CN117162531B - Full-automatic multidimensional winding system for impregnated fiber sleeve - Google Patents
Full-automatic multidimensional winding system for impregnated fiber sleeve Download PDFInfo
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- CN117162531B CN117162531B CN202311448809.6A CN202311448809A CN117162531B CN 117162531 B CN117162531 B CN 117162531B CN 202311448809 A CN202311448809 A CN 202311448809A CN 117162531 B CN117162531 B CN 117162531B
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- 238000004804 winding Methods 0.000 title claims abstract description 65
- 239000000835 fiber Substances 0.000 title claims abstract description 22
- 239000003365 glass fiber Substances 0.000 claims abstract description 100
- 229920005989 resin Polymers 0.000 claims abstract description 40
- 239000011347 resin Substances 0.000 claims abstract description 40
- 238000010008 shearing Methods 0.000 claims abstract description 16
- 238000007599 discharging Methods 0.000 claims abstract description 12
- 238000007667 floating Methods 0.000 claims description 59
- 238000007598 dipping method Methods 0.000 claims description 29
- 230000001681 protective effect Effects 0.000 claims description 17
- 238000003825 pressing Methods 0.000 claims description 13
- 238000009434 installation Methods 0.000 claims description 9
- 239000007788 liquid Substances 0.000 claims description 5
- 230000001105 regulatory effect Effects 0.000 claims description 4
- 238000012806 monitoring device Methods 0.000 claims description 3
- 238000002791 soaking Methods 0.000 claims description 2
- 239000003292 glue Substances 0.000 claims 1
- 238000004519 manufacturing process Methods 0.000 description 8
- 239000003822 epoxy resin Substances 0.000 description 4
- 238000005470 impregnation Methods 0.000 description 4
- 229920000647 polyepoxide Polymers 0.000 description 4
- 230000001276 controlling effect Effects 0.000 description 3
- 239000003990 capacitor Substances 0.000 description 2
- 238000010586 diagram Methods 0.000 description 2
- 230000006698 induction Effects 0.000 description 2
- 239000011229 interlayer Substances 0.000 description 2
- 239000010410 layer Substances 0.000 description 2
- 239000011259 mixed solution Substances 0.000 description 2
- 238000012544 monitoring process Methods 0.000 description 2
- 238000007790 scraping Methods 0.000 description 2
- 238000012216 screening Methods 0.000 description 2
- 230000009286 beneficial effect Effects 0.000 description 1
- 230000005540 biological transmission Effects 0.000 description 1
- 230000008859 change Effects 0.000 description 1
- 239000011521 glass Substances 0.000 description 1
- 230000003993 interaction Effects 0.000 description 1
- 230000004807 localization Effects 0.000 description 1
- 239000000463 material Substances 0.000 description 1
- 238000000034 method Methods 0.000 description 1
- 239000000203 mixture Substances 0.000 description 1
- 230000008569 process Effects 0.000 description 1
- 239000000243 solution Substances 0.000 description 1
- 230000009466 transformation Effects 0.000 description 1
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Abstract
The full-automatic multidimensional winding system for the impregnated fiber sleeve comprises an operation platform and a moving platform, wherein a creel, a low-stop-band discharging device and a glass fiber impregnating device are arranged in the operation platform, and the low-stop-band discharging device and the glass fiber impregnating device are arranged in front of the creel side by side; the low-stop band discharge device comprises a discharge platform, wherein the discharge platform is provided with a resin tank, a discharge device is arranged in the resin tank, and the rear end of the discharge platform is provided with a low-stop band shearing and laying device; the glass fiber impregnating device comprises a glass fiber impregnating tank, a glass fiber winding device is arranged in the glass fiber impregnating tank, and a glass fiber shearing and laying device is arranged behind the glass fiber impregnating tank; the mobile platform comprises a winding mandrel and an operation platform moving device, and the operation platform moving device is used for moving the winding mandrel; the winding mandrel comprises a mandrel, a mandrel bearing and a mandrel driving device; the winding mandrel is arranged in front of the operating platform, and the mandrel corresponds to the outlet end of the glass fiber winding device and the outlet end of the tape dispenser.
Description
Technical Field
The invention relates to the field of manufacturing of intelligent power transmission and transformation equipment, in particular to a full-automatic multi-dimensional winding system for impregnated fiber sleeves.
Background
The electric power industry rapidly develops, the safe operation of the extra-high voltage electric power equipment is very important, and especially the extra-high voltage alternating current/direct current sleeve for the power grid engineering always uses imported product equipment such as ABB, siemens and the like, so that the overall localization of the extra-high voltage electric power equipment is restricted; the gum dipping fiber dry type bushing of the Chinese autonomous invention is limited by equipment, the ultra-high voltage AC/DC power grid engineering is not broken through, and a plurality of problems exist in the manufacturing field of the dipping fiber bushing at present, such as the problems that the thickness control between glass fiber layers, the winding angle control, the winding tension control of glass fiber, the bubble control of glass fiber dipping, the manual winding of a capacitor screen can not reach the process size requirement in the manufacturing process of the gum dipping fiber dry type bushing main insulating capacitor core body. And the problem of high manufacturing cost due to the need for a large number of manpower is unavoidable.
Disclosure of Invention
In order to solve the problems, the invention provides the following scheme:
the full-automatic multidimensional winding system for the impregnated fiber sleeve comprises an operation platform and a moving platform, wherein a creel, a low-stop-band discharging device and a glass fiber impregnating device are arranged in the operation platform, and the low-stop-band discharging device and the glass fiber impregnating device are arranged in front of the creel side by side; the low-stop-band tape releasing device comprises a tape releasing platform, wherein the tape releasing platform is provided with a resin groove, a tape releasing device is arranged in the resin groove, and a low-stop-band shearing and laying device is arranged behind the resin groove; the glass fiber impregnating device comprises a glass fiber impregnating tank, a glass fiber winding device is arranged in the glass fiber impregnating tank, and a glass fiber shearing and laying device is arranged behind the glass fiber impregnating tank; the mobile platform comprises a mandrel and an operation platform moving device, the operation platform moving device comprises a support guide rail and a driving guide rail, a support sliding block is arranged on the support guide rail, a driving sliding block is arranged on the driving guide rail, the bottom of the operation platform is fixed with the support sliding block and the driving sliding block, and the driving sliding block is connected with a driving motor; the winding mandrel comprises a mandrel, a mandrel bearing and a mandrel driving device, wherein two ends of the mandrel are respectively connected with the mandrel driving device and the mandrel bearing, and the mandrel driving device drives the mandrel to rotate; the winding mandrel is arranged at the rear side of the operation platform.
Further, the belt releasing device comprises a circumferential anti-slip rotating wheel and a tension roller which are arranged in the resin groove, a pressure roller arranged at the front end of the resin groove and a fastening wheel arranged at the rear end of the resin groove; the front end of the resin tank extends forwards to form a roller bracket, and a guide roller is arranged in the roller bracket; the pressure roller can move up and down along the resin tank; a diameter monitoring device is arranged between the resin groove and the fastening wheel.
Further, the two ends of the pressure roller are connected with pressure cylinders, the pressure cylinders drive the pressure roller to move up and down, and the top of each pressure cylinder is provided with a pressure regulating valve.
Further, the glass fiber winding device comprises a pressing device arranged at the front end of the glass fiber dipping tank, a glass fiber circumferential roller arranged in the glass fiber dipping tank, a resin regulator arranged in front of the glass fiber circumferential roller, a rubber scraper arranged at the rear end of the glass fiber dipping tank and a floating roller device arranged at the rear end of the glass fiber dipping tank; and a temperature sensor and a liquid level sensor are also arranged in the glass fiber dipping tank.
Further, the floating roller device comprises a floating support, a plurality of fixed rollers are arranged at the bottom of the floating support, floating rollers are arranged above the fixed rollers, the floating rollers are arranged in a floating roller installation frame, the top end of the floating roller installation frame is connected with a floating cylinder, the floating cylinder is fixed with the floating support, and the floating cylinder stretches and contracts to drive the floating roller installation frame to move up and down along the floating support.
Further, glass fiber impregnation groove front end still is provided with the entry support, and entry support front end and rear end all are provided with entry comb spare, and entry support middle part sets up pressure control device, pressure control device is including compressing tightly end and rotation end, rotation end and entry support lateral wall rotate to be connected, compress tightly the end and rotate the end and be connected through the connecting plate, compress tightly the end and rotate with the connecting plate to be connected, and compress tightly the end and be located the entry comb spare of rear end and offset.
Further, a safety guard rail is arranged around the operation platform, at least one protective door is arranged on the safety guard rail, an alarm is arranged on the protective door, and the alarm is electrically connected with or in signal connection with a device in the operation platform and controls the opening and closing of the device; the safety protection door is used as an entrance safety door, and an entrance ladder is arranged outside the safety protection door.
Further, a circuit track is further arranged below the operation platform, and a power data line energy chain for providing power for the operation platform and transmitting data is arranged in the circuit track.
Further, the edge of the operation platform is also provided with a plane scanner.
Further, a mandrel bearing moving guide rail is further arranged below the mandrel bearing, a mandrel bearing moving block is arranged at the lower end of the mandrel bearing, and the mandrel bearing moving block can slide along the mandrel bearing moving guide rail.
The invention has the beneficial effects that:
1. the full-automatic winding system for the impregnated fiber sleeve is realized without manual intervention in the production and manufacturing process.
2. The functions of automatic glass fiber interlayer thickness control, winding angle control, glass fiber winding tension control, glass fiber dipping bubble control and the like are realized through the control of the tape dispenser and the glass fiber winding device.
3. The protective doors are provided with alarm devices, so long as one protective door is opened, the operation of the operation platform is stopped, and after the protective door is closed, the operation platform is restarted, so that the safety of personnel in and out is ensured.
4. The spindle bearing moves along the spindle bearing moving guide rail, so that the change of the distance between the spindle bearing and the spindle driving device is realized, and spindles with different lengths can be adapted.
Drawings
FIG. 1 is a schematic diagram of an operation platform;
FIG. 2 is a schematic diagram of the structure of the present invention;
FIG. 3 is a schematic view of a glass fiber winding device;
fig. 4 is a schematic view of a tape dispenser.
1. The device comprises a first protective door, a belt discharger, a low stop-band shearing and laying device, a glass fiber winding device, a floating roller device, a glass fiber shearing and laying device, a glass fiber winding device, a floating roller device and a glass fiber shearing and laying device, wherein the first protective door, the belt discharger, the low stop-band shearing and laying device, the glass fiber winding device, the floating roller device and the glass fiber winding device are arranged in sequence, and the glass fiber shearing and laying device is arranged in sequence. 7, a glass fiber angle controller, 8, a second protective door, 9, a main operation panel, 10, a safety guard rail, 11, a first plane scanner inlet safety door, inlet step, creel, second plane scanner, operating platform, control power cabinet, mandrel driving device, mandrel bearing moving guide rail, mandrel bearing, support rail, drive guide rail, and power line energy chain, wherein the support rail is a guide rail, and the power line energy chain is a guide rail, a guide rail is a guide rail, and the power line energy chain is a guide rail. 25. The device comprises floating roll cylinders 26, first floating rolls 27, second fixed floating rolls 28, third fixed floating rolls 29, a rubber scraper 30, a temperature sensor 31, a glass fiber circumferential roller 32, a liquid level sensor 33, a resin regulator 34, a first outlet comb, 35, first fixed floating rolls 36, a moving driving device 37, a second outlet comb, 38, a glass fiber dipping tank, 39, a compacting device 40, a first inlet comb, 41, a pressure controller 42 and a second inlet comb. 43. Guide rollers, 44, pressure regulating valve, 45, pressure rollers, 46, annular anti-slip wheel, 47, tension rollers, 48, fastening wheel, 49, annular rollers, 50, temperature controller, 51, resin tank, 52, diameter monitoring sensor, 53, low stop band winder.
Detailed Description
The present invention will now be described in detail with reference to the accompanying drawings:
example 1: 1-4, a full-automatic multidimensional winding system for impregnated fiber sleeve comprises an operation platform 16 and a moving platform, wherein a creel 14, a low-stop-band discharging device and a glass fiber impregnating device are arranged in the operation platform 16, and the low-stop-band discharging device and the glass fiber impregnating device are arranged in front of the creel 4 side by side; the low-stop-band tape discharging device comprises a tape discharging platform, wherein the tape discharging platform is provided with a resin groove 51, a tape discharging device 2 is arranged in the resin groove 51, and a low-stop-band shearing and laying device 3 is arranged behind the resin groove 51; the glass fiber impregnating device comprises a glass fiber impregnating tank 38, a glass fiber winding device 4 is arranged in the glass fiber impregnating tank 38, and a glass fiber shearing and laying device 6 is arranged behind the glass fiber impregnating tank 38; the mobile platform comprises a mandrel 19 and an operation platform moving device, the operation platform moving device comprises a support guide rail 22 and a drive guide rail 23, a support slide block is arranged on the support guide rail 22, a drive slide block is arranged on the drive guide rail 23, the bottom of the operation platform 16 is fixed with the support slide block and the drive slide block, and the drive slide block is connected with a drive motor; the winding mandrel comprises a mandrel 19, a mandrel bearing 21 and a mandrel driving device 18, wherein two ends of the mandrel 19 are respectively connected with the mandrel driving device 18 and the mandrel bearing 21, and the mandrel driving device 18 drives the mandrel 19 to rotate; the winding mandrel is disposed on the rear side of the operating platform 16.
The belt feeder 2 comprises a circumferential anti-slip rotating wheel 46 and a tension roller 47 which are arranged in a resin groove 51, a circumferential roller 49 below the circumferential anti-slip rotating wheel 46, a pressure roller 45 arranged at the front end of the resin groove 51 and a fastening wheel 48 arranged at the rear end of the resin groove 51; a roller bracket is extended forward from the front end of the resin tank 51, and a guide roller 43 is arranged in the roller bracket; the pressure roller 45 can move up and down along the resin tank 51; a diameter monitoring device 52 is arranged between the resin tank 51 and the fastening wheel 48, and a temperature controller 50 is arranged at the bottom of the resin tank.
The two ends of the pressure roller 45 are connected with pressure cylinders, the pressure cylinders drive the pressure roller 45 to move up and down, and the top of each pressure cylinder is provided with a pressure regulating valve 44.
The glass fiber winding device 4 comprises a pressing device 39 arranged at the front end of a glass fiber dipping tank 38, a glass fiber circumferential roller 31 arranged in the glass fiber dipping tank 38, a resin regulator 33 arranged in front of the glass fiber circumferential roller 31, a doctor 29 arranged at the rear of the glass fiber dipping tank 38 and a floating roller device 5 arranged at the rear end of the glass fiber dipping tank 38; a temperature sensor 30 and a liquid level sensor 32 are also provided in the glass fiber impregnation tank 38.
The pressing device 39 comprises a pressing plate arranged on the front end face of the glass fiber dipping tank 38, and the pressing plate is used for pressing the glass fiber passing through the pressing plate and the front end face of the glass fiber dipping tank 38.
The doctor 29 comprises two groups of sliding blocks, the sliding blocks are sleeved on the side wall of the glass fiber dipping tank 38 and can slide back and forth along the glass fiber dipping tank 38, the doctor bars are arranged between each group of sliding blocks, and the resin thickness passing through the surface of the glass fiber between the two doctor bars is controlled by changing the distance between the two groups of doctor bars.
The floating roll device 5 comprises a floating support, a first fixed floating roll 35, a second fixed floating roll 27 and a third fixed floating roll 28 are arranged at the bottom of the floating support, a first floating roll 26 and a second floating roll are arranged above the fixed rolls, the floating rolls are arranged in a floating roll installation frame, the top end of the floating roll installation frame is connected with a floating cylinder 25, the floating cylinder 25 is fixed with the floating support, and the floating cylinder 25 stretches and contracts to drive the floating roll installation frame to move up and down along the floating support.
The front end of the glass fiber dipping tank 38 is also provided with an inlet bracket, the front end and the rear end of the inlet bracket are respectively provided with a first inlet comb 40 and a second inlet comb 42, the middle part of the inlet bracket is provided with a pressure control device 41, the pressure control device 41 comprises a pressing end and a rotating end, the rotating end is rotationally connected with the side wall of the inlet bracket, the pressing end is connected with the rotating end through a connecting plate, the pressing end is rotationally connected with the connecting plate, and the pressing end is propped against the first inlet comb 40; a second outlet comb 37 is arranged between the third fixed floating roller 28 and the doctor 29, and a first outlet comb 34 is arranged behind the first fixed floating roller. The bottom of the fiber impregnation tank 38 is also provided with a movement driving device 36 for adjusting the position of the fiber impregnation tank 38.
The safety guard rail 10 is arranged around the operation platform, the safety guard rail 10 is provided with three protective doors, the protective doors are provided with alarms, and the alarms are electrically connected or in signal connection with devices in the operation platform 16 and control the opening and closing of the devices; the entrance safety door 12 is taken as the entrance safety door 12, an entrance ladder 13 is arranged outside the entrance safety door 12, and the other two safety doors 12 are respectively the first safety door 1 and the second safety door 8.
A circuit track is also arranged under the operation platform, and a power data line energy chain 24 for providing power supply for the operation platform and transmitting data is arranged in the circuit track.
The left and right edges of the operation platform 16 are respectively provided with a first plane scanner 11 and a second plane scanner 15.
The lower part of the mandrel bearing 21 is also provided with a mandrel bearing moving guide rail 20, the lower end of the mandrel bearing 21 is provided with a mandrel bearing moving block, and the mandrel bearing moving block can slide along the mandrel bearing moving guide rail 20.
The full-automatic multidimensional winding system of the impregnated fiber sleeve is mainly driven by equipment through an electric control cabinet. The control commands are transmitted in real time through the power data line energy chain 24. The man-machine interaction of the control program and the control command is input and output through the main operation panel 9. The operation platform 16 is driven to move left and right on the support rail 22 by a motor driving the guide rail 23. The mandrel 19 is fixed on the mandrel driving device 18 and the mandrel bearing 21, the rotation function of the mandrel 19 is realized through a servo motor, the rotation can be controlled by controlling the speed of the servo motor, and the servo motor is powered and controlled by the control power supply cabinet 17.
Low stop band winding control mode: the low stop band is pulled out and stretched by a low stop band winder 53, and the low stop band end is wound on a fastening wheel 48 by sequentially passing through the low stop band shearing and laying device 3 and then wound on a mandrel 19, wherein the lower stop band end is positioned above a guide roller 43, below a pressure roller 45, between a circumferential roller 49 and a circumferential anti-slip rotating wheel 46, below a tension roller 47; an infrared sensing system (such as a liquid level sensor and a diameter monitoring sensor 52) is arranged in the resin tank 51, and after the epoxy resin material in the resin tank 51 is lower than a set value, the system automatically performs filling without manual intervention; uniformly soaking the epoxy resin mixed solution into the low stop band by adjusting the pressure value of a pressure cylinder connected with the pressure roller 45, and automatically winding the low stop band semi-lap joint on the surface of the rotating mandrel 19 by a band releasing device; the winding tension is set and controlled by the relative rotation of the tension roller 47 and the fastening wheel 48 in the tape releasing device, and after the winding length and the alternating winding times are set by the program of the main operation panel 9, the winding length precision can reach +/-0.1 mm by controlling the left and right movement of the operation platform 16.
Glass fiber winding control mode: the glass fiber is pulled out from the creel 4, the end of the glass fiber sequentially passes through the inlet bracket, the pressing device 39, the lower part of the resin regulator 33, the upper part of the glass fiber circumferential roller 31, the doctor 29, the floating roller device 5 and finally the glass fiber shearing and laying device 6 and the glass fiber angle controller 7 are wound on the mandrel 19.
Placing the glass fiber yarn group on a creel 4 with an automatic tension control screening system, wherein the automatic tension control screening creel system has the functions of automatic tension control, yarn breakage and automatic yarn shortage early warning of single-strand glass fibers; the glass fiber controls the thickness of resin on the surface of the glass fiber through the distance between the scraping rollers in the scraping device 29 in the glass fiber winding device 4, so as to realize the content control of the impregnated epoxy resin mixed solution; the size of the pulling force is automatically controlled through the up-down floating distance of the floating roller device 5, the final winding tension is controlled through the pulling force, and the air bubbles of the epoxy resin mixture are removed through the winding tension; each strand of glass fiber is tiled through the glass limiting, shearing and laying device 6, the winding angle is set through a program, automatic angle winding is realized, and the winding round trip times and the number of alternating winding layers are set through the program.
The low stop band and the glass fiber are mutually wound on the mandrel 19 at intervals, the winding frequency of the low stop band and the glass fiber at intervals is realized by controlling the tension, the winding angle and the like, and the winding of the dipping limiting pipe sleeve is completed.
The safety control mode is as follows: the first protective door 1, the second protective door 8 and the safety door 12 have linkage protection measures, when one of the doors is opened, the operation is automatically stopped, and after the doors are closed, the operation can be restored, so that the safety of personnel in an operation platform is ensured. The operation platform 16 is provided with a first plane scanner 11 on the operation slide seat along the forward direction of the moving direction, and is also provided with a second plane scanner 15 on the operation track along the backward direction, so that the safety of personnel on the periphery of the operation platform is mainly ensured; the safe area is set through the plane scanner infrared induction system, and when non-staff and obstacles exceed the safe area, the plane scanner infrared induction system automatically senses, and the operation platform automatically stops.
The invention realizes that no manual intervention is needed in the production and manufacturing process of the full-automatic winding system of the impregnated fiber sleeve. The functions of automatic glass fiber and low stop band interlayer thickness control, winding angle control, tension control, dipping bubble control and the like are realized through the control of the belt releasing device and the glass fiber winding device 4. The protective doors are provided with alarm devices, so long as one protective door is opened, the operation of the operation platform is stopped, and after the protective door is closed, the operation platform is restarted, so that the safety of personnel in and out is ensured. The spindle bearing 21 moves along the spindle bearing moving guide rail 20, so that the distance between the spindle bearing 21 and the spindle driving device 18 is changed, and the spindles 19 with different lengths can be adapted.
The foregoing has described in detail the technical solutions provided by the embodiments of the present invention, and specific examples have been applied to illustrate the principles and implementations of the embodiments of the present invention, where the above description of the embodiments is only suitable for helping to understand the principles of the embodiments of the present invention; meanwhile, as for the person skilled in the art, according to the embodiments of the present invention, the details of the present invention and the application range may vary, and the present description should not be construed as limiting the present invention.
Claims (8)
1. The full-automatic multidimensional winding system for the impregnated fiber sleeve is characterized in that: the device comprises an operation platform and a moving platform, wherein a creel, a low-stop-band discharging device and a glass fiber dipping device are arranged in the operation platform, and the low-stop-band discharging device and the glass fiber dipping device are arranged in front of the creel side by side; the low-stop-band tape releasing device comprises a tape releasing platform, wherein the tape releasing platform is provided with a resin groove, a tape releasing device is arranged in the resin groove, and a low-stop-band shearing and laying device is arranged behind the resin groove; the belt releasing device comprises a circumferential anti-slip rotating wheel arranged in the resin groove, a tension roller, a pressure roller arranged at the front end of the resin groove and a fastening wheel arranged at the rear end of the resin groove; the front end of the resin tank extends forwards to form a roller bracket, and a guide roller is arranged in the roller bracket; the pressure roller can move up and down along the resin tank; a diameter monitoring device is arranged between the resin groove and the fastening wheel; the glass fiber impregnating device comprises a glass fiber impregnating tank, a glass fiber winding device is arranged in the glass fiber impregnating tank, and a glass fiber shearing and laying device is arranged behind the glass fiber impregnating tank; the glass fiber winding device comprises a pressing device arranged at the front end of the glass fiber dipping tank, a glass fiber circumferential roller arranged in the glass fiber dipping tank, a resin regulator arranged in front of the glass fiber circumferential roller, a glue scraper arranged at the rear end of the glass fiber dipping tank and a floating roller device arranged at the rear end of the glass fiber dipping tank; a temperature sensor and a liquid level sensor are also arranged in the glass fiber dipping tank; the mobile platform comprises a mandrel and an operation platform moving device, the operation platform moving device comprises a support guide rail and a driving guide rail, a support sliding block is arranged on the support guide rail, a driving sliding block is arranged on the driving guide rail, the bottom of the operation platform is fixed with the support sliding block and the driving sliding block, and the driving sliding block is connected with a driving motor; the winding mandrel comprises a mandrel, a mandrel bearing and a mandrel driving device, wherein two ends of the mandrel are respectively connected with the mandrel driving device and the mandrel bearing, and the mandrel driving device drives the mandrel to rotate; the winding mandrel is arranged at the rear side of the operation platform.
2. A fully automatic multi-dimensional winding system for impregnated fiber sleeves as defined in claim 1, wherein: the two ends of the pressure roller are connected with pressure cylinders, the pressure cylinders drive the pressure roller to move up and down, and the top of each pressure cylinder is provided with a pressure regulating valve.
3. A fully automatic multi-dimensional winding system for impregnated fiber sleeves as defined in claim 1, wherein: the floating roller device comprises a floating support, a plurality of fixed rollers are arranged at the bottom of the floating support, floating rollers are arranged above the fixed rollers, the floating rollers are arranged in a floating roller installation frame, the top end of the floating roller installation frame is connected with a floating cylinder, the floating cylinder is fixed with the floating support, and the floating cylinder stretches and contracts to drive the floating roller installation frame to move up and down along the floating support.
4. A fully automatic multi-dimensional winding system for impregnated fiber sleeves as defined in claim 1, wherein: the glass fiber soaking tank front end still is provided with the entry support, and entry support front end and rear end all are provided with entry comb spare, and entry support middle part sets up pressure control device, pressure control device is including compressing tightly end and rotation end, rotation end and entry support lateral wall rotate to be connected, compress tightly the end and rotate the end and be connected through the connecting plate, compress tightly the end and rotate with the connecting plate to be connected, and compress tightly the end and be located the entry comb spare of rear end and offset.
5. A fully automatic multi-dimensional winding system for impregnated fiber sleeves as defined in claim 1, wherein: the operation platform is provided with a safety guard rail around, the safety guard rail is provided with at least one protective door, the protective door is provided with an alarm, and the alarm is electrically connected or in signal connection with a device in the operation platform and controls the opening and closing of the device.
6. A fully automatic multi-dimensional winding system for impregnated fiber sleeves as defined in claim 1, wherein: the operation platform is characterized in that a circuit track is further arranged below the operation platform, and a power data line energy chain used for providing power for the operation platform and transmitting data is arranged in the circuit track.
7. A fully automatic multi-dimensional winding system for impregnated fiber sleeves as defined in claim 1, wherein: the edge of the operation platform is also provided with a plane scanner.
8. A fully automatic multi-dimensional winding system for impregnated fiber sleeves as defined in claim 1, wherein: the lower end of the mandrel bearing is provided with a mandrel bearing moving block which can slide along the mandrel bearing moving guide rail.
Priority Applications (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN202311448809.6A CN117162531B (en) | 2023-11-02 | 2023-11-02 | Full-automatic multidimensional winding system for impregnated fiber sleeve |
Applications Claiming Priority (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN202311448809.6A CN117162531B (en) | 2023-11-02 | 2023-11-02 | Full-automatic multidimensional winding system for impregnated fiber sleeve |
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|---|---|
| CN117162531A CN117162531A (en) | 2023-12-05 |
| CN117162531B true CN117162531B (en) | 2024-02-13 |
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| CN202311448809.6A Active CN117162531B (en) | 2023-11-02 | 2023-11-02 | Full-automatic multidimensional winding system for impregnated fiber sleeve |
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| ES330328A2 (en) * | 1965-09-17 | 1967-09-16 | Soc Europeenne D'isolateurs En Verre (Sediver) | Improvements introduced in the coupling elements for insulating assemblies, such as particularly insulators for conductor lines of electric energy or of medium voltage distribution networks. (Machine-translation by Google Translate, not legally binding) |
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