CN115864249B - Stable type installation device for ship cable - Google Patents

Abstract

The invention discloses a stable installation device for ship cables, which relates to the technical field of ship cable installation, and is characterized in that the ship cables with different outer diameters are subjected to adaptive extrusion stabilization, on the basis of forming nodes, environmental information at the nodes is collected for analysis and display, then a virtual layout diagram capable of being dynamically refreshed is formed by combining the ship cables, and the environmental conditions at each node are observed in real time through the virtual layout diagram so as to pre-sense the ship cables and the environments nearby the ship cables, and further intuitively and comprehensively control the ship cables, so that the ship cables are simpler and more convenient to replace and maintain; and the environmental parameters in the process of transmitting the power through the ship cable are collected to influence the ship cable, the ageing condition of the ship cable is converted and pre-separated, maintenance personnel are reminded to plan and replace the ship cable in advance, the power transmission failure probability of the ship is reduced, and meanwhile, the efficient operation of ship equipment is guaranteed.

Description

Stable type installation device for ship cable

Technical Field

The invention relates to the technical field of ship cable installation, in particular to a ship cable stable installation device.

Background

The cable is an electric energy or signal transmission device, usually consists of several or several groups of wires, the cable is safely and firmly arranged on the inner wall of a ship or on a telegraph pole and a building wall, the existing ship cable is generally directly fixed on the inner wall of the ship through a cable pipe clamp, the method is firmly connected, but has the defects that the ship can not timely remind the replacement of the ship cable because the ship runs on the river surface or the sea surface for a long time, the humidity of the river surface or the sea surface is high, the temperature changes quickly, the aging of the ship cable is often accelerated, after the aging of the ship cable is accelerated, the protection layer of the ship cable combusts due to aging oxidation, and after the ship cable combusts, the environment information at the ship cable can not be acquired for analysis and display to generate a virtual layout diagram which can be dynamically refreshed;

in view of the above technical drawbacks, a solution is now proposed.

Disclosure of Invention

The invention aims at: the method comprises the steps of carrying out adaptive extrusion stabilization on single-stranded or multi-stranded ship cables with different outer diameters, forming a node basis, collecting environmental information at the node, analyzing and displaying, forming a virtual layout capable of being refreshed dynamically by combining the ship cables, and observing environmental conditions at each node in real time through the virtual layout so as to pre-sense the ship cables and environments nearby the ship cables, and further intuitively and comprehensively controlling the ship cables, so that replacement and maintenance are simpler and more convenient; and the environmental parameters in the process of transmitting the power through the ship cable are collected to influence the ship cable, the ageing condition of the ship cable is converted and pre-separated, maintenance personnel are reminded to plan and replace the ship cable in advance, the power transmission failure probability of the ship is reduced, and meanwhile, the efficient operation of ship equipment is guaranteed.

In order to achieve the above purpose, the present invention adopts the following technical scheme:

a stable type installation device for ship cables comprises an induction installation unit, a mark construction unit, a supervision server and an acquisition analysis unit;

the induction installation unit performs adaptive extrusion stabilization on single-stranded or multi-stranded ship cables with different outer diameters, and simultaneously generates environmental information in an induction way;

the method comprises the steps that a marking construction unit marks a plurality of sensing installation monomers to form an environment sensing node, the environment sensing node is connected through a ship cable to form a virtual layout, and the virtual layout is sent to a supervision server and displayed;

the acquisition and analysis unit is used for acquiring the environmental information at the node and comparing the data of the environmental information at the node with the corresponding preset value respectively: when the data are smaller than the corresponding preset value, no signal is generated, otherwise, a lighting signal is generated; extracting a virtual layout stored in the supervision server after generating a lighting signal, lighting a corresponding node, and refreshing and displaying the virtual layout after the node is lighted;

simultaneously acquiring the number of lighting signals in the same time period, generating a voice reminding text when the number of the lighting signals is larger than the preset number, and sending the voice reminding text to a supervision server for playing;

the supervision server is used for storing and refreshing data and connecting terminal equipment, wherein the terminal equipment is a ship display screen.

Further, the response installation monomer includes the bottom plate, four mounting holes have been seted up in four hanging angle departments of bottom plate, the top surface fixed mounting of bottom plate has a top shell, top shell internal rotation is equipped with receives a line section of thick bamboo, the both ends of receiving a line section of thick bamboo are fixed to be equipped with spacing smooth protruding, spacing smooth protruding is equipped with a plurality of, and spacing smooth protruding uses the section of thick bamboo center of receiving a line section of thick bamboo as the center and distributes according to annular array, spacing smooth protruding slip joint has stable smooth leaf, the arc slide of the spacing smooth protruding slip joint of adaptation has been seted up to stable smooth leaf, the outer end and the arc slide sliding connection of spacing smooth protruding, the tip of stable smooth She Yuanli is articulated to have the articulated support through the pivot, the one end that stabilizes smooth leaf is kept away from to the articulated support is fixed to be located in the top shell, be equipped with torsion spring between articulated support and the stable smooth leaf, torsion spring's both ends respectively with articulated support and stable smooth She Hanjie.

Further, the fixed cover in middle part of the outer terminal surface of receiving a line section of thick bamboo is equipped with first bevel gear, first bevel gear meshing is connected with second bevel gear, second bevel gear transmission is connected with micro motor, micro motor is fixed to be located in the top shell, and micro motor's output shaft and second bevel gear are fixed to be cup jointed, first bevel gear's both sides are equipped with the stop collar, the outer end of receiving a line section of thick bamboo is located to the stop collar fixed cover, and stop collar and first bevel gear clearance set up, the inner of stop collar rotates with a line section of thick bamboo through the bearing and is connected, and the outer end fixedly connected with fixed block of stop collar, fixed block and top shell fixed connection, the stop collar is passed through the bearing and is received a line section of thick bamboo at a spacing.

Further, the temperature and humidity sensors are symmetrically arranged at the top shell, wherein the environmental information at the node comprises the temperature and humidity in the induction installation unit sensed by the temperature and humidity sensors.

Further, the monitoring server is in signal connection with a temporary storage unit and an aging analysis unit;

the temporary storage unit acquires the environmental information at the node through the acquisition and analysis unit, temporarily stores the environmental information at the node, packages the environmental information at the node into a data packet when the environmental information at the node reaches a preset byte, and sends the data packet to the aging analysis unit;

after receiving the data packet, the aging analysis unit decompresses and analyzes the data packet:

when the data in the data packet is respectively smaller than the minimum value of the preset threshold value, subtracting the minimum value of the preset threshold value from the data in the data packet corresponding to the minimum value of the preset threshold value, multiplying the subtracted difference by a weight factor I corresponding to the subtracted difference, and adding the multiplied products to obtain a deviation result; when the data in the data packet is respectively larger than the maximum value of the preset threshold value, subtracting the maximum value of the preset threshold value corresponding to the data in the data packet from the data in the data packet, multiplying the subtracted difference with a weight factor II corresponding to the subtracted difference, and adding the multiplied products to obtain a deviation result; and the maximum value of the preset threshold value is smaller than the preset value;

when a deviation result or a deviation result is generated, multiplying the deviation result or the deviation result by corresponding conversion factors respectively, multiplying the multiplied result by a corresponding weight factor III to obtain an aging factor, and storing the aging factor;

and randomly acquiring an accumulated aging factor mean value of the single-path ship cable at the related node, generating a line replacement signal when the accumulated aging factor mean value reaches an aging critical point, and performing line processing operation after generating the line replacement signal.

Further, the line processing operation process is specifically;

after the line replacement signal is generated, node information corresponding to the line replacement signal is obtained and a node set is generated, the node set is sent to a supervision server after being generated, the supervision server receives the node set to refresh and highlight the corresponding node in the node set, after the highlighting, a maintainer replaces the aged ship cable, after the replacement is completed, after the ship cable is detected to transmit normal power, the highlighted node is recovered, and the total maintenance times of the maintainer are recorded once.

Furthermore, the supervision server is also in signal connection with a registration login module, the registration login module is used for submitting personnel information through a mobile phone terminal for registration, and sending the personnel information which is successfully registered to the supervision server for storage, meanwhile, the supervision server marks the successfully registered maintenance personnel as registered personnel, and meanwhile, the moment of receiving the personnel information is marked as the registration moment of the registered personnel; the personnel information comprises the name, the mobile phone number and the age of the maintenance personnel, and the virtual layout is directly sent to the mobile phone terminal of the maintenance personnel for display.

In summary, due to the adoption of the technical scheme, the beneficial effects of the invention are as follows:

according to the invention, the self-adaptive extrusion stabilization is carried out on single-stranded or multi-stranded ship cables with different outer diameters, the environmental information at the nodes is collected for analysis and display on the basis of the nodes, then a virtual layout diagram capable of being dynamically refreshed is formed by combining the ship cables, and the environmental conditions at each node are observed in real time through the virtual layout diagram, so that the ship cables and the environments nearby the ship cables are pre-sensed, the ship cables are further intuitively and comprehensively controlled, and the replacement and maintenance are simpler and more convenient;

the invention also discloses a ship cable ageing system, which is characterized in that the ship cable ageing system is provided with a ship cable ageing system, wherein the ship cable ageing system is provided with a ship cable ageing system, and the ship cable ageing system is provided with a ship cable ageing system.

Drawings

FIG. 1 shows a flow diagram of the present invention;

FIG. 2 shows a perspective view of an induction mount unit;

FIG. 3 shows a schematic structural diagram within an induction mounting unit;

FIG. 4 shows an enlarged cross-sectional view of the torsion spring;

legend description: 1. a bottom plate; 2. a top shell; 3. a wire receiving cylinder; 4. limiting sliding convex; 5. stabilizing the sliding leaves; 6. an arc-shaped slideway; 7. a hinged bracket; 8. a torsion spring; 9. a first bevel gear; 10. a second bevel gear; 11. a micro motor; 12. a limit sleeve; 13. a fixed block; 14. a temperature and humidity sensor; 15. and a threading opening.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present invention, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

Example 1

As shown in fig. 1-4, a stable installation device for a ship cable comprises an induction installation unit, a mark construction unit, a supervision server and an acquisition and analysis unit;

the induction installation unit comprises a bottom plate 1, four installation holes are formed in four hanging corners of the bottom plate 1, a plurality of induction installation units are installed in a ship through four bolts penetrating through the installation holes, a top shell 2 is fixedly installed on the top surface of the bottom plate 1, a wire receiving cylinder 3 is rotatably arranged in the top shell 2, limiting sliding protrusions 4 are fixedly arranged at two ends of the wire receiving cylinder 3, a plurality of limiting sliding protrusions 4 are arranged, the limiting sliding protrusions 4 take the cylinder center of the wire receiving cylinder 3 as the center and are distributed according to an annular array, the limiting sliding protrusions 4 are in sliding connection with stable sliding leaves 5, arc-shaped slide ways 6 which are matched with the limiting sliding protrusions 4 in sliding connection are formed in the stable sliding leaves 5, the outer ends of the limiting sliding protrusions 4 are in sliding connection with the arc-shaped slide ways 6, the ends of the limiting sliding protrusions 4, which are far away from the limiting sliding protrusions 4, are hinged with hinged supports 7 through rotating shafts, one ends of the hinged supports 7, which are far away from the stable sliding leaves 5, are fixedly arranged in the top shell 2, torsion springs 8 are arranged between the hinged supports 7 and the stable sliding leaves 5, and two ends of the torsion springs 8 are respectively welded with the hinged supports 7 and the stable sliding leaves 5;

the middle part of the outer end surface of the wire receiving cylinder 3 is fixedly sleeved with a first bevel gear 9, the first bevel gear 9 is in meshed connection with a second bevel gear 10, the second bevel gear 10 is in transmission connection with a miniature motor 11, the miniature motor 11 is fixedly arranged in the top shell 2, an output shaft of the miniature motor 11 is fixedly sleeved with the second bevel gear 10, two sides of the first bevel gear 9 are provided with limiting sleeves 12, the limiting sleeves 12 are fixedly sleeved at the outer end of the wire receiving cylinder 3, the limiting sleeves 12 are in clearance arrangement with the first bevel gear 9, the inner ends of the limiting sleeves 12 are in rotary connection with the wire receiving cylinder 3 through bearings, the outer ends of the limiting sleeves 12 are fixedly connected with fixing blocks 13, the fixing blocks 13 are fixedly connected with the top shell 2, and the limiting sleeves 12 are in limiting and wire receiving cylinder 3 through bearings;

the temperature and humidity sensors 14 are symmetrically arranged at the top shell 2, and the temperature and humidity sensors 14 are respectively used for sensing temperature and humidity;

the specific working process and principle of the invention are as follows:

firstly, a plurality of induction installation monomers are installed at an installation node of a planning ship cable of a ship, then a micro motor 11 is controlled to rotate to drive a second bevel gear 10 fixed with the micro motor to rotate, the second bevel gear 10 rotates to drive a first bevel gear 9 meshed with the second bevel gear 10 to rotate, the first bevel gear 9 rotates to drive a storage wire barrel 3 fixed with the first bevel gear 9 to rotate anticlockwise, the storage wire barrel 3 rotates anticlockwise to drive a limit sliding vane 4 fixed with the storage wire barrel to slide along a stable sliding vane 5 in sliding clamping mode, and as a limit sleeve 12 limits the storage wire barrel 3, the stable sliding vane 5 is pushed to open in the sliding process of the 4 along an arc-shaped slide 6, the stable sliding vane 5 drives a torsion spring 8 fixed with the stable sliding vane 5 to open after being opened, when the stable sliding vane 5 is opened completely, the ship cable passes through a threading opening 15 of a top shell 2, then the micro motor 11 is stopped to run, at the moment, the stable sliding vane 5 is retracted under the reverse acting force of the torsion spring 8, the stable sliding vane 5 is propped against the outer end face of the ship cable to be stabilized, and simultaneously, and a plurality of temperature and humidity sensors 14 are opened to conduct different external diameters of the ship cable or stable ship cable;

marking a plurality of sensing installation monomers by a marking construction unit to form an environment sensing node, connecting the environment sensing node through a ship cable to form a virtual layout, and sending the virtual layout to a supervision server and displaying; the maintenance personnel can visually check the position of the ship cable through the virtual layout diagram, so that the maintenance work of the ship cable is facilitated;

step three, the collection analysis unit is used for collecting the environmental information at the node and comparing the data of the environmental information at the node with the corresponding preset value respectively,

when the data are smaller than the corresponding preset value, no signal is generated, otherwise, a lighting signal is generated; extracting a virtual layout stored in the supervision server after generating a lighting signal, lighting a corresponding node, and refreshing and displaying the virtual layout after the node is lighted; wherein the environmental information at the node includes sensing temperature and humidity within the mounting unit;

simultaneously acquiring the number of lighting signals in the same time period, generating a voice reminding text when the number of the lighting signals is larger than the preset number, and sending the voice reminding text to a supervision server for playing, wherein the supervision server is connected with a display screen and a player; the voice reminding text voice reminding maintenance personnel carry out voice reminding on the ship cable at the node;

according to the technical scheme, the single-stranded or multi-stranded ship cables with different outer diameters are adaptively extruded and stabilized, the node is formed, the environmental information at the node is generally collected for analysis and display, then a virtual layout diagram capable of being dynamically refreshed is formed by combining the ship cables, and the environmental conditions at each node are observed in real time through the virtual layout diagram, so that the ship cables and the environments nearby the ship cables are pre-sensed conveniently, the ship is intuitively, conveniently and comprehensively controlled, and the replacement and maintenance are simpler and more convenient.

Example 2

As shown in fig. 1: the monitoring server is in signal connection with a temporary storage unit, the temporary storage unit acquires the environmental information at the node through the acquisition and analysis unit, temporarily stores the environmental information at the node, and packages the environmental information at the node into a data packet and sends the data packet to the aging analysis unit when the environmental information at the node reaches a preset byte;

for example, when the environmental information at the node reaches 1 megabyte, the environmental information is packed into a data packet; thus, the calculation force of real-time calculation is reduced, and the cost is reduced; megabits are the storage unit;

after receiving the data packet, the aging analysis unit decompresses and analyzes the data packet:

when the data in the data packet is respectively smaller than the minimum value of the preset threshold value, subtracting the minimum value of the preset threshold value from the data in the data packet corresponding to the minimum value of the preset threshold value, multiplying the subtracted difference by a weight factor I corresponding to the subtracted difference, and adding the multiplied products to obtain a deviation result; when the data in the data packet is respectively larger than the maximum value of the preset threshold value, subtracting the maximum value of the preset threshold value corresponding to the data in the data packet from the data in the data packet, multiplying the subtracted difference with a weight factor II corresponding to the subtracted difference, and adding the multiplied products to obtain a deviation result; and the maximum value of the preset threshold value is smaller than the preset value;

when a deviation result or a deviation result is generated, multiplying the deviation result or the deviation result by corresponding conversion factors respectively, multiplying the multiplied result by a corresponding weight factor III to obtain an aging factor, and storing the aging factor; the weight factor I, the weight factor II, the weight factor III and the conversion factor are subjected to data simulation and formula fitting, the corresponding weight size is distributed according to the influence degree of parameters on the result, the aging factor is used for judging the influence of the environment on the cable, and when the aging factor appears, the node environment of the cable is abnormal;

randomly acquiring an accumulated aging factor mean value of a single-path ship cable at a joint, generating a line replacement signal when the accumulated aging factor mean value reaches an aging critical point, and performing line processing operation after generating the line replacement signal;

the line processing operation process comprises the following steps of;

the method comprises the steps that after a line replacement signal is generated, node information corresponding to the line replacement signal is obtained and a node set is generated, the node set is sent to a supervision server after being generated, the supervision server receives the node set to refresh and highlight corresponding nodes in the node set, after highlighting, maintenance personnel replace aged ship cables, after replacement is completed, after detecting that the ship cables are normal in power transmission, the highlighted nodes are restored, and the total maintenance times of maintenance personnel are recorded once;

according to the technical scheme, the ship cable ageing is converted and pre-separated by collecting the influence of the environmental parameters on the ship cable in the power transmission process, so that maintenance personnel is pre-reminded to plan and replace the ship cable in advance, the power transmission failure probability of the ship is reduced, and the efficient operation of ship equipment is ensured.

Example 3

As shown in fig. 1, the supervision server is further in signal connection with a registration login module, and the registration login module is used for submitting personnel information through a mobile phone terminal for registration by a maintainer, sending the personnel information which is successfully registered to the supervision server for storage, marking the maintainer which is successfully registered as a registrant by the supervision server, and marking the time when the personnel information is received as the registration time of the registrant; the personnel information comprises the name, the mobile phone number and the age of the maintainer, and the virtual layout can be directly sent to the mobile phone terminal of the maintainer for display, so that the reminding assistance is more convenient and efficient.

In the drawings of the disclosed embodiments, only the structures related to the embodiments of the present disclosure are referred to, other structures can refer to the general design, and the same embodiment and different embodiments of the present disclosure can be combined with each other under the condition of no conflict; the foregoing is only a preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art, who is within the scope of the present invention, should make equivalent substitutions or modifications according to the technical scheme of the present invention and the inventive concept thereof, and should be covered by the scope of the present invention.

Claims (5)

1. The stable type installation device for the ship cable is characterized by comprising an induction installation unit, a mark construction unit, a supervision server and an acquisition analysis unit;

the induction installation unit performs adaptive extrusion stabilization on single-stranded or multi-stranded ship cables with different outer diameters, and simultaneously generates environmental information in an induction way;

the method comprises the steps that a marking construction unit marks a plurality of sensing installation monomers to form an environment sensing node, the environment sensing node is connected through a ship cable to form a virtual layout, and the virtual layout is sent to a supervision server and displayed;

the acquisition and analysis unit is used for acquiring the environmental information at the node and comparing the data of the environmental information at the node with the corresponding preset value respectively: when the data are smaller than the corresponding preset value, no signal is generated, otherwise, a lighting signal is generated; extracting a virtual layout stored in the supervision server after generating a lighting signal, lighting a corresponding node, and refreshing and displaying the virtual layout after the node is lighted;

simultaneously acquiring the number of lighting signals in the same time period, generating a voice reminding text when the number of the lighting signals is larger than the preset number, and sending the voice reminding text to a supervision server for playing;

the supervision server is used for storing and refreshing data and connecting terminal equipment, wherein the terminal equipment is a ship display screen;

the induction installation monomer comprises a bottom plate (1), four installation holes are formed in four hanging corners of the bottom plate (1), a top shell (2) is fixedly installed on the top surface of the bottom plate (1), a receiving wire barrel (3) is rotationally arranged in the top shell (2), limiting sliding lugs (4) are fixedly arranged at two ends of the receiving wire barrel (3), the limiting sliding lugs (4) are provided with a plurality of limiting sliding lugs (4), the barrel centers of the receiving wire barrel (3) are used as centers and distributed according to an annular array, the limiting sliding lugs (4) are in sliding joint with stable sliding leaves (5), an arc-shaped slide way (6) which is matched with the limiting sliding lugs (4) in sliding joint is arranged on the stable sliding leaves (5), the outer ends of the limiting sliding lugs (4) are in sliding connection with the arc-shaped slide way (6), the ends of the stable sliding leaves (5) are far away from the limiting sliding lugs (4) and are hinged with hinged supports (7) through rotating shafts, one ends of the hinged supports (7) far away from the stable sliding leaves (5) are fixedly arranged in the top shell (2), and the stable sliding leaves (5) are respectively welded with the two ends of the stable sliding leaves (8) through torsion springs (8);

the utility model discloses a take-up line section of thick bamboo (3) outer terminal surface middle part fixed cover is equipped with first bevel gear (9), first bevel gear (9) meshing is connected with second bevel gear (10), second bevel gear (10) transmission is connected with micro motor (11), micro motor (11) are fixed to be located in top shell (2), and the output shaft of micro motor (11) is fixed cup joint with second bevel gear (10), the both sides of first bevel gear (9) are equipped with stop collar (12), the outer end of taking-up line section of thick bamboo (3) is located to stop collar (12) fixed cover, and stop collar (12) and first bevel gear (9) clearance setting, the inner of stop collar (12) is through bearing and take-up line section of thick bamboo (3) rotation connection, and the outer fixedly connected with fixed block (13) of stop collar (12), fixed block (13) and top shell (2) fixed connection, stop collar (12) are received line section of thick bamboo (3) through the bearing spacing receipts.

2. A marine cable stable installation according to claim 1 wherein the top shell (2) is symmetrically fitted with temperature and humidity sensors (14), wherein the environmental information at the node comprises the temperature and humidity within the induction installation unit sensed by the temperature and humidity sensors (14).

3. The ship cable stable installation device according to claim 1, wherein the monitoring server is signally connected with a temporary storage unit and an aging analysis unit;

the temporary storage unit acquires the environmental information at the node through the acquisition and analysis unit, temporarily stores the environmental information at the node, packages the environmental information at the node into a data packet when the environmental information at the node reaches a preset byte, and sends the data packet to the aging analysis unit;

after receiving the data packet, the aging analysis unit decompresses and analyzes the data packet:

when the data in the data packet is respectively smaller than the minimum value of the preset threshold value, subtracting the minimum value of the preset threshold value from the data in the data packet corresponding to the minimum value of the preset threshold value, multiplying the subtracted difference by a weight factor I corresponding to the subtracted difference, and adding the multiplied products to obtain a deviation result; when the data in the data packet is respectively larger than the maximum value of the preset threshold value, subtracting the maximum value of the preset threshold value corresponding to the data in the data packet from the data in the data packet, multiplying the subtracted difference with a weight factor II corresponding to the subtracted difference, and adding the multiplied products to obtain a deviation result; and the maximum value of the preset threshold value is smaller than the preset value;

when a deviation result or a deviation result is generated, multiplying the deviation result or the deviation result by corresponding conversion factors respectively, multiplying the multiplied result by a corresponding weight factor III to obtain an aging factor, and storing the aging factor;

and randomly acquiring an accumulated aging factor mean value of the single-path ship cable at the related node, generating a line replacement signal when the accumulated aging factor mean value reaches an aging critical point, and performing line processing operation after generating the line replacement signal.

4. A marine cable stable installation according to claim 3 wherein the course of the line handling operation is in particular;

after the line replacement signal is generated, node information corresponding to the line replacement signal is obtained and a node set is generated, the node set is sent to a supervision server after being generated, the supervision server receives the node set to refresh and highlight the corresponding node in the node set, after the highlighting, a maintainer replaces the aged ship cable, after the replacement is completed, after the ship cable is detected to transmit normal power, the highlighted node is recovered, and the total maintenance times of the maintainer are recorded once.

5. The stable installation device of the ship cable according to claim 1, wherein the supervision server is further in signal connection with a registration login module, the registration login module is used for enabling maintenance personnel to submit personnel information through a mobile phone terminal for registration, and sending the personnel information which is successfully registered to the supervision server for storage, meanwhile, the supervision server marks the maintenance personnel which is successfully registered as registration personnel, and meanwhile, marks the time when the personnel information is received as the registration time of the registration personnel; the personnel information comprises the name, the mobile phone number and the age of the maintenance personnel, and the virtual layout is directly sent to the mobile phone terminal of the maintenance personnel for display.