CN117649984B - Drying device for 5G cable production - Google Patents

Abstract

The invention relates to the technical field of 5G cable production and discloses a drying device for 5G cable production, which comprises a main belt pulley, an auxiliary belt pulley, a variable-frequency gas heating structure, a cam type telescopic structure and a sponge adsorption type liquid extrusion structure. This a drying device for 5G cable production can carry out the drying effect of blowing to the cable, and when blowing to the cable, its gas flow direction can carry out the circular motion for the cable of directional motion to make high temperature gas can carry out the omnidirectional drying effect to the liquid on cable surface, improve the drying uniformity of high temperature gas to the cable and the degree of heating uniformity of cable, in addition, the device can carry out preliminary extrusion formula liquid adsorption function to the cable in cable direction of entering, in order to improve the dehumidification ability to the cable, and, the required kinetic energy of device all comes from a driving motor, thereby improve driving motor's kinetic energy utilization, reduce use cost and equipment cost.

Description

Drying device for 5G cable production

Technical Field

The invention relates to the technical field of 5G cable production, in particular to a drying device for 5G cable production.

Background

The cable or the 5G cable is an electric energy or signal transmission device, and is generally a cable similar to a rope formed by twisting several or several groups of wires (at least two wires in each group), wherein each group of wires are mutually insulated and often twisted around a center, the whole outer surface of the cable or the 5G cable is covered with a high-insulation covering layer, the cable or the 5G cable has the characteristics of inner electrifying and outer insulating, the cable or the 5G cable is generally subjected to water cooling after extrusion molding in the production process, the existing cable or the 5G cable is usually not subjected to water removal operation after water cooling, and the attached water can have adverse effects on subsequent production, such as incapability of immediately carrying out printing on the surface of the cable. The current water trap is when wiping cable or 5G cable, along with operating time's growth, wipes the water that accumulates in the cotton and can increase gradually, leads to wiping effect reduction for the cable is more and more difficult to dry, and the cable or 5G cable surface humidity is higher after wiping to accomplish, leads to drying efficiency lower.

For example, chinese patent publication No. CN116453778A discloses a cable production drying device, which mainly comprises a drying box, wherein a supporting frame is fixedly connected to an inner wall of the drying box, and a wiping device is fixedly connected to a top of the supporting frame; the drying device is arranged on one side of the wiping device on the support frame and is fixedly connected with the support frame; the wiping device includes: the fixed ring is internally provided with a rotating ring, one end of the rotating ring is fixedly connected with a rotating plate, and the outer side of the rotating plate is rotationally connected with the inner wall of the fixed ring through a rotating shaft layer; the fixed slide Kong Kaishe is on the rotation ring, the fixed slide is provided with the multiunit and evenly distributed is on the rotation ring, the fixed slide inner wall is provided with the cotton of wiping, and above-mentioned cable production drying device relates to cable production technical field. This cable production drying device avoids producing and cleans the dead angle, cleans the effect better, avoids stopping to handle to cleaning cotton, conveniently improves work efficiency.

In the actual working process, the cable production drying device utilizes the exhaust hole at the fixed space position to blow and dry the cable or the cable body of the cable, and because the cable can not generate a rotation phenomenon in the moving process, the cable facing the exhaust hole can be always influenced by high temperature, on one hand, the drying capacity of the cable deviating from the exhaust hole part is low, and the drying uniformity is poor, on the other hand, the cable body facing the exhaust hole is always influenced by high temperature, so that the rubber on the cable surface can be negatively influenced by high temperature, and meanwhile, the single blowing type drying is utilized, so that the drying capacity is weaker.

Disclosure of Invention

The invention provides a drying device for 5G cable production, which can perform a blowing drying effect on cables, and when the cables are blown, the gas flow direction of the drying device can perform surrounding motion relative to the cables which move directionally, so that the high-temperature gas can perform an omnibearing drying effect on the liquid on the surfaces of the cables, the drying uniformity of the high-temperature gas and the heating uniformity of the cables are improved, in addition, the device can perform a preliminary extrusion type liquid adsorption function on the cables in the cable inlet direction, so that the dehumidification capability of the cables is improved, and the kinetic energy required by the device is from a driving motor, so that the kinetic energy utilization rate of the driving motor is improved, the use cost and the equipment cost are reduced, and the technical problems are solved.

In order to achieve the above object, the present invention provides the following technical solutions: the utility model provides a drying device for 5G cable production, including putting in the horizontal barrel in two bottom support bases through the bearing housing, the wind-force dry cavity that sets up in horizontal barrel center, set up in the peripheral annular gas reservation chamber of wind-force dry cavity, set up in horizontal barrel and be used for the gaseous a plurality of gas injection holes of discharging to the wind-force dry cavity inside by annular gas reservation chamber, the driving motor of fixed mounting in one of them bottom support base top through the fixed cover, be located the turbine shell of driving motor's rotor front end, be located the turbine shell inside and with rotor pivoted turbine flabellum, install in the peripheral hollow shell of horizontal barrel through the mechanical seal structure, be used for hollow shell fixed mounting in the first support of another bottom support base one side and set up in the hollow shell inside and be used for to the annular cavity of annular gas reservation intracavity exhaust, still include main belt pulley and auxiliary belt pulley, main belt pulley is installed in the axis body periphery of rotor, auxiliary belt pulley is installed in the periphery of horizontal barrel, and pass through the belt linkage between main belt pulley and the auxiliary belt pulley; the variable-frequency gas heating structure is arranged between the exhaust port of the turbine shell and the air inlet port of the hollow shell, and is internally provided with an induction coil which generates a magnetic field after variable-frequency current is injected and a metal rod which is positioned in the middle of the induction coil and is heated by electromagnetic induction; the cam type telescopic structure is fixedly arranged on the side surface of one of the bottom support bases through a second bracket, and a cam rotating along with the turbine fan blades and a movable block generating longitudinal telescopic movement along with the rotation of the cam are arranged in the cam type telescopic structure; and the sponge adsorption type liquid extrusion structure is fixedly arranged under the movable block, and a bottom extrusion plate positioned at the bottom of the cable inlet direction, a top extrusion plate positioned above the cable inlet direction and a sponge body positioned between the bottom extrusion plate and the top extrusion plate and used for adsorbing liquid on the surface of the moving cable are arranged in the sponge adsorption type liquid extrusion structure.

Preferably, the variable-frequency gas heating structure comprises an insulating pipeline body and a metal rod, wherein the insulating pipeline body and the metal rod are fixedly arranged between a turbine shell and a hollow shell, a gas flow channel communicated with an exhaust port of the turbine shell and an air inlet port of an annular cavity is arranged in the center of the insulating pipeline body, an annular component mounting cavity is arranged on the periphery of the gas flow channel, an induction coil is arranged in the annular component mounting cavity in a winding mode, a first power access column and a second power access column are arranged on the circumferential side face of the insulating pipeline body and connected with an electric power injection end and an electric power output end of the induction coil, the metal rod is located at the axial center of the gas flow channel, and the bottom end of the metal rod is fixedly arranged on the side wall of the air inlet port of the annular cavity through a transverse connecting rod.

Preferably, the metal rod has a structure radius smaller than that of the gas flow channel, and the top end of the metal rod is provided with an upward tip structure.

Preferably, in operation, the first power access column and the second power access column are respectively connected with two corresponding power access ports of a frequency converter outputting variable frequency current.

Preferably, the cam type telescopic structure comprises a longitudinal hollow shell fixedly mounted on one side surface of a bottom support base through a second bracket and a transverse rotating shaft, wherein the end part of the transverse rotating shaft is fixedly mounted inside the end surface of a turbine fan blade air inlet and penetrates through the turbine shell air inlet, a cam is mounted right above the longitudinal hollow shell, a longitudinal part movable cavity is formed in the longitudinal hollow shell, a movable block capable of longitudinally moving along the longitudinal part movable cavity is mounted inside the longitudinal part movable cavity, a top telescopic rod penetrating through the top end structure of the longitudinal hollow shell is mounted on the upper end surface of the movable block, a collision plate abutting against the bottom of the annular side surface of the cam is mounted on the top end of the top telescopic rod, a bottom telescopic rod penetrating through the bottom structure of the longitudinal hollow shell is mounted on the bottom end of the movable block, and a coil spring in a compressed state is mounted below the movable block.

Preferably, the transverse rotation axis has a smaller radius than the radius of the turbine housing inlet.

Preferably, the distance between the edge structure at one side of the cam and the axial lead of the transverse rotating shaft is smaller than the distance between the edge structure at the other side of the cam and the axial lead of the transverse rotating shaft.

Preferably, the cross section of the movable block has a structural shape identical to that of the cross section of the movable cavity of the longitudinal component, and is of a polygonal structure, and the structural size of the cross section is identical to that of the cross section of the movable cavity of the longitudinal component.

Preferably, the sponge adsorption type liquid extrusion structure comprises a top extrusion plate and a bottom extrusion plate, a rod body fixing groove for fixedly mounting a bottom telescopic rod bottom rod body is formed in the top end of the top extrusion plate, a longitudinal support rod is mounted at the bottom end of the bottom extrusion plate, the rod body of the longitudinal support rod is fixedly mounted on the side face of one bottom support base through a transverse support rod and a fixed mounting plate, a downward-protruding sponge body is embedded in the bottom of the top extrusion plate, and a wire groove for being clamped at the periphery of a cable is formed in the bottom of the sponge body.

Preferably, the central line of the wire slot and the axial line of the wind drying cavity are positioned on the same horizontal line.

Compared with the prior art, the invention provides a drying device for 5G cable production, which has the following beneficial effects:

this a drying device for 5G cable production can carry out the drying effect of blowing to the cable, and when blowing to the cable, its gas flow direction can carry out the circular motion for the cable of directional motion to make high temperature gas can carry out the omnidirectional drying effect to the liquid on cable surface, improve the drying uniformity of high temperature gas to the cable and the degree of heating uniformity of cable, in addition, the device can carry out preliminary extrusion formula liquid adsorption function to the cable in cable direction of entering, in order to improve the dehumidification ability to the cable, and, the required kinetic energy of device all comes from a driving motor, thereby improve driving motor's kinetic energy utilization, reduce use cost and equipment cost.

Drawings

FIG. 1 is a schematic diagram of the present invention in full section;

FIG. 2 is a schematic diagram of a variable frequency gas heating structure in full section;

FIG. 3 is a perspective view of a cam type telescoping structure of the present invention;

FIG. 4 is a perspective cross-sectional view of a cam type telescoping structure of the present invention;

FIG. 5 is a perspective view of a sponge adsorption type liquid squeezing structure in accordance with the present invention;

fig. 6 is a perspective cross-sectional view of a sponge adsorption type liquid squeezing structure in accordance with the present invention.

Wherein: 1. a horizontal cylinder; 2. a bottom support base; 3. drying the cavity by wind power; 4. an annular gas reserving cavity; 5. a gas injection hole; 6. a fixed sleeve; 7. a driving motor; 8. a rotor; 9. a turbine housing; 10. turbine blades; 11. a first bracket; 12. a hollow housing; 13. an annular cavity; 14. a main pulley; 15. a belt; 16. a secondary pulley; 17. a variable frequency gas heating structure; 171. an insulating pipe body; 172. a gas flow channel; 173. an annular component mounting cavity; 174. an induction coil; 175. a first power access column; 176. a second power access column; 177. a metal rod; 178. a transverse connecting rod; 18. cam type telescopic structure; 181. a longitudinal hollow housing; 182. a longitudinal member movable cavity; 183. a movable block; 184. a top telescoping rod; 185. a contact plate; 186. a cam; 187. a transverse rotation axis; 188. a bottom telescopic rod; 189. a coil spring; 19. a sponge adsorption type liquid extrusion structure; 191. a top squeeze plate; 192. a bottom squeeze plate; 193. a rod fixing groove; 194. a sponge body; 195. a longitudinal support bar; 196. a transverse support bar; 197. a fixed mounting plate; 198. a wire slot; 20. and a second bracket.

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, a drying device for 5G cable production includes a horizontal cylinder 1 sleeved in two bottom support bases 2 through bearings, a wind-driven drying cavity 3 disposed in the center of the horizontal cylinder 1, an annular gas reserving cavity 4 disposed in the periphery of the wind-driven drying cavity 3, a plurality of gas injection holes 5 disposed in the horizontal cylinder 1 and used for exhausting gas from the annular gas reserving cavity 4 to the inside of the wind-driven drying cavity 3, a driving motor 7 fixedly mounted above one of the bottom support bases 2 through a fixing sleeve 6, a turbine housing 9 positioned at the front end of a rotor 8 of the driving motor 7, turbine blades 10 positioned in the turbine housing 9 and rotating with the rotor 8, a hollow shell 12 mounted in the periphery of the horizontal cylinder 1 through a mechanical sealing structure, an annular cavity 13 disposed in the hollow shell 12 and used for exhausting gas to the inside of the annular gas reserving cavity 4, and a cable to be dried passing through the wind-driven drying cavity 3, and keeping the cable in the center area of the wind-driven drying cavity 3, after the driving motor 7 is started, the rotor 8 drives the turbine blades 10 to rotate along with the rotor 8, and the gas enters the air injection holes through the annular cavity 9 through the air injection holes, and finally enters the air injection holes through the turbine housing 9, and the air inlet cavity is heated by the turbine housing 9.

In order to generate the circumferential rotation type wind drying effect, referring to fig. 1, a main belt pulley 14 and an auxiliary belt pulley 16 are required to be arranged, the main belt pulley 14 is installed on the periphery of a shaft body of the rotor 8, the auxiliary belt pulley 16 is installed on the periphery of the horizontal cylinder body 1, and the main belt pulley 14 and the auxiliary belt pulley 16 are linked through a belt 15, when the rotor 8 rotates, the horizontal cylinder body 1 is driven to synchronously rotate, so that the high-temperature gas is enabled to generate the circumferential rotation phenomenon on the cable, the movement direction of wind force is changed, the high-temperature gas is enabled to perform the omnibearing drying effect on the liquid on the cable surface, the drying uniformity of the high-temperature gas and the heating uniformity of the cable are improved, and the kinetic energy required by the device is derived from one driving motor 7, so that the kinetic energy utilization rate of the driving motor 7 is improved, and the use cost and the equipment cost are reduced.

In order to heat flowing gas and dry the flowing gas by using high temperature gas, referring to fig. 1 and 2, a variable frequency gas heating structure 17 is required to be installed between the exhaust port of the turbine housing 9 and the inlet port of the hollow housing 12, and an induction coil 174 generating a magnetic field after injecting variable frequency current and a metal rod 177 positioned in the middle of the induction coil 174 and heated by electromagnetic induction are provided inside the variable frequency gas heating structure, and when the variable frequency current is injected into the induction coil 174, alternating current is converted into high frequency electric energy and the metal rod 177 is heated by electromagnetic induction. The basic principle is as follows: after rectifying the alternating current, a resonant circuit is formed by a capacitor and an inductor, the direct current is converted into high-frequency electricity by a drying device T power module for 5G cable production through an IG, then the metal rod 177 is heated by an alternating magnetic field generated by an induction coil 174, and gas passing through the vicinity of the metal rod 177 can be heated, so that the drying is performed by using high-temperature gas.

Referring to fig. 2, the variable frequency gas heating structure 17 comprises an insulating pipe body 171 and a metal rod 177 fixedly installed between the turbine casing 9 and the hollow casing 12, a gas flow channel 172 communicating an exhaust port of the turbine casing 9 with an air inlet port of the annular cavity 13 is arranged in the center of the insulating pipe body 171, an annular component installation cavity 173 arranged on the periphery of the gas flow channel 172, an induction coil 174 installed in the annular component installation cavity 173 in a winding manner, a first power access column 175 and a second power access column 176 installed on the circumferential side surface of the insulating pipe body 171 and connected with an electric power injection end and an electric power output end of the induction coil 174, the metal rod 177 is located at the axial center of the gas flow channel 172, and the bottom end of the metal rod 177 is fixedly installed on the side wall of the air inlet port of the annular cavity 13 through a transverse connecting rod 178.

In order to convert the rotational motion of the driving motor 7 into the longitudinal telescopic motion, thereby improving the kinetic energy utilization rate of the driving motor 7, reducing the use cost and the equipment cost, referring to fig. 1, 3 and 4, a cam telescopic structure 18 is required to be provided, and is fixedly mounted on the side surface of one of the bottom support bases 2 through a second bracket 20, a cam 186 rotating along with the turbine blade 10 and a movable block 183 generating the longitudinal telescopic motion along with the rotation of the cam 186 are provided in the bottom support base, the rotor 8 drives the cam 186 to generate the rotational motion, and the rotation of the cam 186 can generate the high influence on the contact plate 185, and under the cooperation of the coil spring 189, the longitudinal reciprocating motion is generated, so as to convert the rotational motion of the driving motor 7 into the longitudinal telescopic motion, thereby improving the kinetic energy utilization rate of the driving motor 7, and reducing the use cost and the equipment cost.

With respect to the specific structure of the cam type telescopic structure 18, please refer to fig. 3 and 4, including a longitudinal hollow housing 181 fixedly mounted to the side of one of the bottom support bases 2 through a second bracket 20 and a transverse rotation shaft 187 having an end fixedly mounted to the inside of the air inlet end surface of the turbine blade 10 and penetrating the air inlet of the turbine housing 9, in order that the outside air can be sucked normally, it is required that the radius of the structure of the transverse rotation shaft 187 is smaller than that of the air inlet of the turbine housing 9, the transverse rotation shaft 187 is mounted with a cam 186 directly above the longitudinal hollow housing 181, in order that the distance between one side edge structure of the cam 186 and the axis of the transverse rotation shaft 187 is smaller than that between the other side edge structure of the cam 186 and the axis of the transverse rotation shaft 187, the inside of the said vertical hollow shell 181 has a vertical component movable cavity 182, the said vertical hollow shell 181 has a movable block 183 which can move along the vertical component movable cavity 182 in the vertical component movable cavity 182, in order to prevent the rotation of the component, the cross section of the said movable block 183 has a polygonal structure, the cross section has a structure size consistent with the cross section of the said vertical component movable cavity 182, the upper end of the said movable block 183 has a top expansion link 184 penetrating the top structure of the vertical hollow shell 181, the top of the said top expansion link 184 has a contact plate 185 contacting the bottom of the circular side of the cam 186, the bottom of the said movable block 183 has a bottom expansion link 188 penetrating the bottom structure of the vertical hollow shell 181, the bottom telescoping rod 188 houses a coil spring 189 under compression under the movable block 183.

In order to realize the extrusion type liquid adsorption function of the liquid on the cable surface, please refer to fig. 1, 5 and 6, a sponge adsorption type liquid extrusion structure 19 is required to be arranged, and is fixedly installed under the movable block 183, a bottom extrusion plate 192 positioned at the bottom of the cable inlet direction, a top extrusion plate 191 positioned above the cable inlet direction and a sponge 194 positioned between the bottom extrusion plate 192 and the top extrusion plate 191 and adsorbing the liquid on the cable surface are arranged in the sponge block, when the cable passes through the wire slot 198 of the sponge 194, the moisture on the cable surface is adsorbed by the sponge 194 and remains in the sponge 194, and when the bottom extrusion plate 192 and the top extrusion plate 191 produce extrusion effect on the sponge 194, the moisture in the sponge 194 is extruded and discharged, so that the sponge 194 maintains a certain water storage capacity, and the extrusion type liquid adsorption function of the liquid on the cable surface is realized.

With respect to the specific structure of the sponge adsorption type liquid squeezing structure 19, please refer to fig. 5 and 6, the sponge adsorption type liquid squeezing structure comprises a top squeezing plate 191 and a bottom squeezing plate 192, a rod body fixing groove 193 for fixedly installing a bottom rod body of the bottom telescopic rod 188 is provided at the top end of the top squeezing plate 191, a longitudinal supporting rod 195 is installed at the bottom end of the bottom squeezing plate 192, the rod body of the longitudinal supporting rod 195 is fixedly installed on the side surface of one of the bottom supporting bases 2 through a transverse supporting rod 196 and a fixing installation plate 197, a sponge 194 protruding downwards is embedded into the bottom of the top squeezing plate 191, a wire groove 198 for being clamped at the periphery of a cable is provided at the bottom of the sponge 194, and in order to maintain the continuous moisture adsorption capability of the cable, the center line of the wire groove 198 and the axial line of the wind drying cavity 3 are required to be on the same horizontal line.

When the cable is used, the cable passes through the wind drying cavity 3 and the wire groove 198, the cable is kept to be positioned in the central area of the wind drying cavity 3, after the driving motor 7 is started, the rotor 8 can drive the turbine blade 10 to rotate rapidly, at the moment, gas can enter from the air inlet port of the turbine shell 9 and enter into the annular gas reserving cavity 4 through the air outlet port of the turbine shell 9, finally, heated air can dry the surface of the cable through the air injection hole 5 in a blowing mode, meanwhile, when the cable passes through the wire groove 198 of the sponge 194, moisture on the surface of the cable can be adsorbed by the sponge 194 and remains in the sponge 194, when the bottom extruding plate 192 and the top extruding plate 191 produce an extruding effect on the sponge 194, the moisture positioned in the sponge 194 can be extruded and discharged, and accordingly the sponge 194 can keep certain water storage capacity, and the moisture on the surface of the cable can be dried.

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 (7)

1. The utility model provides a drying device for production of 5G cable, including put in horizontal barrel (1) in two bottom sprag bases (2) through the bearing housing, set up in wind-force dry cavity (3) at horizontal barrel (1) center, set up in peripheral annular gas reservation chamber (4) of wind-force dry cavity (3), set up in inside and be used for gaseous a plurality of gas jet holes (5) of discharging to wind-force dry cavity (3) inside by annular gas reservation chamber (4) of horizontal barrel (1), drive motor (7) through fixed cover (6) fixed mounting in one of them bottom sprag base (2), turbine casing (9) that are located rotor (8) front end of drive motor (7), be located turbine flabellum (10) that turbine casing (9) are inside and rotate along with rotor (8), install in the peripheral hollow casing (12) of horizontal barrel (1) through mechanical seal structure, be used for hollow casing (12) fixed mounting in the inside and be used for to the inside annular cavity (13) of reserving gas of annular gas chamber (4) inside of another bottom sprag base (2), its characterized in that: also included is a method of manufacturing a semiconductor device,

the main belt pulley (14) and the auxiliary belt pulley (16), wherein the main belt pulley (14) is arranged on the periphery of a shaft body of the rotor (8), the auxiliary belt pulley (16) is arranged on the periphery of the horizontal cylinder body (1), and the main belt pulley (14) and the auxiliary belt pulley (16) are in linkage through a belt (15);

the variable-frequency gas heating structure (17) is arranged between the discharge port of the turbine shell (9) and the air inlet port of the hollow shell (12), and is internally provided with an induction coil (174) which generates a magnetic field after variable-frequency current is injected and a metal rod (177) which is positioned in the middle of the induction coil (174) and heated by electromagnetic induction;

the variable-frequency gas heating structure (17) comprises an insulating pipeline body (171) and a metal rod (177) which are fixedly arranged between a turbine shell (9) and a hollow shell (12), wherein the center of the insulating pipeline body (171) is provided with a gas flow channel (172) which is communicated with an exhaust port of the turbine shell (9) and an air inlet port of an annular cavity (13), an annular component mounting cavity (173) which is arranged on the periphery of the gas flow channel (172), an induction coil (174) which is arranged in the annular component mounting cavity (173) in a winding manner, a first power access column (175) and a second power access column (176) which are arranged on the circumferential side surface of the insulating pipeline body (171) and are connected with an electric power injection end and an electric power output end of the induction coil (174), and the metal rod (177) is positioned at the axial center part of the gas flow channel (172) and the bottom end of the metal rod (177) is fixedly arranged on the side wall of the air inlet port of the annular cavity (13) through a transverse connecting rod (178);

the cam type telescopic structure (18) is fixedly arranged on the side surface of one of the bottom support bases (2) through a second bracket (20), and a cam (186) rotating along with the turbine fan blades (10) and a movable block (183) generating longitudinal telescopic movement along with the rotation of the cam (186) are arranged in the cam type telescopic structure;

the cam type telescopic structure (18) comprises a longitudinal hollow shell (181) fixedly arranged on the side surface of one bottom supporting base (2) through a second bracket (20) and a transverse rotating shaft (187) with the end part fixedly arranged inside the air inlet end surface of the turbine fan blade (10) and penetrating through the air inlet of the turbine shell (9), a cam (186) is arranged right above the longitudinal hollow shell (181) through the transverse rotating shaft (187), a longitudinal part movable cavity (182) is arranged inside the longitudinal hollow shell (181), a movable block (183) capable of longitudinally moving along the longitudinal part movable cavity (182) is arranged inside the longitudinal part movable cavity (182) through the longitudinal hollow shell (181), a top telescopic rod (184) penetrating through the top end surface of the longitudinal hollow shell (181) is arranged on the upper end surface of the movable block (183), a collision plate (185) abutting against the bottom of the annular side surface of the cam (186) is arranged at the top end of the top telescopic rod (184), a bottom telescopic rod (188) penetrating through the bottom structure of the longitudinal hollow shell (181) is arranged at the bottom end of the movable block (183), and the bottom telescopic rod (188) is arranged below the movable block (183) in a compressed state (189);

the sponge adsorption type liquid extrusion structure (19) is fixedly arranged under the movable block (183), and a bottom extrusion plate (192) positioned at the bottom of the cable inlet direction, a top extrusion plate (191) positioned above the cable inlet direction and a sponge body (194) positioned between the bottom extrusion plate (192) and the top extrusion plate (191) and used for adsorbing liquid on the surface of the moving cable are arranged in the sponge adsorption type liquid extrusion structure;

the utility model provides a sponge absorption formula liquid extrusion structure (19) is including top stripper plate (191) and bottom stripper plate (192), the top of top stripper plate (191) is provided with body of rod fixed slot (193) that are used for fixed mounting bottom telescopic link (188) bottom body of rod, vertical bracing piece (195) are installed to the bottom of bottom stripper plate (192), the body of rod of vertical bracing piece (195) is through horizontal bracing piece (196) and fixed mounting board (197) fixed mounting in the side of one of them bottom support base (2), the bottom embedding of top stripper plate (191) has bellied cavernosum (194) downwards, the bottom of cavernosum (194) is provided with wire casing (198) that are used for the card at the cable periphery.

2. A drying apparatus for 5G cable production according to claim 1, wherein: the metal rod (177) has a smaller radius than the gas flow channel (172), and the top end of the metal rod (177) is provided with an upward tip structure.

3. A drying apparatus for 5G cable production according to claim 1, wherein: in operation, the first power access column (175) and the second power access column (176) are respectively connected with two corresponding power access ports of a frequency converter outputting variable frequency current.

4. A drying apparatus for 5G cable production according to claim 1, wherein: the transverse rotation shaft (187) has a smaller structural radius than the air inlet of the turbine housing (9).

5. A drying apparatus for 5G cable production according to claim 1, wherein: the distance between one side edge structure of the cam (186) and the axial lead of the transverse rotating shaft (187) is smaller than the distance between the other side edge structure of the cam (186) and the axial lead of the transverse rotating shaft (187).

6. A drying apparatus for 5G cable production according to claim 1, wherein: the cross section of the movable block (183) has a structural shape consistent with that of the cross section of the movable cavity (182) of the longitudinal component, and is of a polygonal structure, and the structural size of the cross section is consistent with that of the cross section of the movable cavity (182) of the longitudinal component.

7. A drying apparatus for 5G cable production according to claim 1, wherein: the central line of the wire groove (198) and the axial line of the wind-driven drying cavity (3) are positioned on the same horizontal line.