CN115460108A

CN115460108A - Test system for power communication network

Info

Publication number: CN115460108A
Application number: CN202211094884.2A
Authority: CN
Inventors: 刘新; 刘冬兰; 常英贤; 张昊; 王睿; 姚洪磊; 马雷; 张方哲; 孙莉莉; 于灏; 秦佳峰; 苏冰; 赵勇; 井俊双
Original assignee: Electric Power Research Institute of State Grid Shandong Electric Power Co Ltd
Current assignee: Electric Power Research Institute of State Grid Shandong Electric Power Co Ltd
Priority date: 2022-09-08
Filing date: 2022-09-08
Publication date: 2022-12-09

Abstract

The invention belongs to the technical field of network test, and discloses a test system for a power communication network, which comprises: the invention discloses a detection instrument, which comprises a detection instrument transmitting end, wherein a first jack is formed in the detection instrument transmitting end, and the first jack is used for connecting a crystal head at one end of a network cable and transmitting data.

Description

Test system for power communication network

Technical Field

The invention belongs to the technical field of network testing, and particularly relates to a testing system for a power communication network.

Background

The network test mainly aims at network equipment such as a switch, a router, a firewall and the like, whether the equipment can achieve the established function can be verified through manual test or automatic test, before the existing communication equipment is used, a network is required to be connected to provide a network for the communication equipment, in order to ensure that the network can normally work, whether the network is normally communicated with a crystal head is required to be tested through the test equipment before the network is connected, when the existing test equipment tests the network, the crystal head at one end of the network is connected with a transmitting end of a detector, then the crystal head at the other end of the network is connected with a receiving end of the detector, and whether the network is normally communicated with the crystal head is prompted through the state of a corresponding indicator lamp on the receiving end of the detector.

When two ends of a plurality of network cables are located at different positions, detection personnel need to move between different positions, or at least two detection personnel are needed to be matched to detect the network cables, so that the detection difficulty of the network cables is increased, the detection efficiency of the network cables is reduced, and human resources are wasted.

Disclosure of Invention

The present invention provides a testing system for an electrical power communication network, so as to solve the problem that the detection personnel need to move between different positions or at least two detection personnel need to cooperate to detect a network cable, which is proposed in the above background art.

In order to achieve the purpose, the invention provides the following technical scheme: a test system for a power communication network, comprising: the detector transmitting end is provided with a first jack, and the first jack is used for connecting a crystal head at one end of a network cable and transmitting data; the detector receiving end is provided with a second jack, the second jack is used for connecting a crystal head at the other end of a network cable and receiving data sent by the detector transmitting end, and indicator lamps are arranged at the tops of the detector transmitting end and the detector receiving end; the detector transmitting end and the detector receiving end are detachably arranged on the supporting member; the limiting plate is provided with a limiting groove, and the limiting groove is used for placing one end, close to the crystal head, of the net wire; and the driving member is arranged on one side, close to the transmitting end and the receiving end of the detector, of the supporting member and is used for driving the limiting plate to horizontally reciprocate relative to the transmitting end and the receiving end of the detector, so that the crystal head is inserted into the first jack and the second jack or is pulled out of the first jack and the second jack.

Preferably, the support member comprises a first base; the top of the first base is fixedly connected with a first support frame; two first clamping grooves are symmetrically formed in the top of the first support frame; the two symmetrical sides of the emission end of the detector are fixedly connected with first clamping rods matched with the first clamping grooves.

Preferably, the support member further comprises a second base; the top of the second base is fixedly connected with a second support frame, and magnetic plates are arranged on the opposite sides of the second base and the first base; two second clamping grooves are symmetrically formed in the top of the second support frame; and two symmetrical sides of the receiving end of the detector are fixedly connected with second clamping rods matched with the second clamping grooves.

Preferably, one side of the top of the limiting plate is rotatably connected with a pressing plate; one side of the bottom of the pressing plate, which is close to the limiting groove, is fixedly connected with a limiting frame; the limiting grooves are matched with the limiting frames one by one.

Preferably, one side of the top of the limiting plate, which is close to the pressing plate, is fixedly connected with a magnetic sticker; the pressing plate is made of magnetic metal.

Preferably, the drive member comprises an electric push rod; the bottom of the limiting plate is fixed on the telescopic end of the electric push rod.

Preferably, the driving member further comprises a moving plate; top grooves are formed in the tops of the second base and the first base, motors are fixedly connected to the sides, opposite to the magnetic plate, of the second base and the first base, and a first wireless controller is fixedly connected to one side, adjacent to the magnetic plate, of the second base; one side of the first base, which is adjacent to the magnetic plate, is fixedly connected with a second wireless controller; a screw rod is rotatably connected inside the top groove; the output end of the motor is connected with the screw rod; the moving plate is sleeved on the screw rod, and the top of the moving plate is fixedly connected with a top plate; the electric push rod is fixed on the top of the top plate.

Preferably, protective housings are fixedly connected to the second base and one side, opposite to the magnetic plate, of the first base; the outer side of the protective shell is fixedly connected with a heat dissipation plate; the motor is fixedly connected to the inside of the protective shell.

Preferably, the second base and one side of the first base, which is opposite to the first wireless controller and one side of the second wireless controller, are fixedly connected with side frames; the guide rollers are rotatably connected inside the side frames; and a guide roller groove is formed on the outer side of the guide roller.

Preferably, the bottom of the limiting frame forms an inwards concave arc-shaped groove; the arc-shaped groove is used for abutting against the positioning net wire in the limiting groove.

Compared with the prior art, the invention has the beneficial effects that:

(1) According to the invention, one end of the network cable is placed through the limiting groove on the limiting plate, the driving component drives the limiting plate to move, so that the crystal head at one end of the network cable is inserted into the first jack at the transmitting end of the detector, the other end of the network cable is placed through the limiting groove on the other limiting plate, the driving component drives the limiting plate to move, so that the crystal head at the other end of the network cable is inserted into the second jack at the receiving end of the detector, when two ends of a plurality of network cables are in different positions, a detector does not need to move among different positions, and the network cable can be detected without the cooperation of at least two detectors, so that the detection difficulty of the network cable is reduced, the detection efficiency of the network cable is improved, and human resources are saved.

(2) On the basis of the beneficial effects, when the net wire is supported through the limiting groove in the limiting plate, the pressing plate is pulled to rotate around the limiting plate, the limiting frame is driven to rotate through the pressing plate, the limiting frame abuts against the net wire in the limiting groove, the net wire is more stable in moving, and the net wire is convenient to insert into the transmitting end and the receiving end of the detector.

(3) On the basis of the beneficial effects, when the pressure plate drives the limiting frame to rotate, the magnetic plate adsorbs the pressure plate, so that the pressure plate is more stable after rotating, the pressure plate and the limiting frame are more stable when abutting against the network cable, the stability of the network cable during moving is further improved, and the efficiency of inserting the network cable into the transmitting end and the receiving end of the detector is further improved.

(4) On the basis of the beneficial effects, when the limiting plate drives the net wires to move, the side frames rotate the guide rollers, when the net wires move, the guide rollers rotate around the side frames and are matched with the guide roller grooves on the guide rollers, so that the net wires move more stably, the net wires are prevented from accidentally falling off from the limiting plate, and the stability of the net wires during moving is further improved.

Drawings

FIG. 1 is a front view of the present invention;

FIG. 2 is a front view of the present invention with the platen removed;

FIG. 3 is a front view of the removal plate of FIG. 2;

FIG. 4 is a rear view of FIG. 2;

FIG. 5 is a top view of the present invention;

FIG. 6 is a top view of FIG. 2;

FIG. 7 is a top view of the plate of FIG. 6 with the plate of restriction removed;

FIG. 8 is a top view of the disassembled monitor transmitting end and monitor receiving end of FIG. 7;

FIG. 9 is a top view of the removable plate of FIG. 8;

fig. 10 is an internal structural view of the protective case of the present invention;

FIG. 11 is an enlarged view of portion A of FIG. 1;

FIG. 12 is an enlarged view of portion B of FIG. 1;

FIG. 13 is an enlarged view of portion C of FIG. 5;

FIG. 14 is an enlarged view of portion D of FIG. 5;

in the figure: 1. a side frame; 2. a heat dissipation plate; 3. a protective shell; 4. a first support frame; 5. a detector transmitting end; 6. pressing a plate; 7. a limiting plate; 8. magnetic pasting; 9. a detector receiving end; 10. a limiting frame; 11. a limiting groove; 12. a second base; 13. a magnetic plate; 14. a guide roller; 15. a guide roller groove; 16. a first base; 17. a first jack; 18. a second jack; 19. a second support frame; 20. a first wireless controller; 21. a second wireless controller; 22. an indicator light; 23. an electric push rod; 24. a top plate; 25. moving the plate; 26. a screw rod; 27. a top groove; 28. a motor; 29. a first clamping rod; 30. a second card slot; 31. a first card slot; 32. and a second clamping rod.

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 derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1-14, the present invention provides the following technical solutions:

the first embodiment is as follows:

a test system for a power communication network, comprising:

the detector comprises a detector transmitting end 5, wherein a first jack 17 is formed in the detector transmitting end 5, and the first jack 17 is used for connecting a crystal head at one end of a network cable and transmitting data;

the detector receiving end 9 is provided with a second jack 18, the second jack 18 is used for being connected with a crystal head at the other end of the network cable and receiving data sent by the detector transmitting end 5, and indicator lamps 22 are arranged at the tops of the detector transmitting end 5 and the detector receiving end 9;

the detector transmitting end 5 and the detector receiving end 9 are detachably mounted on the supporting member;

the limiting plate 7 is provided with a limiting groove 11, and the limiting groove 11 is used for placing one end, close to the crystal head, of the network cable;

and the driving component is arranged on one side of the supporting component, which is close to the detector transmitting end 5 and the detector receiving end 9, and is used for driving the limiting plate 7 to horizontally reciprocate relative to the detector transmitting end 5 and the detector receiving end 9, so that the crystal head is inserted into the first jack 17 and the second jack 18, or the crystal head is pulled out of the first jack 17 and the second jack 18.

Through the technical scheme, the emission end 5 of the detector is arranged on one of the supporting members, the crystal head at one end of the network cable is placed in the limiting groove 11 on the limiting plate 7, so that the network cable is arranged on the limiting plate 7, the receiving end 9 of the detector is arranged on the other supporting member, the crystal head at the other end of the network cable is placed in the limiting groove 11 on the limiting plate 7, so that the other end of the network cable is arranged on the limiting plate 7, after the network cable is connected with the limiting plate 7, the limiting plate 7 at one side of the emission end 5 of the detector is driven to move by the driving member, so that the crystal head at one end of the network cable is inserted into the first jack 17 on the emission end 5 of the detector, the limiting plate 7 at one side of the receiving end 9 of the detector is driven to move by the driving member, so that the limiting plate 7 drives the network cable to move, the crystal heads at one end of the network cable are inserted into the second jacks 18 on the detector receiving end 9, the crystal heads at two ends of the network cable are respectively connected with the detector receiving end 9 and the detector transmitting end 5, testers do not need to move between different positions, at least two testers do not need to operate cooperatively, data are sent through the detector transmitting end 5, the data are transmitted to the detector receiving end 9 through the network cable, the data transmitted by the network cable are received through the detector receiving end 9, if the crystal heads at two ends of the network cable are normally connected with the network cable, corresponding indicating lamps 22 on the detector receiving end 9 and the detector transmitting end 5 are normally on, and if the crystal heads at two ends of the network cable are abnormally connected with the network cable, corresponding indicating lamps 22 on the detector receiving end 9 and the detector transmitting end 5 are not on.

Example two:

a test system for a power communication network, comprising:

the driving component is arranged on one side, close to the detector transmitting end 5 and the detector receiving end 9, of the supporting component and is used for driving the limiting plate 7 to horizontally reciprocate relative to the detector transmitting end 5 and the detector receiving end 9, so that the crystal head is inserted into the first jack 17 and the second jack 18 or is pulled out of the first jack 17 and the second jack 18;

the support member includes a first base 16;

the top of the first base 16 is fixedly connected with a first support frame 4;

two first clamping grooves 31 are symmetrically formed in the top of the first support frame 4;

two symmetrical sides of the transmitting end 5 of the detector are fixedly connected with first clamping rods 29 matched with the first clamping grooves 31;

the support member further comprises a second base 12;

a second supporting frame 19 is fixedly connected to the top of the second base 12, and magnetic plates 13 are arranged on the opposite sides of the second base 12 and the first base 16;

two second clamping grooves 30 are symmetrically formed in the top of the second supporting frame 19;

and two symmetrical sides of the detector receiving end 9 are fixedly connected with second clamping rods 32 matched with the second clamping grooves 30.

Through the technical scheme, the second base 12 is connected with the first base 16 in an adsorption way through the two magnetic plates 13, so that the second base 12 and the first base 16 are convenient to move, the detector transmitting end 5 is connected with a first clamping groove 31 on a first supporting frame 4 at the top of the first base 16 in a clamping way through a first clamping rod 29, so that the detector transmitting end 5 is fixed on the first base 16, a crystal head at one end of a network cable is placed in a limiting groove 11 of a limiting plate 7 on the first base 16, the network cable is installed on the limiting plate 7, the detector receiving end 9 is connected with a second clamping groove 30 on a second supporting frame 19 at the top of the second base 12 in a clamping way through a second clamping rod 32, so that the detector receiving end 9 is fixed on the second base 12, the crystal head at the other end of the network cable is placed in a limiting groove 11 of the limiting plate 7 on the second base 12, so that the network cable is installed on the limiting plate 7, the limiting plate 7 on one side of the transmitting end 5 of the detector is driven to move by the driving member, so that the limiting plate 7 drives the network cable to move, the crystal head on one end of the network cable is inserted into the first jack 17 on the transmitting end 5 of the detector, the limiting plate 7 on one side of the receiving end 9 of the detector is driven to move by the driving member, so that the crystal head on one end of the network cable is inserted into the second jack 18 on the receiving end 9 of the detector, the crystal heads on two ends of the network cable are respectively connected with the receiving end 9 of the detector and the transmitting end 5 of the detector, so that testers do not need to move between different positions or cooperate with at least two testers, data is sent by the transmitting end 5 of the detector, the data is transmitted to the receiving end 9 of the detector through the network cable, the data transmitted by the network cable is received by the receiving end 9 of the detector, and if the crystal heads on two ends of the network cable are normally connected with the network cable, the corresponding indicator lights 22 on the detector receiving end 9 and the detector transmitting end 5 are normally on, and if the connection between the crystal heads at the two ends of the network cable and the network cable is abnormal, the corresponding indicator lights 22 on the detector receiving end 9 and the detector transmitting end 5 are not on.

Example three:

a test system for a power communication network, comprising:

the support member includes a first base 16;

the top of the first base 16 is fixedly connected with a first support frame 4;

the support member further comprises a second base 12;

two symmetrical sides of the detector receiving end 9 are fixedly connected with second clamping rods 32 matched with the second clamping grooves 30;

one side of the top of the limiting plate 7 is rotatably connected with a pressing plate 6;

one side of the bottom of the pressure plate 6 close to the limiting groove 11 is fixedly connected with a limiting frame 10;

the limiting grooves 11 are matched with the limiting frames 10 one by one;

the bottom of the limiting frame 10 forms an inwards concave arc-shaped groove;

the arc-shaped groove is used for supporting the positioning net thread in the limiting groove 11.

Through the technical proposal, the method has the advantages that,

the second base 12 is connected with the first base 16 in an adsorption way through two magnetic plates 13, so that the second base 12 and the first base 16 are convenient to move, the emission end 5 of the detector is connected with a first clamping groove 31 on a first supporting frame 4 at the top of the first base 16 in a clamping way through a first clamping rod 29, so that the emission end 5 of the detector is fixed on the first base 16, the crystal head at one end of the network cable is placed in a limiting groove 11 of a limiting plate 7 on the first base 16, the network cable is installed on the limiting plate 7, the pressing plate 6 is pulled, the pressing plate 6 rotates around one side of the limiting plate 7, the limiting frame 10 is driven to rotate through the pressing plate 6, the network cable in the limiting groove 11 is supported through the limiting frame 10 and an arc-shaped groove, so that the network cable is more stable when moving, and then the receiving end 9 of the detector is connected with a second clamping groove 30 on a second supporting frame 19 at the top of the second base 12 in a clamping way through a second clamping rod 32, thereby fixing the receiving end 9 of the detector on the second base 12, placing the crystal head at the other end of the network cable in the limiting groove 11 of the limiting plate 7 on the second base 12, so that the network cable is installed on the limiting plate 7, pulling the pressing plate 6 to rotate the pressing plate 6 around one side of the limiting plate 7, driving the limiting frame 10 to rotate through the pressing plate 6, abutting against the network cable in the limiting groove 11 through the limiting frame 10 and the arc-shaped groove, so that the network cable is more stable when moving, driving the limiting plate 7 at one side of the emitting end 5 of the detector to move through the driving member, so that the limiting plate 7 drives the network cable to move, so that the crystal head at one end of the network cable is inserted into the first jack 17 on the emitting end 5 of the detector, driving the limiting plate 7 at one side of the receiving end 9 of the detector to move through the driving member, so that the limiting plate 7 drives the network cable to move, so that the crystal head at one end of the network cable is inserted into the second jack 18 on the receiving end 9 of the detector, the quartzy head at net twine both ends is connected with detector receiving terminal 9 and detector transmitting terminal 5 respectively, let the tester need not to remove between different positions, also need not two at least testers interoperation, send data through detector transmitting terminal 5, carry data to detector receiving terminal 9 through the net twine, receive the data that the net twine was carried through detector receiving terminal 9, if the quartzy head at net twine both ends is connected normally with the net twine, then the pilot lamp 22 that corresponds on detector receiving terminal 9 and the detector transmitting terminal 5 is bright often, if the quartzy head at net twine both ends is connected abnormally with the net twine, then the pilot lamp 22 that corresponds on detector receiving terminal 9 and the detector transmitting terminal 5 is not bright.

Example four:

a test system for a power communication network, comprising:

the support member includes a first base 16;

the top of the first base 16 is fixedly connected with a first support frame 4;

two symmetrical sides of the detector transmitting end 5 are fixedly connected with first clamping rods 29 matched with the first clamping grooves 31;

the support member further comprises a second base 12;

the limiting grooves 11 are matched with the limiting frames 10 one by one;

one side of the top of the limiting plate 7, which is close to the pressing plate 6, is fixedly connected with a magnetic sticker 8;

the pressing plate 6 is made of magnetic metal.

By the technical scheme, the second base 12 is connected with the first base 16 in an adsorption way through the two magnetic plates 13, so that the second base 12 and the first base 16 are convenient to move, the detector transmitting end 5 is connected with the first clamping groove 31 on the first support frame 4 at the top of the first base 16 in an adsorption way through the first clamping rod 29, so that the detector transmitting end 5 is fixed on the first base 16, the crystal head at one end of the crystal line is placed in the limiting groove 11 of the limiting plate 7 on the first base 16, so that the crystal line is installed on the limiting plate 7, the pressing plate 6 is pulled, the pressing plate 6 rotates around one side of the limiting plate 7, the limiting frame 10 is driven to rotate through the pressing plate 6, one side of the pressing plate 6 is adsorbed by the magnetic paste 8, the crystal line in the limiting groove 11 is abutted by the limiting frame 10, so that the crystal line is more stable when the crystal line moves, the detector receiving end 9 is connected with the second clamping groove 30 on the second support frame 19 at the top of the second base 12 through the second clamping rod 32, so that the crystal head on the second base 12 is moved to drive the pressing plate 7 to move through the rotary pressing plate 7, so that the crystal line is moved through the pressing plate 6, so that the pressing plate 7 is moved through the rotary pressing plate 6 in the limiting groove 7, thereby the limiting plate 7, the detector, the detecting head which drives the crystal line to drive the detecting end 7, the detecting instrument 7, and the detecting end to move, and the detecting instrument 7, and the detecting instrument 9 is moved through the rotary wire to drive the detecting instrument 7, the crystal heads at one end of the network cable are inserted into the second jacks 18 on the detector receiving end 9, the crystal heads at two ends of the network cable are respectively connected with the detector receiving end 9 and the detector transmitting end 5, testers do not need to move between different positions, at least two testers do not need to operate cooperatively, data are sent through the detector transmitting end 5, the data are transmitted to the detector receiving end 9 through the network cable, the data transmitted by the network cable are received through the detector receiving end 9, if the crystal heads at two ends of the network cable are normally connected with the network cable, corresponding indicating lamps 22 on the detector receiving end 9 and the detector transmitting end 5 are normally on, and if the crystal heads at two ends of the network cable are abnormally connected with the network cable, corresponding indicating lamps 22 on the detector receiving end 9 and the detector transmitting end 5 are not on.

Example five:

a test system for a power communication network, comprising:

the support member includes a first base 16;

the top of the first base 16 is fixedly connected with a first support frame 4;

the support member further comprises a second base 12;

the top of the second base 12 is fixedly connected with a second support frame 19, and one side of the second base 12 opposite to the first base 16 is provided with a magnetic plate 13;

the limiting grooves 11 are matched with the limiting frames 10 one by one;

the pressing plate 6 is made of magnetic metal;

the drive means comprise an electric push rod 23;

the bottom of the limiting plate 7 is fixed on the telescopic end of the electric push rod 23;

the driving means further comprise a moving plate 25;

top grooves 27 are formed in the tops of the second base 12 and the first base 16, a motor 28 is fixedly connected to one side of each of the second base 12 and the first base 16, which is opposite to the magnetic plate 13, and a first wireless controller 20 is fixedly connected to one side of the second base 12, which is adjacent to the magnetic plate 13;

one side of the first base 16 adjacent to the magnetic plate 13 is fixedly connected with a second wireless controller 21;

a screw rod 26 is rotatably connected inside the top groove 27;

the output end of the motor 28 is connected with the screw rod 26;

the moving plate 25 is sleeved on the screw rod 26, and the top of the moving plate 25 is fixedly connected with a top plate 24;

the electric push rod 23 is fixed on the top of the top plate 24;

one sides of the second base 12 and the first base 16, which are opposite to the magnetic plate 13, are both fixedly connected with a protective shell 3;

the outer side of the protective shell 3 is fixedly connected with a heat dissipation plate 2;

the motor 28 is fixedly connected to the inside of the protective casing 3.

Through the technical scheme, the second base 12 is connected with the first base 16 in an adsorption way through the adsorption connection of the two magnetic plates 13, so that the second base 12 and the first base 16 are convenient to move, the emission end 5 of the detector is connected with the first clamping groove 31 on the first support frame 4 at the top of the first base 16 in a clamping way through the first clamping rod 29, so that the emission end 5 of the detector is fixed on the first base 16, the crystal head at one end of the network cable is placed in the limiting groove 11 of the limiting plate 7 on the first base 16, the network cable is installed on the limiting plate 7, the pressing plate 6 is pulled to rotate around one side of the limiting plate 7, the limiting frame 10 is driven to rotate through the pressing plate 6, one side of the pressing plate 6 is adsorbed through the magnetic paste 8, the network cable in the limiting groove 11 is supported through the limiting frame 10, so that the network cable is more stable when moving, the receiving end 9 of the detector is connected with the second clamping groove 30 on the second support frame 19 at the top of the second base 12 in a clamping way through the second clamping rod 32, thereby fixing the detector receiving end 9 on the second base 12, placing the crystal head at the other end of the network cable in the limiting groove 11 of the limiting plate 7 on the second base 12, installing the network cable on the limiting plate 7, pulling the pressing plate 6 to rotate the pressing plate 6 around one side of the limiting plate 7, driving the limiting frame 10 to rotate through the pressing plate 6, adsorbing one side of the pressing plate 6 through the magnetic paste 8, abutting the network cable in the limiting groove 11 through the limiting frame 10, making the network cable more stable when moving, protecting the motor 28 through the heat dissipation plate 2 and the protective shell 3, driving the lead screw 26 to rotate through the motor 28, matching through the top groove 27, making the moving plate 25 move in the top groove 27, driving the top plate 24 to move through the moving plate 25, thereby driving the electric push rod 23 to move, driving the limiting plate 7 at one side of the detector transmitting end 5 to move through the electric push rod 23, therefore, the limiting plate 7 drives the network cable to move, the crystal head at one end of the network cable is inserted into the first jack 17 on the transmitting end 5 of the detector, the lead screw 26 is driven by the motor 28 to rotate, the movable plate 25 is driven to move in the top groove 27 through the cooperation of the top groove 27, the top plate 24 is driven to move through the movable plate 25, the electric push rod 23 is driven to move, the limiting plate 7 on one side of the receiving end 9 of the detector is driven by the electric push rod 23 to move, the limiting plate 7 drives the network cable to move, the crystal head at one end of the network cable is inserted into the second jack 18 on the receiving end 9 of the detector, the crystal heads at two ends of the network cable are respectively connected with the receiving end 9 of the detector and the transmitting end 5 of the detector, so that the testers do not need to move between different positions and do not need to cooperatively operate by at least two testers, data is sent through the transmitting end 5 of the detector, the data is transmitted to the receiving end 9 of the network cable, the data transmitted to the receiving end 9 of the detector through the network cable, if the crystal heads at two ends of the network cable are normally connected with the network cable, the indicating lamps 22 on the transmitting end 5 of the detector, and the detector, if the crystal heads at two ends of the network cable are normally connected with the receiving end of the detector, and the indicating lamps 22 of the detector, and the indicating lamps on the detector are not normally connected with the detector, and the indicating lamps 22 of the detector 5.

Example six:

a test system for a power communication network, comprising:

the support member includes a first base 16;

the top of the first base 16 is fixedly connected with a first support frame 4;

the support member further comprises a second base 12;

one side of the bottom of the pressing plate 6 close to the limiting groove 11 is fixedly connected with a limiting frame 10;

the limiting grooves 11 are matched with the limiting frames 10 one by one;

the pressing plate 6 is made of magnetic metal;

the drive member comprises an electric push rod 23;

the driving means further comprise a moving plate 25;

a screw rod 26 is rotatably connected inside the top groove 27;

the output end of the motor 28 is connected with the screw rod 26;

the electric push rod 23 is fixed on the top of the top plate 24;

one sides of the second base 12 and the first base 16 opposite to the magnetic plate 13 are fixedly connected with a protective shell 3;

the motor 28 is fixedly connected to the inside of the protective shell 3;

the side frames 1 are fixedly connected to the second base 12 and the first base 16 on the opposite sides of the first wireless controller 20 and the second wireless controller 21;

the guide roller 14 is rotatably connected inside the side frame 1;

the guide roller 14 has a guide roller groove 15 formed on the outer side thereof.

Through the technical scheme, the second base 12 and the first base 16 are connected in an adsorption manner through the two magnetic plates 13, so that the second base 12 and the first base 16 are convenient to move, the detector transmitting end 5 is connected with a first clamping groove 31 on a first support frame 4 at the top of the first base 16 in an adsorption manner through a first clamping rod 29, so that the detector transmitting end 5 is fixed on the first base 16, a crystal head at one end of a network cable is placed in a limiting groove 11 of a limiting plate 7 on the first base 16, the network cable is installed on the limiting plate 7, the pressing plate 6 is pulled to rotate around one side of the limiting plate 7, the limiting frame 10 is driven to rotate through the pressing plate 6, one side of the pressing plate 6 is adsorbed through the magnetic paste 8, the network cable in the limiting groove 11 is propped against through the limiting frame 10, so that the receiving end of the network cable is more stable when the network cable moves, and the detector 9 is connected with a second clamping groove 30 on a second support frame 19 at the top of the second base 12 in an adsorption manner through a second clamping rod 32, thereby fixing the detector receiving end 9 on the second base 12, placing the crystal head at the other end of the network cable in the limiting groove 11 of the limiting plate 7 on the second base 12, installing the network cable on the limiting plate 7, pulling the pressing plate 6 to rotate the pressing plate 6 around one side of the limiting plate 7, driving the limiting frame 10 to rotate through the pressing plate 6, adsorbing one side of the pressing plate 6 through the magnetic paste 8, abutting the network cable in the limiting groove 11 through the limiting frame 10, making the network cable more stable when moving, driving the screw rod 26 to rotate through the motor 28, moving the moving plate 25 in the top groove 27 through the cooperation of the top groove 27, driving the top plate 24 to move through the moving plate 25, driving the electric push rod 23 to move, driving the limiting plate 7 at one side of the detector transmitting end 5 to move through the electric push rod 23, thereby driving the network cable to move through the limiting plate 7, the method comprises the steps that a crystal head at one end of a network cable is inserted into a first jack 17 on a detector transmitting end 5, a lead screw 26 is driven to rotate through a motor 28, a moving plate 25 moves in a top groove 27 through the cooperation of the top groove 27, a top plate 24 is driven to move through the moving plate 25, a motor push rod 23 is driven to move, a limiting plate 7 on one side of a detector receiving end 9 is driven to move through the motor push rod 23, the limiting plate 7 drives the network cable to move, the crystal head at one end of the network cable is inserted into a second jack 18 on the detector receiving end 9, when the limiting plate 7 drives the network cable to move, a guide roller 14 is supported through a side frame 1, the guide roller 14 rotates around the side frame 1 and is matched through a guide roller groove 15, the network cable moves more stably, the crystal heads at two ends of the network cable are respectively connected with the detector receiving end 9 and the detector transmitting end 5, a tester does not need to move between different positions, at least two testers cooperatively operate, data are sent through the detector transmitting end 5, the data are transmitted to the network cable to the detector receiving end 9, the detector receiving end 9 and the detector transmitting end 9 are connected with the crystal head, if the crystal head at two ends of the network cable, the detector is not normally connected with the detector, and the detector transmitting end 22 is normally connected with the detector.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that various changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims

1. A test system for a power communication network, comprising:

the device comprises a detector transmitting end (5), wherein a first jack (17) is formed in the detector transmitting end (5), and the first jack (17) is used for connecting a crystal head at one end of a network cable and transmitting data;

the device comprises a detector receiving end (9), wherein a second jack (18) is formed in the detector receiving end (9), the second jack (18) is used for being connected with a crystal head at the other end of a network cable and receiving data sent by a detector transmitting end (5), and indicator lamps (22) are arranged at the tops of the detector transmitting end (5) and the detector receiving end (9);

the detector transmitting end (5) and the detector receiving end (9) are both detachably mounted on the supporting member;

the limiting plate (7), a limiting groove (11) is formed in the limiting plate (7), and the limiting groove (11) is used for placing one end, close to the crystal head, of the network cable;

the driving component is arranged on one side, close to the detector transmitting end (5) and the detector receiving end (9), of the supporting component, and the driving component is used for driving the limiting plate (7) to horizontally reciprocate relative to the detector transmitting end (5) and the detector receiving end (9), so that the crystal head is inserted into the first jack (17) and the second jack (18), or the crystal head is pulled out of the first jack (17) and the second jack (18).

2. A test system for an electric power communication network according to claim 1, characterized in that: the support member comprises a first base (16);

the top of the first base (16) is fixedly connected with a first support frame (4);

two first clamping grooves (31) are symmetrically formed in the top of the first support frame (4);

the two symmetrical sides of the emission end (5) of the detector are fixedly connected with first clamping rods (29) matched with the first clamping grooves (31).

3. A test system for an electric power communication network according to claim 2, characterized in that: the support member further comprises a second base (12);

the top of the second base (12) is fixedly connected with a second support frame (19), and magnetic plates (13) are arranged on one sides of the second base (12) opposite to the first base (16);

two second clamping grooves (30) are symmetrically formed in the top of the second supporting frame (19);

and two symmetrical sides of the detector receiving end (9) are fixedly connected with second clamping rods (32) matched with the second clamping grooves (30).

4. A test system for an electric power communication network according to claim 3, characterized in that: one side of the top of the limiting plate (7) is rotatably connected with a pressing plate (6);

one side of the bottom of the pressure plate (6) close to the limiting groove (11) is fixedly connected with a limiting frame (10);

the limiting grooves (11) are matched with the limiting frames (10) one by one.

5. A test system for an electric power communication network according to claim 4, characterized in that: one side, close to the pressing plate (6), of the top of the limiting plate (7) is fixedly connected with a magnetic sticker (8);

the pressing plate (6) is made of magnetic metal.

6. A test system for electric power communication networks according to claim 3, 4 or 5, characterized in that: the drive member comprises an electric push rod (23);

the bottom of the limiting plate (7) is fixed on the telescopic end of the electric push rod (23).

7. A test system for an electric power communication network according to claim 6, characterized in that: the drive means further comprise a moving plate (25);

top grooves (27) are formed in the tops of the second base (12) and the first base (16), a motor (28) is fixedly connected to one sides, opposite to the magnetic plate (13), of the second base (12) and the first base (16), and a first wireless controller (20) is fixedly connected to one side, adjacent to the magnetic plate (13), of the second base (12);

one side of the first base (16) adjacent to the magnetic plate (13) is fixedly connected with a second wireless controller (21);

a screw rod (26) is rotatably connected inside the top groove (27);

the output end of the motor (28) is connected with the screw rod (26);

the moving plate (25) is sleeved on the screw rod (26), and the top of the moving plate (25) is fixedly connected with a top plate (24);

the electric push rod (23) is fixed on the top of the top plate (24).

8. A test system for an electric power communication network according to claim 7, characterized in that: one sides of the second base (12) and the first base (16), which are opposite to the magnetic plate (13), are fixedly connected with a protective shell (3);

the outer side of the protective shell (3) is fixedly connected with a heat dissipation plate (2);

the motor (28) is fixedly connected to the inside of the protective shell (3).

9. A test system for an electric power communication network according to claim 7, characterized in that: one sides, opposite to the first wireless controller (20) and the second wireless controller (21), of the second base (12) and the first base (16) are fixedly connected with side frames (1);

a guide roller (14) is rotatably connected inside the side frame (1);

and a guide roller groove (15) is formed on the outer side of the guide roller (14).

10. A test system for an electric power communication network according to claim 4, characterized in that: the bottom of the limiting frame (10) forms an inwards concave arc-shaped groove;

the arc-shaped groove is used for abutting against the internal positioning network cable of the limiting groove (11).