CN215852042U - Automatic winding device for glass fiber cone yarn - Google Patents

Abstract

The application discloses an automatic winding device for glass fiber cone yarn, which relates to the technical field of packaging equipment and comprises a frame, a machine base, a film holding mechanism, a table-board mechanism, a winding mechanism and a cutting mechanism, wherein the machine base is arranged beside the vertical part of the frame; realized grasping the plastic film with winding mechanism, it is rotatory to surround the section of thick bamboo yarn to with the plastic film winding at the circumference lateral wall of section of thick bamboo yarn, after the winding, start shutdown mechanism cuts off the plastic film, then will twine the section of thick bamboo yarn of plastic film and take off from mesa mechanism, with this work of replacing traditional manual work around rolling up the plastic film, and then effectively improve the work efficiency of parcel plastic film on the yarn section of thick bamboo.

Description

Automatic winding device for glass fiber cone yarn

Technical Field

The application relates to the technical field of packaging equipment, in particular to an automatic winding device for glass fiber cone yarns.

Background

Glass fiber cheese is a device that is used for glass fiber yarn winding and accomodates, and the wide application is processed in glass fiber textile production, and back on the glass fiber cheese with glass fiber spinning winding, often has unnecessary yarn protrusion on the lateral wall of cheese, and the glass fiber shortcoming is that the nature is crisp, and the wearability is relatively poor, can lead to the yarn fracture phenomenon that drops to appear like this in the transportation, can wrap up the plastic film on glass fiber yarn section of thick bamboo at present to reduce the yarn fracture.

However, at present, the plastic film is wrapped on the glass fiber yarn cylinder by manual winding, and the working efficiency is lower.

SUMMERY OF THE UTILITY MODEL

For the work efficiency who wraps up the plastic film on the yarn section of thick bamboo of improvement, this application provides a fine section of thick bamboo yarn of glass automatic wind.

The application provides a pair of fine section of thick bamboo yarn automatic winding device of glass adopts following technical scheme: the utility model provides an automatic wind of glass fiber cone yarn, includes frame (100), frame (110), holds membrane mechanism (200), mesa mechanism (300), winding mechanism (400) and shutdown mechanism (500), frame (110) sets up on frame (100), it sets up the upper surface that rotates and set up at frame (110) to hold membrane mechanism (200), mesa mechanism (300) also sets up the upper surface at frame (110), mesa mechanism (300) are kept away from and are held membrane mechanism (200), winding mechanism (400) rotate and set up on frame (100), winding mechanism (400) are including last holder and lower holder that is used for the centre gripping plastic film, go up the holder and rotate respectively with lower holder and set up the upper and lower both sides at mesa mechanism, shutdown mechanism (500) rotate and set up on frame (110).

Through adopting above-mentioned technical scheme, during the use, the staff places the section of thick bamboo yarn on mesa mechanism, meanwhile, the plastic film that the staff will need the parcel is placed on holding membrane mechanism, holder and lower holder centre gripping plastic film in control, it is rotatory to drive the plastic film around the section of thick bamboo yarn, thereby with the plastic film winding at the circumference lateral wall of section of thick bamboo yarn, after the winding back, start shutdown mechanism, cut off the plastic film, then take off the section of thick bamboo yarn that will twine the plastic film from mesa mechanism, with this work of replacing traditional manual work around rolling up the plastic film, and then effectively improve the work efficiency of parcel plastic film on the section of thick bamboo yarn.

Preferably, a moving assembly (701) and a clamping assembly (702) are arranged on the machine frame (100), the moving assembly (701) is arranged on the horizontal portion of the machine frame (100) in a sliding mode along the length direction, the clamping assembly (702) is fixedly connected to the lower end of the moving assembly (701), and the moving assembly (701) is located above the base (340).

Through adopting above-mentioned technical scheme, when work begins, start the centre gripping subassembly, the section of thick bamboo yarn that the plastic film needs to be twined is lived to the centre gripping subassembly centre gripping, then start the removal subassembly, the removal subassembly slides along the horizontal part of frame and drives the centre gripping subassembly to the top of rotating the piece, start first cylinder group this moment and promote the below of rotating the piece butt at the section of thick bamboo yarn, then control the centre gripping subassembly and loosen the centre gripping to the section of thick bamboo yarn, move the subassembly and drive the centre gripping subassembly and leave directly over rotating the piece starting, with this carry out winding work at the back.

Preferably, the table top mechanism (300) comprises a rotating part and a servo motor (310) used for driving the rotating part to rotate, the servo motor (310) is arranged in the base (110), an output shaft of the servo motor (310) vertically penetrates out of the upper end face of the base (110) upwards, and the rotating part is fixedly connected to the output shaft of the servo motor (310).

Through adopting above-mentioned technical scheme, after the plastic film was lived to winding mechanism centre gripping, start servo motor, servo motor drives and rotates a rotation, when rotating a rotation, places the section of thick bamboo yarn on rotating a piece and can rotate along with rotating a synchronous rotation to be convenient for with the plastic film winding on the circumference lateral surface of section of thick bamboo yarn.

Preferably, a support seat (130) is fixedly connected to the machine base (110), the lower clamping piece is fixedly connected to an output shaft of the servo motor (310), the upper clamping piece is rotatably arranged on the support seat (130), and a transmission piece used for rotating the upper clamping piece is arranged on the support seat (130).

Through adopting above-mentioned technical scheme, during the use, with last holder and the lower both ends of holder centre gripping plastic film end respectively down, when winding mechanism rotates, it can drive the end of plastic film and twine at the circumference lateral wall of section of thick bamboo yarn with holder down to go up the holder, after twining a week, the end of plastic film is pushed down to the second floor plastic film of winding on the section of thick bamboo yarn, then the holder is loosened the centre gripping to the plastic film with lower holder in the control, along with the rotation of rotating the piece this moment, drive the plastic film and wrap up the second floor with the whole winding of the circumference side of section of thick bamboo yarn, the plastic film is held once more to the holder and lower holder in the uncontrolled this moment, then cut off the plastic film between holder and lower holder and the section of thick bamboo yarn with shutdown mechanism.

Preferably, the cutting mechanism (500) comprises a hot knife cutting piece and a first driving piece for driving the hot knife cutting piece to rotate, the first driving piece is arranged on the supporting seat (130), and the hot knife cutting piece is connected to the output end of the first driving piece.

By adopting the technical scheme, when the winding device is used, the first driving piece is controlled to push the hot knife cutting piece to be close to the plastic film, and the plastic film between the cone yarn and the winding mechanism is cut off by utilizing the heat of the hot knife cutting piece.

Be provided with first press mold subassembly (601) on frame (110) and be used for driving the second driving piece that first press mold subassembly (601) removed, first press mold subassembly (601) sets up the one side at the rotation piece, first press mold subassembly (601) includes first press mold frame (660), still be provided with shower nozzle (670) of blowing towards first press mold running roller on first press mold frame (660), the air intake and the external air supply intercommunication of shower nozzle (670).

By adopting the technical scheme, when the winding mechanism rotates and passes through the first film pressing assembly, the second driving piece is started, the second driving piece pushes the first film pressing assembly to be in contact with the circumferential outer side wall of the cheese covered with the first layer of plastic film, so that the plastic film is in close contact with the circumferential outer side wall of the cheese, and the plastic film is ensured to be in good contact with the cheese; and the hot air is conveyed into the spray head and blown to the outer surface of the plastic film through the spray head, so that the plastic film can be better attached to the circumferential outer side surface of the cone yarn.

Preferably, still be provided with second press mold subassembly (602) on frame (110) and be used for driving the third driving piece that second press mold subassembly (602) removed, second press mold subassembly (602) set up the opposite side at the rotation piece, first press mold subassembly (601) and second press mold subassembly (602) symmetry set up, second press mold subassembly (602) include second press mold frame 640, second press mold frame 640 fixed connection is at the output of third driving piece, second press mold frame 640 rotates to the one end of third driving piece dorsad and is connected with second press mold running roller.

Through adopting above-mentioned technical scheme, after the end of plastic film is pushed down to the second layer of plastic film of winding on the section of thick bamboo yarn, start the third driving piece, the third driving piece promotes second press mold frame and is close to the front end at the plastic film cutting point, and make the outer surface contact of second press mold running roller and plastic film, then the plastic film cutting off between second press mold subassembly and the winding mechanism is cut off to shutdown mechanism, then it is rotatory once more to rotate the piece, second press mold running roller is rotatory along with the section of thick bamboo yarn together, thereby press the plastic film of hot fusing on the second layer of plastic film, the rolling extrusion of reuse second press mold running roller prevents that the plastic film that cuts off from taking place to break away from on the section of thick bamboo yarn.

Preferably, the base (110) is further provided with a left hoop membrane assembly (801) and a right hoop membrane assembly (802), the base (340) is provided with a fourth driving piece for driving the left hoop membrane assembly (801) and the right hoop membrane assembly (802), an output end of the fourth driving piece faces a vertical center line of the rotating member, and the left hoop membrane assembly (801) and the right hoop membrane assembly (802) are located above the rotating member.

By adopting the technical scheme, when the clamping device is used, the bobbin yarn is clamped and lifted by the clamping assembly, then the left hoop membrane assembly and the right hoop membrane assembly are started firstly, and the width of the plastic membrane wound on the circumferential side surface of the bobbin yarn is larger than the axial length of the bobbin yarn, so that the left hoop membrane assembly and the right hoop membrane assembly can be clamped oppositely, and the overlong plastic membranes on the circumferential side wall of the bobbin yarn are extruded together.

Preferably, a squeezing assembly (803) is arranged on the right hoop membrane assembly (802), a fifth driving member for driving the squeezing assembly (803) to move is arranged on the right hoop membrane assembly (802), and the running direction of the output end of the fifth driving member is perpendicular to the running direction of the output end of the fourth driving member.

Through adopting above-mentioned technical scheme, after left hoop membrane subassembly and right hoop membrane subassembly centre gripping relatively, start the fifth driving piece, the fifth driving piece promotes the extrusion subassembly motion, the extrusion subassembly is once extrudeing piling up the plastic film together, because the extrusion of left hoop membrane subassembly and right hoop membrane subassembly and extrusion subassembly is mutually perpendicular, consequently the extrusion subassembly can strengthen the extrusion effect of plastic film, and make it take place certain buckling, after the extrusion subassembly centre gripping, start first cylinder group, first cylinder group promotes the rotation piece upward movement and promotes the plastic film that the extrusion is together and pile up in the bottom of section of thick bamboo yarn.

Preferably, the rotating member comprises a base (340) and a first cylinder group (330), the first cylinder group (330) is fixedly connected to an output shaft of the servo motor (310), and the output shaft of the first cylinder group (330) is vertically and upwardly fixedly connected with the base (340).

Through adopting above-mentioned technical scheme, accomplish the extrusion back to piling up plastic film together when extrusion subassembly, start first cylinder group, first cylinder group promotes first cylinder group upward movement to the base that drives first cylinder upper surface contacts with the plastic film of section of thick bamboo yarn below, promotes to pile up plastic film together and is close to the bottom surface of section of thick bamboo yarn, and then makes the plastic film pile up the lower bottom surface at the section of thick bamboo yarn.

In summary, the present application includes at least one of the following beneficial technical effects:

1. the plastic film is clamped by the winding mechanism and rotates around the cone yarn by arranging the table-board mechanism, the winding mechanism and the cutting mechanism, so that the plastic film is wound on the circumferential outer side wall of the cone yarn;

2. the plastic film is tightly contacted with the circumferential outer side wall of the cone yarn by arranging the first film pressing assembly, so that good contact between the plastic film and the cone yarn is ensured;

3. through setting up second press mold subassembly, the plastic film pressure that second press mold subassembly will hot melt is on the second floor plastic film, utilizes the extrusion of second press mold subassembly to prevent that the plastic film that cuts off from taking place to break away from on the section of thick bamboo yarn.

Drawings

Fig. 1 is a schematic overall structure diagram of an embodiment of the present application.

Fig. 2 is a top view of an embodiment of the present application.

Fig. 3 is a schematic structural diagram of a moving assembly and a clamping assembly in an embodiment of the present application.

Fig. 4 is a schematic structural view of the table top mechanism and the winding mechanism in the embodiment of the present application.

Fig. 5 is a schematic structural diagram of a table-board mechanism, a film pressing mechanism and a film hooping mechanism in the embodiment of the application.

Fig. 6 is a schematic structural diagram of a film pressing mechanism and a film hooping mechanism in the embodiment of the application.

Fig. 7 is a top view of the table top mechanism and winding mechanism in an embodiment of the present application.

Description of reference numerals: 100. a frame; 110. a machine base; 120. an electrical cabinet; 130. a supporting seat; 140. a connecting rod;

200. a film holding mechanism; 210. an inner shaft; 220. an inner support shaft; 230. a support frame;

300. a table-board mechanism; 310. a servo motor; 320. a work table; 330. a first cylinder group; 340. a base;

400. a winding mechanism; 401. an upper clamping member; 402. a lower clamping member; 410. rotating the rotating shaft; 420. an upper holding arm; 430. a pneumatic upper clamping block; 440. a lower holding arm; 450. a pneumatic lower clamping block; 460. rotating the shaft downwards; 470. a drive shaft; 480. a lower belt; 481. a lower belt wheel; 491. an upper belt wheel; 490. a belt is arranged;

500. a cutting mechanism; 510. a swing arm bracket; 520. a swing arm cylinder; 530. a hot knife swing arm; 540. cutting off the hot knife; 550. a hot knife pushing cylinder;

600. a film pressing mechanism; 601. a first lamination assembly; 602. a second lamination assembly; 610. pressing a film supporting column; 620. a second film pressing fixing plate; 630. a third cylinder; 640. a second film pressing frame; 650. a second cylinder; 660. a first film pressing frame; 670. a spray head; 680. a first film pressing fixing plate;

700. a moving mechanism; 701. a moving assembly; 702. a clamping assembly; 710. a sliding plate; 720. a sixth cylinder; 730. a connecting plate; 740. a seventh cylinder; 750. a clamping frame; 760. a guide roll shaft;

800. a film hooping mechanism; 801. a left hoop membrane assembly; 802. a right hoop membrane assembly; 803. an extrusion assembly; 810. a hoop membrane support post; 820. a left hoop membrane support plate; 830. a fourth cylinder; 840. a left hoop membrane push plate; 850. a right hoop membrane support plate; 860. a right hoop membrane push plate; 870. a fifth cylinder; 880. a first squeeze plate; 890. a second compression plate;

900. and (5) positioning the conveyor.

Detailed Description

The present application is described in further detail below with reference to figures 1-6. The application discloses fine section of thick bamboo yarn automatic winding device of glass refers to fig. 1 and 2 and shows, a fine section of thick bamboo yarn automatic winding device of glass, including frame 100 and frame 110, frame 100 is provided with horizontal part and vertical portion, and vertical portion stands subaerial perpendicularly, and horizontal part fixed connection is at the up end of vertical portion. The base 110 is rectangular and horizontally placed on the ground and contacted with the side wall of the vertical part of the frame 100, the base 110 is positioned below the horizontal part of the frame 100, a positioning conveyor 900 for transporting cheese is further arranged below the horizontal part of the frame 100, the positioning conveyor 900 is positioned on one side of the base 110, and the other side, opposite to the positioning conveyor 900, of the base 110 is fixedly connected with the electric cabinet 120.

Referring to fig. 1 and 3, a moving mechanism 700 is disposed on the frame 100, the moving mechanism 700 includes a moving assembly 701 slidably disposed on the horizontal portion of the frame 100, and a clamping assembly 702 is fixedly connected to an end of the moving assembly 701 away from the horizontal portion of the frame 100. The moving unit 701 includes a sliding plate 710 and a connecting plate 730, and the sliding plate 710 is slidably disposed along a longitudinal direction of the horizontal portion of the frame 100. The top of the sliding plate 710 is fixedly connected with a sixth cylinder 720, and the output shaft of the sixth cylinder 720 vertically passes through the sliding plate 710 downwards and is fixedly connected with the connecting plate 730. The clamping assembly 702 includes two seventh air cylinders 740 and a clamping bracket 750. The two seventh cylinders 740 are fixedly connected to the connecting plate 730 and arranged in a staggered manner, the output shafts of the two seventh cylinders 740 extend along the length direction of the connecting plate 730 and are respectively fixedly connected with the clamping frames 750, and the guide roller shafts 760 are rotatably arranged at the lower parts of the opposite end surfaces of the two clamping frames 750.

The sliding plate 710 may be moved on the horizontal portion of the frame 100 by pneumatic or hydraulic means, and in this embodiment, electromagnetic movement is used. When the device is used, the position of the horizontal part of the frame 100 is controlled by the electromagnetic control sliding plate 710, when the heights of the two clamping frames 750 are adjusted, the extension and contraction of the sixth air cylinder 720 are controlled, when the cheese needs to be clamped, the seventh air cylinder 740 is controlled, and the seventh air cylinder 740 drives the two clamping frames 750 to mutually approach or separate in the length direction of the connecting plate 730, so that the cheese is clamped and separated.

The upper surface of the machine base 110 is provided with a table-board mechanism 300, a film holding mechanism 200, a winding mechanism 400 and a cutting mechanism 500. The table mechanism 300 is disposed away from the vertical portion of the frame 100, and the film holding mechanism 200 is disposed close to the vertical portion of the frame 100. The winding mechanism 400 is disposed on the side of the table-board mechanism 300, and the cutting mechanism 500 acts between the table-board mechanism 300 and the film holding mechanism 200.

During the use, the staff places the plastic film on holding membrane mechanism 200, then with the end position of winding mechanism 400 centre gripping plastic film, start moving assembly 701 and drive centre gripping subassembly 702 and centre gripping the section of thick bamboo yarn that needs the winding plastic film on locating conveyor 900, place the section of thick bamboo yarn on mesa mechanism 300, start winding mechanism 400 with the plastic film winding on the circumference side of section of thick bamboo yarn, after winding, start shutdown mechanism 500 and cut off the plastic film.

Referring to fig. 1 and 4, the table top mechanism 300 includes a table 320, a servo motor 310, and a rotation member, wherein a lower bottom surface of the table 320 is fixedly connected to an upper bottom surface of the base 110, and the servo motor 310 is fixedly disposed on the lower surface of the table 320. The output shaft of the servo motor 310 vertically penetrates upwards into the workbench 320 and is connected with a gear set, the rotating member is located above the servo motor 310, the rotating member comprises a first cylinder group 330 and a base 340, and the rotating axis of the first cylinder group 330 is not overlapped with the rotating axis of the servo motor 310. The first cylinder group 330 is connected to the gear set and driven by the gear set to rotate.

During the use, start servo motor 310, servo motor 310 drives first cylinder group 330 through the gear train and rotates, and first cylinder group 330 drives base 340 synchronous revolution, and when the level of base 340 was adjusted to needs, start first cylinder group 330, first cylinder group 330 promoted base 340 and changes on vertical height.

Referring to fig. 1 and 4, the winding mechanism 400 includes an upper clamp 401 and a lower clamp 402, wherein the support base 130 is fixedly connected to the base 110, and the support base 130 is located on a side of the base 340 away from the worktable 320. The support seat 130 is fixedly connected with a connecting rod 140 towards the upper part of the working end face, one end of the connecting rod 140 far away from the support seat 130 is fixedly connected with an upper clamping piece 401, and the upper clamping piece 401 comprises an upper rotating shaft 410 and a pneumatic upper clamping block 430. The upper rotating shaft 410 vertically penetrates through one end, far away from the supporting seat 130, of the connecting rod 140, and the upper rotating shaft 410 and the output shaft of the servo motor 310 are coaxially arranged. The lower extreme fixedly connected with of last axis of rotation 410 holds arm 420, holds arm 420 and keeps away from the one end of going up axis of rotation 410 and pneumatic last grip block 430 fixed connection, and pneumatic last grip block has two to promote through pointing the cylinder and accomplishes clamping work.

The lower clamping member 402 includes a lower rotating shaft 460, a lower holding arm 440 and a pneumatic lower clamping block 450, the lower rotating shaft 460 is inserted from the bottom surface of the working table 320 and is connected to the gear set, and the rotating axis of the lower rotating shaft 460 coincides with the rotating axis of the first cylinder group 330. The lower holding arm 440 is fixedly connected with the other output shaft of the servo motor 310, and the output shaft of the first cylinder group 330 passes through the bottom surface of the lower holding arm 440. One end of the lower holding arm 440, which is far away from the output shaft of the servo motor 310, is fixedly connected to a pneumatic lower clamping block 450, wherein two pneumatic lower clamping blocks are also pushed by a finger cylinder to complete the clamping operation. The supporting base 130 is provided with a transmission member for the upper clamping member 401 and the lower clamping member 402 to rotate synchronously.

During the use, start finger actuating cylinder, the upper and lower side of plastic film tip is held respectively to the last grip block 430 of control pneumatics and the pneumatic grip block 450 down, then start servo motor 310, servo motor 310 drives when rotating the piece rotatory, can drive pneumatics grip block 450 down and rotate around the section of thick bamboo yarn on rotating the piece through the transmission of holding down arm 440, meanwhile, go up rotation axis 410 and servo motor 310 output shaft synchronous revolution through the transmission power of driving medium, with this drive hold the arm 420 rotatory on, thereby it is rotatory also around the section of thick bamboo yarn to drive pneumatic grip block 430, and then twine the plastic film on the circumference side of section of thick bamboo yarn.

Referring to fig. 1 and 4, the transmission member includes a transmission shaft 470, an upper belt 490, and a lower belt 480, wherein the transmission shaft 470 is rotatably disposed on the support base 130, and an axial output of the transmission shaft 470 is disposed. The lower rotating shaft 460 is fixedly connected with a lower belt wheel 481 with the same axis, and the lower belt 480 is sleeved on the lower end of the rotating shaft 470 and the lower belt wheel 481. The upper rotating shaft 410 is coaxially and fixedly connected with an upper belt wheel 491, an upper belt 490 is sleeved on the upper end of the rotating shaft 470 and the upper belt wheel 491, and the upper belt 490 is positioned above the connecting rod 140.

When the servo motor 310 rotates, the servo motor 310 rotates the output shaft inside the base 110 to drive the lower rotating shaft 460 to rotate, the rotating lower rotating shaft 460 drives the transmission shaft 470 to rotate through the lower belt 480, and when the transmission shaft 470 rotates, the upper rotating shaft 410 is driven to rotate through the upper belt 490, so that the upper clamping piece 401 and the lower clamping piece 402 are driven to complete the synchronous rotation through the rotation of the servo motor 310.

Referring to fig. 1 and 4, the film holding mechanism 200 includes a support frame 230, an inner shaft 210 and an inner support shaft 220, wherein the support frame 230 is fixedly connected to one side of the support base 130 facing the workbench 320, one end of the inner shaft 210 is rotatably disposed on the upper surface of the support frame 230, and the other end of the inner shaft 210 passes through the connecting rod 140 and is driven by the upper belt 490 to rotate. The inner support shaft 220 is sleeved on the inner shaft 210 and is in threaded connection with the inner shaft 210, when the plastic film cylinder is sleeved on the inner shaft 210, then the inner support shaft 220 is in bolt connection with the inner shaft 210, the outer peripheral side surface of the inner support shaft 220 is abutted against the side wall of the inner shaft 210 of the plastic film cylinder, and therefore when the inner shaft 210 rotates, the plastic film can rotate together.

Referring to fig. 1 and 5, two sides of the base 110 are respectively and fixedly connected with a support platform, the two support platforms are symmetrically arranged on two sides of the support base 130, upper surfaces of the two support platforms are respectively and fixedly connected with hoop film support columns 810, and the two hoop film support columns 810 are respectively and fixedly connected with a film pressing support column 610 towards the upper end of the side surface of the support base 130. Wherein the lamination mechanism 600 is arranged on the lamination support column 610.

Referring to fig. 1 and 5, the lamination mechanism 600 includes a first lamination assembly 601 and a second lamination assembly 602, the first lamination assembly 601 being disposed on one lamination support post 610 and the second lamination assembly 602 being disposed on the other support post. And a second driving member and a third driving member are respectively arranged on the two film pressing support columns 610. The first lamination assembly 601 includes a first lamination fixing plate 680 and a first lamination frame 660, and the first lamination fixing plate 680 is fixedly connected to the upper surface of the lamination supporting column 610. The second driving piece is a second cylinder 650, the second cylinder 650 is fixedly connected to the end surface of the first film pressing fixing plate 680 facing the supporting seat 130, the output shaft of the second cylinder 650 faces the side surface of the other film pressing supporting column 610, the output shaft of the second cylinder 650 is fixedly connected to the first film pressing frame 660, and the first film pressing frame 660 is connected to the first film pressing roller in a rotating manner at the end, back to the second cylinder 650, of the first film pressing frame 660. The first film pressing frame 660 is further provided with a spray head 670 blowing towards the first film pressing roller, and an air inlet of the spray head 670 is communicated with an external air source.

The second lamination assembly 602 includes a second lamination fixing plate 620 and a second lamination holder 640, and the second lamination fixing plate 620 is fixedly connected to the upper surface of the other lamination support column 610. The third driving piece is a third cylinder 630, the third cylinder 630 is fixedly connected to the end surface of the second film pressing fixing plate 620, which faces away from the supporting seat 130, the output shaft of the third cylinder 630 faces the output shaft of the second cylinder 650, the output shaft of the third cylinder 630 is fixedly connected to the second film pressing frame 640, and one end of the second film pressing frame 640, which faces away from the third cylinder 630, is rotatably connected to a second film pressing roller.

During use, when the pneumatic upper clamping block 430 and the pneumatic lower clamping block 450 clamp the plastic film to be wound on the circumferential side wall of the cheese to cross the first film pressing frame 660, the second cylinder 650 is started, the second cylinder 650 pushes the first film pressing frame 660 to be close to the circumferential side wall of the cheese, the first film pressing roller is extruded on the first layer of plastic film, the first film pressing roller rolls on the first layer of plastic film along with the rotation of the cheese, meanwhile, hot air is blown onto the plastic film through the spray head 670, and the plastic film is attached to the circumferential side wall of the cheese. When the pneumatic upper clamping block 430 and the pneumatic lower clamping block 450 clamp the plastic film to pass through the second film pressing frame 640, the third air cylinder 630 is started, the third air cylinder 630 pushes the second film pressing frame 640 to be close to the cheese, so that the second film pressing roller presses the first-layer plastic film, then the clamping of the pneumatic upper clamping block 430 and the pneumatic lower clamping block 450 to the plastic film is cancelled, the plastic film is continuously rotated to be wound on the circumferential side wall of the cheese along with the base 340, after the plastic film is wound for two circles, the first film pressing wheel and the second film pressing wheel are respectively extruded on the second-layer plastic film, the base 340 is stopped, and the pneumatic upper clamping block 430 and the pneumatic lower clamping block 450 are controlled to clamp the plastic film again.

Referring to fig. 5 and 6, a hoop membrane support column 810 is also provided with a hoop membrane mechanism 800. The hoop membrane mechanism 800 includes a left hoop membrane assembly 801, a right hoop membrane assembly 802, and a fourth driver, wherein the left hoop membrane assembly 801 is disposed on the upper surface of one hoop membrane support column 810 and below the second lamination assembly 602. The right hoop film assembly 802 is disposed on the upper surface of another hoop film support column 810 below the first squeeze film assembly 601.

The left hoop membrane assembly 801 includes a left hoop membrane support plate 820 and a left hoop membrane push plate 840. The left hoop membrane supporting plate 820 is fixedly connected to the upper surface of the hoop membrane supporting column 810, the fourth driving member comprises a fourth cylinder 830 fixedly connected to the upper surface of the left hoop membrane supporting plate 820, and an output shaft of the fourth cylinder 830 faces to the side wall of the other hoop membrane supporting column 810 and is fixedly connected with the left hoop membrane pushing plate 840.

The right hoop membrane assembly 802 includes a right hoop membrane support plate 850, a right hoop membrane push plate 860, and a squeeze assembly 803. The right hoop membrane supporting plate 850 is fixedly connected to the upper surface of the other hoop membrane supporting column 810, the fourth driving member further comprises another fourth cylinder 830 fixedly connected to the upper surface of the right hoop membrane supporting plate 850, and an output shaft of the fourth cylinder 830 faces the left hoop membrane pushing plate 840 and is fixedly connected with the right hoop membrane pushing plate 860.

When the plastic film winding machine is used, after the plastic film is wound on the circumferential side wall of the cone yarn, the cone yarn is clamped by the two clamping frames 750, and then the two fourth air cylinders 830 are started simultaneously to respectively push the left hoop film push plate 840 and the right hoop film push plate 860 to be close to each other, so that the plastic film growing out of the cone yarn is extruded together.

Referring to fig. 5 and 6, the pressing assembly 803 includes first and second pressing plates 880 and 890, and a fifth driving member. The fifth driving member includes two fifth cylinders 870 fixedly disposed on upper and lower end surfaces of the right hoop membrane supporting plate 850, and the directions of output shafts of the two fifth cylinders 870 are staggered and perpendicular to the output shaft of the fourth cylinder 830. One end of the first pressing plate 880 passes through the right hoop membrane supporting plate 850 to be fixedly connected with the output shaft of the fifth cylinder 870, and the first pressing plate 880 is slidably disposed along the axial direction of the fifth cylinder 870, and the other end of the first pressing plate 880 is far away from the right hoop membrane supporting plate 850. The second pressing plate 890 is slidably disposed along the right hoop membrane supporting plate 850, and is fixedly connected to the output shaft of the fifth cylinder 870 on the lower bottom surface of the right hoop membrane supporting plate 850.

In use, after the left hoop film pushing plate 840 and the right hoop film pushing plate 860 push the plastic film growing out of the cone yarn together, the two fifth cylinders 870 are activated, and the two fifth cylinders 870 push the first pressing plate 880 and the second pressing plate 890 to approach each other. And extruding and stacking the plastic film from the other direction.

Referring to fig. 2 and 7, the cutting mechanism 500 includes a first driving member and a hot knife cutting member, wherein the first driving member is a swing arm cylinder 520, a swing arm support 510 is fixedly connected to an end surface of the support base 130 facing away from the worktable 320, and a cylinder body of the swing arm cylinder 520 is rotatably connected to the swing arm support 510. The hot knife cutting device comprises a hot knife swing arm 530, a hot knife pushing cylinder 550 and a cutting hot knife 540, wherein the hot knife swing arm 530 is rotatably connected to the side wall of the supporting seat 130, which is back to the right hoop film pushing plate 860. The output shaft of the swing arm cylinder 520 is fixedly connected to the other end of the hot knife swing arm 530, and the other end of the hot knife swing arm 530 is fixedly connected to the hot knife pushing cylinder 550. The output shaft of the hot knife pushing cylinder is perpendicular to the length direction of the hot knife swing arm 530 and faces the workbench 320. The cutting hot knife 540 is fixedly connected to the output shaft of the hot knife pushing cylinder.

During the use, start hot sword and promote the cylinder, hot sword promotes the cylinder and promotes the one end of hot sword swing arm 530, and hot sword swing arm 530 rotates at the lateral wall of supporting seat 130, makes to cut off hot sword 540 and is located between second press mold wheel and the pneumatic grip block 430 of going up, then starts hot sword and promotes the cylinder and promote to cut off hot sword 540 and the plastic film contact to cut off the plastic film, and guarantee to hold the plastic film port on membrane mechanism 200 and be held on pneumatic grip block 430 and the pneumatic grip block 450 down.

The embodiment of the application is an implementation principle of an automatic winding device for glass fiber cone yarns: when the device is used, the sixth air cylinder 720 is started, the sixth air cylinder 720 pushes the connecting plate 730 to move downwards, the two clamping frames 750 are made to approach the positioning conveyor 900, the seventh air cylinder 740 is started to drive the two clamping frames 750 to move oppositely to clamp the cheese needing to be wound with the plastic film on the positioning conveyor 900, then the cheese slides on the horizontal part of the frame 100 through the electromagnetic control sliding plate 710, the cheese is made to be positioned right above the base 340, the first air cylinder group 330 is controlled to push the base 340 to move upwards to be in contact with the bottom surface of the cheese, then the seventh air cylinder 740 is controlled to release clamping of the cheese, and the cheese is reset through the electromagnetic control sliding plate 710.

At the same time, the first cylinder group 330 is controlled to drive the cone yarn to move downwards. Then the servo motor 310 is started, the servo motor 310 drives the base 340, the pneumatic upper clamping block 430 and the pneumatic lower clamping block 450 to rotate around the axis of the base 340, when the pneumatic upper clamping block 430 and the pneumatic lower clamping block 450 clamp the plastic film to be wound on the circumferential side wall of the cheese to cross the first film pressing frame 660 in the rotating process, the second air cylinder 650 is started, the second air cylinder 650 pushes the first film pressing frame 660 to be close to the circumferential side wall of the cheese, the first film pressing roller is extruded on the first layer of plastic film, the first film pressing roller rolls on the first layer of plastic film along with the rotation of the cheese, meanwhile, hot air is blown onto the plastic film through the spray head 670, and the plastic film is enabled to be attached to the circumferential side wall of the cheese. When the pneumatic upper clamping block 430 and the pneumatic lower clamping block 450 clamp the plastic film to pass through the second film pressing frame 640, the third air cylinder 630 is started, the third air cylinder 630 pushes the second film pressing frame 640 to be close to the cheese, so that the second film pressing roller presses the first-layer plastic film, then the clamping of the pneumatic upper clamping block 430 and the pneumatic lower clamping block 450 to the plastic film is cancelled, the plastic film is continuously rotated to be wound on the circumferential side wall of the cheese along with the base 340, after two circles of winding are carried out, the first film pressing wheel and the second film pressing wheel are respectively extruded on the second-layer plastic film, the rotation of the servo motor 310 is stopped, and the pneumatic upper clamping block 430 and the pneumatic lower clamping block 450 are controlled to clamp the plastic film again.

Then, the hot knife pushing cylinder is started, the hot knife pushing cylinder pushes one end of the hot knife swing arm 530, the hot knife swing arm 530 rotates on the side wall of the supporting seat 130, the cutting hot knife 540 is located between the second film pressing wheel and the pneumatic upper clamping block 430, and then the hot knife pushing cylinder is started to push the cutting hot knife 540 to contact with the plastic film, so that the plastic film is cut off, and the plastic film port on the film holding mechanism 200 is clamped on the pneumatic upper clamping block 430 and the pneumatic lower clamping block 450.

Then the electromagnetic control sliding plate 710 moves to the right above the base 340 again, then the two clamping frames 750 clamp the cheese, and control the first cylinder group 330 to move downwards, and then the two fourth cylinders 830 are started simultaneously to respectively push the left hoop film pushing plate 840 and the right hoop film pushing plate 860 to approach each other, so as to press the plastic film growing out the cheese together. After the extrusion is completed, the two fifth cylinders 870 are activated, and the two fifth cylinders 870 push the first extrusion plate 880 and the second extrusion plate 890 to approach each other. And extruding and stacking the plastic film from the other direction. The excess plastic film is then pressed against the bottom surface of the package upon activation of the first cylinder group 330.

The slider plate 710 is then moved again by electromagnetic control to move the package through the two gripper blocks 750 onto the positioning conveyor 900.

The above embodiments are preferred embodiments of the present application, and the protection scope of the present application is not limited by the above embodiments, so: all equivalent changes made according to the structure, shape and principle of the present application shall be covered by the protection scope of the present application.

Claims (10)

1. The utility model provides a fine section of thick bamboo yarn automatic wind which characterized in that of glass: including frame (100), frame (110), hold membrane mechanism (200), mesa mechanism (300), winding mechanism (400) and shutdown mechanism (500), frame (110) sets up on frame (100), hold membrane mechanism (200) and set up the upper surface that rotates and set up at frame (110), mesa mechanism (300) also sets up the upper surface at frame (110), mesa mechanism (300) are kept away from and are held membrane mechanism (200), winding mechanism (400) rotate and set up on frame (100), winding mechanism (400) are including last holder (401) and lower holder (402) that are used for the centre gripping plastic film, go up holder (401) and lower holder (402) and rotate respectively and set up the upper and lower both sides at mesa mechanism, shutdown mechanism (500) rotate and set up on frame (110).

2. The automatic winding device for glass fiber cone yarn as claimed in claim 1, wherein: the movable clamping device is characterized in that a moving assembly (701) and a clamping assembly (702) are arranged on the rack (100), the moving assembly (701) is arranged on the horizontal portion of the rack (100) in a sliding mode along the length direction, the clamping assembly (702) is fixedly connected to the lower end of the moving assembly (701), and the moving assembly (701) is located above the base (340).

3. The automatic winding device for glass fiber cone yarn as claimed in claim 2, wherein: mesa mechanism (300) including rotate the piece and be used for the drive to rotate rotatory servo motor (310), servo motor (310) set up in frame (110) and the vertical up end of wearing out frame (110) of output shaft of servo motor (310), it is on the output shaft of servo motor (310) to rotate a fixed connection.

4. The automatic winding device for glass fiber cone yarn as claimed in claim 3, wherein: the support frame (130) is fixedly connected to the machine base (110), the lower clamping piece (402) is fixedly connected to an output shaft of the servo motor (310), the upper clamping piece (401) is rotatably arranged on the support frame (130), and a transmission piece used for rotating the upper clamping piece (401) is arranged on the support frame (130).

5. The automatic winding device for glass fiber cone yarn as claimed in claim 4, wherein: the cutting-off mechanism (500) comprises a hot knife cutting piece and a first driving piece used for driving the hot knife cutting piece to rotate, the first driving piece is arranged on the supporting seat (130), and the hot knife cutting piece is connected to the output end of the first driving piece.

6. The automatic winding device for glass fiber cone yarn as claimed in claim 5, wherein: be provided with first press mold subassembly (601) on frame (110) and be used for driving the second driving piece that first press mold subassembly (601) removed, first press mold subassembly (601) sets up the one side at the rotation piece, first press mold subassembly (601) includes first press mold frame (660), still be provided with shower nozzle (670) of blowing towards first press mold running roller on first press mold frame (660), the air intake and the external air supply intercommunication of shower nozzle (670).

7. The automatic winding device for glass fiber cone yarn as claimed in claim 6, wherein: still be provided with second press mold subassembly (602) on frame (110) and be used for driving the third driving piece that second press mold subassembly (602) removed, second press mold subassembly (602) set up the opposite side at the rotation piece, first press mold subassembly (601) and second press mold subassembly (602) symmetry set up, second press mold subassembly (602) include second press mold frame (640), second press mold frame (640) fixed connection is at the output of third driving piece, second press mold frame (640) rotate to the one end of third driving piece dorsad and are connected with second press mold running roller.

8. The automatic winding device for glass fiber cone yarn as claimed in claim 5, wherein: the base (110) is further provided with a left hoop membrane assembly (801) and a right hoop membrane assembly (802), the base (340) is provided with a fourth driving piece for driving the left hoop membrane assembly (801) and the right hoop membrane assembly (802), an output end of the fourth driving piece faces a vertical center line of the rotating piece, and the left hoop membrane assembly (801) and the right hoop membrane assembly (802) are located above the rotating piece.

9. The automatic winding device for glass fiber cone yarn as claimed in claim 8, wherein: the right hoop membrane assembly (802) is provided with an extrusion assembly (803), the right hoop membrane assembly (802) is provided with a fifth driving piece for driving the extrusion assembly (803) to move, and the running direction of the output end of the fifth driving piece is perpendicular to the running direction of the output end of the fourth driving piece.

10. The automatic winding device for glass fiber cone yarn as claimed in claim 9, wherein: the rotating piece comprises a base (340) and a first cylinder group (330), the first cylinder group (330) is fixedly connected to an output shaft of the servo motor (310), and the output shaft of the first cylinder group (330) is vertically and upwards fixedly connected with the base (340).

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