CN114414152A - Optical cable performance detection system - Google Patents

Abstract

The invention discloses an optical cable performance detection system, which comprises a main machine body, wherein a working cavity which is communicated with each other in a left-right penetrating way is arranged in the main machine body, the upper wall and the lower wall in the working cavity are communicated and provided with symmetrical lifting cavities, a working plate which can move up and down is arranged in the lifting cavities, a detection cavity with an opening facing the working cavity is arranged in the working plate, the upper wall of the detection cavity is communicated and provided with a telescopic pipeline, one end of the telescopic pipeline is communicated and provided with a connecting pipeline, and the left wall of the lifting cavity at the upper side is provided with a water storage cavity. And then the tensile property of the optical cable is detected, and the performance detection of the optical cable is realized.

Description

Optical cable performance detection system

Technical Field

The invention relates to the technical field of optical cable detection, in particular to an optical cable performance detection system.

Background

After the optical cable is produced, the optical cable needs to be subjected to multiple performance tests, particularly waterproof tests, and because part of the optical cable needs to be buried and underground for transmission, the accuracy of the waterproof performance test of an optical cable shell can influence whether the optical cable can be normally used, meanwhile, the tensile strength of the optical cable is also the optical cable performance test key point, and a common optical cable waterproof performance tester cannot perform drying treatment on the optical cable passing through the test after the test is finished, so that the detected sample optical cable can only become a disposable product of the test, and the waste of resources can be caused.

Disclosure of Invention

The present invention is directed to a system for detecting performance of an optical cable, which overcomes the above-mentioned drawbacks of the prior art.

The optical cable performance detection system comprises a main machine body, wherein a working cavity which is communicated in a penetrating manner from left to right is arranged in the main machine body, a symmetrical lifting cavity is communicated with the upper wall and the lower wall in the working cavity, a working plate which can move up and down is arranged in the lifting cavity, a detection cavity with an opening facing the working cavity is arranged in the working plate, a telescopic pipeline which can be telescopic is communicated with the upper wall of the detection cavity, one end of the telescopic pipeline is communicated with a connecting pipeline, a water storage cavity is arranged in the left wall of the lifting cavity at the upper side, the connecting pipeline at the upper side is communicated with the water storage cavity, a water outlet pipeline is communicated with the connecting pipeline at the lower side, a handheld groove which is communicated in a penetrating manner from front to back is arranged in the right wall of the lifting cavity at the upper side, a power shaft is vertically arranged at the left side in the working cavity, a supporting turntable is fixedly connected to the outer circular surface of the power shaft, clamping grooves which are symmetrical in both sides and have outward openings are arranged at the left side and the right side in the supporting turntable, the downside be equipped with in the lift chamber right wall the opening upwards and with the removal spout of working chamber intercommunication, be equipped with the removal slider that can remove about moving in the removal spout, remove the backup pad of slider up end fixedly connected with disc, be equipped with the ascending lift screw sleeve of opening in the removal slider, be equipped with the lift connecting rod that can reciprocate in the lift screw sleeve, under the lift connecting rod terminal surface with fixedly connected with elevator motor between the lift screw sleeve lower wall, the lift connecting rod up end upwards extends and the grip block of fixedly connected with disc, the grip block with the backup pad is close to a side end face each other and is fixed and is equipped with the friction disc.

Preferably, the lower side transversely rotates in the removal spout and is equipped with the removal screw thread axle, remove the screw thread axle with remove slider threaded connection, the removal spout left side wall internal fixation is equipped with the removal motor, remove screw thread axle left end power connect in the removal motor.

Preferably, the right wall of the movable sliding groove is communicated with a telescopic cavity, a stress detection plate is fixedly arranged on the inner wall of the telescopic cavity, a transmission connecting rod capable of moving left and right is arranged in the telescopic cavity, a telescopic spring is fixedly connected between the right end face of the transmission connecting rod and the right wall of the telescopic cavity, the left end face of the transmission connecting rod extends leftwards into the movable sliding groove and is fixedly connected with a transmission plate, and the transmission plate is fixedly connected with the right end face of the movable sliding block.

Preferably, both sides are equipped with the centre gripping connecting plate that the symmetry just can reciprocate about the centre gripping inslot, be equipped with the transmission chamber in a side wall of centre gripping groove, the transmission intracavity rotates perpendicularly and is equipped with the input shaft, the outer disc cover of input shaft is equipped with the transmission screw sleeve that longitudinal symmetry and screw thread are opposite, centre gripping connecting plate left end face extend left and with transmission screw sleeve threaded connection, the input shaft up end upwards extends and fixedly connected with rotates the disc, it is connected with the rotation handrail to rotate the disc up end rotation.

Preferably, the fixed elastic plate that is equipped with in both sides around the lower terminal surface of working plate, the elastic plate has elasticity, be equipped with the joint groove that the opening is decurrent in the elastic plate, both sides from top to bottom the elastic plate can mutually support and joint, it is equipped with semi-circular and the outside joint hole of opening to detect two wall intercommunications about the intracavity, the fixed elastic sealed rubber ring that has that is equipped with of joint downthehole wall, the upside detect the chamber and keep away from a working chamber lateral wall intercommunication is equipped with the ascending gas pocket of opening, the fixed protection shield that is equipped with of upside in the gas pocket.

Preferably, both sides intercommunication is equipped with the closed chamber about in the connecting tube, be equipped with the closing plate that can reciprocate in the closed chamber, the closing plate can move to in the connecting tube and with the connecting tube left and right sides is sealed, closing plate a side end with fixedly connected with sealing spring between a closed chamber lateral wall, a closed chamber lateral wall is fixed and is equipped with the sealed electro-magnet, the closing plate has magnetism.

Preferably, two walls intercommunication are equipped with the fan chamber of symmetry around the working chamber, the rotation is equipped with the rotation fan in the fan chamber, the fan chamber is kept away from a working chamber lateral wall internal fixation is equipped with the rotation motor, rotation fan one end power connect in rotate the motor, the fan chamber is kept away from a working chamber lateral wall intercommunication is equipped with the outside air pipe of opening.

Preferably, the front wall and the rear wall of the lifting cavity on the upper side and the lower side are communicated with symmetrical lifting chutes, a guide connecting rod is fixedly arranged between the upper wall and the lower wall of the lifting chute on the front side, a lifting rotating shaft is rotatably arranged between the upper wall and the lower wall of the lifting chute on the rear side, lifting threaded sleeves with opposite threads are sleeved on the upper side and the lower side of the outer circular surface of the lifting rotating shaft, lifting slide blocks are fixedly connected with the end surfaces of the front side and the rear side of the working plate, the lifting slide blocks on the front side are slidably connected with the guide connecting rod, the lifting slide blocks on the rear side are in threaded connection with the lifting threaded sleeves, a lifting motor is fixedly arranged in the lower wall of the lifting chute on the rear side, and the lower end of the lifting rotating shaft is in power connection with the lifting motor.

Preferably, a power motor is fixedly arranged in the left wall of the lifting cavity on the lower side, and the lower end of the power shaft is in power connection with the power motor.

The invention has the beneficial effects that: in the detection process, a closed detection cavity is formed, the optical cable is soaked into detection water, if the waterproof performance of the optical cable is poor, the detection water can enter the optical cable and leak outwards from one end of the optical cable, and the waterproof performance of the optical cable is further conveniently judged.

Drawings

FIG. 1 is a schematic external view of the present invention;

FIG. 2 is a schematic diagram of the overall configuration of a cable performance testing system of the present invention;

FIG. 3 is a schematic view of A-A of FIG. 2 in accordance with the present invention;

FIG. 4 is an enlarged partial schematic view of the invention at the moving slide subassembly of FIG. 2;

FIG. 5 is an enlarged, fragmentary view of the closure plate member of FIG. 2 in accordance with the present invention;

FIG. 6 is an enlarged, fragmentary schematic view of the invention at the input shaft assembly of FIG. 2.

In the figure:

11. a main body; 12. an input shaft; 13. a support turntable; 14. a power shaft; 15. a power motor; 16. a lifting cavity; 17. a moving motor; 18. a moving chute; 19. moving the threaded shaft; 20. moving the slide block; 21. a support plate; 22. a lifting connecting rod; 23. a friction plate; 24. a clamping plate; 25. a working chamber; 26. a detection chamber; 27. sealing the rubber ring; 28. a hand-held tank; 29. air holes; 30. a protection plate; 31. a working plate; 32. a telescopic pipeline; 33. a closing plate; 34. connecting a pipeline; 35. a water storage cavity; 36. a guide link; 37. a lifting chute; 38. a lifting slide block; 39. an elastic plate; 40. a clamping groove; 41. a ventilation duct; 42. rotating the fan; 43. rotating the motor; 44. a fan cavity; 45. a lifting motor; 46. lifting the threaded sleeve; 47. a drive plate; 48. a transmission connecting rod; 49. a stress detection plate; 50. a telescoping chamber; 51. a tension spring; 52. a closed cavity; 53. a closing spring; 54. closing the electromagnet; 55. a drive threaded sleeve; 56. a transmission cavity; 57. a lifting rotating shaft; 58. a clamping groove; 59. clamping the connecting plate; 60. rotating the armrest; 61. rotating the disc; 62. a clamping hole; 63. a water outlet pipeline.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be obtained by a person skilled in the art without any inventive step based on the embodiments of the present invention, are within the scope of the present invention:

referring to fig. 1-6, an optical cable performance detection system according to an embodiment of the present invention includes a main body 11, a working chamber 25 penetrating and communicating from left to right is disposed in the main body 11, symmetrical lifting chambers 16 are disposed in the working chamber 25 and communicate with an upper wall and a lower wall, a working plate 31 capable of moving up and down is disposed in the lifting chamber 16, a detection chamber 26 having an opening facing the working chamber 25 is disposed in the working plate 31, a telescopic pipe 32 capable of extending and retracting is disposed in the upper wall of the detection chamber 26, one end of the telescopic pipe 32 is communicated with a connecting pipe 34, a water storage chamber 35 is disposed in the left wall of the lifting chamber 16 on the upper side, the connecting pipe 34 on the upper side is communicated with the water storage chamber 35, a water outlet pipe 63 is communicated with the connecting pipe 34 on the lower side, a handheld groove 28 penetrating and communicating from front to back is disposed in the right wall of the lifting chamber 16 on the upper side, a power shaft 14 is vertically rotatably disposed in the left side of the working chamber 25, the outer circular surface of the power shaft 14 is fixedly connected with a supporting turntable 13, the left side and the right side in the supporting turntable 13 are provided with clamping grooves 58 which are symmetrical at two sides and have outward openings, a moving chute 18 with an upward opening and communicated with the working cavity 25 is arranged in the right wall of the lifting cavity 16 at the lower side, a movable sliding block 20 capable of moving left and right is arranged in the movable sliding chute 18, a disc-shaped supporting plate 21 is fixedly connected with the upper end surface of the movable sliding block 20, a lifting threaded sleeve 46 with an upward opening is arranged in the movable sliding block 20, a lifting connecting rod 22 capable of moving up and down is arranged in the lifting threaded sleeve 46, a lifting motor 45 is fixedly connected between the lower end surface of the lifting connecting rod 22 and the lower wall of the lifting threaded sleeve 46, the upper end of the lifting link 22 extends upwards and is fixedly connected with a disc-shaped clamping plate 24, the friction plate 23 is fixedly arranged on the end surface of one side, close to each other, of the clamping plate 24 and the supporting plate 21.

Beneficially, a moving threaded shaft 19 is transversely and rotatably arranged on the inner lower side of the moving chute 18, the moving threaded shaft 19 is in threaded connection with the moving slider 20, a moving motor 17 is fixedly arranged in the left wall of the moving chute 18, the left end of the moving threaded shaft 19 is in power connection with the moving motor 17, and the moving motor 17 can drive the moving threaded shaft 19 to rotate when being started, so as to drive the moving slider 20 to move left and right.

Beneficially, a telescopic cavity 50 is communicated with the right wall of the moving sliding groove 18, a stress detection plate 49 is fixedly arranged on the inner wall of the telescopic cavity 50, a transmission connecting rod 48 capable of moving left and right is arranged in the telescopic cavity 50, a telescopic spring 51 is fixedly connected between the right end face of the transmission connecting rod 48 and the right wall of the telescopic cavity 50, the left end face of the transmission connecting rod 48 extends leftwards into the moving sliding groove 18 and is fixedly connected with a transmission plate 47, and the transmission plate 47 is fixedly connected with the right end face of the moving sliding block 20.

Beneficially, the upper side and the lower side of the clamping groove 58 are provided with clamping connection plates 59 which are symmetrical and can move up and down, a transmission cavity 56 is arranged in one side wall of the clamping groove 58, the transmission cavity 56 is internally provided with the input shaft 12 in a vertical rotating mode, the outer circular surface of the input shaft 12 is sleeved with transmission threaded sleeves 55 which are symmetrical up and down and have opposite threads, the left end face of the clamping connection plate 59 extends leftwards and is in threaded connection with the transmission threaded sleeves 55, the upper end face of the input shaft 12 extends upwards and is fixedly connected with a rotating disc 61, and the upper end face of the rotating disc 61 is rotatably connected with a rotating handrail 60.

Beneficially, fixed elastic plate 39 that is equipped with in front of back both sides of the lower terminal surface of working plate 31, elastic plate 39 has elasticity, be equipped with the decurrent joint groove 40 of opening in the elastic plate 39, both sides from top to bottom elastic plate 39 can mutually support and joint, two wall intercommunications are equipped with semicircular and the outside joint hole 62 of opening about in detecting chamber 26, the fixed elastic sealed rubber ring 27 that has that is equipped with of joint hole 62 inner wall, the upside detect chamber 26 and keep away from a lateral wall intercommunication of working chamber 25 is equipped with the ascending gas pocket 29 of opening, the fixed protection shield 30 that is equipped with of upside in the gas pocket 29.

Beneficially, a closed cavity 52 is arranged in the connecting pipeline 34 in a communicating manner at the upper side and the lower side, a closed plate 33 capable of moving up and down is arranged in the closed cavity 52, the closed plate 33 can move into the connecting pipeline 34 and close the left side and the right side of the connecting pipeline 34, a closed spring 53 is fixedly connected between one side end face of the closed plate 33 and one side wall of the closed cavity 52, a closed electromagnet 54 is fixedly arranged on one side wall of the closed cavity 52, the closed plate 33 has magnetism, the closed electromagnet 54 has magnetism when being started, and then the closed plate 33 is driven by magnetic force to move into the closed cavity 52 by overcoming the elastic force of the closed spring 53, and the two sides of the connecting pipeline 34 are communicated.

Beneficially, two walls of the front and the rear of the working cavity 25 are communicated and provided with symmetrical fan cavities 44, a rotating fan 42 is rotatably arranged in the fan cavity 44, a rotating motor 43 is fixedly arranged in a side wall of the fan cavity 44 far away from the working cavity 25, one end of the rotating fan 42 is connected to the rotating motor 43 in a power mode, a ventilation duct 41 with an outward opening is communicated and arranged on a side wall of the fan cavity 44 far away from the working cavity 25, and the rotating motor 43 can drive the rotating fan 42 to rotate when being started, so that air in the ventilation duct 41 is driven to enter the fan cavity 44.

Beneficially, the front wall and the rear wall of the lifting cavity 16 on the upper side and the lower side are communicated with each other and provided with symmetrical lifting chutes 37, the upper wall and the lower wall of the lifting chute 37 on the front side are fixedly provided with guide connecting rods 36, the upper wall and the lower wall of the lifting chute 37 on the rear side are rotatably provided with a lifting rotating shaft 57, the upper side and the lower side of the outer circular surface of the lifting rotating shaft 57 are sleeved with lifting threaded sleeves 46 with opposite threads, the front side and the rear side of the working plate 31 are fixedly connected with lifting sliders 38, the lifting sliders 38 on the front side are slidably connected with the guide connecting rods 36, the lifting sliders 38 on the rear side are in threaded connection with the lifting threaded sleeves 46, the lower wall of the lifting chute 37 on the rear side is fixedly provided with 5 lifting motors 45, the lower end of the lifting rotating shaft 57 is connected with the lifting motors 45, when the lifting motors 45 are started, the lifting rotating shafts 57 can be driven to rotate, and further drive the lifting threaded sleeves 46 to rotate, thereby driving the lifting chutes 37 at the rear side to move closer to each other, and further driving the working plates 31 at the upper and lower sides to move closer to each other.

Advantageously, a power motor 15 is fixedly arranged in the left wall of the lifting cavity 16 on the lower side, the lower end of the power shaft 14 is connected to the power motor 15 in a power mode, and when the power motor 15 is started, the power shaft 14 can be driven to rotate, so that the supporting rotary table 13 is driven to rotate.

The invention relates to an optical cable performance detection system, which comprises the following working procedures:

during operation, a tester holds the handheld slot 28 by hand and drives the main body 11 to move integrally to a working position, then manually drives the clamping plate 24 to move upwards, at the same time, the clamping plate 24 drives the lifting connecting rod 22 to move upwards against the elastic action of the lifting motor 45, at the same time, after winding one end of an optical cable to be tested around the lifting connecting rod 22 for one turn, at the same time, the tester does not pull the clamping plate 24 any more, then the lifting connecting rod 22 moves downwards under the elastic action of the lifting motor 45, and then one end of the optical cable is clamped and stably bound through the friction plate 23, and then the other end of the optical cable is moved to the clamping slot 58, at the same time, the rotating handrail 60 is held by hand and drives the rotating disc 61 to rotate, at the same time, the rotating disc 61 rotates and then drives the input shaft 12 to rotate, and then drives the transmission threaded sleeve 55 to rotate and then drives the clamping connecting plates 59 at two sides to move close to each other, and stably clamps two sides of the optical cable, at this time, the power motor 15 can drive the power shaft 14 to rotate when being started, and further drive the supporting turntable 13 to rotate, at this time, the supporting turntable 13 drives the optical cable to wind around the outer circular surface of the supporting turntable 13, and gradually tighten and straighten the optical cable between the supporting turntable 13 and the lifting connecting rod 22, at this time, the lifting motor 45 can drive the lifting rotating shaft 57 to rotate when being started, and further drive the lifting threaded sleeve 46 to rotate, and further drive the lifting chute 37 at the rear side to move close to each other, and further drive the working plates 31 at the upper and lower sides to move close to each other, and further mutually match through the clamping holes 62 at the upper and lower sides, stably clamp the outer circular surface of the optical cable, mutually match through the elastic plate 39, and form a closed space with the detection cavity 26, at this time, the upper closed electromagnet 54 has magnetism when being started, and further drives the closing plate 33 to move into the closed cavity 52 by magnetic force against the elastic force of the closed spring 53, and the two sides of the connecting pipeline 34 at the upper side are communicated, then the detection water stored in the water storage cavity 35 enters the telescopic pipeline 32 through the connecting pipeline 34 and enters the detection cavity 26, and the optical cable is soaked in the detection water, if the waterproof performance of the optical cable is poor, the detection water can enter the optical cable and leak from one end of the optical cable, and then the waterproof performance of the optical cable is conveniently judged, if the waterproof performance of the optical cable is good, the closed electromagnet 54 at the lower side is magnetic when being started, and then the closed plate 33 is driven by magnetic force to overcome the elastic force of the closed spring 53 and move into the closed cavity 52, and the two sides of the connecting pipeline 34 at the lower side are communicated, at this time, the detection water in the detection cavity 26 is discharged outwards through the telescopic pipeline 32 at the lower side, then the lifting motor 45 is turned over, and the working plates 31 at the two sides are moved and opened, and the rotating motors 43 at the two sides can drive the rotating fan 42 to rotate when being started, and then drive air in ventilation pipe 41 and enter into fan chamber 44, and input to working chamber 25, and the optical cable surface that will detect the performance and pass through is dry, convenient follow-up use, can drive when moving motor 17 starts afterwards and move threaded shaft 19 and rotate, and then drive and move slider 20 and move to the right, and drive driving plate 47 and move to the right, and drive connecting rod 48 and overcome the effect of expanding spring 51 elasticity and move to the right, and then detect tensile stress through stress detection board 49, and then detect the tensile property of optical cable, and then realize the performance detection of optical cable.

It will be apparent to those skilled in the art that various modifications may be made to the above embodiments without departing from the general spirit and concept of the invention. All falling within the scope of protection of the present invention. The protection scheme of the invention is subject to the appended claims.

Claims (9)

1. An optical cable performance detection system, including a main body (11), characterized in that: the portable multifunctional lifting machine is characterized in that a working cavity (25) which penetrates through the communication from left to right is arranged in the main machine body (11), a lifting cavity (16) which is symmetrical is arranged in the working cavity (25) in a communicating mode through upper and lower walls, a working plate (31) which can move up and down is arranged in the lifting cavity (16), a detection cavity (26) which is provided with an opening facing the working cavity (25) is arranged in the working plate (31), a telescopic pipeline (32) which can be telescopic is arranged in the upper wall of the detection cavity (26) in a communicating mode, a connecting pipeline (34) is arranged at one end of the telescopic pipeline (32) in a communicating mode, a water storage cavity (35) is arranged in the left wall of the lifting cavity (16) at the upper side, the connecting pipeline (34) at the upper side is communicated with the water storage cavity (35), a water outlet pipeline (63) is arranged in the connecting pipeline (34) at the lower side in a communicating mode, and a handheld groove (28) which penetrates through the front and the rear and the upper side is arranged in the right wall of the lifting cavity (16), a power shaft (14) is vertically and rotatably arranged on the left side in the working cavity (25), a supporting rotary table (13) is fixedly connected to the outer circular surface of the power shaft (14), clamping grooves (58) which are bilaterally symmetrical and have outward openings are formed in the left side and the right side in the supporting rotary table (13), a movable sliding groove (18) which has an upward opening and is communicated with the working cavity (25) is formed in the right wall of the lifting cavity (16) on the lower side, a movable sliding block (20) which can move left and right is arranged in the movable sliding groove (18), a supporting plate (21) is fixedly connected to the upper end face of the movable sliding block (20), a lifting threaded sleeve (46) with an upward opening is arranged in the movable sliding block (20), a lifting connecting rod (22) which can move up and down is arranged in the lifting threaded sleeve (46), and a lifting motor (45) is fixedly connected between the lower end face of the lifting connecting rod (22) and the lower wall of the lifting threaded sleeve (46), the upper end face of the lifting connecting rod (22) extends upwards and is fixedly connected with a clamping plate (24), and a friction plate (23) is fixedly arranged on the end face of one side, close to the supporting plate (21), of the clamping plate (24).

2. An optical cable performance testing system according to claim 1, wherein: the movable sliding groove is characterized in that a movable threaded shaft (19) is transversely arranged on the inner lower side of the movable sliding groove (18) in a rotating mode, the movable threaded shaft (19) is in threaded connection with the movable sliding block (20), a movable motor (17) is fixedly arranged in the left wall of the movable sliding groove (18), and the left end of the movable threaded shaft (19) is in power connection with the movable motor (17).

3. An optical cable performance testing system according to claim 1, wherein: remove spout (18) right wall intercommunication and be equipped with flexible chamber (50), flexible chamber (50) inner wall is fixed and is equipped with stress detection board (49), be equipped with transmission connecting rod (48) that can remove about in flexible chamber (50), transmission connecting rod (48) right-hand member face with fixedly connected with expanding spring (51) between flexible chamber (50) right wall, transmission connecting rod (48) left end face extends to left remove in spout (18) and fixedly connected with driving plate (47), driving plate (47) with remove slider (20) right-hand member face fixed connection.

4. An optical cable performance testing system according to claim 1, wherein: centre gripping groove (58) interior upper and lower both sides are equipped with symmetry and can reciprocate centre gripping connecting plate (59), be equipped with transmission chamber (56) in centre gripping groove (58) a lateral wall, perpendicular rotation is equipped with input shaft (12) in transmission chamber (56), the outer disc cover of input shaft (12) is equipped with transmission threaded sleeve (55) that symmetry and screw thread are opposite from top to bottom, centre gripping connecting plate (59) left end face extend left and with transmission threaded sleeve (55) threaded connection, upward extension and fixedly connected with of input shaft (12) upper end rotate the disc (61), it is connected with rotation handrail (60) to rotate disc (61) upper end rotation.

5. An optical cable performance testing system according to claim 1, wherein: fixed elastic plate (39) that are equipped with in both sides around the terminal surface under work board (31), be equipped with joint groove (40) that the opening is decurrent in elastic plate (39), both sides from top to bottom elastic plate (39) can mutually support and joint, two wall intercommunications are equipped with outside joint hole (62) of opening about in detecting chamber (26), joint hole (62) inner wall is fixed and is equipped with sealed rubber ring (27), the upside detect chamber (26) and keep away from a side wall intercommunication of work chamber (25) is equipped with opening ascending gas pocket (29), upside is fixed and is equipped with protection shield (30) in gas pocket (29).

6. An optical cable performance testing system according to claim 1, wherein: the upper and lower both sides intercommunication is equipped with closed chamber (52) in connecting tube (34), be equipped with in closed chamber (52) and move up and down's closing plate (33), closing plate (33) can move to in connecting tube (34) and with the connecting tube (34) left and right sides is sealed, closing plate (33) a side end with fixedly connected with sealing spring (53) between closed chamber (52) a lateral wall, closed chamber (52) a lateral wall is fixed and is equipped with sealed electro-magnet (54).

7. An optical cable performance testing system according to claim 1, wherein: two wall intercommunications are equipped with fan chamber (44) of symmetry around working chamber (25), fan chamber (44) internal rotation is equipped with rotation fan (42), fan chamber (44) are kept away from a working chamber (25) lateral wall internal fixation is equipped with rotation motor (43), rotation fan (42) one end power connect in rotate motor (43), fan chamber (44) are kept away from a working chamber (25) lateral wall intercommunication is equipped with outside air pipe (41) of opening.

8. An optical cable performance testing system according to claim 1, wherein: the front wall and the rear wall of the lifting cavity (16) at the upper side and the lower side are communicated with and provided with symmetrical lifting chutes (37), a guide connecting rod (36) is fixedly arranged between the upper wall and the lower wall of the lifting chute (37) at the front side, a lifting rotating shaft (57) is rotatably arranged between the upper wall and the lower wall of the lifting chute (37) at the rear side, the upper and lower sides of the excircle surface of the lifting rotating shaft (57) are sleeved with lifting threaded sleeves (46) with opposite threads, the front and back end faces of the working plate (31) are fixedly connected with lifting slide blocks (38), the front lifting slide block (38) is in sliding connection with the guide connecting rod (36), the rear lifting slide block (38) is in threaded connection with the lifting threaded sleeve (46), the lower wall of the rear lifting chute (37) is internally and fixedly provided with a 5-step lifting motor (45), the lower end of the lifting rotating shaft (57) is in power connection with the lifting motor (45).

9. An optical cable performance testing system according to claim 1, wherein: a power motor (15) is fixedly arranged in the left wall of the lifting cavity (16) on the lower side, and the lower end of the power shaft (14) is in power connection with the power motor (15).

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