CN114464356B - Flame-retardant cable for wind power generation and processing equipment - Google Patents

Abstract

The invention discloses a flame-retardant cable for wind power generation and processing equipment, comprising an open type insulating leather, a chain link type lining and a plurality of wires, wherein the wires are wrapped in the chain link type lining, and the open type insulating leather wraps the chain link type lining; the chain link liner comprises: the two adjacent sections are connected through the longitudinal claw feet and the claw shaft; the claw feet and the grabbing shafts are made of metal materials; the invention relates to the technical field of cables, in particular to a claw leg which consists of an integrally formed clamping ring and an internally bent shaft sleeve distributed on the clamping ring, wherein the clamping ring is fixed on the outer wall of a bushing, and a plurality of wires are arranged in the bushing. The technical scheme adopts an all-new type cable structure, and the cable structure can ensure that the inside of a cable is effectively protected, and meanwhile, the weight of the cable is lighter than that of a traditional cable, and meanwhile, the technical scheme provides corresponding processing equipment to realize automatic production.

Description

Flame-retardant cable for wind power generation and processing equipment

Technical Field

The invention relates to the technical field of cables, in particular to a flame-retardant cable for wind power generation and processing equipment.

Background

Typically rope-like cables formed by twisting several or groups of conductors (at least two in each group), each group being insulated from each other and often twisted around a centre, the whole being covered with a highly insulating coating. The cable has the characteristics of inner electrifying and outer insulating;

the traditional multi-mode cable has basically the same composition structure, and the characteristics of the cable mainly need to have certain softness, certain firmness and fireproof and high-temperature resistant properties;

the current cable structure comprises a plurality of layers of wrapping layers, and the cable structure of the process has large weight and thick wire tube.

Disclosure of Invention

Aiming at the defects of the prior art, the invention provides a flame-retardant cable for wind power generation and processing equipment.

In order to achieve the above purpose, the invention is realized by the following technical scheme: the flame-retardant cable for wind power generation comprises an open type insulating sheath, a chain link type lining and a plurality of wires, wherein the wires are wrapped in the chain link type lining, and the open type insulating sheath wraps the chain link type lining;

the chain link liner comprises: the two adjacent sections are connected through the longitudinal claw feet and the claw shaft;

the claw feet and the grabbing shafts are made of metal materials;

the claw foot comprises an integrally formed clamping ring and an internally bent shaft sleeve distributed on the clamping ring, wherein the clamping ring is fixed on the outer wall of the bushing, and the plurality of wires are arranged in the bushing.

The processing equipment of the flame-retardant cable for the wind power generation comprises a spliced seat body, an assembling seat body and a containing seat body, and is characterized in that the spliced seat body, the assembling seat body and the containing seat body are arranged from left to right at one time;

the inside of the spliced seat body is provided with a chain link type lining and insulating leather conveying structure, the assembled seat body is provided with an assembling structure, and the accommodating seat body is provided with an accommodating structure;

the chain link type lining and insulating cover conveying structure comprises: the device comprises a pair of adjustable feeding components, a linear module translation table, a feeding component, a pair of sliding rails and a pair of arc-shaped bearing frames;

one of the adjustable feed assemblies comprises: the device comprises a calibration tube, a pair of adjusting shafts and an adjusting motor, wherein the end face of the spliced seat body is provided with an opening, the adjusting shafts are inserted into the opening of the spliced seat body, the calibration tube is positioned on the shaft body, and the driving end of the adjusting motor is connected with the shaft body;

the linear module translation table is arranged on the side wall of the spliced seat body, the sliding rail is positioned on the opposite wall surface of the linear module translation table, and the pair of arc-shaped bearing frames are arranged on the sliding rail through the synchronous beam;

the feed assembly comprises: the device comprises three layers of arc frames, a pair of compression frames, a compression motor and a connector;

the lateral wall of three-layer arc frame all is connected with the removal end of straight line module translation platform, a pair of frame that compresses tightly sets up inside three-layer arc frame to connect through the connector run-through, compressing tightly the up end that the motor is located three-layer arc frame, compressing tightly the drive end of motor and being connected with the connector.

Preferably, the assembly structure comprises: the device comprises an assembly box, pulleys, an adjusting arm, a wheel frame, a telescopic motor, a link rod, a lower bracket, a frame body wheel and a lifting motor;

the assembling box is arranged on the assembling seat body, the left end and the right end of the assembling box are respectively provided with a feeding hole and a discharging hole, the end part of the assembling box is provided with a track, the upper end of the adjusting arm is movably arranged on the track, the telescopic motor is positioned in the assembling box, one end of the connecting rod is connected with the pin shaft of the adjusting arm, the other end is connected with a telescopic end pin shaft of a telescopic motor, the wheel frame is arranged on the adjusting arm, the pulley is arranged on the wheel frame, the bottom of the lower bracket is connected with the lifting motor, the frame body wheel is positioned at the end part of the lower bracket, and the lifting motor is positioned at the bottom of the assembly box.

Preferably, the assembly structure further comprises: the heating device comprises a heating gun, a heating head, a heating scraper, a heat conductor and a heating plate;

the heat conductor, the hot scraper blade, the heating plate laminating are in the same place and fix on the discharge gate of equipment case, the heating rifle is assembled in an organic wholely with the heating head and is fixed on the frame, the heating rifle passes through electric putter and sets up in the inside of equipment case, one side of hot scraper blade is provided with surplus gluey derivation structure, still be provided with the quick cooling structure of sealing department on the frame.

The residual glue guiding structure comprises: a pair of bending type guiding-out grooves, a storage box and a dredging assembly;

the pair of bending type guiding grooves are formed in the left end and the right end of the scraping plate, the front end portion of the scraping plate is provided with a shielding groove, the shielding groove is communicated with the bending type guiding grooves, the storage box is located below the pair of bending type guiding grooves, and the dredging assembly is arranged on the pair of bending type guiding grooves.

Preferably, the rapid cooling structure comprises: a pair of cooling arc-shaped sheets, a cooling box, a circulating pump, a circulating pipeline and a refrigerator;

the refrigerator is embedded on the outer wall of the cooling box, the heat exchange end of the refrigerator is exposed outside the cooling box, the pair of cooling arc-shaped sheets are provided with connecting frames and are fixed on the machine base, the circulating pipeline is provided with cooling sub-boxes, the cooling sub-boxes are attached to the cooling arc-shaped sheets, and the cooling box, the circulating pump and the circulating pipeline are sequentially communicated.

Preferably, the dredging assembly comprises: a pair of conveying motors, a pair of planet gears and a sinking type conical outflow groove;

the pair of conveying motors is located at the bottom of the bending type guiding-out groove, the driving end is connected with the pair of planetary gears, the sinking type conical outflow groove is located on the bending type guiding-out groove and is integrally formed with the bending type guiding-out groove, and the feeding port of the sinking type conical outflow groove is located at the middle part of the pair of planetary gears.

Preferably, a fastening frame is arranged between the conveying motor and the bending type guiding-out groove.

Preferably, the base and the bottom of the base body are both provided with supporting bodies.

Preferably, the storage structure is an electric frame structure.

Advantageous effects

The invention provides a flame-retardant cable for wind power generation and processing equipment. The novel cable structure has the beneficial effects that the novel cable structure is adopted, the cable structure can ensure that the inside of a cable is effectively protected, meanwhile, the weight of the novel cable is lighter than that of a traditional cable, and meanwhile, corresponding processing equipment is provided by the novel cable structure, so that automatic production is realized.

Drawings

FIG. 1 is a schematic view of a flame retardant cable for wind power generation and a processing device according to the present invention;

FIG. 2 is a schematic view of a chain link liner and insulation sheath transport structure according to the present invention;

FIG. 3 is a schematic view of a partially enlarged construction of a conveyor structure for a chain link type lining and insulating sheath according to the present invention;

FIG. 4 is a schematic view of the structure of the residual glue guiding-out structure, the rapid cooling structure and the dredging assembly according to the invention;

FIG. 5 is a schematic diagram of the structure of the residual glue guiding structure according to the present invention;

FIG. 6 is a schematic side view of the residual glue guiding structure according to the present invention;

FIG. 7 is a schematic view of the rapid cooling structure according to the present invention;

FIG. 8 is a schematic view of the construction of a link liner according to the present invention;

FIG. 9 is a schematic view of an open insulating cover according to the present invention;

in the figure: 1. an open-type insulating cover; 2. a bushing; 3. claw feet; 4. a claw shaft; 5. a spliced seat body; 6. assembling a seat body; 7. a linear module translation stage; 8. a feed assembly; 9. a slide rail; 10. an arc-shaped bearing frame; 11. calibrating the tube; 12. an adjusting shaft; 13. adjusting a motor; 14. three layers of arc frames; 15. compressing the frame; 16. a compacting motor; 17. a connecting body; 18. assembling a box; 19. a pulley; 20. an adjusting arm; 21. a wheel carrier; 22. a telescopic motor; 23. a link rod; 24. a lower bracket; 25. a frame body wheel; 26. a lifting motor; 27. sinking type conical outflow groove; 28. a heating gun; 29. a heating head; 30. a thermal blade; 31. a heat conductor; 32. a heating sheet; 33. a bending type guiding groove; 34. a storage box; 35. cooling the arc-shaped sheet; 36. a cooling box; 37. a circulation pump; 38. a circulation line; 39. a refrigerator; 40. a conveying motor; 41. and (3) a planet wheel.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present invention, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

Referring to fig. 1-9, the present invention provides a technical solution: a flame-retardant cable for wind power generation and a processing device.

Examples

The flame-retardant cable for wind power generation comprises an open type insulating sheath 1, a chain link type lining and a plurality of wires, wherein the wires are wrapped in the chain link type lining, and the open type insulating sheath 1 wraps the chain link type lining;

the chain link type lining comprises: the two adjacent sections are connected through the longitudinal claw feet 3 and the claw shafts 4;

the claw feet 3 and the grabbing shaft are made of metal materials;

the claw 3 is composed of an integrally formed clamping ring and an internally bent shaft sleeve distributed on the clamping ring, the clamping ring is fixed on the outer wall of the bushing 2, and a plurality of wires are arranged in the bushing 2.

It should be noted that, the chain-link type lining of the structure has the functions of supporting and increasing breaking resistance, in order to meet the requirements of various situations such as bending in the cable installation, etc., the plurality of bushings 22 respectively adopt the structure as shown in fig. 1, and are mounted and fixed by adopting the cooperation of the horizontally arranged and longitudinally arranged claw feet 33 and the claw shafts 44, so that the bending at different angles is convenient for the later-stage user;

examples

The processing equipment of the flame-retardant cable for the wind power generation comprises a spliced type seat body 5, an assembling seat body 6 and a containing seat body, wherein the spliced type seat body 5, the assembling seat body 6 and the containing seat body are arranged from left to right at one time;

the inside of the spliced seat body 5 is provided with a chain link type lining and insulating leather conveying structure, the assembling seat body 6 is provided with an assembling structure, and the accommodating seat body is provided with an accommodating structure;

the chain link type lining and insulating sheath conveying structure comprises: the device comprises a pair of adjustable feeding components, a linear module translation table 7, a feeding component 8, a pair of sliding rails 9 and a pair of arc-shaped bearing frames 10;

one of the adjustable feed assemblies comprises: the device comprises a calibration tube 11, a pair of adjusting shafts 12 and an adjusting motor 13, wherein an opening is formed in the end face of the spliced seat body 5, the adjusting shafts 12 are inserted into the opening of the spliced seat body 5, the calibration tube 11 is positioned on the shaft body, and the driving end of the adjusting motor 13 is connected with the shaft body;

the linear module translation table 7 is arranged on the side wall of the spliced seat body 5, the sliding rail 9 is positioned on the opposite wall surface of the linear module translation table 7, and a pair of arc-shaped bearing frames 10 are arranged on the sliding rail 9 through a synchronous beam;

the feed assembly 8 comprises: three layers of arc frames 14, a pair of pressing frames 15, a pressing motor 16 and a connecting body 17;

the lateral wall of three-layer arc frame 14 all is connected with the removal end of straight line module translation platform 7, and a pair of frame 15 that compresses tightly sets up in three-layer arc frame 14 to connect through connector 17 run-through, compress tightly motor 16 and be located the up end of three-layer arc frame 14, compress tightly the drive end of motor 16 and be connected with connector 17.

It should be noted that, the open-type insulating sheath 1 and the chain-link type lining pass through the upper pair of calibration pipes 11 respectively, the angle of the calibration pipes 11 can be adjusted, and the adjustment motor 13 can drive the adjustment shaft 12 to adjust the angle of the calibration pipes 11; when the open type insulating sheath 1 and the chain link type lining machine enter, the moving end of the linear module translation table 7 needs to be controlled to move to one side of the calibration tube 11 with the feeding component 8, then the compressing motor 16 is driven to drive the connector 17, the three-layer arc-shaped frame 14 and the pair of compressing frames 15 are matched to clamp the open type insulating sheath 1 and the chain link type lining respectively, then the linear module translation table 7 is used for moving the open type insulating sheath 1 and the chain link type lining, meanwhile, in order to ensure that the moving direction is correct, the sliding rail 9 is arranged, and the pair of arc-shaped bearing frames 10 are arranged on the sliding rail 9 to realize the movement of the open type insulating sheath 1 and the chain link type lining.

Specifically, the assembled structure comprises: assembly box 18, pulley 19, regulating arm 20, wheel frame 21, telescopic motor 22, link 23, lower bracket 24, frame wheel 25 and lifting motor 26;

the assembly box 18 is arranged on the assembly seat body 6, the left end and the right end of the assembly box 18 are respectively provided with a feeding hole and a discharging hole, the end part of the assembly box 18 is provided with a track, the upper end of the adjusting arm 20 is movably arranged on the track, the telescopic motor 22 is positioned in the assembly box 18, one end of the connecting rod 23 is in pin shaft connection with the adjusting arm 20, the other end of the connecting rod is in pin shaft connection with the telescopic end of the telescopic motor 22, the wheel frame 21 is arranged on the adjusting arm 20, the pulley 19 is arranged on the wheel frame 21, the bottom of the lower bracket is connected with the lifting motor 26, the frame body wheel 25 is positioned at the end part of the lower bracket, and the lifting motor 26 is positioned at the bottom of the assembly box 18.

It should be noted that, when the open-type insulating sheath 1 and the chain-link type lining enter the inside of the assembly box 18 through the feed inlet, the open-type insulating sheath 1 and the chain-link type lining are extruded and assembled together through the pulley 19 and the frame body wheel 25, and are moved out through the assembly box 18;

in a specific assembly process, the link rod 23 can be driven by the telescopic motor 22, and the link rod 23 carries the adjusting arm 20 to adjust the angle, so that the position of the pulley 19 can be adjusted, and meanwhile, the height of the telescopic end of the lifting motor 26 can be adjusted, so that the height position of the frame body wheel 25 on the lower bracket 24 can be adjusted.

Specifically, the assembled structure further includes: a heating gun 28, a heating head 29, a second calibration tube 11, a hot scraper 30, a heat conductor 31 and a heating plate 32;

the heat conductor 31, the hot scraping plate 30 and the heating plate 32 are attached together and fixed on a discharge hole of the assembly box 18, the heating gun 28 and the heating head 29 are assembled into a whole and fixed on the machine base, the heating gun 28 is arranged in the assembly box 18 through the electric push rod, one side of the hot scraping plate 30 is provided with a residual glue guiding structure, and the machine base is also provided with a sealing part rapid cooling structure.

Firstly, the outer insulating skins are assembled together in the assembly process, a heating gun 28 heats a heating head 29 and is attached to an opening of the temporarily closed outer insulating skin to start hot-melt sealing, and then the heated opening part is extruded and scratched by a heat conductor 31, a hot scraping plate 30 and a heating sheet 32 to realize bonding;

the residual glue guiding structure comprises: a pair of bent guide grooves 33, a storage case 34, and a dredging unit;

the pair of bending type guiding grooves 33 are arranged at the left end and the right end of the scraper, the front end part of the scraper is provided with a shielding groove which is communicated with the bending type guiding grooves 33, the storage box 34 is arranged below the pair of bending type guiding grooves 33, and the dredging assembly is arranged on the pair of bending type guiding grooves 33.

The overflowed adhesive tape is led out through the bending type leading-out groove 33, and is dredged through the dredging component when the overflowed adhesive tape is more;

the colloid refers to a substance overflowed after the deformation of the material of the colloid is close to the state of fluid after the opening part of the outer insulating sheath is heated, and the substance is derived from the outer insulating sheath.

Specifically, the rapid cooling structure comprises: a pair of cooling arcuate pieces 35, a cooling tank 36, a circulation pump 37, a circulation line 38, a refrigerator 39;

the refrigerator 39 is embedded on the outer wall of the cooling box 36, the heat exchange end of the refrigerator 39 is exposed outside the cooling box 36, a pair of cooling arc-shaped sheets are provided with connecting frame bodies and are fixed on the engine base, the circulating pipeline 38 is provided with cooling sub-boxes, the cooling sub-boxes are attached to the cooling arc-shaped sheets 35, and the cooling box 36, the circulating pump 37 and the circulating pipeline 38 are sequentially communicated.

In order to ensure that the bonding sealing part can realize quick cooling bonding, circulating liquid flows into the cooling sub-boxes on the cooling arc-shaped sheets by the circulating pump 37, the shape of the cooling sub-boxes is basically the same as that of the cooling arc-shaped sheets, the cooling arc-shaped sheets are ensured to be uniformly cooled, and the periphery of the opening sealing of the external insulating leather is quickly cooled by the cooling arc-shaped sheets.

Specifically, the dredging assembly comprises: a pair of conveying motors 40, a pair of planetary gears 41, a sinking type conical outflow groove 27;

the pair of conveying motors 40 are located at the bottom of the bending type guiding-out groove 33, the driving end is connected with the pair of planetary gears 41, the sinking type conical outflow groove 27 is located on the bending type guiding-out groove 33 and is integrally formed with the bending type guiding-out groove, and the feeding hole of the sinking type conical outflow groove 27 is located at the middle part of the pair of planetary gears 41.

The purpose of the sinking type conical outflow slot 27 is to increase the slope of the bent type guiding-out slot 33 so as to facilitate the outflow of the surplus substances by sliding down.

Specifically, a fastening frame is provided between the conveying motor 40 and the bent guide groove 33.

Specifically, the base and the bottom of the base body are both provided with supporting bodies.

Specifically, the storage structure is an electric frame structure.

It is noted that relational terms such as first and second, and the like are used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Moreover, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus. Without further limitation. The term "comprising" an element defined by the term "comprising" does not exclude the presence of other identical elements in a process, method, article or apparatus that comprises the element.

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

Claims (8)

1. The processing equipment of the flame-retardant cable for the wind power generation comprises a spliced seat body, an assembling seat body and a containing seat body, and is characterized in that the spliced seat body, the assembling seat body and the containing seat body are arranged from left to right at one time;

the inside of the spliced seat body is provided with a chain link type lining and insulating leather conveying structure, the assembled seat body is provided with an assembling structure, and the accommodating seat body is provided with an accommodating structure;

the chain link type lining and insulating cover conveying structure comprises: the device comprises a pair of adjustable feeding components, a linear module translation table, a feeding component, a pair of sliding rails and a pair of arc-shaped bearing frames;

one of the adjustable feed assemblies comprises: the device comprises a calibration tube, a pair of adjusting shafts and an adjusting motor, wherein the end face of the spliced seat body is provided with an opening, the adjusting shafts are inserted into the opening of the spliced seat body, the calibration tube is positioned on the shaft body, and the driving end of the adjusting motor is connected with the shaft body;

the linear module translation table is arranged on the side wall of the spliced seat body, the sliding rail is positioned on the opposite wall surface of the linear module translation table, and the pair of arc-shaped bearing frames are arranged on the sliding rail through the synchronous beam;

the feed assembly comprises: the device comprises three layers of arc frames, a pair of compression frames, a compression motor and a connector;

the lateral wall of three-layer arc frame all is connected with the removal end of straight line module translation platform, a pair of frame that compresses tightly sets up inside three-layer arc frame to connect through the connector run-through, compressing tightly the up end that the motor is located three-layer arc frame, compressing tightly the drive end of motor and being connected with the connector.

2. The processing apparatus for a flame retardant cable for wind power generation according to claim 1, wherein the assembly structure comprises: the device comprises an assembly box, pulleys, an adjusting arm, a wheel frame, a telescopic motor, a link rod, a lower bracket, a frame body wheel and a lifting motor;

the assembling box is arranged on the assembling seat body, the left end and the right end of the assembling box are respectively provided with a feeding hole and a discharging hole, the end part of the assembling box is provided with a track, the upper end of the adjusting arm is movably arranged on the track, the telescopic motor is positioned in the assembling box, one end of the connecting rod is connected with the pin shaft of the adjusting arm, the other end is connected with a telescopic end pin shaft of a telescopic motor, the wheel frame is arranged on the adjusting arm, the pulley is arranged on the wheel frame, the bottom of the lower bracket is connected with the lifting motor, the frame body wheel is positioned at the end part of the lower bracket, and the lifting motor is positioned at the bottom of the assembly box.

3. The processing apparatus for a flame retardant cable for wind power generation according to claim 2, wherein the assembly structure further comprises: the heating device comprises a heating gun, a heating head, a heating scraper, a heat conductor and a heating plate;

the heat conductor, the hot scraping plate and the heating plate are attached together and fixed on a discharge hole of the assembly box, the heating gun and the heating head are assembled into a whole and fixed on the machine base, the heating gun is arranged in the assembly box through the electric push rod, one side of the hot scraping plate is provided with a residual glue guiding structure, and the machine base is also provided with a quick cooling structure at a sealing position;

the residual glue guiding structure comprises: a pair of bending type guiding-out grooves, a storage box and a dredging assembly;

the pair of bending type guiding grooves are formed in the left end and the right end of the scraping plate, the front end portion of the scraping plate is provided with a shielding groove, the shielding groove is communicated with the bending type guiding grooves, the storage box is located below the pair of bending type guiding grooves, and the dredging assembly is arranged on the pair of bending type guiding grooves.

4. A processing apparatus for a flame retardant cable for wind power generation according to claim 3, wherein said rapid cooling structure comprises: a pair of cooling arc-shaped sheets, a cooling box, a circulating pump, a circulating pipeline and a refrigerator;

the refrigerator is embedded on the outer wall of the cooling box, the heat exchange end of the refrigerator is exposed outside the cooling box, the pair of cooling arc-shaped sheets are provided with connecting frames and are fixed on the machine base, the circulating pipeline is provided with cooling sub-boxes, the cooling sub-boxes are attached to the cooling arc-shaped sheets, and the cooling box, the circulating pump and the circulating pipeline are sequentially communicated.

5. A processing apparatus for a fire resistant cable for wind power generation according to claim 3 wherein the dredging module comprises: a pair of conveying motors, a pair of planet gears and a sinking type conical outflow groove;

the pair of conveying motors is located at the bottom of the bending type guiding-out groove, the driving end is connected with the pair of planetary gears, the sinking type conical outflow groove is located on the bending type guiding-out groove and is integrally formed with the bending type guiding-out groove, and the feeding port of the sinking type conical outflow groove is located at the middle part of the pair of planetary gears.

6. The processing apparatus for a flame-retardant cable for wind power generation according to claim 5, wherein a fastening frame is provided between the conveying motor and the bent-type lead-out groove.

7. A processing apparatus for a flame retardant cable for wind power generation according to claim 3, wherein the base and the bottom of the base are provided with supporting bodies.

8. The processing apparatus for a flame retardant cable for wind power generation according to claim 1, wherein the housing structure is an electric frame structure.