CN109841354B - Flame retardant cable processing system - Google Patents

Abstract

The invention relates to a processing mechanism, in particular to a flame-retardant cable processing system, which comprises a containing support, a positioning support, a power mechanism, a driving containing mechanism, a driven containing mechanism, a positioning mechanism, a smearing mechanism, an extrusion mechanism and a cable core, wherein the driving containing mechanism, the driven containing mechanism and the positioning mechanism can be simultaneously driven by the power mechanism to simultaneously rotate around the axes of the driving containing mechanism, the driving containing mechanism and the driven containing mechanism can drive the cable core arranged on the driving containing mechanism to rotate around the axis of the positioning mechanism, so that the cable core sequentially passes through an anti-abrasion ring II, three positioning extrusion wheels, two smearing arc plates, two extrusion molding wheels and an anti-abrasion ring I when the driving containing mechanism contains the cable core, the cable processing material on the positioning support is sequentially wound on the cable core, the two coating arc plates uniformly coat the heated fluid flame-retardant rubber on the cable core.

Description

Flame retardant cable processing system

Technical Field

The invention relates to a processing mechanism, in particular to a flame-retardant cable processing system.

Background

For example, a flame retardant cable processing system and method disclosed in publication number CN207068541U, includes a cable core, a cable protective sleeve is disposed outside the cable core, the cable protective sleeve includes a semiconductive nylon belt, an insulation shielding layer is sleeved outside the semiconductive nylon belt, an aluminum sheath is sleeved outside the insulation shielding layer, an asphalt anticorrosive layer is sleeved outside the aluminum sheath, a low smoke halogen-free flame retardant polyolefin layer is sleeved outside the asphalt anticorrosive layer, a glass fiber layer is sleeved outside the low smoke halogen-free flame retardant polyolefin layer, and a central tensile wire body is disposed inside the cable core; the utility model discloses a shortcoming is that can not accomodate the winding processing of accomplishing fire-retardant power cable simultaneously to the cable.

Disclosure of Invention

The invention aims to provide a flame-retardant cable processing system which can complete the processing of a flame-retardant power cable while accommodating and winding the cable.

The purpose of the invention is realized by the following technical scheme:

a flame-retardant cable processing system comprises a storage support, a positioning support, a power mechanism, a driving storage mechanism, a driven storage mechanism, a positioning mechanism, a smearing mechanism, an extruding mechanism and a cable core, wherein the positioning support is fixedly connected to the storage support, the power mechanism is fixedly connected to the positioning support, the driving storage mechanism and the driven storage mechanism are respectively and rotatably connected to two ends of the storage support, the power mechanism and the driving storage mechanism are in gear meshing transmission, the power mechanism and the driven storage mechanism are in gear meshing transmission, the positioning mechanism is rotatably connected to the positioning support, the positioning mechanism and the power mechanism are in gear meshing transmission, the smearing mechanism is slidably connected to the storage support, a flame-retardant rubber heating pipe is connected to the smearing mechanism, a compression spring II is arranged between the smearing mechanism and the storage support, the two extruding mechanisms are arranged, and both the two extruding mechanisms are, a compression spring III is arranged between the extrusion mechanism and the storage support, one end of the cable core is wound on the driven storage mechanism, and the other end of the cable core is wound on the driving storage mechanism sequentially through the positioning mechanism, the smearing mechanism and the extrusion mechanism.

As a further optimization of the technical scheme, the invention relates to a flame-retardant cable processing system, which comprises a bottom plate, two support plates I, two connecting columns, two connecting plates I, two connecting rings I, two connecting plates II, two support plates II, two connecting plates III, a sliding groove, two sliding blocks I and two connecting rings II, wherein the two support plates I are fixedly connected with the two support plates I, the connecting columns are fixedly connected between the two support plates I on two sides, the two connecting plates I are respectively and fixedly connected with the two support plates I on one side, the two connecting rings II are fixedly connected between the two connecting plates I, the two connecting plates II are respectively and fixedly connected with the two support plates I on the other side, the two support plates II are respectively and fixedly connected with the support plates II, and the connecting plate III is fixedly connected between the upper ends of the two support plates II, be provided with two sliding trays on the connecting plate III, two equal sliding connection in sliding tray have sliding block I, fixedly connected with go-between II between two connecting plates.

As a further optimization of the technical scheme, the flame-retardant cable processing system comprises a positioning support, a winding positioning shaft, a positioning nut, a winding barrel, a rotating groove, a positioning sliding groove and a sliding block II, wherein three winding positioning shafts are uniformly and fixedly connected to one side of the positioning support in the circumferential direction, the three winding positioning shafts are respectively connected with the positioning nut through threads, the winding barrels are in clearance fit with the three winding positioning shafts, the rotating groove is formed in the other side of the positioning support, the three positioning sliding grooves are uniformly and circumferentially formed in the positioning support, the sliding block II is slidably connected in the three positioning sliding grooves, and two ends of the positioning support are respectively and fixedly connected to two connecting columns.

As further optimization of the technical scheme, the flame-retardant cable processing system comprises a power mechanism, wherein the power mechanism comprises a motor, a gear I, a gear II and a gear III, the motor is fixedly connected to a positioning bottom plate, the gear I, the gear II and the gear III are fixedly connected to an output shaft of the motor, and the diameters of the gear I, the gear II and the gear III are equal.

As a further optimization of the technical scheme, the flame-retardant cable processing system comprises an active receiving disc, a gear ring I, an anti-abrasion ring I, a support frame I, a driving shaft, an active receiving cylinder, a motor support and a receiving motor, wherein the active receiving disc is fixedly connected with the anti-abrasion ring I, the anti-abrasion ring I and the active receiving disc are coaxially arranged, the active receiving disc is rotatably connected to a connecting ring II, one side of the active receiving disc is fixedly connected with the gear ring I, the gear ring I and a gear III are in meshing transmission, the eccentric position of the other side of the active receiving disc is fixedly connected with the two support frames I, the two support frames I are respectively provided with a clamping groove I, the two ends of the driving shaft are respectively and slidably connected into the two clamping grooves I, the motor support is fixedly connected to one support frame I, the motor support is fixedly connected with the receiving motor, and an, the active storage barrel is in clearance fit with the driving shaft, and the storage motor is a servo motor.

As a further optimization of the technical scheme, the flame-retardant cable processing system comprises a driven receiving mechanism, a gear ring II and an anti-abrasion ring II, support frame II, the driven shaft, driven storage cylinder and mounting nut, driven storage disc rotates to be connected on go-between I, one side fixedly connected with ring gear II of driven storage disc, ring gear II and I meshing transmission of gear, ring gear II equals with the diameter of ring gear I, fixedly connected with anti-abrasion circle II on the driven storage disc, anti-abrasion circle II and the coaxial setting of driven storage disc, two support frames II of eccentric position fixedly connected with of driven storage disc opposite side, all be provided with draw-in groove II on two support frames II, sliding connection is in two draw-in grooves II respectively at the both ends of driven shaft, the both ends of driven shaft all have mounting nut through threaded connection, two mounting nut's inboard contacts with two support frames II respectively.

As a further optimization of the technical scheme, the invention relates to a flame-retardant cable processing system, wherein a positioning mechanism comprises a positioning rotating ring, a sliding support plate, positioning sliding columns, positioning limiting columns, positioning extrusion wheels and a spring baffle plate I, the sliding support plate is rotatably connected in a rotating groove and is in meshing transmission with a gear II, the reference circle diameters of the sliding support plate and the gear ring I are equal, three sliding support plates are uniformly and fixedly connected on the sliding support plate in the circumferential direction, the three sliding support plates are respectively and slidably connected with the positioning sliding columns, the three positioning sliding columns are respectively and slidably connected in three sliding blocks II, the inner sides of the three positioning sliding columns are respectively and rotatably connected with the positioning extrusion wheels, the three positioning sliding columns are respectively and fixedly connected with the spring baffle plate I, the three positioning sliding columns are respectively sleeved with a compression spring I, compression spring I is located between spring baffle I and the slip backup pad.

According to the further optimization of the technical scheme, the flame-retardant cable processing system comprises two smearing pipes, two smearing arc plates, two spring baffle plates II and two smearing limiting columns, wherein the two smearing pipes are respectively connected to the two connecting plates II in a sliding mode, the outer ends of the two smearing pipes are respectively connected with a flame-retardant rubber heating pipe, the inner ends of the two smearing pipes are respectively fixedly connected with the smearing arc plates, the two smearing pipes are respectively fixedly connected with the spring baffle plates II and the smearing limiting columns, the two smearing limiting columns are respectively connected to the two sliding blocks I in a sliding mode, the two smearing pipes are respectively sleeved with a compression spring II, and the compression spring II is located between the connecting plates II and the spring baffle plates II.

According to the further optimization of the technical scheme, the flame-retardant cable processing system comprises an extrusion sliding column I, an extrusion plate, two extrusion sliding columns II and extrusion forming wheels, wherein one end of each extrusion sliding column I is fixedly connected with the extrusion plate, the other end of each extrusion sliding column I is rotatably connected with the extrusion forming wheels, two extrusion sliding columns II are fixedly connected onto the extrusion plate, the two extrusion sliding columns II on two sides are respectively and slidably connected onto corresponding connecting plates II, compression springs III are sleeved on the four extrusion sliding columns II, and the compression springs III are located between the connecting plates II and the extrusion plates.

As a further optimization of the technical scheme, one end of the cable core is wound on the driven storage barrel, and the other end of the cable core sequentially passes through the anti-abrasion ring II, the space between the three positioning extrusion wheels, the space between the two smearing arc plates, the space between the two extrusion molding wheels and the anti-abrasion ring I to be wound on the driving storage barrel.

The flame-retardant cable processing system has the beneficial effects that:

the invention relates to a flame-retardant cable processing system, which can simultaneously drive a driving storage mechanism, a driven storage mechanism and a positioning mechanism to simultaneously rotate by taking the axes of the driving storage mechanism, the driven storage mechanism and the positioning mechanism as the centers, and the driving storage mechanism and the driven storage mechanism can drive a cable core arranged on the driving storage mechanism to rotate by taking the axis of the positioning mechanism as the center when rotating, so that the cable core on the driving storage mechanism sequentially passes through an anti-abrasion ring II, between three positioning extrusion wheels, between two smearing arc plates, between two extrusion molding wheels and between an anti-abrasion ring I to rotate relatively, different cable processing materials on a positioning bracket are sequentially wound on the cable core, the two smearing arc plates uniformly smear heated fluid flame-retardant rubber on the cable core, and the fluid flame-retardant rubber is extruded and formed by extrusion between the two extrusion molding wheels.

Drawings

The invention is described in further detail below with reference to the accompanying drawings and specific embodiments.

FIG. 1 is a schematic view of the overall structure of the flame retardant power cable of the present invention;

FIG. 2 is a schematic view of the storage rack of the present invention;

FIG. 3 is a first schematic view of the positioning bracket of the present invention;

FIG. 4 is a schematic view of the positioning bracket of the present invention;

FIG. 5 is a schematic diagram of a power mechanism according to the present invention;

FIG. 6 is a first structural view of the active stowing mechanism of the invention;

FIG. 7 is a second schematic structural view of the active stowing mechanism of the present invention;

FIG. 8 is a first schematic structural view of the driven receiving mechanism of the present invention;

FIG. 9 is a second schematic structural view of the driven storage mechanism of the present invention;

FIG. 10 is a schematic view of the positioning mechanism of the present invention;

FIG. 11 is a schematic view of the applicator mechanism of the present invention;

fig. 12 is a schematic view of the pressing mechanism of the present invention.

In the figure: a storage rack 1; a bottom plate 1-1; a support plate I1-2; 1-3 of connecting columns; 1-4 connecting plates; 1-5 of a connecting ring; connecting plates II 1-6; support plates II 1-7; 1-8 of a connecting plate III; 1-9 of a sliding groove; 1-10 sliding blocks; connecting rings II 1-11; a positioning bracket 2; positioning the bottom plate 2-1; winding a positioning shaft 2-2; 2-3 of a positioning nut; 2-4 of a winding drum; 2-5 of a rotating groove; 2-6 of a positioning sliding groove; 2-7 of a sliding block II; a power mechanism 3; a motor 3-1; a gear I3-2; 3-3 of a gear; 3-4 parts of a gear; an active storage mechanism 4; an active storage tray 4-1; the gear ring I4-2; 4-3 parts of an anti-abrasion ring; 4-4 of a support frame I; 4-5 of a driving shaft; 4-6 of an active storage cylinder; 4-7 of a motor bracket; accommodating motors 4-8; a driven storage mechanism 5; a driven storage tray 5-1; a gear ring II 5-2; 5-3 parts of an anti-abrasion ring; 5-4 of a support frame II; 5-5 parts of a driven shaft; 5-6 of driven storage cylinder; mounting nuts 5-7; a positioning mechanism 6; positioning the rotating ring 6-1; a sliding support plate 6-2; 6-3 of a positioning sliding column; 6-4 of a positioning limiting column; 6-5 of a positioning extrusion wheel; 6-6 parts of a spring baffle plate; a coating mechanism 7; 7-1 of a coating pipe; coating an arc plate 7-2; 7-3 of a spring baffle plate; coating a limiting column 7-4; an extrusion mechanism 8; extruding the sliding column I8-1; 8-2 of an extrusion plate; extruding the sliding column II 8-3; 8-4 of an extrusion molding wheel; a cable core 9.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings.

In the description of the present invention, it should be noted that the terms "center", "longitudinal", "lateral", "up", "down", "front", "back", "left", "right", "top", "bottom", "inner", "outer" and "upright", etc., indicate orientations or positional relationships based on those shown in the drawings, and are only for convenience of description and simplicity of description, but do not indicate or imply that the referred device or element must have a specific orientation, be constructed and operated in a specific orientation, and thus, should not be construed as limiting the present invention.

In the description of the present invention, it should be noted that unless otherwise explicitly stated or limited, the terms "mounted," "connected," and "connected" are to be construed broadly, and may be, for example, fixedly connected, detachably connected, or integrally connected, directly or indirectly connected through an intermediate medium, and may be a communication between two members. The specific meanings of the above terms in the present invention can be understood in specific cases to those skilled in the art.

In addition, in the description of the present invention, the meaning of "a plurality", and "a plurality" is two or more unless otherwise specified.

The first embodiment is as follows:

the embodiment is described below with reference to fig. 1 to 12, a flame retardant cable processing system, which includes a storage bracket 1, a positioning bracket 2, a power mechanism 3, a driving storage mechanism 4, a driven storage mechanism 5, a positioning mechanism 6, a smearing mechanism 7, an extrusion mechanism 8 and a cable core 9, wherein the positioning bracket 2 is fixedly connected to the storage bracket 1, the power mechanism 3 is fixedly connected to the positioning bracket 2, the driving storage mechanism 4 and the driven storage mechanism 5 are respectively rotatably connected to two ends of the storage bracket 1, the power mechanism 3 and the driving storage mechanism 4 are in gear engagement transmission, the power mechanism 3 and the driven storage mechanism 5 are in gear engagement transmission, the positioning mechanism 6 is rotatably connected to the positioning bracket 2, the positioning mechanism 6 and the power mechanism 3 are in gear engagement transmission, the smearing mechanism 7 is slidably connected to the storage bracket 1, and the smearing mechanism 7 is connected to a flame retardant rubber heating pipe, a compression spring II is arranged between the smearing mechanism 7 and the containing support 1, two squeezing mechanisms 8 are arranged, the two squeezing mechanisms 8 are connected to the containing support 1 in a sliding mode, a compression spring III is arranged between the squeezing mechanisms 8 and the containing support 1, one end of the cable core 9 is wound on the driven containing mechanism 5, and the other end of the cable core 9 is wound on the driving containing mechanism 4 sequentially through the positioning mechanism 6, the smearing mechanism 7 and the squeezing mechanism 8; the driving storage mechanism 4, the driven storage mechanism 5 and the positioning mechanism 6 can be driven by the power mechanism 3 to rotate simultaneously with the axis of the driving storage mechanism 4 as the center, the cable core 9 arranged on the driving storage mechanism 4 and the driven storage mechanism 5 can be driven to rotate when rotating and the axis of the positioning mechanism 6 as the center, so that the cable core 9 sequentially passes through the anti-abrasion ring II 5-3, the three positioning extrusion wheels 6-5, the two smearing arc plates 7-2, the two extrusion molding wheels 8-4 and the anti-abrasion ring I4-3 when the driving storage mechanism 4 stores the cable core 9, different cable processing materials on the positioning bracket 2 are sequentially wound on the cable core 9, the two smearing arc plates 7-2 evenly smear the heated fluid flame retardant rubber on the cable core 9, the plastic is extruded between two extrusion molding wheels 8-4 and finally is stored on a driving storage cylinder 4-6. The flame-retardant rubber can be chloroprene rubber, chlorosulfonated polyethylene, polyvinyl chloride, silicon rubber and the like, the flame-retardant polymer and the flammable rubber are used together to improve the flame retardance, for example, the polyvinyl chloride and the nitrile rubber are used together to improve the crosslinking density of vulcanized rubber and also improve the flame retardance, the flame retardant is added to improve the flame retardance of the rubber, and the commonly used flame retardants are as follows: the cable processing material can be glass fiber and other materials which can be wound.

The second embodiment is as follows:

the embodiment is described below with reference to fig. 1-12, and the embodiment will be further described, wherein the storage rack 1 comprises a bottom plate 1-1, support plates i 1-2, connecting columns 1-3, connecting plates i 1-4, connecting rings i 1-5, connecting plates ii 1-6, support plates ii 1-7, connecting plates iii 1-8, sliding grooves 1-9, sliding blocks i 1-10 and connecting rings ii 1-11, two support plates i 1-2 are provided, two support plates i 1-2 are fixedly connected to the two support plates i 1-2, two connecting columns 1-3 are fixedly connected between the two support plates i 1-2 on two sides, two connecting plates i 1-4 are provided, two connecting plates i 1-4 are respectively fixedly connected to the two support plates i 1-2 on one side, two connecting rings II 1-5 are fixedly connected between the two connecting plates I1-4, two connecting plates II 1-6 are arranged, the two connecting plates II 1-6 are respectively and fixedly connected to the two supporting plates I1-2 on the other side, the two connecting plates II 1-6 are respectively and fixedly connected with supporting plates II 1-7, a connecting plate III 1-8 is fixedly connected between the upper ends of the two supporting plates II 1-7, two sliding grooves 1-9 are arranged on the connecting plate III 1-8, sliding blocks I1-10 are respectively and slidably connected with the two sliding grooves 1-9, and connecting rings II 1-11 are fixedly connected between the two connecting plates II 1-6.

The third concrete implementation mode:

the embodiment is described below with reference to fig. 1-12, and the embodiment will be further described, wherein the positioning bracket 2 includes a positioning bottom plate 2-1, a winding positioning shaft 2-2, a positioning nut 2-3, a winding cylinder 2-4, a rotating groove 2-5, a positioning sliding groove 2-6 and a sliding block ii 2-7, three winding positioning shafts 2-2 are uniformly and fixedly connected to one side of the positioning bottom plate 2-1 in the circumferential direction, the three winding positioning shafts 2-2 are all connected to the positioning nut 2-3 through threads, the winding cylinder 2-4 is in clearance fit with the three winding positioning shafts 2-2, the rotating groove 2-5 is arranged on the other side of the positioning bottom plate 2-1, the three positioning sliding grooves 2-6 are uniformly arranged on the positioning bottom plate 2-1 in the circumferential direction, sliding blocks II 2-7 are connected in the three positioning sliding grooves 2-6 in a sliding manner, and two ends of the positioning bottom plate 2-1 are fixedly connected to the two connecting columns 1-3 respectively; the three winding drums 2-4 are all wound with materials required by cable processing, the cable processing materials can be glass fibers and other materials capable of being wound, the materials on the three winding drums 2-4 are sequentially and respectively fixedly connected onto the cable core 9, winding is sequentially and fixedly connected onto the cable core 9 according to requirements, one processing material required to be wound is fixedly connected firstly, the next material is fixed onto the previous material after the cable core 9 moves for a certain distance, and the winding of different sequences of different types of materials is sequentially completed through repeated operation.

The fourth concrete implementation mode:

the third embodiment is further described with reference to fig. 1 to 12, where the power mechanism 3 includes a motor 3-1, a gear i 3-2, a gear ii 3-3, and a gear iii 3-4, the motor 3-1 is fixedly connected to the positioning bottom plate 2-1, an output shaft of the motor 3-1 is fixedly connected to the gear i 3-2, the gear ii 3-3, and the gear iii 3-4, and diameters of the gear i 3-2, the gear ii 3-3, and the gear iii 3-4 are equal; when the cable core is used, one end of a cable core 9 is wound on a driven storage barrel 5-6, the other end of the cable core 9 sequentially passes through an anti-abrasion ring II 5-3, three positioning extrusion wheels 6-5, two smearing arc plates 7-2, two extrusion forming wheels 8-4 and an anti-abrasion ring I4-3 to be wound on a driving storage barrel 4-6, the storage motor 4-8 is started, an output shaft of the storage motor 4-8 starts to rotate, an output shaft of the storage motor 4-8 drives a driving shaft 4-5 to rotate by taking the axis of the driving shaft 4-5 as the center, the driving shaft 4-5 drives the driving storage barrel 4-6 to rotate by taking the axis of the driving shaft 4-6 as the center, the driving storage barrel 4-6 pulls the cable core 9 to be wound on the driving storage barrel 4-6, and the motor 3-, the output shaft of the motor 3-1 starts to rotate, the output shaft of the motor 3-1 drives the gear I3-2, the gear II 3-3 and the gear III 3-4 to rotate by taking the axis of the gear I3-2, the gear II 3-3 and the gear III 3-4 as the center, the diameters of the gear I3-2, the gear II 3-3 and the gear III 3-4 are equal, the same rotating speed is guaranteed, and the cable core 9 is guaranteed not to generate differential speed when passing through a plurality of mechanisms when autorotation occurs.

The fifth concrete implementation mode:

the fourth embodiment is further described with reference to fig. 1-12, wherein the driving storage mechanism 4 includes a driving storage disk 4-1, a gear ring i 4-2, an anti-wear ring i 4-3, a support frame i 4-4, a driving shaft 4-5, a driving storage cylinder 4-6, a motor support 4-7 and a storage motor 4-8, the anti-wear ring i 4-3 is fixedly connected to the driving storage disk 4-1, the anti-wear ring i 4-3 and the driving storage disk 4-1 are coaxially arranged, the driving storage disk 4-1 is rotatably connected to a connecting ring ii 1-11, the gear ring i 4-2 is fixedly connected to one side of the driving storage disk 4-1, the gear ring i 4-2 and the gear iii 3-4 are in meshing transmission, two support frames i 4-4 are fixedly connected to the eccentric position of the other side of the driving storage disk 4-1, the two support frames I4-4 are respectively provided with a clamping groove I, two ends of a driving shaft 4-5 are respectively connected in the two clamping grooves I in a sliding mode, a motor support 4-7 is fixedly connected to one support frame I4-4, a storage motor 4-8 is fixedly connected to the motor support 4-7, an output shaft of the storage motor 4-8 is fixedly connected to the driving shaft 4-5, a driving storage cylinder 4-6 is in clearance fit with the driving shaft 4-5, and the storage motor 4-8 is a servo motor; the rotating speed of the storage motor 4-8 can be adjusted, the speed of the active storage barrel 4-6 for storing the cable core 9 is adjusted, two ends of the driving shaft 4-5 are respectively connected in the two clamping grooves I in a sliding mode, the active storage barrel 4-6 is in clearance fit with the driving shaft 4-5, and replacement of the active storage barrel 4-6 is facilitated.

The sixth specific implementation mode:

the embodiment is described below with reference to fig. 1-12, and the fifth embodiment is further described, in which the driven receiving mechanism 5 includes a driven receiving disk 5-1, a gear ring ii 5-2, an anti-wear ring ii 5-3, a support frame ii 5-4, a driven shaft 5-5, a driven receiving cylinder 5-6 and a mounting nut 5-7, the driven receiving disk 5-1 is rotatably connected to a connecting ring i 1-5, one side of the driven receiving disk 5-1 is fixedly connected with the gear ring ii 5-2, the gear ring ii 5-2 and a gear i 3-2 are in meshing transmission, the gear ring ii 5-2 and the gear ring i 4-2 have the same diameter, the driven receiving disk 5-1 is fixedly connected with the anti-wear ring ii 5-3, the anti-wear ring ii 5-3 and the driven receiving disk 5-1 are coaxially arranged, two supporting frames II 5-4 are fixedly connected to the eccentric position of the other side of the driven storage disc 5-1, clamping grooves II are formed in the two supporting frames II 5-4, two ends of the driven shaft 5-5 are connected into the two clamping grooves II in a sliding mode respectively, two ends of the driven shaft 5-5 are connected with mounting nuts 5-7 through threads, and the inner sides of the two mounting nuts 5-7 are in contact with the two supporting frames II 5-4 respectively; the two clamping grooves II are formed in the two support frames II 5-4, the two ends of the driven shaft 5-5 are respectively connected into the two clamping grooves II in a sliding mode, the two ends of the driven shaft 5-5 are respectively connected with mounting nuts 5-7 through threads, and the inner sides of the two mounting nuts 5-7 are respectively in contact with the two support frames II 5-4, so that the driven storage barrels 5-6 can be detached quickly, and the cable cores 9 on the driven storage barrels 5-6 can be replaced quickly when the cable cores are replaced by the driving storage barrels 4-6.

The seventh embodiment:

the sixth embodiment is further described with reference to fig. 1-12, wherein the positioning mechanism 6 includes a positioning rotating ring 6-1, a sliding support plate 6-2, a positioning sliding post 6-3, a positioning limiting post 6-4, a positioning extrusion wheel 6-5 and a spring baffle plate i 6-6, the sliding support plate 6-2 is rotatably connected in a rotating groove 2-5, the sliding support plate 6-2 and a gear ii 3-3 are in meshing transmission, the reference circle diameters of the sliding support plate 6-2 and the gear ring i 4-2 are equal, three sliding support plates 6-2 are uniformly and fixedly connected to the sliding support plate 6-2 in the circumferential direction, the positioning sliding posts 6-3 are slidably connected to the three sliding support plates 6-2, and the positioning limiting posts 6-4 are fixedly connected to the three positioning sliding posts 6-3, three positioning limiting columns 6-4 are respectively connected in three sliding blocks II 2-7 in a sliding mode, the inner sides of the three positioning sliding columns 6-3 are respectively connected with positioning extrusion wheels 6-5 in a rotating mode, spring baffles I6-6 are fixedly connected to the three positioning sliding columns 6-3, compression springs I are sleeved on the three positioning sliding columns 6-3 and are located between the spring baffles I6-6 and the sliding support plates 6-2; the compression spring I pushes the three positioning extrusion wheels 6-5 to be in contact with the cable core 9, the cable core 9 is positioned in an extrusion mode, the cable core 9 is located in the axis center position of the anti-abrasion ring II 5-3, when the diameter of the cable core 9 changes, the three positioning extrusion wheels 6-5 can still conduct extrusion positioning on the cable core 9, and the cable core is suitable for different use requirements.

The specific implementation mode is eight:

the following describes the present embodiment with reference to fig. 1 to 12, which further describes an embodiment seven, wherein the smearing mechanism 7 includes two smearing tubes 7-1, two smearing arc plates 7-2, two spring baffles ii 7-3 and two smearing limiting columns 7-4, the smearing tube 7-1 is provided with two smearing tubes 7-1, the two smearing tubes 7-1 are respectively slidably connected to the two connecting plates ii 1-6, the outer ends of the two smearing tubes 7-1 are both connected with a flame-retardant rubber heating pipe, the inner ends of the two smearing tubes 7-1 are both fixedly connected with the smearing arc plates 7-2, the two smearing tubes 7-1 are both fixedly connected with the spring baffles ii 7-3 and the smearing limiting columns 7-4, the two smearing limiting columns 7-4 are respectively slidably connected in the two sliding blocks i 1-10, the two smearing pipes 7-1 are sleeved with compression springs II, and the compression springs II are located between the connecting plates II 1-6 and the spring baffles II 7-3; the flame-retardant rubber heating pipe heats the flame-retardant rubber into a fluid and pushes the fluid into the two smearing pipes 7-1, the two smearing pipes 7-1 evenly smear the flame-retardant rubber heated into the fluid on the cable core 9 wound by the processing material, and the cable core 9 is more evenly smeared by the flame-retardant rubber which is automatically converted into the fluid, so that when the diameter of the cable core 9 wound by the processing material is changed, the compression spring II is extruded and generates a reaction force to enable the two smearing arc plates 7-2 to still be in contact with the cable core 9 wound by the processing material.

The specific implementation method nine:

this embodiment will be described with reference to fig. 1 to 12, and this embodiment will further describe embodiment eight, the extrusion mechanism 8 comprises an extrusion sliding column I8-1, an extrusion plate 8-2, an extrusion sliding column II 8-3 and an extrusion forming wheel 8-4, one end of the extrusion sliding column I8-1 is fixedly connected with the extrusion plate 8-2, the other end of the extrusion sliding column I8-1 is rotatably connected with the extrusion forming wheel 8-4, two extrusion sliding columns II 8-3 are fixedly connected onto the extrusion plate 8-2, the extrusion mechanism 8 is provided with two extrusion sliding columns II 8-3, the two extrusion sliding columns II 8-3 on two sides are respectively and slidably connected onto corresponding connecting plates II 1-6, compression springs III are sleeved on the four extrusion sliding columns II 8-3, and the compression springs III are positioned between the connecting plates II 1-6 and the extrusion plate 8-2; the two extrusion molding wheels 8-4 perform extrusion molding on the cable core 9 coated with the fluid flame-retardant rubber under the action of the compression spring III, and the fluid flame-retardant rubber is rapidly cooled and molded due to the lower temperature of the two extrusion molding wheels 8-4.

The detailed implementation mode is ten:

the following describes the present embodiment with reference to fig. 1 to 12, and the present embodiment further describes an embodiment nine, where one end of the cable core 9 is wound on the driven storage barrel 5 to 6, and the other end of the cable core 9 sequentially passes through the anti-abrasion ring ii 5 to 3, between the three positioning extrusion wheels 6 to 5, between the two smearing arc plates 7 to 2, between the two extrusion molding wheels 8 to 4, and the anti-abrasion ring i 4 to 3 to be wound on the driving storage barrel 4 to 6.

The invention relates to a flame-retardant cable processing system, which has the working principle that:

when the cable core is used, one end of a cable core 9 is wound on a driven storage barrel 5-6, the other end of the cable core 9 sequentially passes through an anti-abrasion ring II 5-3, three positioning extrusion wheels 6-5, two smearing arc plates 7-2, two extrusion forming wheels 8-4 and an anti-abrasion ring I4-3 to be wound on a driving storage barrel 4-6, the storage motor 4-8 is started, an output shaft of the storage motor 4-8 starts to rotate, an output shaft of the storage motor 4-8 drives a driving shaft 4-5 to rotate by taking the axis of the driving shaft 4-5 as the center, the driving shaft 4-5 drives the driving storage barrel 4-6 to rotate by taking the axis of the driving shaft 4-6 as the center, the driving storage barrel 4-6 pulls the cable core 9 to be wound on the driving storage barrel 4-6, and the motor 3-, the output shaft of the motor 3-1 starts to rotate, the output shaft of the motor 3-1 drives the gear I3-2, the gear II 3-3 and the gear III 3-4 to rotate by taking the axis of the gear I3-2, the gear II 3-3 and the gear III 3-4 as the center, the diameters of the gear I3-2, the gear II 3-3 and the gear III 3-4 are equal, the same rotating speed is ensured, and the cable core 9 is ensured not to generate differential speed when passing through a plurality of mechanisms when autorotation occurs; the rotation speed of the storage motor 4-8 can be adjusted, the speed of the active storage barrel 4-6 for storing the cable core 9 is adjusted, two ends of the driving shaft 4-5 are respectively connected in the two clamping grooves I in a sliding mode, the active storage barrel 4-6 is in clearance fit with the driving shaft 4-5, and replacement of the active storage barrel 4-6 is facilitated; the two support frames II 5-4 are respectively provided with a clamping groove II, two ends of the driven shaft 5-5 are respectively connected in the two clamping grooves II in a sliding manner, two ends of the driven shaft 5-5 are respectively connected with mounting nuts 5-7 through threads, and the inner sides of the two mounting nuts 5-7 are respectively contacted with the two support frames II 5-4, so that the driven storage barrel 5-6 can be quickly disassembled, and the cable core 9 on the driven storage barrel 5-6 can be quickly replaced when the cable core is completed by the driving storage barrel 4-6; the compression spring I pushes the three positioning extrusion wheels 6-5 to be in contact with the cable core 9, the cable core 9 is extruded and positioned, the cable core 9 is guaranteed to be located at the axis center position of the anti-abrasion ring II 5-3, when the diameter of the cable core 9 changes, the three positioning extrusion wheels 6-5 can still extrude and position the cable core 9, and the cable core pressing device is suitable for different use requirements; materials required by cable processing are wound on the three winding drums 2-4, the cable processing materials can be glass fibers and other materials capable of being wound, the materials on the three winding drums 2-4 are sequentially and respectively fixedly connected to the cable core 9, the materials are sequentially and fixedly connected to the cable core 9 according to the winding sequence required, one processing material required to be wound is fixedly connected firstly, the next material is fixed on the previous material after the cable core 9 moves for a certain distance, and the winding of different types of materials in different sequences is completed sequentially by repeated operation; the flame-retardant rubber heating pipe heats the flame-retardant rubber into a fluid and pushes the fluid into the two smearing pipes 7-1, the two smearing pipes 7-1 evenly smear the fluid-heated flame-retardant rubber on the cable core 9 wound by the processing material, and as the cable core 9 is automatically converted into the fluid, the fluid-heated flame-retardant rubber can be smeared more evenly, when the diameter of the cable core 9 wound by the processing material is changed, the compression spring II is extruded and generates a reaction force to ensure that the two smearing arc plates 7-2 can still be contacted with the cable core 9 wound by the processing material; the two extrusion molding wheels 8-4 perform extrusion molding on the cable core 9 coated with the fluid flame-retardant rubber under the action of the compression spring III, and the fluid flame-retardant rubber is rapidly cooled and molded due to the lower temperature of the two extrusion molding wheels 8-4.

It is to be understood that the above description is not intended to limit the present invention, and the present invention is not limited to the above examples, and that various changes, modifications, additions and substitutions which are within the spirit and scope of the present invention and which may be made by those skilled in the art are also within the scope of the present invention.

Claims (10)

1. The utility model provides a flame retarded cable system of processing, is including accomodating support (1), locating support (2), power unit (3), initiative receiving mechanism (4), driven receiving mechanism (5), positioning mechanism (6), scribble mechanism (7), extrusion mechanism (8) and cable core (9), its characterized in that: the flame-retardant rubber coating machine is characterized in that the positioning support (2) is fixedly connected to the containing support (1), the positioning support (2) is fixedly connected with a power mechanism (3), two ends of the containing support (1) are respectively and rotatably connected with a driving containing mechanism (4) and a driven containing mechanism (5), the power mechanism (3) and the driving containing mechanism (4) are in gear engagement transmission, the power mechanism (3) and the driven containing mechanism (5) are in gear engagement transmission, the positioning support (2) is rotatably connected with a positioning mechanism (6), the positioning mechanism (6) and the power mechanism (3) are in gear engagement transmission, the coating mechanism (7) is in sliding connection with the containing support (1), the coating mechanism (7) is connected with a flame-retardant rubber heating pipe, a compression spring II is arranged between the coating mechanism (7) and the containing support (1), and two extrusion mechanisms (8) are arranged, the two extrusion mechanisms (8) are both connected with the containing support (1) in a sliding manner, a compression spring III is arranged between the extrusion mechanisms (8) and the containing support (1), one end of a cable core (9) is wound on the driven containing mechanism (5), and the other end of the cable core (9) is wound on the driving containing mechanism (4) through the positioning mechanism (6), the smearing mechanism (7) and the extrusion mechanism (8) in sequence;

the positioning support (2) comprises a positioning bottom plate (2-1), winding positioning shafts (2-2), positioning nuts (2-3), winding cylinders (2-4), rotating grooves (2-5), positioning sliding grooves (2-6) and sliding blocks II (2-7), wherein three winding positioning shafts (2-2) are uniformly and fixedly connected to one side of the positioning bottom plate (2-1) in the circumferential direction, the three winding positioning shafts (2-2) are connected with the positioning nuts (2-3) through threads, the winding cylinders (2-4) are in clearance fit with the three winding positioning shafts (2-2), the rotating grooves (2-5) are arranged on the other side of the positioning bottom plate (2-1), the three positioning sliding grooves (2-6) are uniformly arranged on the positioning bottom plate (2-1) in the circumferential direction, sliding blocks II (2-7) are connected in the three positioning sliding grooves (2-6) in a sliding manner.

2. A fire retardant cable processing system according to claim 1, wherein: the storage support (1) comprises a bottom plate (1-1), support plates I (1-2), connecting columns (1-3), connecting plates I (1-4), connecting rings I (1-5), connecting plates II (1-6), support plates II (1-7), connecting plates III (1-8), sliding grooves (1-9), sliding blocks I (1-10) and connecting rings II (1-11), wherein two support plates I (1-2) are arranged, the two support plates I (1-2) are fixedly connected with the two support plates I (1-2), the connecting columns (1-3) are fixedly connected between the two support plates I (1-2) on two sides, the two connecting plates I (1-4) are arranged, and the two connecting plates I (1-4) are respectively and fixedly connected to the two support plates I (1-2) on one side, fixedly connected with go-between II (1-5) between two connecting plates I (1-4), connecting plate II (1-6) are provided with two, two connecting plates II (1-6) are respectively fixedly connected on two backup pads I (1-2) of opposite side, equal fixedly connected with backup pad II (1-7) on two connecting plates II (1-6), fixedly connected with connecting plate III (1-8) between the upper end of two backup pads II (1-7), be provided with two sliding tray (1-9) on connecting plate III (1-8), equal sliding connection of two sliding tray (1-9) has sliding block I (1-10), fixedly connected with go-between II (1-11) between two connecting plates II (1-6).

3. A fire retardant cable processing system according to claim 2, wherein: two ends of the positioning bottom plate (2-1) are respectively and fixedly connected to the two connecting columns (1-3).

4. A fire retardant cable processing system according to claim 3, wherein: the power mechanism (3) comprises a motor (3-1), a gear I (3-2), a gear II (3-3) and a gear III (3-4), the motor (3-1) is fixedly connected to the positioning bottom plate (2-1), the gear I (3-2), the gear II (3-3) and the gear III (3-4) are fixedly connected to an output shaft of the motor (3-1), and the diameters of the gear I (3-2), the gear II (3-3) and the gear III (3-4) are equal.

5. A fire retardant cable processing system according to claim 4, wherein: the driving storage mechanism (4) comprises a driving storage disc (4-1), a gear ring I (4-2), an anti-abrasion ring I (4-3), a support frame I (4-4), a driving shaft (4-5), a driving storage barrel (4-6), a motor support (4-7) and a storage motor (4-8), wherein the driving storage disc (4-1) is fixedly connected with the anti-abrasion ring I (4-3), the anti-abrasion ring I (4-3) and the driving storage disc (4-1) are coaxially arranged, the driving storage disc (4-1) is rotatably connected onto a connecting ring II (1-11), one side of the driving storage disc (4-1) is fixedly connected with the gear ring I (4-2), the gear ring I (4-2) and a gear III (3-4) are in meshing transmission, and the eccentric position of the other side of the driving storage disc (4-1) is fixedly connected with two support frames I (4) through fixedly connected with -4), the two support frames I (4-4) are respectively provided with a clamping groove I, two ends of the driving shaft (4-5) are respectively connected in the two clamping grooves I in a sliding mode, one support frame I (4-4) is fixedly connected with a motor support (4-7), the motor support (4-7) is fixedly connected with a storage motor (4-8), an output shaft of the storage motor (4-8) is fixedly connected to the driving shaft (4-5), the driving storage barrel (4-6) is in clearance fit with the driving shaft (4-5), and the storage motor (4-8) is a servo motor.

6. A fire retardant cable processing system according to claim 5, wherein: the driven storage mechanism (5) comprises a driven storage disc (5-1), a gear ring II (5-2), an anti-abrasion ring II (5-3), a support frame II (5-4), a driven shaft (5-5), a driven storage barrel (5-6) and a mounting nut (5-7), the driven storage disc (5-1) is rotatably connected to the connecting ring I (1-5), the gear ring II (5-2) is fixedly connected to one side of the driven storage disc (5-1), the gear ring II (5-2) and the gear I (3-2) are in meshing transmission, the gear ring II (5-2) and the gear ring I (4-2) are equal in diameter, the anti-abrasion ring II (5-3) is fixedly connected to the driven storage disc (5-1), and the anti-abrasion ring II (5-3) and the driven storage disc (5-1) are coaxially arranged, two supporting frames II (5-4) are fixedly connected to the eccentric position of the other side of the driven storage disc (5-1), clamping grooves II are formed in the two supporting frames II (5-4), two ends of the driven shaft (5-5) are connected into the two clamping grooves II in a sliding mode respectively, mounting nuts (5-7) are connected to two ends of the driven shaft (5-5) through threads, and the inner sides of the two mounting nuts (5-7) are in contact with the two supporting frames II (5-4) respectively.

7. A fire retardant cable processing system according to claim 6, wherein: the positioning mechanism (6) comprises a positioning rotating ring (6-1), a sliding support plate (6-2), a positioning sliding column (6-3), a positioning limiting column (6-4), a positioning extrusion wheel (6-5) and a spring baffle I (6-6), the sliding support plate (6-2) is rotatably connected in a rotating groove (2-5), the sliding support plate (6-2) and a gear II (3-3) are in meshing transmission, the reference circle diameters of the sliding support plate (6-2) and the gear ring I (4-2) are equal, three sliding support plates (6-2) are uniformly and fixedly connected to the sliding support plate (6-2) in the circumferential direction, the positioning sliding columns (6-3) are respectively and slidably connected to the three sliding support plates (6-2), and the positioning limiting columns (6-4) are respectively and fixedly connected to the three positioning sliding columns (6-3), three positioning limiting columns (6-4) are respectively connected in three sliding blocks II (2-7) in a sliding mode, the inner sides of the three positioning sliding columns (6-3) are respectively connected with positioning extrusion wheels (6-5) in a rotating mode, spring baffles I (6-6) are fixedly connected to the three positioning sliding columns (6-3), compression springs I are sleeved on the three positioning sliding columns (6-3) and located between the spring baffles I (6-6) and the sliding supporting plates (6-2).

8. A fire retardant cable processing system according to claim 7, wherein: the smearing mechanism (7) comprises smearing pipes (7-1), smearing arc plates (7-2), spring baffles II (7-3) and smearing limiting columns (7-4), two smearing pipes (7-1) are arranged, the two smearing pipes (7-1) are respectively connected to the two connecting plates II (1-6) in a sliding mode, the outer ends of the two smearing pipes (7-1) are respectively connected with a flame-retardant rubber heating pipe, the inner ends of the two smearing pipes (7-1) are respectively fixedly connected with the smearing arc plates (7-2), the two smearing pipes (7-1) are respectively fixedly connected with the spring baffles II (7-3) and the smearing limiting columns (7-4), the two smearing limiting columns (7-4) are respectively connected into the two sliding blocks I (1-10) in a sliding mode, compression springs II are sleeved on the two smearing pipes (7-1), and the compression spring II is positioned between the connecting plate II (1-6) and the spring baffle II (7-3).

9. A fire retardant cable processing system according to claim 8, wherein: the extrusion mechanism (8) comprises an extrusion sliding column I (8-1) and an extrusion plate (8-2), the extrusion sliding column II (8-3) and the extrusion forming wheel (8-4), one end of the extrusion sliding column I (8-1) is fixedly connected with an extrusion plate (8-2), the other end of the extrusion sliding column I (8-1) is rotatably connected with the extrusion forming wheel (8-4), two extrusion sliding columns II (8-3) are fixedly connected onto the extrusion plate (8-2), two extrusion mechanisms (8) are arranged, the two extrusion sliding columns II (8-3) on two sides are respectively connected onto the corresponding connecting plates II (1-6) in a sliding mode, compression springs III are sleeved on the four extrusion sliding columns II (8-3), and the compression springs III are located between the connecting plates II (1-6) and the extrusion plates (8-2).

10. A fire retardant cable processing system according to claim 9, wherein: one end of the cable core (9) is wound on the driven storage barrel (5-6), and the other end of the cable core (9) sequentially penetrates through the anti-abrasion ring II (5-3), the three positioning extrusion wheels (6-5), the two smearing arc plates (7-2), the two extrusion molding wheels (8-4) and the anti-abrasion ring I (4-3) to be wound on the driving storage barrel (4-6).

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