CN111792836A - Intelligent beam splitting glass fiber wire drawing machine - Google Patents

Abstract

The invention provides an intelligent beam splitting glass fiber drawing machine which comprises a rack, a first supporting plate, a second supporting plate, a supporting rod, a bushing plate, a fiber penetrating and cooling box structure, an oiling device, a bundling motor, a bundling wheel shaft, a fiber bundling wheel, a cutting and penetrating box structure, a penetrating and inserting port, a steel conveying plate, a positioning motor, a ball screw, a detachable winding cylinder structure, a pushing plate frame structure, a PLC (programmable logic controller), a driving switch, a moving seat and a drawing motor, wherein the first supporting plate is welded at the middle upper part of the inner wall of the rack; the second supporting plate is welded in the middle of the inner wall of the rack; the support rods are respectively welded at the right side and the middle part of the front part and the rear part of the upper end of the rack. The invention has the beneficial effects that: through the setting of fibre interlude cooling box structure, be convenient for cooperate the copper circulating pipe to install, also be convenient for simultaneously pour into the coolant liquid into the inside of copper circulating pipe into to supplementary fin carries out radiating work.

Description

Intelligent beam splitting glass fiber wire drawing machine

Technical Field

The invention belongs to the technical field of glass fiber processing, and particularly relates to an intelligent beam splitting glass fiber drawing machine.

Background

The glass fiber composite material is used as a basic raw material, and has been widely applied to the fields of transportation, electronic information, aerospace, infrastructure, medical health and environmental protection energy along with the development of processing technology and auxiliary material technology, the glass fiber and products thereof are increasingly emphasized by people with excellent functional material characteristics, the existing glass fiber drawing machine is mechanical equipment for drawing glass melt into fiber filaments at high speed and winding the fiber filaments into fiber rolls according to a certain rule, and the existing glass fiber drawing machine adopts a single drawing technology.

However, the existing split glass fiber drawing machine also has the problems that the discharging part is not convenient to cool and use, the glass fiber is not convenient to cut after drawing, and the winding drum for drawing and winding is not convenient to replace.

Therefore, it is necessary to invent an intelligent split-beam glass fiber drawing machine.

Disclosure of Invention

In order to solve the technical problems, the invention provides an intelligent split glass fiber drawing machine, which aims to solve the problems that the existing split glass fiber drawing machine is inconvenient to cool and use a discharging part, is inconvenient to cut glass fibers after drawing and is inconvenient to replace a winding drum for drawing and winding. An intelligent beam splitting glass fiber drawing machine comprises a frame, a first supporting plate, a second supporting plate, a supporting rod, a bushing plate, a fiber penetrating and cooling box structure, an oiling device, a bundling motor, a bundling wheel shaft, a fiber bundling wheel, a cutting and penetrating box structure, a penetrating port, a steel conveying plate, a positioning motor, a ball screw, a detachable winding cylinder structure, a pushing plate frame structure, a PLC (programmable logic controller), a driving switch, a moving seat and a drawing motor, wherein the first supporting plate is welded on the middle upper part of the inner wall of the frame; the second supporting plate is welded in the middle of the inner wall of the rack; the support rods are respectively welded at the right side and the middle part of the front part and the rear part of the upper end of the rack; the bushing plate bolt is arranged at the upper end of the supporting rod; the fiber interpenetration cooling box structure is arranged on the support rod; the oiling device is arranged on the right side of the upper end of the first supporting plate; the cluster motor bolt is arranged on the left side of the upper surface of the second supporting plate; one end of the cluster wheel shaft is connected with an output shaft coupler of the cluster motor, and the other end of the cluster wheel shaft is arranged in the middle of the right side of the inner wall of the rack through a bearing; the fiber bundling wheel is respectively connected with the left side, the right side and the middle part of the outer wall of the bundling wheel shaft in a key way; the structure of the cuttable inserting box is arranged on the right side inside the second supporting plate; the inserting port is formed in the lower portion of the right side in the rack; the steel conveying plate is welded at the lower part of the inner wall of the inserting hole; the positioning motor is mounted at the lower part of the left end of the rack through a bolt, and an output shaft of the positioning motor is connected with a ball screw coupler; the right end of the ball screw is arranged at the lower part of the right side of the inner wall of the frame through a bearing; the detachable winding drum structure is arranged on the wire drawing motor; the pushing plate frame structures are respectively arranged on the front side and the rear side of the upper part of the movable seat; the PLC bolt is arranged at the middle lower part of the left end of the rack, and the front surface of the PLC is electrically connected with a driving switch; the lower bolt of the moving seat is arranged on the ball screw, and the upper bolt of the moving seat is provided with a wire drawing motor; the fiber interpenetration cooling box structure comprises a fixed plate, an outer guard plate, a radiating fin, a mounting seat, a mounting frame, a supporting sheet, a radiating fan and a copper circulating pipe, wherein the fixed plate is welded at the left ends of the outer guard plate and the radiating fin; the mounting seats are respectively welded on the left side and the right side of the outer wall of the outer guard plate; the mounting frame is welded at the right ends of the outer guard plate and the radiating fins; the supporting sheet is welded on the inner wall of the mounting frame, and a copper circulating pipe is embedded in the supporting sheet; the cooling fan is installed at the right end of the installation frame through bolts.

Preferably, the structure of the cutting interpenetration box comprises an interpenetration main box, an upper interpenetration insertion pipe, a supporting seat, a lower interpenetration insertion pipe, a cutting cylinder, an assembling seat and a cutting knife, wherein the upper interpenetration insertion pipe is welded on the left side, the right side and the middle part above the inside of the interpenetration main box respectively; the supporting seat is welded between the upper penetrating insertion pipe and the lower penetrating insertion pipe; the cutting cylinders are respectively installed on the left side and the right side of the front end of the interpenetration main box through bolts; the assembling seat bolt is arranged on an output shaft of the cutting cylinder; the cutting knife is inserted into the assembling seat and is fixed through a bolt.

Preferably, the detachable winding barrel structure comprises a limiting plate, a connecting shaft, a through hole, an installation block, a clamping screw, an insertion column and a winding main barrel, wherein the connecting shaft is welded in the middle of the left end of the limiting plate; the through insertion holes are respectively arranged at the front side and the rear side in the limiting disc; the mounting blocks are respectively welded on the upper part and the lower part of the right surface of the limiting plate, and the internal threads of the mounting blocks are connected with clamping screws; the insertion column is welded in the middle of the right end of the limiting disc; the winding main cylinder is sleeved on the outer side of the insertion column.

Preferably, the pushing plate frame structure comprises a vertical plate, a sleeving seat, an assembling edge, a pushing cylinder, a pushing main plate and an assembling head, wherein the assembling edge is welded at the upper end and the lower end of the sleeving seat respectively; the assembling side bolt is arranged on the outer side of the vertical plate; the pushing cylinder is placed in the sleeving seat; an assembly head is welded at the left end of the pushing main plate; the assembling head bolt is arranged on an output shaft of the pushing cylinder.

Preferably, a plurality of radiating fins are arranged between the fixing plate and the mounting frame, the radiating fins are copper sheets, and the upper parts of the radiating fins correspond to the bushing plate.

Preferably, the left side and the right side of the installation frame are provided with openings, a plurality of supporting sheets are arranged in the installation frame, and the copper circulating pipe is supported by the supporting sheets.

Preferably, alternate main box welding on the inside right side of second backup pad, the inside pipe that alternates of main box on be provided with threely, alternate on simultaneously and alternate a tub upper end and correspond with fibre bundling wheel.

Preferably, the cutting knife on the output shaft of the cutting cylinder is arranged at the front part of the supporting seat, and glass fibers are inserted between the supporting seat and the cutting knife.

Preferably, two insertion holes are formed in the limiting disc, the left end of each insertion hole corresponds to the pushing main board, and a connecting shaft at the left end of the limiting disc is connected with an output shaft coupling of the wire drawing motor.

Preferably, the vertical plate is welded on the front portion and the rear portion of the upper surface of the movable seat respectively, the sleeving seat on the vertical plate is set to be U-shaped, and the sleeving seat is matched with the assembling edge to fix the pushing cylinder.

Compared with the prior art, the invention has the beneficial effects that:

1. in the invention, a plurality of radiating fins are arranged between the fixing plate and the mounting frame, the radiating fins are made of copper sheets, and the upper parts of the radiating fins correspond to the bushing plate.

2. According to the invention, the left side and the right side of the mounting frame are provided with the openings, the plurality of supporting sheets are arranged in the mounting frame, the copper circulating pipe is supported by the supporting sheets, the copper circulating pipe is convenient to be mounted in a matching manner, and meanwhile, cooling liquid is convenient to be injected into the copper circulating pipe, so that the radiating work of the radiating fins is assisted.

3. According to the invention, the C-shaped hole is formed in the mounting seat, the bolt is arranged at the front part of the mounting seat, and the mounting seat is conveniently sleeved on the supporting rod and fixed through the bolt during mounting, so that the mounting seat is convenient to mount, use or dismount and maintain.

4. According to the invention, the penetration main box is welded on the right side in the second supporting plate, three upper penetration pipes are arranged in the penetration main box, and the upper ends of the upper penetration pipes correspond to the fiber bundling wheels, so that glass fibers can be conveniently penetrated and passed along, and the glass fibers can be better processed and used.

5. According to the glass fiber cutting device, the cutting knife on the output shaft of the cutting cylinder is arranged at the front part of the supporting seat, glass fibers penetrate between the supporting seat and the cutting knife, and after the cutting cylinder is driven, the cutting knife is driven to move so as to be matched with the supporting seat to cut the glass fibers, so that the functionality is improved.

6. According to the invention, the assembling seat is U-shaped, and the cutting knife is fixed in the assembling seat through the bolt, so that the assembling seat is convenient to assemble or disassemble in cooperation with the cutting knife, and is convenient to replace.

7. In the invention, the winding main cylinder is matched with the insertion column and is fixed by the clamping screw rod, so that the winding main cylinder is convenient to assemble and disassemble in a matching way, and after the winding main cylinder finishes the wire drawing and winding of the glass fiber, the winding main cylinder is convenient to replace with a new winding main cylinder, thereby playing a function of storing the glass fiber.

8. In the invention, the mounting block is rectangular, the clamping screw rod inside the mounting block is T-shaped, and after the winding main cylinder is inserted into the inner side of the mounting block, the clamping screw rod is screwed to support the winding main cylinder for fixing and using.

9. According to the wire drawing machine, two insertion holes are formed in the limiting disc, the left end of each insertion hole corresponds to the pushing main board, and the connecting shaft at the left end of the limiting disc is connected with the output shaft coupler of the wire drawing motor, so that the limiting disc is conveniently matched with the limiting disc to be installed and driven to rotate for use, and therefore the winding main cylinder is better driven to rotate and perform wire drawing work.

10. According to the invention, the vertical plates are respectively welded on the front part and the rear part of the upper surface of the movable seat, the sleeving seats on the vertical plates are set to be U-shaped, and the sleeving seats are matched with the assembling edges to fix the pushing cylinder, so that the pushing cylinder is convenient to install and use along with the sleeving seats, and is also convenient to disassemble and maintain along with the pushing cylinder.

11. In the invention, the pushing main board is connected with the pushing cylinder through the assembling head, and when the pushing cylinder is driven to drive the pushing main board to move, the pushing main board can pass through the through-insertion hole to drive the winding main cylinder to separate.

Drawings

Fig. 1 is a schematic structural view of the present invention.

Fig. 2 is a schematic structural view of a fiber-interspersed cooling box structure of the present invention.

Fig. 3 is a schematic structural diagram of a structure of the cuttable insert box of the present invention.

Fig. 4 is a schematic structural view of the removable winding drum structure of the present invention.

Fig. 5 is a schematic structural diagram of the structure of the pushing plate rack of the invention.

Fig. 6 is a schematic electrical wiring diagram of the present invention.

In the figure:

1. a frame; 2. a first support plate; 3. a second support plate; 4. a support bar; 5. a bushing; 6. the fiber is inserted into the cooling box structure; 61. a fixing plate; 62. an outer shroud; 63. a heat sink; 64. a mounting seat; 65. installing a frame; 66. a support sheet; 67. a heat radiation fan; 68. a copper circulation pipe; 7. an oiling device; 8. a cluster motor; 9. a cluster wheel axle; 10. a fiber cluster wheel; 11. the structure of the inserting box can be cut; 111. inserting the main box; 112. an upper cannula is penetrated; 113. a supporting seat; 114. inserting a tube downwards; 115. a cutting cylinder; 116. assembling a seat; 117. cutting knife; 12. inserting the socket; 13. a steel conveying plate; 14. a positioning motor; 15. a ball screw; 16. a detachable winding drum structure; 161. a confinement plate; 162. a connecting shaft; 163. inserting holes; 164. mounting blocks; 165. clamping the screw rod; 166. inserting the column; 167. winding the main cylinder; 17. a push plate frame structure; 171. a vertical plate; 172. a socket joint seat; 173. assembling edges; 174. a push cylinder; 175. pushing the mainboard; 176. assembling the head; 18. a PLC; 19. a drive switch; 20. a movable seat; 21. a wire drawing motor.

Detailed Description

The invention is further described below with reference to the accompanying drawings:

example (b):

as shown in fig. 1 to 2, an intelligent beam splitting glass fiber drawing machine comprises a frame 1, a first support plate 2, a second support plate 3, a support rod 4, a bushing 5, a fiber penetrating and cooling box structure 6, an oiling device 7, a bundling motor 8, a bundling wheel shaft 9, a fiber bundling wheel 10, a cuttable and penetrating box structure 11, a penetrating port 12, a steel conveying plate 13, a positioning motor 14, a ball screw 15, a detachable winding drum structure 16, a pushing plate frame structure 17, a PLC18, a driving switch 19, a moving seat 20 and a drawing motor 21, wherein the first support plate 2 is welded on the middle upper part of the inner wall of the frame 1; the second supporting plate 3 is welded in the middle of the inner wall of the frame 1; the support rods 4 are respectively welded at the right side and the middle part of the front part and the rear part of the upper end of the frame 1; the bushing 5 is arranged at the upper end of the support rod 4 by bolts; the fiber interpenetration cooling box structure 6 is arranged on the support rod 4; the oiling device 7 is arranged on the right side of the upper end of the first supporting plate 2; the bundling motor 8 is arranged on the left side of the upper surface of the second supporting plate 3 through a bolt; one end of the cluster wheel shaft 9 is connected with an output shaft coupler of the cluster motor 8, and the other end of the cluster wheel shaft is arranged in the middle of the right side of the inner wall of the rack 1 through a bearing; the fiber bundling wheels 10 are respectively connected with the left side, the right side and the middle part of the outer wall of the bundling wheel shaft 9 in a key way; the cuttable penetrating box structure 11 is arranged on the right side inside the second supporting plate 3; the penetrating port 12 is arranged below the right side in the rack 1; the steel conveying plate 13 is welded at the lower part of the inner wall of the inserting hole 12; the position adjusting motor 14 is mounted on the lower portion of the left end of the rack 1 through a bolt, and an output shaft of the position adjusting motor 14 is connected with a ball screw 15 through a coupler; the right end of the ball screw 15 is arranged at the lower part of the right side of the inner wall of the frame 1 through a bearing; the detachable winding drum structure 16 is arranged on a wire drawing motor 21; the pushing plate frame structures 17 are respectively arranged at the front side and the rear side of the upper part of the moving seat 20; the PLC18 bolt is arranged at the middle lower part of the left end of the frame 1, and the front surface of the PLC18 is electrically connected with a driving switch 19; the lower part of the moving seat 20 is mounted on the ball screw 15 through a bolt, and the upper end of the moving seat 20 is mounted with a wire drawing motor 21 through a bolt; the fiber penetrating cooling box structure 6 comprises a fixing plate 61, an outer protective plate 62, a radiating fin 63, a mounting seat 64, a mounting frame 65, a supporting sheet 66, a radiating fan 67 and a copper circulating pipe 68, wherein the fixing plate 61 is welded at the left ends of the outer protective plate 62 and the radiating fin 63; the mounting seats 64 are respectively welded on the left side and the right side of the outer wall of the outer guard plate 62; the mounting frame 65 is welded at the right ends of the outer guard plate 62 and the radiating fins 63; the supporting sheet 66 is welded on the inner wall of the mounting frame 65, and a copper circulating pipe 68 is embedded in the supporting sheet 66; the heat radiation fan 67 is mounted at the right end of the mounting frame 65 through bolts; the heat radiation fan 67 is driven to blow air, and simultaneously, cooling liquid is injected into the copper circulating pipe 68, so that the glass fiber can be cooled and used by matching with the heat radiation fins 63.

As shown in fig. 3, in the above embodiment, specifically, the structure 11 of the cuttable insertion box includes an insertion main box 111, an upper insertion pipe 112, a supporting base 113, a lower insertion pipe 114, a cutting cylinder 115, an assembling base 116 and a cutting knife 117, wherein the upper insertion pipe 112 is welded on the left side, the right side and the middle part above the inside of the insertion main box 111; the supporting seat 113 is welded between the upper penetrating insertion pipe 112 and the lower penetrating insertion pipe 114; the cutting cylinders 115 are respectively installed on the left side and the right side of the front end of the penetrating main box 111 through bolts; the assembling seat 116 is mounted on an output shaft of the cutting cylinder 115 through bolts; the cutting knife 117 is inserted into the assembling seat 116 and fixed by bolts; the cutting cylinder 115 is driven to drive the cutting knife 117 to move, so that the glass fiber passing through the upper penetrating pipe 112 and the lower penetrating pipe 114 is cut.

As shown in fig. 4, in the above embodiment, specifically, the detachable winding drum structure 16 includes a limiting disc 161, a connecting shaft 162, a through hole 163, a mounting block 164, a clamping screw 165, an insertion column 166 and a winding main drum 167, and the connecting shaft 162 is welded at the middle part of the left end of the limiting disc 161; the through holes 163 are respectively arranged at the front side and the rear side inside the limiting disc 161; the mounting block 164 is welded on the upper part and the lower part of the right surface of the limiting disc 161 respectively, and the internal thread of the mounting block 164 is connected with a clamping screw 165; the insertion column 166 is welded in the middle of the right end of the limiting disc 161; the winding main cylinder 167 is sleeved on the outer side of the plug column 166.

As shown in fig. 5, in the above embodiment, specifically, the pushing plate frame structure 17 includes a vertical plate 171, a sleeve seat 172, an assembling edge 173, a pushing cylinder 174, a pushing main plate 175 and an assembling head 176, wherein the assembling edge 173 is welded to the upper end and the lower end of the sleeve seat 172; the assembling edge 173 is installed on the outer side of the vertical plate 171 through bolts; the pushing cylinder 174 is placed inside the socket 172; an assembly head 176 is welded at the left end of the pushing main board 175; the assembly head 176 is bolted to the output shaft of the push cylinder 174.

In the above embodiment, specifically, a plurality of heat dissipation fins 63 are provided between the fixing plate 61 and the mounting frame 65, the heat dissipation fins 63 are made of copper sheets, and the upper portions of the heat dissipation fins 63 correspond to the bushing 5, so that when in use, glass fibers can penetrate through the heat dissipation fins 63 to perform a heat dissipation protection function.

In the above embodiment, specifically, the left and right sides of the mounting frame 65 are provided with openings, the plurality of supporting sheets 66 are arranged inside the mounting frame 65, the copper circulating pipe 68 is supported by the supporting sheets 66, so that the mounting is facilitated by matching with the copper circulating pipe 68, and meanwhile, the cooling liquid is conveniently injected into the copper circulating pipe 68, so as to assist the heat dissipation operation of the heat dissipation fins 63.

In the above embodiment, specifically, the mounting seat 64 is provided with a C-shaped hole inside, and the front portion of the mounting seat 64 is provided with a bolt, so that during installation, the mounting seat 64 is conveniently sleeved on the support rod 4 and fixed by the bolt, thereby facilitating installation and use or disassembly and maintenance.

In the above embodiment, specifically, the main penetrating box 111 is welded on the right side inside the second support plate 3, three penetrating pipes 112 are arranged inside the main penetrating box 111, and the upper ends of the penetrating pipes 112 correspond to the fiber bundling wheel 10, so that the glass fibers are conveniently penetrated and pass through the penetrating pipes, and the glass fibers are better processed and used.

In the above embodiment, specifically, the cutting blade 117 on the output shaft of the cutting cylinder 115 is arranged at the front of the supporting base 113, the glass fiber is inserted between the supporting base 113 and the cutting blade 117, and after the cutting cylinder 115 is driven, the cutting blade 117 is driven to move so as to cooperate with the supporting base 113 to cut the glass fiber, so that the functionality is increased.

In the above embodiment, specifically, the assembling seat 116 is configured to be U-shaped, and the cutting knife 117 is fixed inside the assembling seat 116 through a bolt, so that the assembling seat is convenient to be installed or detached in cooperation with the cutting knife 117, and is convenient to replace.

In the above embodiment, specifically, the winding main cylinder 167 is adapted to the plug-in post 166 and fixed by the clamping screw 165, so that the winding main cylinder 167 can be conveniently assembled and disassembled, and after the winding main cylinder 167 finishes the drawing and winding of the glass fiber, a new winding main cylinder 167 can be conveniently replaced, and further, the function of storing the glass fiber is achieved.

In the above embodiment, specifically, the mounting block 164 is rectangular, the internal clamping screw 165 is T-shaped, and after the winding main cylinder 167 is inserted into the inner side of the mounting block 164, the clamping screw 165 is screwed to be fixed against the winding main cylinder 167 for use.

In the above embodiment, specifically, two insertion holes 163 are provided in the limiting disc 161, the left end of each insertion hole 163 corresponds to the pushing main board 175, and the connecting shaft 162 at the left end of the limiting disc 161 is coupled to the output shaft of the wire drawing motor 21, so that the limiting disc 161 is conveniently installed and driven to rotate, and the winding main cylinder 167 is better driven to rotate and perform wire drawing.

In the above embodiment, specifically, the vertical plate 171 is welded at the front and rear portions of the upper surface of the movable seat 20, the sleeve seat 172 on the vertical plate 171 is U-shaped, and the sleeve seat 172 is matched with the assembling edge 173 to fix the pushing cylinder 174, so that the pushing cylinder 174 can be conveniently installed and used, and the pushing cylinder 174 can be conveniently detached and maintained.

In the above embodiment, specifically, the pushing main board 175 is connected to the pushing cylinder 174 through the assembling head 176, and when the pushing cylinder 174 is driven to drive the pushing main board 175 to move, the pushing main board 175 can pass through the through hole 163 to drive the winding main cylinder 167 to separate.

In the above embodiment, the bundling motor 8 is a motor with a model of TCH/V-750.

In the above embodiment, specifically, the positioning motor 14 is a motor of model HJX57 RO.

In the above embodiment, specifically, the PLC18 is a PLC of model FX 2N-48.

In the above embodiment, the wire drawing motor 21 is a motor with model number TCH/V-750.

In the above embodiment, the heat dissipation fan 67 is a fan with a model number of 130-WYS 5-2.

In the above embodiment, the cutting cylinder 115 is a cylinder of an SDA type.

In the above embodiment, specifically, the pushing cylinder 174 is an SC50 type cylinder.

In the above embodiment, specifically, the driving switch 19 is electrically connected to an input terminal of the PLC18, the cluster motor 8 is electrically connected to an output terminal of the PLC18, the positioning motor 14 is electrically connected to an output terminal of the PLC18, the wire drawing motor 21 is electrically connected to an output terminal of the PLC18, the heat dissipation fan 67 is electrically connected to an output terminal of the PLC18, the cutting cylinder 115 is electrically connected to an output terminal of the PLC18, and the pushing cylinder 174 is electrically connected to an output terminal of the PLC18, so that the control and the use are more intelligent.

Principle of operation

The working principle of the invention is as follows: when the glass fiber drawing machine is used, firstly, glass fibers are drawn to penetrate through the bushing 5, the oiling device 7 and the fiber bundling wheel 10 to be wound on the cooling fan 67, then the wire drawing motor 21 is driven to drive the winding main cylinder 167 to rotate, so that wire drawing is carried out, in the working process, the bundling motor 8 is driven to drive the fiber bundling wheel 10 to rotate, so that glass fibers are bundled, then, the glass fibers are coated with oil when passing through the oiling device 7, finally, in the use process, the cooling fan 67 is driven to blow air, meanwhile, cooling liquid is injected into the copper circulating pipe 68, so that the glass fibers can be cooled and used by matching with the cooling fins 63, after the use is finished, the cutting cylinder 115 is driven to drive the cutting knife 117 to move, so that the glass fibers passing through the upper penetrating pipe 112 and the lower penetrating pipe 114 are cut, after the cutting is finished, the clamping screw 165 is rotated to loosen with the winding main cylinder 167, finally, the pushing cylinder 174 is driven to drive the pushing main board 175 to, the winding main cylinder 167 can be pushed to separate from the plug column 166, and then the winding main cylinder 167 reaches the steel conveying plate 13 and falls down, and a new winding main cylinder 167 can be installed to continue to be used while the detachment is completed.

The technical solutions of the present invention or similar technical solutions designed by those skilled in the art based on the teachings of the technical solutions of the present invention are all within the scope of the present invention.

Claims (10)

1. The intelligent beam splitting glass fiber drawing machine is characterized by comprising a machine frame (1), a first supporting plate (2), a second supporting plate (3), a supporting rod (4), a bushing plate (5), a fiber penetrating and cooling box structure (6), an oiling device (7), a bundling motor (8), a bundling wheel shaft (9), a fiber bundling wheel (10), a cutting and penetrating box structure (11), penetrating ports (12), a steel conveying plate (13), a positioning motor (14), a ball screw (15), a detachable winding cylinder structure (16), a pushing plate frame structure (17), a PLC (18), a driving switch (19), a moving seat (20) and a drawing motor (21), wherein the first supporting plate (2) is welded on the middle upper part of the inner wall of the machine frame (1); the second supporting plate (3) is welded in the middle of the inner wall of the rack (1); the support rods (4) are respectively welded at the right side and the middle part of the front part and the rear part of the upper end of the rack (1); the bushing plate (5) is arranged at the upper end of the support rod (4) by bolts; the fiber interpenetration cooling box structure (6) is arranged on the support rod (4); the oiling device (7) is arranged on the right side of the upper end of the first supporting plate (2); the bundling motor (8) is arranged on the left side of the upper surface of the second supporting plate (3) through a bolt; one end of the cluster wheel shaft (9) is connected with an output shaft coupler of the cluster motor (8), and the other end of the cluster wheel shaft is arranged in the middle of the right side of the inner wall of the rack (1) through a bearing; the fiber bundling wheel (10) is respectively connected with the left side, the right side and the middle part of the outer wall of the bundling wheel shaft (9) in a key mode; the cuttable inserting box structure (11) is arranged on the right side inside the second supporting plate (3); the inserting hole (12) is formed in the lower portion of the right side of the inner portion of the rack (1); the steel conveying plate (13) is welded at the lower part of the inner wall of the inserting hole (12); the positioning motor (14) is arranged at the lower part of the left end of the rack (1) through a bolt, and an output shaft of the positioning motor (14) is connected with a ball screw (15) through a coupler; the right end of the ball screw (15) is arranged at the lower part of the right side of the inner wall of the frame (1) through a bearing; the detachable winding drum structure (16) is arranged on the wire drawing motor (21); the pushing plate frame structures (17) are respectively arranged on the front side and the rear side of the upper part of the moving seat (20); the PLC (18) is installed at the middle lower part of the left end of the rack (1) through a bolt, and meanwhile, the front surface of the PLC (18) is electrically connected with a driving switch (19); the lower part of the moving seat (20) is arranged on the ball screw (15) through a bolt, and the upper end of the moving seat (20) is provided with a wire drawing motor (21) through a bolt; the fiber interpenetration cooling box structure (6) comprises a fixing plate (61), an outer guard plate (62), a radiating fin (63), a mounting seat (64), a mounting frame (65), a supporting sheet (66), a radiating fan (67) and a copper circulating pipe (68), wherein the fixing plate (61) is welded at the left ends of the outer guard plate (62) and the radiating fin (63); the mounting seats (64) are respectively welded on the left side and the right side of the outer wall of the outer guard plate (62); the mounting frame (65) is welded at the right ends of the outer guard plate (62) and the radiating fins (63); the supporting sheet (66) is welded on the inner wall of the mounting frame (65), and a copper circulating pipe (68) is embedded in the supporting sheet (66); the heat radiation fan (67) is installed at the right end of the installation frame (65) through bolts; the structure (11) of the cutting penetrating box comprises a penetrating main box (111), an upper penetrating insertion pipe (112), a supporting seat (113), a lower penetrating insertion pipe (114), a cutting air cylinder (115), an assembling seat (116) and a cutting knife (117), wherein the upper penetrating insertion pipe (112) is welded on the left side, the right side and the middle part above the inside of the penetrating main box (111) respectively; the supporting seat (113) is welded between the upper penetrating insertion pipe (112) and the lower penetrating insertion pipe (114); the cutting cylinders (115) are respectively installed on the left side and the right side of the front end of the penetrating main box (111) through bolts; the assembling seat (116) is mounted on an output shaft of the cutting cylinder (115) through a bolt; the cutting knife (117) is inserted into the assembling seat (116) and fixed by a bolt; the detachable winding barrel structure (16) comprises a limiting plate (161), a connecting shaft (162), a through hole (163), an installation block (164), a clamping screw (165), an insertion column (166) and a winding main barrel (167), wherein the connecting shaft (162) is welded in the middle of the left end of the limiting plate (161); the through insertion holes (163) are respectively arranged at the front side and the rear side inside the limiting disc (161); the mounting blocks (164) are respectively welded on the upper part and the lower part of the right surface of the limiting disc (161), and the internal threads of the mounting blocks (164) are connected with clamping screws (165); the insertion column (166) is welded in the middle of the right end of the limiting disc (161); the winding main cylinder (167) is sleeved on the outer side of the plug column (166).

2. The intelligent split-beam glass fiber drawing machine according to claim 1, wherein the pushing plate frame structure (17) comprises a vertical plate (171), a sleeve seat (172), an assembling edge (173), a pushing cylinder (174), a pushing main plate (175) and an assembling head (176), wherein the assembling edge (173) is welded to the upper end and the lower end of the sleeve seat (172) respectively; the assembling edge (173) is installed on the outer side of the vertical plate (171) through bolts; the pushing cylinder (174) is placed inside the sleeving seat (172); an assembly head (176) is welded at the left end of the pushing main board (175); the assembling head (176) is mounted on an output shaft of the pushing cylinder (174) through bolts.

3. The intelligent split-beam glass fiber drawing machine as claimed in claim 1, wherein a plurality of heat radiating fins (63) are arranged between the fixing plate (61) and the mounting frame (65), and the heat radiating fins (63) are made of copper sheets and correspond to the bushing plate (5) from the upper side.

4. The intelligent split-beam glass fiber drawing machine according to claim 1, wherein openings are formed in the left side and the right side of the mounting frame (65), a plurality of supporting sheets (66) are arranged inside the mounting frame (65), and the copper circulating pipe (68) is supported by the supporting sheets (66).

5. The intelligent split-beam glass fiber drawing machine according to claim 1, wherein the cutting blade (117) on the output shaft of the cutting cylinder (115) is arranged at the front part of the support base (113), and the glass fiber is inserted between the support base (113) and the cutting blade (117).

6. The intelligent split-glass fiber drawing machine according to claim 1, wherein the assembly base (116) is provided with a U-shape, and a cutting blade (117) is fixed inside the assembly base (116) through a bolt.

7. The intelligent split-beam glass fiber drawing machine as claimed in claim 1, wherein said winding main cylinder (167) is fitted with a plug post (166) and fixed by a clamping screw (165).

8. The intelligent split-glass fiber drawing machine according to claim 1, wherein said mounting block (164) is configured as a rectangle, while the internal clamping screw (165) is configured as a T-shape.

9. The intelligent split-beam glass fiber drawing machine according to claim 1, wherein two through holes (163) are arranged in the limiting disc (161), the left end of each through hole (163) corresponds to the pushing main board (175), and the connecting shaft (162) at the left end of the limiting disc (161) is in coupling connection with the output shaft of the drawing motor (21).

10. The intelligent split-beam glass fiber drawing machine according to claim 2, wherein said pusher main plate (175) is connected to a pusher cylinder (174) through an assembly head (176).

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