolt far away from the dividing plate is rotatably arranged on the side wall of the rotating block; the rotary winding mechanism comprises a groove, a power magnet, a driving shaft, a three-phase coil, a roller and a limiting plate, the driving shaft array is arranged on the side wall of the dividing plate at one end of the rotating shaft far away from the rotating motor, the driving shaft is rotationally arranged on the side wall of the dividing plate and is opposite to the spring, the three-phase coil is arranged at one end of the driving shaft far away from the dividing plate, the roller wheel is arranged at one side of the driving shaft close to the three-phase coil, the roller is arranged between the roller and the rotating block, the inner wall of the roller is respectively attached to the side walls of the roller and the rotating block, the limiting plates are respectively arranged at one end of the rotating block close to the roller and one end of the driving shaft close to the roller, two sides of the roller are attached to the limiting plates, the grooves are formed in the inner wall of one end, close to the driving shaft, of the roller in multiple groups, the grooves are cavities with one open ends, the power magnets are arranged in the grooves, and the power magnets are arranged on the outer sides of the three-phase coils; under the initial condition, the roller is kept away from to turning block and running roller, when rolling the fine yarn of glass, lay the roller between the division board, twist the bolt, the bolt rotates along the screw hole and drives the turning block to the one side removal that is close to the division board, this moment, the spring takes place elastic deformation under the effect of external force and drives the turning block and remove, the roller inserts on the drive shaft, running roller lateral wall and roller inner wall laminating, rotate the bolt, the bolt drives the turning block along the screw hole and is close to the roller, spring reset drives the turning block and inserts the roller inner wall, the energization of three-phase coil, the roller revolutes turning block and running roller rotation rolling under the effect of magnetic field power magnet and three-phase coil between.

Preferably, the non-contact type surge portable adsorption cleaning mechanism comprises a surge impact mechanism, a surge generation mechanism and an ascending air flow filtering mechanism, the surge impact mechanism is arranged at one end of the frame far away from the rotating motor, the surge generation mechanism is arranged on the inner wall of the frame between the roller and the surge impact mechanism, the ascending air flow filtering mechanism is arranged on the upper wall of the frame above the surge generation mechanism, the surge impact mechanism comprises a power box, a pulse generator, an electrostatic eliminator, a power pipe, an annular shunt pipe, an impact pipe and a winding groove, the power box is arranged on the upper wall of the bottom plate, the pulse generator is arranged on the side wall of the power box, the power end of the pulse generator is arranged on the inner wall of the power box in a penetrating way, the electrostatic eliminator is arranged on the side wall of the power box, the power end of the electrostatic eliminator is arranged on the inner wall of the power box in a penetrating way, the power pipe is symmetrically arranged on one side of the power box far away from the rotating motor, the power tube is communicated with the power box, the winding groove is formed in one side, away from the rotating motor, of the frame, the winding groove is arranged in a through mode, the annular shunt tubes are arranged at one end, close to the winding groove, of the frame in a penetrating mode, the multiple groups of impact tubes penetrate through the frame and are arranged between the winding groove and the annular shunt tubes in a communicating mode, and one ends, away from the power box, of the power tubes penetrate through the frame and are arranged on the side walls of the annular shunt tubes; the inrush current generating mechanism comprises a hot gas box, heating iron bars and heating coils, wherein the hot gas box is arranged on the inner wall of the frame, the hot gas box is a cavity with an opening at the upper end, a plurality of groups of the heating iron bars are arranged between the hot gas boxes, and the heating coils are arranged between the hot gas boxes on the outer side of the heating iron bars; the ascending air current filtering mechanism comprises a vent cover, a support column, filtering iron rods, filtering coils and air vents, wherein the support column is symmetrically arranged at two ends of the upper wall of the frame; the static eliminator produces neutralizing ions to the inside of the power box through the power end, the pulse generator emits pulse waves to the inside of the power box through the power end, the neutralizing ions are driven by impact to enter the annular shunt pipe through the power pipe, the annular shunt pipe shunts the impact waves and the neutralizing ions, the neutralizing ions carried by the impact waves are ejected through the impact pipe, the impact waves ejected by the impact pipe vibrate the glass fiber yarns adsorbed on the surfaces of the glass fiber yarns under the action of the neutralizing ions, so that dust adsorbed on the surfaces of the glass fiber yarns is loosened, the heating coil is electrified to heat the heating iron rod, the ambient air temperature is raised after the heating iron rod is heated, the gas is raised after the temperature is raised to carry out heat treatment on the glass fiber yarns, the hot gas is continuously raised, the dust adsorbed on the surfaces of the glass fiber yarns is carried to the inside the ventilation hood under the action force of the flowing of the gas, and a magnetic field is generated between the electrifying of the filtering iron rod and the filtering coil, under the magnetic force of the magnetic field, dust contained in the ascending air flow is adsorbed, and the purified air flow flows out of the ventilation cover through the ventilation opening.

Specifically, the frame side wall is provided with a controller.

The controller is electrically connected with the rotating motor, the power magnet, the pulse generator, the static eliminator, the heating coil and the filtering iron rod respectively.

The beneficial effect who adopts above-mentioned structure this scheme to gain is as follows: the utility model provides a pair of this scheme provides under two magnetic action, realizes exempting from the fine yarn coiling mechanism of contact type nonmetal mineral products glass of two magnetic force of contact clearance to the dust beneficial effect as follows:

compared with the prior art, the existing glass fiber yarn winding device simply winds glass fiber yarn on the premise that the glass fiber yarn is not pretreated, according to the scheme, according to the characteristics of brittleness and poor wear resistance of the glass fiber yarn, the tension of the glass fiber yarn is improved in advance in a heating mode, cracks of the glass fiber yarn are effectively avoided when the glass fiber yarn is wound, dust adsorbed on the surface of the glass fiber yarn is vibrated and loosened under the intervention of shock waves, so that the hot air drives the loosened dust on the surface of the glass fiber yarn to rise through rising hot air while heating the glass fiber yarn, the purpose of cleaning the glass fiber yarn is achieved, and under the interference of an ascending air flow filtering mechanism, the dust contained in the rising hot air is filtered, so that the hot air is discharged in an environment-friendly mode;

2. traditional rolling section of thick bamboo takes off the back at the rolling completion back, go on laying new receipts reel, waste time and energy like this, very big reduction the rolling efficiency of glass fiber yarn, and this scheme replaces the winding mechanism through the multidirectional rotation type ordering that sets up, realize the multiunit setting of receipts reel, accomplish the self steering rolling to receiving the reel through the mode that turns to and autogyration, can change the receipts reel simultaneously on one side, roll up glass fiber yarn on one side, two do not delay, abundant use rolling equipment, improve the rolling efficiency and the rolling speed of glass fiber yarn.

Drawings

FIG. 1 is a schematic view of the overall structure of a dual-magnetic-force contact-free glass fiber yarn winding device for a nonmetallic mineral product according to the present invention;

FIG. 2 is a perspective view of a dual magnetic force contact-free type glass fiber yarn winding device for nonmetallic mineral products according to the present invention;

FIG. 3 is an exploded view of a dual magnetic force contact-free glass fiber yarn winding device for a nonmetallic mineral product according to the present invention;

FIG. 4 is a top view of a dual magnetic force contact-free type glass fiber yarn winding device for a nonmetallic mineral product according to the scheme;

FIG. 5 is a sectional view taken along section A-A of FIG. 4;

FIG. 6 is a sectional view of portion B-B of FIG. 4;

FIG. 7 is a partial cross-sectional view of C-C of FIG. 4;

fig. 8 is a schematic structural view of a rotary winding mechanism of a double-magnetic-acting-force contact-free type glass fiber yarn winding device for a nonmetallic mineral product according to the scheme;

FIG. 9 is a schematic structural view of a steering adjustment mechanism of a dual-magnetic-force contact-free type glass fiber yarn winding device for nonmetallic mineral products according to the present disclosure;

fig. 10 is a circuit diagram of a controller of a dual-magnetic-force contact-free type glass fiber yarn winding device for nonmetallic mineral products according to the scheme;

FIG. 11 is a circuit diagram of a rotating motor of a dual-magnetic-acting non-contact glass fiber yarn winding device for non-metallic mineral products according to the present disclosure;

FIG. 12 is a circuit diagram of a power magnet of a glass fiber yarn winding device for a double-magnetic-force contact-free type non-metallic mineral product according to the scheme;

fig. 13 is a schematic block diagram of a double-magnetic-force contact-free glass fiber yarn winding device for a nonmetallic mineral product according to the scheme.

The device comprises a base plate 1, a bottom plate 2, a support frame 3, a frame 4, a multidirectional self-rotation type ordered replacement winding mechanism 5, a steering adjusting mechanism 6, a rotating motor 7, a rotating shaft 8, a dividing plate 9, an adaptive dismounting mechanism 10, a threaded hole 11, a bolt 12, a spring 13, a rotating block 14, a rotary winding mechanism 15, a groove 16, a power magnet 17, a driving shaft 18, a three-phase coil 19, a roller 20, a contact-free inrush current carrying type adsorption cleaning mechanism 21, a fluctuation impact mechanism 22, a power box 23, a pulse generator 24, an electrostatic eliminator 25, a power pipe 26, a ring-shaped shunt pipe 27, an impact pipe 28, a winding groove 29, an inrush current generating mechanism 30, a hot gas box 31, a heating iron rod 32, a heating coil 33, an updraft filtering mechanism 34, a ventilation hood 35, a ventilation hood, a frame, a, Support column, 36, filter iron bar, 37, filter coil, 38, vent, 39, controller, 40, roller, 41, limiting plate.

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

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments; all other embodiments obtained by a person of ordinary skill in the art based on the embodiments in the present disclosure without any creative effort belong to the protection scope of the present disclosure.

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

As shown in fig. 1-3, the present invention provides a dual-magnetic-acting-force contact-free type glass fiber yarn winding device for nonmetallic mineral products, which comprises a bottom plate 1, a supporting frame 2, a frame 3, a multidirectional self-rotating ordered winding mechanism 4 and a contact-free inrush current portable adsorption cleaning mechanism 20, wherein the supporting frame 2 is symmetrically arranged at two ends of the upper wall of the bottom plate 1, the frame 3 is arranged on the upper wall of the supporting frame 2, the multidirectional self-rotating ordered winding mechanism 4 is arranged at one end of the frame 3, the contact-free inrush current portable adsorption cleaning mechanism 20 is arranged at one end of the frame 3 far away from the multidirectional self-rotating ordered winding mechanism 4, the multidirectional self-rotating ordered winding mechanism 4 comprises a steering adjusting mechanism 5, an adaptive dismounting mechanism 9 and a rotary winding mechanism 14, the steering adjusting mechanism 5 is arranged on the side wall of the frame 3, the adaptive dismounting mechanism 9 is arranged at one end of the frame 3 close to the steering adjusting mechanism 5, the rotary winding mechanism 14 is arranged at one end of the steering adjusting mechanism 5 far away from the adaptive dismounting mechanism 9.

As shown in fig. 2, 3, 7 and 8, the steering adjustment mechanism 5 includes a rotating electrical machine 6, a rotating shaft 7 and an index plate 8, the rotating electrical machine 6 is disposed on the side wall of the frame 3, the rotating shaft 7 is rotatably disposed between the inner walls of the frame 3, the rotating shaft 7 penetrates through the frame 3 and is disposed at the power end of the rotating electrical machine 6, and the index plate 8 is symmetrically disposed at two ends of the rotating shaft 7; the adaptive dismounting mechanism 9 comprises a threaded hole 10, a bolt 11, a spring 12 and a rotating block 13, the threaded hole 10 is arranged on the side wall of the dividing plate 8 at one end of the rotating shaft 7 close to the rotating motor 6 in an array mode, the spring 12 is arranged on one side, away from the rotating motor 6, of the dividing plate 8, the spring 12 is arranged on the side wall of the dividing plate 8 on the outer side of the threaded hole 10, the bolt 11 penetrates through the spring 12 and is arranged in the threaded hole 10, the bolt 11 is in threaded connection with the threaded hole 10, the rotating block 13 is arranged on one side, away from the dividing plate 8, of the spring 12, and one side, away from the dividing plate 8, of the bolt 11 is rotatably arranged on the side wall of the rotating block 13; the rotary winding mechanism 14 comprises grooves 15, a power magnet 16, a driving shaft 17, a three-phase coil 18, rollers 19, rollers 40 and limit plates 41, the driving shaft 17 is arranged on the side wall of the dividing plate 8 at one end of the rotating shaft 7 far away from the rotating motor 6 in an array manner, the driving shaft 17 is rotatably arranged on the side wall of the dividing plate 8, the driving shaft 17 is arranged opposite to the spring 12, the three-phase coil 18 is arranged at one end of the driving shaft 17 far away from the dividing plate 8, the rollers 19 are arranged on one side of the driving shaft 17 close to the three-phase coil 18, the rollers 40 are arranged between the rollers 19 and the rotating blocks 13, the inner walls of the rollers 40 are respectively attached to the rollers 19 and the side walls of the rotating blocks 13, the limit plates 41 are respectively arranged at one end of the rotating blocks 13 close to the rollers 40 and one end of the driving shaft 17 close to the rollers 40, two sides of the rollers 40 are attached to the limit plates 41, a plurality of the grooves 15 are arranged on the inner wall of one end of the rollers 40 close to the driving shaft 17, and the grooves 15 are cavities with one open ends, the power magnet 16 is arranged in the groove 15, and the power magnet 16 is arranged outside the three-phase coil 18; in an initial state, the rotating block 13 and the roller 19 are far away from the roller 40, when the glass fiber yarn is rolled, the roller 40 is placed between the dividing plates 8, the bolt 11 is screwed, the bolt 11 rotates along the threaded hole 10 to drive the rotating block 13 to move towards one side close to the dividing plates 8, at the moment, the spring 12 generates elastic deformation under the action of external force to drive the rotating block 13 to move, the roller 40 is inserted into the driving shaft 17, the side wall of the roller 19 is attached to the inner wall of the roller 40, the bolt 11 is rotated, the bolt 11 drives the rotating block 13 to approach the roller 40 along the threaded hole 10, the spring 12 resets to drive the rotating block 13 to be inserted into the inner wall of the roller 40, the three-phase coil 18 is electrified, and the roller 40 rotates around the rotating block 13 and the roller 19 under the action of magnetic field force between the power magnet 16 and the three-phase coil 18 to roll.

As shown in fig. 1-6, the non-contact type surge portable adsorption cleaning mechanism 20 comprises a surge impact mechanism 21, a surge generating mechanism 29 and an ascending air flow filtering mechanism 33, the surge impact mechanism 21 is arranged at one end of the frame 3 far away from the rotating motor 6, the surge generating mechanism 29 is arranged at the inner wall of the frame 3 between the roller 40 and the surge impact mechanism 21, the ascending air flow filtering mechanism 33 is arranged at the upper wall of the frame 3 above the surge generating mechanism 29, the surge impact mechanism 21 comprises a power box 22, a pulse generator 23, an electrostatic eliminator 24, a power pipe 25, an annular shunt pipe 26, an impact pipe 27 and a winding groove 28, the power box 22 is arranged at the upper wall of the bottom plate 1, the pulse generator 23 is arranged at the side wall of the power box 22, the power end of the pulse generator 23 is arranged at the inner wall of the power box 22 in a penetrating manner, the electrostatic eliminator 24 is arranged at the side wall of the power box 22, the power end of the electrostatic eliminator 24 is arranged at the inner wall of the power box 22 in a penetrating manner, the power tubes 25 are symmetrically arranged on one side of the power box 22 far away from the rotating motor 6, the power tubes 25 are communicated with the power box 22, the winding groove 28 is arranged on one side of the frame 3 far away from the rotating motor 6, the winding groove 28 is arranged in a through manner, the annular shunt tubes 26 are arranged at one end of the frame 3 close to the winding groove 28 in a penetrating manner, a plurality of groups of impact tubes 27 are arranged between the winding groove 28 and the annular shunt tubes 26 in a penetrating manner, and one ends of the power tubes 25 far away from the power box 22 are arranged on the side walls of the annular shunt tubes 26 in a penetrating manner through the frame 3; the inrush current generation mechanism 29 comprises a hot air box 30, heating iron rods 31 and a heating coil 32, wherein the hot air box 30 is arranged on the inner wall of the frame 3, the hot air box 30 is a cavity with an opening at the upper end, a plurality of groups of the heating iron rods 31 are arranged between the hot air boxes 30, and the heating coil 32 is arranged between the hot air boxes 30 outside the heating iron rods 31; the ascending air current filtering mechanism 33 comprises a ventilation cover 34, a support pillar 35, a filtering iron bar 36, a filtering coil 37 and air vents 38, wherein the support pillar 35 is symmetrically arranged at two ends of the upper wall of the frame 3, the ventilation cover 34 is arranged at one side of the support pillar 35 far away from the frame 3, the ventilation cover 34 is a cavity with an opening at the lower end, the filtering iron bar 36 is symmetrically arranged on the inner wall of the ventilation cover 34, the filtering coil 37 is arranged on the inner wall of the ventilation cover 34 at the outer side of the filtering iron bar 36, and a plurality of groups of the air vents 38 are arranged on the upper wall of the ventilation cover 34; the static eliminator 24 produces neutralizing ions to the power box 22 through a power end, the pulse generator 23 emits pulse waves to the power box 22 through the power end, neutralizing ions are driven by impact to enter the annular shunt pipe 26 through the power pipe 25, the annular shunt pipe 26 shunts the impact waves and the neutralizing ions, the impact waves carry the neutralizing ions to be ejected out through the impact pipe 27, the impact waves ejected from the impact pipe 27 enable the neutralizing ions to be adsorbed on the surface of the glass fiber yarn to vibrate under the action of the neutralizing ions, so that dust adsorbed on the surface of the glass fiber yarn is loosened, the heating coil 32 is electrified to heat the heating iron rod 31, the temperature of the surrounding air is raised after the heating iron rod 31 is heated, the air is raised after the temperature is raised to carry out heat treatment on the glass fiber yarn, hot air is continuously raised, the dust adsorbed on the surface of the glass fiber yarn is carried to the inside the ventilation hood 34 under the action force of air flowing, a magnetic field is generated between the filtering iron rod 36 and the filtering coil 37, the dust contained in the ascending air flow is adsorbed by the magnetic force of the magnetic field, and the purified air flow flows out of the inside of the ventilation hood 34 through the ventilation port 38.

As shown in fig. 3, the side wall of the frame 3 is provided with a controller 39.

As shown in fig. 10 to 13, the controller 39 is electrically connected to the rotating electric machine 6, the power magnet 16, the pulse generator 23, the static eliminator 24, the heating coil 32, and the filter iron 36, respectively.

In particular, in the initial state, the turning block 13 and the roller 19 are away from the roller 40.

In the first embodiment, the roller 40 is fixed, and the glass fiber yarn is wound and placed.

Specifically, the roller 40 is placed between the dividing plates 8, the bolt 11 is screwed, the bolt 11 rotates along the threaded hole 10 to drive the rotating block 13 to move towards one side close to the dividing plates 8, at the moment, the spring 12 elastically deforms under the action of external force to drive the rotating block 13 to move, the roller 40 is inserted into the driving shaft 17, the side wall of the roller 19 is attached to the inner wall of the roller 40, the bolt 11 is rotated, the bolt 11 drives the rotating block 13 to approach the roller 40 along the threaded hole 10, the spring 12 resets to drive the rotating block 13 to be inserted into the inner wall of the roller 40, at the moment, two sides of the roller 40 are attached to the limiting plate 41, the glass fiber yarns sequentially pass through the coiling groove 28, the hot air box 30 and the vent hood 34 to be placed on the roller 40, the controller 39 controls the three-phase coil 18 to be electrified, after the three-phase coil 18 is electrified, the roller 40 rotates around the rotating block 13 and the roller 19 under the action of magnetic field force between the power magnet 16 and the three-phase coil 18, the drum 40 rotates to wind the glass fiber yarn.

In the second embodiment, the glass yarn is heated and vibrated in advance based on the above embodiment.

Specifically, the controller 39 controls the static eliminator 24 to start, the static eliminator 24 produces neutralizing ions into the power box 22 through the power end, the controller 39 controls the pulse generator 23 to start, the pulse generator 23 emits pulse waves into the power box 22 through the power end, the neutralizing ions are driven by impact to enter the annular shunt tube 26 through the power tube 25, the annular shunt tube 26 shunts the impact waves and the neutralizing ions, the neutralizing ions carried by the impact waves are ejected out through the impact tube 27, the impact waves ejected from the impact tube 27 vibrate the glass fiber yarns under the action of the neutralizing ions, dust adsorbed on the surface of the glass fiber yarns is loosened, the controller 39 controls the heating coil 32 to start, the heating coil 32 is electrified to heat the heating iron rod 31, the ambient air temperature is raised after the heating iron rod 31 is heated, the air is raised after the temperature is raised to perform heat treatment on the glass fiber yarns, the hot air continues to rise, the dust adsorbed on the surface of the glass fiber yarn is carried to the inside of the ventilation hood 34 under the action of the flowing air, the controller 39 controls the filter iron rod 36 to be started, a magnetic field is generated between the filter iron rod 36 and the filter coil 37, the dust contained in the rising air flow is adsorbed under the magnetic force action of the magnetic field, and the purified air flow flows out of the inside of the ventilation hood 34 through the air vent 38.

Third embodiment, based on the above embodiment, the rolled roller 40 is replaced, the controller 39 controls the rotating motor 6 to start, the rotating motor 6 drives the rotating shaft 7 to rotate through the power end, the rotating shaft 7 drives the dividing plate 8 to rotate, the dividing plate 8 drives the roller 40 to rotate through the rotating block 13 and the roller 19, the rolled roller 40 rotates to one side, a new roller 40 rotates to one side close to the hot air box 30 and the vent cover 34, the rolled roller 40 is taken down, the bolt 11 is rotated, the bolt 11 drives the rotating block 13 to move to one side far away from the roller 40, the spring 12 is deformed to shorten and drive the rotating block 13 to be far away from the roller 40, the rolled roller 40 is pulled down from the roller 19, the new roller 40 is inserted into the roller 19 at the same time, the bolt 11 is rotated, the bolt 11 rotates along the threaded hole 10 to drive the rotating block 13 to be inserted into the roller 40, at the moment, the spring 12 is reset and extended to drive the rotating block 13 to approach the roller 40, so that the roller 40 is replaced; repeating the above operations when using the product for the 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 solution 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 solution, the scope of which is defined in the appended claims and their equivalents.

The present solution and its embodiments have been described above, but the description is not limited thereto, and what is shown in the drawings is only one of the embodiments of the present solution, and the actual structure is not limited thereto. In summary, those skilled in the art should be able to devise similar structural modes and embodiments without inventing any departure from the spirit and scope of the present disclosure.

Claims

1. The utility model provides a fine yarn coiling mechanism of contact type nonmetal mineral products glass is exempted from to two magnetic force, includes bottom plate (1), support frame (2) and frame (3), its characterized in that: the automatic cleaning device is characterized by further comprising a multidirectional self-rotating ordered replacing winding mechanism (4) and a contact-free type gushing flow portable adsorption cleaning mechanism (20), wherein the support frame (2) is symmetrically arranged at two ends of the upper wall of the base plate (1), the frame (3) is arranged on the upper wall of the support frame (2), the multidirectional self-rotating ordered replacing winding mechanism (4) is arranged at one end of the frame (3), the contact-free type gushing flow portable adsorption cleaning mechanism (20) is arranged at one end, away from the multidirectional self-rotating ordered replacing winding mechanism (4), of the frame (3), the multidirectional self-rotating ordered replacing winding mechanism (4) comprises a steering adjusting mechanism (5), an adaptive dismounting mechanism (9) and a rotating mechanism (14), the steering adjusting mechanism (5) is arranged on the side wall of the frame (3), the adaptive dismounting mechanism (9) is arranged at one end, close to the steering adjusting mechanism (5), of the frame (3), the rotary winding mechanism (14) is arranged at one end, far away from the adaptive dismounting mechanism (9), of the steering adjusting mechanism (5).

2. The glass fiber yarn winding device for the double-magnetic-force contact-free nonmetal mineral product according to claim 1, characterized in that: turn to adjustment mechanism (5) and include rotating electrical machines (6), rotation axis (7) and graduated plate (8), frame (3) lateral wall is located in rotating electrical machines (6), rotation axis (7) are rotated and are located between frame (3) inner wall, rotation axis (7) run through frame (3) and locate rotating electrical machines (6) power end, rotation axis (7) both ends are located to graduated plate (8) symmetry.

3. The glass fiber yarn winding device for the double-magnetic-force contact-free nonmetal mineral product according to claim 2, characterized in that: adapt to disassembly body (9) including screw hole (10), bolt (11), spring (12) and turning block (13), rotation axis (7) are located to screw hole (10) array and are close to graduated plate (8) lateral wall of rotating electrical machines (6) one end, one side that rotating electrical machines (6) were kept away from in graduated plate (8) is located in spring (12), graduated plate (8) lateral wall in screw hole (10) outside is located in spring (12), in bolt (11) run through spring (12) are located screw hole (10), bolt (11) and screw hole (10) threaded connection, turning block (13) are located one side that graduated plate (8) were kept away from in spring (12), one side that indexing plate (8) were kept away from in bolt (11) is rotated and is located turning block (13) lateral wall.

4. The glass fiber yarn winding device for the double-magnetic-force contact-free nonmetal mineral product according to claim 3, characterized in that: the rotary winding mechanism (14) comprises a groove (15), a power magnet (16), a driving shaft (17), a three-phase coil (18), a roller (19), a roller (40) and a limiting plate (41).

5. The glass fiber yarn winding device for the double-magnetic-force contact-free type nonmetallic mineral product according to claim 4, characterized in that: the dividing plate (8) lateral wall of rotating electrical machines (6) one end is kept away from in drive shaft (17) array, and drive shaft (17) rotate and locate dividing plate (8) lateral wall, and drive shaft (17) set up with spring (12) relatively, the one end that dividing plate (8) were kept away from in drive shaft (17) is located in three-phase coil (18), one side that drive shaft (17) are close to three-phase coil (18) is located in running roller (19), between running roller (19) and turning block (13) is located in roller (40), roller (40) inner wall laminate with running roller (19) and turning block (13) lateral wall respectively, limiting plate (41) locate the one end that turning block (13) are close to roller (40) and drive shaft (17) are close to the one end of roller (40) respectively, roller (40) both sides and limiting plate (41) laminating setting, the one end inner wall that roller (40) are close to drive shaft (17) is located to recess (15) multiunit, the groove (15) is a cavity with an opening at one end, the power magnet (16) is arranged in the groove (15), and the power magnet (16) is arranged on the outer side of the three-phase coil (18).

6. The glass fiber yarn winding device for the double-magnetic-force contact-free nonmetal mineral product according to claim 5, characterized in that: exempt from contact type surge portable type and adsorb clearance mechanism (20) and include undulant impact mechanism (21), surge and take place mechanism (29) and updraft filter mechanism (33), the one end of rotating electrical machines (6) is kept away from in frame (3) is located in undulant impact mechanism (21), surge and take place mechanism (29) and locate frame (3) inner wall between roller (40) and undulant impact mechanism (21), updraft filter mechanism (33) are located and are shoved frame (3) upper wall of taking place mechanism (29) top.

7. The glass fiber yarn winding device for the double-magnetic-force contact-free nonmetal mineral product according to claim 6, characterized in that: the fluctuation impact mechanism (21) comprises a power box (22), a pulse generator (23), a static eliminator (24), a power pipe (25), an annular shunt pipe (26), an impact pipe (27) and a winding groove (28).

8. The glass fiber yarn winding device for the double-magnetic-force contact-free nonmetal mineral product according to claim 7, characterized in that: the utility model discloses a take-up device, including power box (22), headstock (1), pulse generator (23), headstock (22) lateral wall, pulse generator (23) power end runs through and locates headstock (22) inner wall, headstock (22) lateral wall is located in static eliminator (24), and headstock (22) inner wall is located in static eliminator (24) power end, and the one side of rotating electrical machines (6) is kept away from in headstock (22) is located to power tube (25) symmetry, and headstock (22) is located in power tube (25) intercommunication, take-up groove (28) locate frame (3) one side of keeping away from rotating electrical machines (6), take-up groove (28) for having a perfect understanding the setting, annular shunt tubes (26) run through and locate frame (3) and be close to the one end of taking-up groove (28), impact tube (27) multiunit runs through frame (3) intercommunication and locates between taking-up groove (28) and annular shunt tubes (26), one end of the power pipe (25) far away from the power box (22) penetrates through the frame (3) and is communicated with the side wall of the annular shunt pipe (26).

9. The glass fiber yarn winding device for the double-magnetic-force contact-free type nonmetallic mineral product according to claim 8, characterized in that: inrush current generating mechanism (29) includes hot-air box (30), heating iron rod (31) and heating coil (32), frame (3) inner wall is located in hot-air box (30), hot-air box (30) are upper end open-ended cavity, heating iron rod (31) multiunit is located between hot-air box (30), heating coil (32) are located between hot-air box (30) in heating iron rod (31) outside.

10. The glass fiber yarn winding device for the double-magnetic-force contact-free type nonmetallic mineral product according to claim 9, characterized in that: updraft filter mechanism (33) are including ventilating cover (34), support column (35), filter iron bar (36), filter coil (37) and blow vent (38), frame (3) upper wall both ends are located to support column (35) symmetry, ventilate cover (34) and locate one side that support column (35) kept away from frame (3), ventilate cover (34) and be lower extreme open-ended cavity, ventilate cover (34) inner wall is located to filter iron bar (36) symmetry, ventilate cover (34) inner wall in the filter iron bar (36) outside is located in filter coil (37), blow vent (38) multiunit is located ventilates cover (34) upper wall.