CN113707387A

CN113707387A - Cable real-time monitoring device

Info

Publication number: CN113707387A
Application number: CN202110828208.2A
Authority: CN
Inventors: 赵小华; 张艳
Original assignee: Zhejiang Yining Cable Technology Co ltd
Current assignee: Zhejiang Yining Cable Technology Co ltd
Priority date: 2021-07-22
Filing date: 2021-07-22
Publication date: 2021-11-26

Abstract

The invention discloses a cable real-time monitoring device which comprises a single-wire processing device, a pair twisting device, a cabling device, a sheath plastic extruding machine and a looping machine and is characterized in that a single-wire detection device is arranged between the single-wire processing device and the pair twisting device, a pair twisting detection device is arranged between the pair twisting device and the cabling device, a cabling detection device is arranged between the cabling device and the sheath plastic extruding machine, a sheath detection device is arranged between the sheath plastic extruding machine and the looping machine, and the looping detection device is arranged behind the looping machine, so that the problem that the production efficiency is reduced because the situation of wire breakage and the like in the cable production process cannot be found is solved.

Description

Cable real-time monitoring device

Technical Field

The invention relates to the technical field of cables, in particular to a cable real-time monitoring device.

Background

A cable is a power or signal transmission device, and is generally composed of several wires or groups of wires. The manufacture of wire and cable is quite different from the way most electromechanical products are produced. Electromechanical products typically employ the assembly of parts into components, and the reassembly of multiple parts into a single product, with the product being metered in units or pieces. The wire and cable are in basic unit of measurement of length. All the electric wires and cables are made by processing conductors, and adding insulation, shielding, cabling, sheath and the like layer by layer on the periphery of the conductors to form electric wire and cable products. The more complex the product structure, the more levels are superimposed.

The main process of the wire cable is that the wire cable passes through: the three processes of drawing, stranding and coating are completed, the more complicated the model specification is, the higher the repeatability is.

1. Drawing (D)

In metal press working, a technical process in which a metal is forced through a die (press roller) by an external force, the cross-sectional area of the metal is compressed, and a desired shape and size of the cross-sectional area are obtained is called metal drawing.

The drawing process comprises the following steps: monofilament drawing and stranding drawing.

2. Twisted system

In order to improve the flexibility and the integrity of the electric wire and cable, 2 or more single wires are interwoven in a predetermined direction, which is called stranding.

The stranding process comprises the following steps: twisting, cabling, weaving, steel wire armouring and winding of the conductors.

3. Coating of

According to different performance requirements of the electric wire and the electric cable, special equipment is adopted to coat different materials outside the conductor. The coating process comprises the following steps:

A. extruding: rubber, plastic, lead, aluminum, and the like.

B. Longitudinally wrapping: rubber, corrugated aluminum strip material.

C. Wrapping: tape-like paper tape, mica tape, alkali-free glass fiber tape, nonwoven fabric, plastic tape, etc., and fiber material such as thread-like cotton yarn, silk, etc.

D. Dip coating: insulating varnish, asphalt, etc

In the manufacturing process of the cable, each procedure is likely to damage the cable, the damage is not obvious, the cable needs to be measured through a professional instrument, the damaged cable cannot be used, the follow-up procedures are invalid, the production efficiency is reduced, and the production resources are wasted.

Disclosure of Invention

The invention aims to provide a cable real-time monitoring device which can monitor a cable in real time at each step in a cable production process and prevent the cable from being damaged and undetected in the production process.

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

a cable real-time monitoring device comprises a single-wire processing device, a pair twisting device, a cabling device, a sheath plastic extruding machine and a looping machine and is characterized in that a single-wire detection device is arranged between the single-wire processing device and the pair twisting device, a pair twisting detection device is arranged between the pair twisting device and the cabling device, a cabling detection device is arranged between the cabling device and the sheath plastic extruding machine, a sheath detection device is arranged between the sheath plastic extruding machine and the looping machine, and a looping detection device is arranged behind the looping machine.

Adopt above-mentioned technical scheme, the conductor becomes the cable after single line processingequipment, pair twist device, stranding device, sheath extruding machine and lopping machine processing, detects in getting into single line detection device after single line processing, detects in getting into pair twist detection device after the pair twist, detects in getting into the stranding detection device after the stranding, detects in getting into the sheath detection device after the sheath extrusion molding, detects in getting into the lopping detection device after the lapping.

Preferably, a wire inlet groove is fixedly connected between the single wire processing device and the pair twisting device, the single wire detection device comprises a micrometer, a direct-current resistance bridge, a first amplification detector, a tensile testing machine and a pressure testing machine, a measurement groove is arranged in the micrometer, the measurement groove is located in the wire inlet groove, the micrometer is fixedly connected with the measurement groove, a detection joint is arranged in the direct-current resistance bridge, the detection joint is respectively located at the head end and the tail end of the wire inlet groove and used for detecting the resistance of the inner wire of the wire inlet groove, the first amplification detector is located above the wire inlet groove and fixedly connected with the wire inlet groove, one side, far away from the single wire processing device, of the wire inlet groove penetrates through the tensile testing machine and the pressure testing machine, and the wire inlet groove sequentially passes through the micrometer, the direct-current resistance bridge, the first amplification detector, the tensile testing machine and the pressure testing machine.

By adopting the technical scheme, the conductor processed by the single-wire processing device enters the pair twisting device through the wire inlet groove, the micrometer measures the diameter of the conductor at the moment in the wire inlet groove, the direct-current resistance bridge detects the resistance of the conductor, when the resistance is abnormal, the conductor is broken, the amplification detector I is used for observing and searching the broken part in the conductor, and the tensile testing machine and the pressure testing machine are respectively used for detecting the compression resistance and the tensile resistance of the conductor.

Preferably, a feeding groove is formed between the pair twisting device and the cabling device, the pair twisting detection device comprises a first steel ruler, a first voltage-withstanding instrument, a first ohmmeter, a first capacitance meter, a first universal meter and a first insulation resistance tester, the first steel ruler is fixedly connected with the bottom of the feeding groove, two ends of the first voltage-withstanding instrument, which are used for detection, are located in the feeding groove, two ends of the first ohmmeter, which are used for detection, are located in the feeding groove, two ends of the first capacitance meter, which are used for detection, are located in the feeding groove, and two ends of the first insulation resistance tester, which are used for detection, are located in the feeding groove.

By adopting the technical scheme, the twisted conductors enter the cabling device through the feeding groove to be cabled, the straight steel ruler I is used for measuring and calibrating the vertical condition, the voltage withstanding instrument I is used for detecting the voltage withstanding capability of the conductors, and the first ohmmeter, the first capacitance meter, the first universal meter and the insulation resistance tester are used for detecting the resistance condition of the conductors.

Preferably, a cable inlet groove is formed between the cabling device and the sheath plastic extruding machine, the cabling detection device comprises a second steel ruler, a second voltage-withstanding instrument, a second ohmmeter, a second capacitance meter, a second universal meter, a second insulation resistance tester and a diameter measuring instrument, the second steel ruler is fixedly connected with the bottom of the cable inlet groove, two ends of the voltage-withstanding instrument for detection are located in the cable inlet groove, two ends of the ohmmeter for detection are located in the cable inlet groove, two ends of the capacitance meter for detection are located in the cable inlet groove, two ends of the universal meter for detection are located in the cable inlet groove, and two ends of the insulation resistance tester for detection are located in the cable inlet groove.

By adopting the technical scheme, the conductor enters the sheath extruder through the cable inlet groove after being cabled in the cabling machine, the steel ruler is used for measuring and calibrating the vertical condition, the voltage withstanding instrument is used for detecting the voltage withstanding capability of the conductor, the second ohmmeter, the second capacitance meter, the second multimeter and the second insulation resistance tester are used for detecting the resistance condition of the conductor, and the diameter measuring instrument is used for measuring the diameter of the cable with the sheath.

Preferably, the diameter measuring instrument comprises a base, a through hole and a laser emitting device, the base is fixedly connected with the cable inlet groove, the through hole is located on two sides of the cable inlet groove, the laser emitting device is connected with the base, and the laser emitting device emits laser from two sides of the cable inlet groove to irradiate the cable in the cable inlet groove through the through hole to measure the diameter of the cable.

By adopting the technical scheme, the laser emitting device emits laser from the two ends of the base and enters the cable inlet groove through the through hole, so that the diameter of the cable with the sheath can be detected.

Preferably, fixedly connected with coiling groove between sheath extruding machine and the looping machine, sheath detection device includes three straightedges of steel, withstand voltage appearance three, resistance meter three, capacitance meter three, omnipotent table three, insulation resistance tester three and enlargies the detector two, three straightedges of steel and coiling tank bottom fixed connection, withstand voltage appearance three uses both ends that detect to be located coiling groove, resistance meter three is used for the both ends that detect to be located coiling groove, capacitance meter three is used for the both ends that detect to be located coiling groove, omnipotent table three is used for the both ends that detect to be located coiling groove, insulation resistance tester three uses both ends that detect to be located coiling groove, enlarge the detector two and be located cabling groove top and with cabling groove fixed connection.

By adopting the technical scheme, the cable enters the looping machine through the coiling groove after completing extrusion molding in the sheath extrusion molding machine, the steel ruler is used for measuring and calibrating the vertical condition, the voltage withstanding instrument is used for detecting the voltage withstanding capability of the cable, the resistance meter III, the capacitance meter III, the multimeter III and the insulation resistance tester are used for detecting the resistance condition of the cable, and the amplification detector II is used for observing and searching the broken part of the cable.

Preferably, the looping detection device comprises a network analyzer, a Fuluke electronic authentication analyzer and a microelectronic universal testing machine.

Preferably, a cable burning test box is arranged behind the looping detection device.

Preferably, a high-temperature test chamber is arranged behind the looping detection device.

Preferably, a thermal aging test box and a tension tester are arranged behind the looping detection device.

Drawings

FIG. 1 is a top view of an embodiment of the invention;

FIG. 2 is an enlarged view of the single line detection device of the invention;

FIG. 3 is an enlarged view of the inventive pair twist detection apparatus;

FIG. 4 is an enlarged view of the cabling inspection device of the invention;

FIG. 5 is an enlarged view of the inventive sheath detection apparatus;

FIG. 6 is a rear connection diagram of the looping detection device of the present invention.

Reference numerals: 1. a single-wire processing device; 2. a pair twisting device; 3. a cabling device; 4. sheath plastic extruding machine; 5. a looping machine; 6. a single wire detection device; 7. a pair twist detection device; 8. a cabling detection device; 9. a sheath detection device; 10. a looping detection device; 11. a wire inlet groove; 12. a micrometer; 13. a DC resistance bridge; 14. a first amplification detector; 15. a tensile testing machine; 16. a pressure testing machine; 17. a measuring tank; 18. detecting the joint; 19. a first steel ruler; 20. a first pressure resistance instrument; 21. a first resistance meter; 22. a first capacitor meter; 23. a universal meter I; 24. an insulation resistance tester I; 25. a feed chute; 26. a cable inlet groove; 27. a second steel ruler; 28. a second pressure resistance instrument; 29. a second resistance meter; 30. a second capacitance meter; 31. a universal watch II; 32. a second insulation resistance tester; 33. a diameter gauge; 34. a base; 35. a through hole; 36. a laser emitting device; 37. a coiling groove; 38. a third steel ruler; 39. a third pressure resistance instrument; 40. a third resistance meter; 41. a third capacitor table; 42. a universal meter III; 43. a third insulation resistance tester; 44. a second amplification detector; 45. a network analyzer; 46. a Fuluke electronic authentication analyzer; 47. a microelectronic universal testing machine; 48. a cable combustion test chamber; 49. a high temperature test chamber; 50. a thermal aging test chamber; 51. a tensile tester.

Detailed Description

The following description is only a preferred embodiment of the present invention, and the protection scope is not limited to the embodiment, and any technical solution that falls under the idea of the present invention should fall within the protection scope of the present invention. It should also be noted that modifications and embellishments within the scope of the invention may occur to those skilled in the art without departing from the principle of the invention.

Referring to fig. 1 to 6, a real-time monitoring device for a cable comprises a single-wire processing device 1, wherein a pair twisting device 2 is connected to the rear of the single-wire processing device 1, a cabling device 3 is connected to the rear of the pair twisting device 2, a sheath extruding machine 4 is connected to the rear of the cabling device 3, and a looping machine 5 is connected to the rear of the sheath extruding machine 4.

A wire inlet groove 11 is fixedly connected between the single wire processing device 1 and the pair twisting device 2, a feeding groove 25 is arranged between the pair twisting device 2 and the cabling device 3, a wire inlet groove 26 is arranged between the cabling device 3 and the sheath plastic extruding machine 4, and a coiling groove 37 is fixedly connected between the sheath plastic extruding machine 4 and the coiling machine 5.

The single wire detection device 6 is arranged on the wire inlet groove 11, the single wire detection device 6 comprises a micrometer 12, a direct current resistance bridge 13, a first amplification detector 14, a tensile testing machine 15 and a pressure testing machine 16, a measurement groove 17 is arranged in the micrometer 12, the measurement groove 17 is positioned in the wire inlet groove 11, the micrometer 12 is fixedly connected with the measurement groove 17, a detection joint 18 is arranged in the direct current resistance bridge 13, the detection joint 18 is respectively positioned at the head end and the tail end of the wire inlet groove 11 and is used for detecting the resistance of the wire in the wire inlet groove 11, the first amplification detector 14 is positioned above the wire inlet groove 11 and is fixedly connected with the wire inlet groove 11, one side of the wire inlet groove 11, which is far away from the single wire processing device 1, penetrates through the tensile testing machine 15 and the pressure testing machine 16, the wire inlet groove 11 sequentially passes through the micrometer 12, the direct current resistance bridge 13, the first amplification detector 14, the tensile testing machine 15 and the pressure testing machine 16, the conductor processed by the single wire processing device 1 enters the pair twisting device 2 through the wire inlet groove 11, the micrometer 12 in the wire inlet groove 11 measures the diameter of the conductor at the moment, the direct current resistance bridge 13 detects the resistance of the conductor, when the resistance is abnormal, the conductor is broken, the first amplification detector 14 is used for observing and searching broken parts in the conductor, and the tensile testing machine 15 and the pressure testing machine 16 are respectively used for detecting the compression resistance and the tensile resistance of the conductor.

The pair twist detection device 7 is arranged on the feeding groove 25, the pair twist detection device 7 comprises a first straight steel ruler 19, a first pressure-resistant instrument 20, a first ohmmeter 21, a first capacitance meter 22, a first universal meter 23 and a first insulation resistance tester 24, the first straight steel ruler 19 is fixedly connected with the bottom of the feeding groove 25, two ends of the first pressure-resistant instrument 20 for detection are located in the feeding groove 25, two ends of the first ohmmeter 21 for detection are located in the feeding groove 25, two ends of the first capacitance meter 22 for detection are located in the feeding groove 25, two ends of the first universal meter 23 for detection are located in the feeding groove 25, two ends of the first insulation resistance tester 24 for detection are located in the feeding groove 25, a conductor subjected to pair twist enters the cabling device 3 through the feeding groove 25 to be cabled and processed, the first straight steel ruler 19 is used for measuring and calibrating the vertical condition, the first pressure-resistant instrument 20 is used for detecting the voltage resistance of the conductor, the first ohmmeter 21, the first capacitance meter 22, the first multimeter and the insulation resistance tester are used for detecting the resistance condition of the conductor.

The cabling detection device 8 is arranged on the cabling groove 26, the cabling detection device 8 comprises a second straightedge 27, a second voltage-withstanding instrument 28, a second ohmmeter 29, a second capacitance meter 30, a second universal meter 31, a second insulation resistance tester 32 and a diameter measuring instrument 33, the second straightedge 27 is fixedly connected with the bottom of the cabling groove 26, two ends of the second voltage-withstanding instrument 28 for detection are located in the cabling groove 26, two ends of the second ohmmeter 29 for detection are located in the cabling groove 26, two ends of the second capacitance meter 30 for detection are located in the cabling groove 26, two ends of the second universal meter 31 for detection are located in the cabling groove 26, two ends of the second insulation resistance tester 32 for detection are located in the cabling groove 26, a conductor enters the sheath extruding machine 4 through the cabling groove 26 after being cabled in the cabling machine, the second straightedge 27 is used for measuring and calibrating the vertical condition, and the second voltage-withstanding instrument 28 is used for detecting the voltage resistance of the conductor, and the second resistance meter 29, the second capacitance meter 30, the second multimeter and the second insulation resistance tester are used for detecting the resistance condition of the conductor, and the diameter measuring instrument 33 is used for measuring the diameter of the cable with the sheath.

The diameter measuring instrument 33 comprises a base 34, a through hole 35 and a laser emitting device 36, wherein the base 34 is fixedly connected with the cable inlet groove 26, the through hole 35 is positioned on two sides of the cable inlet groove 26, the laser emitting device 36 is connected with the base 34, the laser emitting device 36 emits laser from two sides of the cable inlet groove 26, irradiates the laser through the through hole 35 to the cable in the cable inlet groove 26 to measure the diameter of the cable, and the laser emitting device 36 emits laser from two ends of the base 34, enters the cable inlet groove 26 through the through hole 35 and can detect the diameter of the cable with the sheath.

The coiling groove 37 is provided with a sheath detection device 9, the sheath detection device 9 comprises a third steel ruler 38, a third pressure resistance instrument 39, a third resistance meter 40, a third capacitance meter 41, a third universal meter 42, a third insulation resistance tester 43 and a second amplification detector 44, the third steel ruler 38 is fixedly connected with the bottom of the coiling groove 37, two ends of the third pressure resistance instrument 39 for detection are positioned in the coiling groove 37, two ends of the third resistance meter 40 for detection are positioned in the coiling groove 37, two ends of the third capacitance meter 41 for detection are positioned in the coiling groove 37, two ends of the third universal meter 42 for detection are positioned in the coiling groove 37, two ends of the third insulation resistance tester 43 for detection are positioned in the coiling groove 37, the second amplification detector 44 is positioned above the cabling groove and is fixedly connected with the cabling groove, a cable enters the coiling machine 5 through the coiling groove 37 after extrusion molding in the sheath extruder 4, the third straight steel ruler 38 is used for measuring and calibrating the vertical condition, the third voltage withstanding instrument 39 is used for detecting the voltage withstanding capability of the cable, the third resistance meter 40, the third capacitance meter 41, the third multimeter and the third insulation resistance tester are used for detecting the resistance condition of the cable, and the second amplification detector 44 is used for observing and searching the broken part of the cable.

The back of the looping machine 5 is provided with a looping detection device 10, the looping detection device 10 comprises a network analyzer 45, a Fuluke electronic authentication analyzer 46 and a microelectronic universal testing machine 47, a cable combustion test box 48 is arranged at the back of the looping detection device 10, a high-temperature test box 49 is arranged at the back of the looping detection device 10, and a thermal aging test box 50 and a tension tester 51 are arranged at the back of the looping detection device 10.

The working principle of the invention is as follows: the conductor is processed through single line processingequipment 1, 2 pair twists of pair twist device, 3 stranding of stranding device, the cable of being processed into the circle after 4 extrusion molding of sheath extruding machine and 5 lopping of lopping machine, single line processingequipment 1 carries out single line processing back through 6 detection capability of single line detection device to the conductor, 2 pair twist device conductor behind the conductor pair twist through 7 detection capability of pair twist detection device, conductor is through 8 detection capability of stranding detection device behind 3 processing of stranding device conductor, through 9 detection capability of sheath detection device through the cable behind 4 processing of sheath extruding machine cable, the cable detects through 10 detection device that circles behind 5 processing of lopping machine cable.

Claims

1. The utility model provides a cable real-time monitoring device, includes single line processingequipment (1), pair twist device (2), stranding device (3), sheath extruding machine (4) and looping machine (5), its characterized in that, be equipped with single line detection device (6) between single line processingequipment (1) and pair twist device (2), be equipped with pair twist detection device (7) between pair twist device (2) and stranding device (3), be equipped with stranding detection device (8) between stranding device (3) and sheath extruding machine (4), be equipped with sheath detection device (9) between sheath extruding machine (4) and looping machine (5), be equipped with looping detection device (10) behind looping machine (5).

2. The cable real-time monitoring device according to claim 1, wherein a wire inlet groove (11) is fixedly connected between the single wire processing device (1) and the pair twisting device (2), the single wire detection device (6) comprises a micrometer (12), a direct current resistance bridge (13), a first amplification detector (14), a tensile testing machine (15) and a compression testing machine (16), a measuring groove (17) is arranged in the micrometer (12), the measuring groove (17) is positioned in the wire inlet groove (11), the micrometer (12) is fixedly connected with the measuring groove (17), a detection joint (18) is arranged in the direct current resistance bridge (13), the inner wires (18) of the detection joint are respectively positioned at the head end and the tail end of the wire inlet groove (11) and used for detecting the resistance of the wire inlet groove (11), the first amplification detector (14) is positioned above the wire inlet groove (11) and fixedly connected with the wire inlet groove (11), the single wire processing device is characterized in that one side, far away from the single wire processing device (1), of the wire inlet groove (11) penetrates through a tensile testing machine (15) and a pressure testing machine (16), and the wire inlet groove (11) sequentially passes through a micrometer (12), a direct-current resistance bridge (13), an amplification detector I (14), the tensile testing machine (15) and the pressure testing machine (16).

3. A cable real-time monitoring device according to claim 2, characterized in that a feed chute (25) is provided between the pair twisting device (2) and the cabling device (3), the pair twist detection device (7) comprises a first steel ruler (19), a first withstand voltage instrument (20), a first ohmmeter (21), a first capacitance meter (22), a first universal meter (23) and a first insulation resistance tester (24), the first straight steel ruler (19) is fixedly connected with the bottom of the feeding groove (25), two ends of the first pressure resistance instrument (20) for detection are positioned in the feeding groove (25), the two ends of the first ohmmeter (21) for detection are positioned in the feeding groove (25), the two ends of the capacitance meter I (22) for detection are positioned in the feeding groove (25), two ends of the universal meter I (23) for detection are positioned in the feeding groove (25), and two ends of the insulation resistance tester I (24) for detection are positioned in the feeding groove (25).

4. The real-time cable monitoring device according to claim 3, wherein a cable inlet groove (26) is arranged between the cabling device (3) and the sheath plastic extruding machine (4), the cabling detection device (8) comprises a second steel ruler (27), a second voltage-withstanding instrument (28), a second ohmmeter (29), a second capacitance meter (30), a second universal meter (31), a second insulation resistance tester (32) and a diameter measuring instrument (33), the second steel ruler (27) is fixedly connected with the bottom of the cable inlet groove (26), two ends of the second voltage-withstanding instrument (28) for detection are positioned in the cable inlet groove (26), two ends of the second ohmmeter (29) for detection are positioned in the cable inlet groove (26), two ends of the second capacitance meter (30) for detection are positioned in the cable inlet groove (26), two ends of the second universal meter (31) for detection are positioned in the cable inlet groove (26), and two ends of the second insulation resistance tester (32) for detection are positioned in the cable inlet groove (26).

5. The real-time cable monitoring device according to claim 4, wherein the diameter measuring instrument (33) comprises a base (34), a through hole (35) and a laser emitting device (36), the base (34) is fixedly connected with the cable inlet groove (26), the through hole (35) is positioned on two sides of the cable inlet groove (26), the laser emitting device (36) is connected with the base (34), and the laser emitting device (36) emits laser from two sides of the cable inlet groove (26) to irradiate the cable in the cable inlet groove (26) through the through hole (35) to measure the diameter of the cable.

6. The real-time cable monitoring device according to claim 5, wherein a coiling groove (37) is fixedly connected between the sheath extruding machine (4) and the coiling machine (5), the sheath detecting device (9) comprises a third steel ruler (38), a third voltage-withstanding instrument (39), a third resistance meter (40), a third capacitance meter (41), a third universal meter (42), a third insulation resistance tester (43) and a second amplification detector (44), the third steel ruler (38) is fixedly connected with the bottom of the coiling groove (37), two ends of the third voltage-withstanding instrument (39) for detection are positioned in the coiling groove (37), two ends of the third resistance meter (40) for detection are positioned in the coiling groove (37), two ends of the third capacitance meter (41) for detection are positioned in the coiling groove (37), two ends of the third universal meter (42) for detection are positioned in the coiling groove (37), and two ends of the insulation resistance tester III (43) for detection are positioned in the coiling groove (37), and the amplification detector II (44) is positioned above the cabling groove and is fixedly connected with the cabling groove.

7. A cable real-time monitoring device according to claim 6, characterized in that the looping detection device (10) comprises a network analyzer (45), a Fuluke electronic authentication analyzer (46) and a microelectronic universal tester (47).

8. A cable real-time monitoring device according to claim 7, characterized in that a cable burning test box (48) is arranged behind the looping detection device (10).

9. The real-time cable monitoring device according to claim 8, wherein a high temperature test chamber (49) is arranged behind the looping detection device (10).

10. The real-time cable monitoring device according to claim 9, wherein a thermal aging test chamber (50) and a tensile tester (51) are arranged behind the looping detection device (10).