Drawings
FIG. 1 is a block diagram illustrating the flow of a production process for small bend radius cables;
fig. 2 is a schematic view of a polymerization mold for a cable conductor in the present invention;
FIG. 3 is a schematic view of a wire distribution plate;
FIG. 4 is a schematic view of a polycrystalline mold;
FIG. 5 is a schematic view of a first cable pulling mechanism or a second cable pulling mechanism;
FIG. 6 is a schematic view of the structure of a first extruder;
FIG. 7 is a schematic cross-sectional view of the fine adjustment apparatus shown in FIG. 6;
FIG. 8 is a schematic cross-sectional view of the support body of FIG. 7;
FIG. 9 is a cross-sectional view of the guide assembly of FIG. 7;
FIG. 10 is a schematic view of the first embodiment of the drive member of FIG. 7 engaged with a guide assembly;
FIG. 11 is a schematic view of a second embodiment of the drive member of FIG. 7 engaged with a guide assembly;
reference numbers in the drawings:
a is a branching polymerization mechanism, B is a unit to be stranded, C is a stranding mechanism, and D is a stranding unit;
the cable is characterized in that 1 is a distributing board, 2 is a central hole, 3 is a first layer of wire passing channel, 4 is a second layer of wire passing channel, 5 is a third layer of wire passing channel, and 6 is a wire passing hole;
7 is a first polycrystalline die, 8 is a second polycrystalline die, and 9 is a third polycrystalline die;
10 is a polycrystalline die body, 10a is an incident hole section, 10b is a diameter forming hole section, 10c is an outlet hole section, 10d is a straight line, 10e is a first arc transition section, and 10f is a second arc transition section; 10g is a middle transition section, 11 is a polycrystalline layer, and 12 is a fillet;
13 is a belt pulley, 14 is a belt, 15 is a linear driver, 16 is a swinging seat, 17 is a guide wheel, 18 is an elastic component, and 19 is a sensor;
100 is an offset-adjustment-free extruder head;
200 is a fine adjustment device:
210 is a support body, 211 is a first mounting hole, and 212 is a second mounting hole;
220 is a guide component, 221 is a first conduit, 222 is a second conduit, 223 is a flange, 224 is a recess, 225 is a bearing;
230 is a driving part;
300 is a wire guide wheel.
Detailed Description
As shown in fig. 1, the method for producing the cable with small bending radius comprises the following steps:
s1, enabling a plurality of discrete conductors to pass through the branching polymerization mechanism A to be polymerized to form a unit B to be stranded, and arranging the units to be stranded according to the following mode: a first conductor layer formed of a first conductor; a second conductor layer formed of a plurality of second conductors located on the first circumference, the second conductors surrounding the first conductors, the first conductor layer extending in a central direction of the second conductor layer;
in this embodiment, the printed circuit board further includes a third conductor layer and a fourth conductor layer, the third conductor layer is formed by a plurality of third conductors located on the second circumference, the fourth conductor layer is formed by a plurality of fourth conductors located on the third circumference, the third conductor layer surrounds the second conductor, and the fourth conductor layer surrounds the third conductor.
In this embodiment, it is preferable that the number of the first conductor layers is 1, the number of the conductors in the second conductor layer is 6, the number of the conductors in the third conductor layer is 12, and the number of the conductors in the fourth conductor layer is 18.
And S2, feeding the unit to be stranded into a stranding mechanism C for stranding to obtain a stranding unit D, wherein the stranding mechanism C preferably adopts a 500-type strand machine. The twisting mechanism C and the branching polymerization mechanism A form a twisting device.
And S3, the stranding unit passes through a first extruder of a first extruder under the traction of a first traction mechanism, and the first extruder extrudes the insulating material and combines the extruded insulating material on the surface of the stranding unit in the process of passing through the first extruder, so that an insulating layer is formed on the surface of the stranding unit to obtain a single insulating wire core.
S4, stranding the plurality of insulation wire cores by using a cabling machine to obtain a cable core;
s5, forming a shielding layer on the surface of the cable core after the cable core obtained in the step S4 is woven by a weaving machine;
and S6, the cable core braided with the shielding layer passes through a second extruder of a second extruder under the traction of a second traction mechanism, and in the process of extruding the cable core braided with the shielding layer through the second extruder, the second extruder extrudes the insulating material and then bonds the insulating material on the surface of the shielding layer, so that a sheath is formed on the surface of the shielding layer to obtain the cable with the small bending radius.
In this embodiment, the method further includes a step of forming a shielding layer on the surface of the cable core after the cable core obtained in step S4 is braided by a braiding machine, and the shielding layer is formed, so that the cable with a small bending radius has good anti-interference performance.
The branching and aggregating mechanism used in step S1 includes:
as shown in fig. 2 and 3, a wire distributing plate 1 and a polycrystalline die are provided, where the wire distributing plate 1 is provided with a central hole 2 and a plurality of layers of wire passing channels, in this embodiment, preferably, the wire passing channels include a first layer of wire passing channel 3, a second layer of wire passing channel 4, and a third layer of wire passing channel 5, each layer of wire passing channel includes a plurality of discrete wire passing holes 6, centers of the wire passing holes 6 in each layer of wire passing channel are located on the same circumference, and thus, the wire passing holes 6 in each wire passing channel are located around the central hole 2, and since the three layers of wire passing channels are provided in this embodiment, the arrangement modes of the three layers of wire passing channels are as follows: the second layer of wire passing channel 4 is positioned around the first layer of wire passing channel 3, and the third layer of wire passing channel 5 is positioned around the second layer of wire passing channel 4. The distance between the circumference of the circle center of the wire passing hole 6 in any wire passing channel and the central hole 2 is not equal to the distance between the circumference of the circle center of the wire passing hole in other wire passing channels and the central hole;
as shown in fig. 2 and 3, the polycrystalline dies provide a first included incident angle α for the conductor output from each wire through hole, at least one polycrystalline die is disposed downstream of the wire distribution plate, each polycrystalline die aggregates the conductor output from the wire distribution plate, preferably, the polycrystalline dies include a first polycrystalline die 7, a second polycrystalline die 8, and a third polycrystalline die 9, and the distance between the wire distribution plate 1 and each polycrystalline die is determined by the following calculation formula:
x1 is the distance between the distribution board 1 and the first poly crystal module 7, a is the central distance from the central hole 2 on the distribution board 1 to the wire passing hole 6 in the first layer wire passing channel 3;
x2 is the distance between the distribution board 1 and the second polymer die 8, b is the central distance from the central hole 2 on the distribution board 1 to the wire passing hole 6 in the second layer of wire passing channel 4;
x3 is the distance between the distribution board 1 and the third crystal module 9, and c is the central distance from the central hole 2 on the distribution board 1 to the wire passing hole 6 in the third layer of wire passing channel 5;
α is a first included angle of incidence.
as shown in fig. 4, each polycrystalline die comprises a polycrystalline die body 10, and a line gathering hole arranged on the polycrystalline die body 10, wherein the line gathering hole comprises an incident hole section 10a, a diameter forming hole section 10b, and a line outlet section 10c, the radius of the incident hole section 10a gradually shrinks from the input end to the output end, so that a first incident included angle α is an included angle formed between a straight line 10d connecting the input end and the output end of the incident hole section 10a and the axis of the polycrystalline die, the size of the first incident included angle α is 30-40 °, in the present embodiment, preferably, the first incident included angle α is 37.5 °, the diameter forming hole section 10b enables the conductors output from the incident hole section 10a to be converged to form a unit to be twisted, the diameter forming hole section 10b is located downstream of the incident hole section 10a, the line outlet section 10c is located downstream of the diameter forming hole section 10b, the input end of the incident hole section 10a is provided with a round corner 12, the corresponding radius of the round corner 12 is 1.5mm, and the round corner 12 can prevent the input end from generating a conductor side pressure acting force on the input end.
Because the structure of the polycrystalline die and the space between each polycrystalline die and the distributing board 1 are reasonably designed, when the conductor is incident into each polycrystalline die from the input end of the polycrystalline die, the conductor cannot interfere with the inner hole wall surface of the incident hole section 10a of the polycrystalline die, and thus, the conductor cannot be subjected to the lateral pressure of the polycrystalline die on the inner wall of the incident hole section 10a, the conductor smoothly enters the diameter forming hole section 10b and is polymerized in the diameter forming hole section 10b, and the conductors of each layer are arranged according to the arrangement mode of the step S1, so that the leads of each layer are arranged according to the set mode, and further the phenomenon of creek of the conductors of each layer cannot occur after the to-be-twisted unit is formed.
As shown in FIG. 4, the cross section of the reducing hole section 10b comprises a first arc transition section 10e connected with the output end of the incident hole section 10a, a second arc transition section 10f connected with the outlet hole section 10c, and an intermediate transition section 10g positioned between the first arc transition section 10e and the second arc transition section 10f, wherein a tangent of the first arc transition section 10e forms a second included angle β of 9-10 degrees with the axial direction of the ray gathering hole, the radius of the first arc transition section is 1.3-1.7mm, and preferably, the radius of the first arc transition section is 1.5 mm.
As shown in fig. 4, by designing the structure of the bore section 10b, the conductor smoothly transits from the incident hole section 10a and enters into the bore section 10b, so that the entry angle of the conductor into the bore section 10b is reduced, and therefore, the resistance of the conductor in forming the unit to be twisted is reduced, and the jumping of the conductor is avoided.
As shown in FIG. 4, the length of the intermediate transition section 10g and the second arc-shaped transition section 10f along the axial direction of the suture hole is 1.8-2.2mm, and preferably, the length of the intermediate transition section 10g and the second arc-shaped transition section 10f along the axial direction of the suture hole is 2 mm. After the conductor passes through the first arc transition section 10e, the conductor is polymerized in the middle transition section 10g and the second arc transition section 10f, and the sum of the lengths of the middle transition section 10g and the second arc transition section 10f is designed to be 2mm, so that compared with the prior art of the diameter forming area, the length of the diameter forming area in the embodiment is shortened, the resistance of the conductor in the diameter forming area in the diameter forming hole section 10b is reduced, and the conductor is further prevented from jumping.
As shown in fig. 4, the surface of the diameter forming hole section 10b is provided with a polycrystalline layer 11, and the surface of the polycrystalline layer 11 is smooth, so that the resistance of the conductor in the moving process is reduced.
As shown in fig. 4, the radius of the outlet hole section 10c gradually increases from the input end to the output end, and a straight line connecting the output end and the input end of the outlet hole section forms a third included angle γ with the axial direction of the ray gathering hole, where the third included angle γ is 20-30 °.
As shown in fig. 5, in the present embodiment, the first traction mechanism and the second traction mechanism have the same structure, and the first traction mechanism and the second traction mechanism in the present embodiment include: a pair of traction mechanism that makes insulating core or small bend radius cable translation that is symmetrical arrangement, traction mechanism includes: at least two pulleys 13, a belt 14 closed on the pulleys, at least two traction guide mechanisms for driving the belt to move to a traction position according to the outer diameter of the insulating layer or the sheath, the traction guide mechanisms comprise: the device comprises a linear driver 15, a swinging seat 16 and a guide wheel 17, wherein the swinging seat 16 swings according to the direction of a reverse acting force generated by an insulated wire core or a cable with a small bending radius in the traction process, the swinging seat 16 is movably connected with the power output end of the linear driver 15, and the guide wheel 17 is movably connected on the swinging seat 16. The linear actuator 15 may be a pneumatic cylinder, a hydraulic cylinder, or an electric screw, and in this embodiment, the linear actuator 15 is preferably a pneumatic cylinder.
As shown in fig. 5, the insulated wire core or the small bending radius cable is passed through a pulling mechanism, and in the case where the upper and lower belts 14 are held and operated with the belts 14, the insulated wire core or the small bending radius cable is moved with the belts 14 to be pulled.
As shown in fig. 5, however, when the insulated wire core or the cable with small bending radius is pulled by the pulling mechanism, the winder winds the insulated wire core or the cable with small bending radius, and the diameter of the cable roll on the winder changes with the winding of the insulated wire core or the cable with small bending radius, so that an included angle is formed between the insulated wire core or the cable with small bending radius when the insulated wire core or the cable with small bending radius is pulled by the pulling mechanism and the winder, and therefore the insulated wire core or the cable with small bending radius fluctuates to different degrees when the insulated wire core or the cable with small bending radius is pulled by the pulling mechanism, namely the insulated wire core or the cable with small bending radius does not move linearly continuously but fluctuates upwards or downwards, and thus the insulated wire core or the cable with small bending radius generates fluctuating acting force on. And because the insulating core or the insulating layer or the sheath of the cable with small bending radius drawn by the drawing mechanism just undergoes high-temperature extrusion molding, a certain temperature is still maintained and the cable is in an easily deformable state although the cable is cooled by the cooling mechanism, and if the clamping force of the belt 14 is constant, the insulating core or the cable with small bending radius is still easily deformed in the drawing process although the radian of fluctuation is small.
Therefore, in the utility model discloses in, as shown in fig. 5, swing seat 16 is swing joint with the connected mode of linear actuator 15, when insulating sinle silk or little bend radius cable are undulant, the undulant effort that insulating sinle silk or little bend radius cable produced acts on belt 14, transmit through belt 14 and make swing seat 16 take place to swing on swing seat 16, with the effort that adjustment swing seat 16 produced through belt 13, when making insulating sinle silk or little bend radius cable undulant, make swing seat 16 obtain small adjustment to the effort that insulating sinle silk or little bend radius cable produced, in order to avoid insulating sinle silk or little bend radius cable to be out of shape by the drive mechanism traction in-process.
As shown in fig. 5, in addition, because the take-up distance between the winder and the traction mechanism is too small, the influence of the formed included angle is relatively large, the acting force on the cable is large, and the deformation quantity is reduced by fine adjustment after the swing seat 16 at the outlet of the out-position tractor swings, so that the influence on the acting force of the cable is reduced, proper air pressure is selected according to the outer diameter of the cable, the cable is prevented from being flattened by overlarge pressure of the crawler belt, and the roundness of the cable is ensured.
As shown in fig. 5, the traction mechanism further includes an elastic member 18 for limiting the swing arc of the swing seat, one end of the elastic member 18 is engaged with the linear actuator 15, and the other end of the elastic member 18 is engaged with the swing seat. Although swing seat 16 can take place, but wobbling radian can not be too big, otherwise can influence towed speed and receive the influence, consequently, the utility model discloses in restrict swing seat 16's swing radian through elastomeric element 18, impel swing seat 16, leading wheel 17 to belt 14 formation tensioning's state to guarantee the frictional force between belt 14 and insulating core or the small bend radius cable, and then make the traction efficiency of insulating core or small bend radius cable obtain guaranteeing.
As shown in fig. 5, the elastic member 18 is preferably a spring, and the spring is preferably a conical coil spring, a small diameter end of the conical coil spring is engaged with the linear actuator, and a large diameter end of the conical coil spring is engaged with the swing seat. The contact area of the conical spiral spring and the swing seat can be increased by the large-diameter end of the conical spiral spring and the swing seat, so that the swing amplitude of the swing seat is limited within a required range.
As shown in fig. 5, the pulling mechanism further includes a sensor 19 for detecting the displacement of the swing base 16, and one end of the sensor 19 is connected to the swing base 16. When the swing base 16 is driven by the linear driver 15 to ascend and descend, the sensor 19 works along with the ascending and descending of the swing base 16, so that the displacement of the swing base 16 is detected at any time, the displacement is fed back to a controller (not shown in the figure), the linear driver 15 is controlled to work, the position of the swing base 16 is further accurately controlled, the belt 14 is enabled to accurately move to a position where an insulated wire core or a cable with a small bending radius needs to be pulled, and the influence of overlarge pressure on the cable roundness can be prevented. The sensor 19 is preferably a resistive displacement sensor.
As shown in fig. 5, since there are sensors 19 on both the upper and lower sides of the cable H, through the distance between the sensors 19 on both the upper and lower sides of the insulated wire core or the cable with small bending radius, after the linear driver 15 drives the swing seat 16 to make the belt 14 act on the insulated wire core or the cable with small bending radius, the controller can calculate the distance between the two belts 14 on the diameter of the insulated wire core or the cable with small bending radius, and the controller controls the linear driver 15 to finely adjust the acting force of the belt 14 according to the size of the diameter of the insulated wire core or the cable with small bending radius and the distance of the belt 14, so that the roundness of the insulated wire core or the cable with small bending radius is not affected during the pulling process.
As shown in fig. 6, the first extruder includes an offset-free extruder head 100, a fine adjustment mechanism 200 for adjusting the position of the strand unit D so that the center of the strand unit D and the center of the offset-free extruder head are located on the same straight line, and the fine adjustment mechanism 200 is located upstream of the offset-free extruder head.
As shown in fig. 7 and 8, the fine adjustment mechanism 200 includes: the hinge assembly comprises a support body 210, a guide assembly 220 for guiding the twisting unit D, and a plurality of driving members 230, wherein the support body 210 is provided with a first mounting hole 211 penetrating through the axial end face, the circumferential surface of the support body 210 is provided with a plurality of second mounting holes 212 extending along the radial direction of the support body 210, and the second mounting holes 212 are communicated with the first mounting holes 211; one driving member 230 is fitted into each second mounting hole 212, and after a plurality of driving members 230 are fitted to the guide assembly, the driving members 230 clamp the guide assembly 220 such that the guide assembly 220 is loosely fitted into the first mounting hole 211. The driving members 230 are preferably four, and the four driving members 230 are located on the same circumference of the supporting body 210 and are arranged at intervals of 90 degrees.
In the embodiment, as shown in fig. 7 and 8, the second mounting hole 212 is preferably a threaded hole, and the driving member 230 is preferably a screw, and after the screw is threadedly coupled with the threaded hole, the end of the screw is engaged with the guide assembly.
By adjusting the driving component 230, the driving component 230 drives the supporting and guiding assembly 220 to move radially (for example, move along the up-down and left-right directions of the supporting body 210), so that the center of the wire passing through the guiding assembly 220 and the center of the deviation-free extrusion head 100 are located on the same straight line, and the position error caused by abrasion of different programs of the deviation-free extrusion head 100 and the wire wheel 300 is compensated, and after the fine adjustment mechanism 200 is arranged between the wire wheel 300 and the deviation-free extrusion head 100, the fine adjustment mechanism 200 plays a supporting role on the wire, so that the wire can be flatter and straighter in the process of moving from the wire wheel to the deviation-free extrusion head 100, and the shaking amplitude is reduced.
As shown in fig. 7 and 8, the guide assembly 220 includes a first guide pipe 221, a second guide pipe 222 engaged with the driving part, and the second guide pipe 222 is fitted in the inner hole of the first guide pipe 221. Preferably, an inner hole of the first guide pipe 221 is provided with an inner thread, a circumferential surface of the second guide pipe 222 is provided with an outer thread, and the second guide pipe 222 is connected with the first guide pipe 221 through a thread. By combining the first guide duct 221 and the second guide duct 222, when the second guide duct 222 is worn, the second guide duct 222 can be easily replaced to ensure the accuracy of the guidance.
As shown in fig. 7 and 8, one end of the second duct 222 is provided with a flange 223, and the flange 223 is exposed to the outside of the support body 221. The second guide pipe 222 can be conveniently rotated by the flange 223 to engage or disengage the second guide pipe 222 with or from the first guide pipe 221.
As shown in fig. 9 and 10, a recess 224 is formed on the circumferential surface of the guide member 220, and one end of the driving member 230 is engaged with the recess. The recesses 224 are grooves, the number of the recesses 224 is equal to the number of the driving members 230, i.e., 4, and the recesses 224 are distributed on the circumferential surface of the guide assembly 220 and arranged at 90 degrees intervals along the same circumference. For example, when the driving member 230 is a bolt, the end of the bolt is in clearance fit with the recess 224, so that the guide assembly 220 is prevented from sliding relative to the driving member 230, thereby limiting the axial movement of the guide assembly 220 along the first mounting hole 211 and ensuring the adjustment accuracy.
As shown in fig. 11, a recess 224 is formed on the circumferential surface of the guide assembly, the guide assembly 220 further includes a bearing 225, the bearing 225 is installed in the recess, and one end of the driving member is connected to the bearing 225. For example, when the driving member 230 is a bolt, the driving member 230 is rotated, and the driving member 230 and the guide assembly 220 have no frictional force by cooperation with the bearing 225, so that the guide assembly 220 is prevented from sliding relative to the driving member 230, and the axial movement of the guide assembly 220 along the first mounting hole 211 is limited, thereby ensuring the adjustment accuracy.
During the use, at first will wait to extrude transposition unit D and pass micromatic setting 200, then pass transposition unit D and exempt from to transfer inclined to one side extrusion aircraft nose 100, normally extrude the insulation on the conductor, observe whether insulation thickness is even through measuring the concentricity, if the eccentric phenomenon appears in the insulation, because exempt from to transfer inclined to one side extrusion aircraft nose 100 and be unable to adjust insulating concentricity, through adjusting drive part 200 on the micromatic setting 200, and select reasonable conductor admission line mouth size according to transposition unit D external diameter, adjustment transposition unit D position, thereby solve insulating eccentric phenomenon, and mark the scale on the drive part (screw), can more accurate definite transfer the integer value.
The utility model discloses be not limited to adopt above-mentioned embodiment, for example, drive component 230 can also adopt the cylinder, and the cylinder body interference fit of cylinder is in second mounting hole 212, and the piston rod and the cooperation of direction subassembly 220 of cylinder. For example, the piston rod of the cylinder engages the recess 224. The amount of extension and retraction of the cylinder rod can be controlled by a controller (not shown) to facilitate precise adjustment.
The second extruder is an offset-adjustment-free extruder head or an adjustable extruder head.