KR102261216B1 - Apparatus of checking electric power system - Google Patents

Abstract

An apparatus of checking an electric power system is disclosed that includes a plurality of switchboards installed in the cabin of a ship and having parts for forming the power system of the ship; and a management server that obtains measurement data for each power system from the plurality of switchboards and provides information for checking the plurality of switchboards to a mobile terminal executing a power system check application. It is possible to check the abnormal state by comparing measured wattage with design wattage.

Description

Power system inspection device {APPARATUS OF CHECKING ELECTRIC POWER SYSTEM}

The present invention relates to a power system inspection device, and more particularly, to a power system inspection device implemented to remotely inspect the power system for a moored vessel.

Various electrical installations are installed on the ship, and cables for controlling, communication and power supply of various installed electrical installations are routed. For cable routing, junction boxes arranged throughout the ship are used. As an example, KR 10-1215483 B1 exemplifies the structure of a cable wiring device for a ship.

On the other hand, the cables connecting various electrical equipment of the ship should be inspected during test operation or periodically. That is, it is possible to promote normal and efficient operation of various electrical installations connected by cables by checking the cable connection state to check whether the cable is connected to an error, disconnection, or short circuit.

Conventionally, when checking the cable connection status in a ship, a method in which two managers arrive at two junction boxes installed apart from each other and communicate with each other by radio, checking signals for each terminal one by one is used.

For example, if a manager in the first junction box shorts two terminals together and informs the radio about the two shorted terminals, another manager in front of the second junction box uses a tester to short-circuit the first junction box. The cable connection state is checked by measuring the current signal between the two terminals of the second junction box corresponding to the two terminals.

According to this conventional method, in the inspection process, two managers form a pair and each move to a location where the two junction boxes are installed, and must perform a signal check for each connection terminal one by one while continuing to communicate with the radio.

Therefore, there are problems in that manpower is wasted, inspection time is long, and it is difficult to accurately determine and quickly process a problem when a problem occurs.

One aspect of the present invention discloses a power system inspection device that remotely collects the measured power amount of a plurality of distribution boxes, and compares the measured power amount and the design power amount to check an abnormal state.

Another aspect of the present invention discloses a power system inspection device provided to process an alarm by transmitting an alarm when an abnormal state is detected according to a comparison of a measured power amount and a design power amount.

Another aspect of the present invention discloses a power system inspection device that provides an evaluation result for the application by analyzing the evaluation result text for the power system inspection application through a deep learning neural network.

Another aspect of the present invention discloses a power system inspection device including a ladder module used to check the distribution box in a ship provided with a plurality of distribution boxes.

The technical problems of the present invention are not limited to the technical problems mentioned above, and other technical problems not mentioned will be clearly understood by those skilled in the art from the following description.

A power system inspection device according to an embodiment of the present invention is installed in the cabin of a ship, a plurality of switchboards having parts for forming the power system of the ship; and a management server that obtains measurement data for the power system from the plurality of switchboards, respectively, and provides information for checking the plurality of switchboards to a mobile terminal executing a power system check application.

On the other hand, the plurality of switchboards, each of the sensing nodes for obtaining measurement data including a unique number and measured power amount; includes,

The power system inspection device may further include a router that is provided in the cabin and enables communication between a sensing node included in each of the plurality of switchboards and the management server;

The management server receives measurement data according to a predetermined period from the plurality of switchboards, requests and receives the unique number of the switchboard currently being inspected from the mobile terminal, and matches the received unique number to check the pre-stored design power amount and extracting the measurement data including the unique number input through the mobile terminal among the measurement data received from the plurality of switchboards, and comparing the measured power amount included in the extracted measurement data with the pre-stored design power amount, and the measured power amount and When the difference between the design energy is greater than or equal to the threshold, an additional inspection notification according to the measured electric energy is output through the pop-up screen of the electric power system inspection application executed in the mobile terminal, and when the difference between the measured electric energy and the design energy is less than the threshold, the movement Guides the next step of the power system check according to a predetermined step through the pop-up screen of the power system check application executed in the terminal,

The management server requests and receives the evaluation result text for the service from the mobile terminal, accumulates and stores the evaluation result text received from the mobile terminal, extracts the stored evaluation result text as learning data, and the Word2Vec algorithm constructs a neural network that extracts context information from input data by learning learning data with , stores a table in which a rating is given for each section of a vector value representing context information, in advance, and the evaluation result currently received from the mobile terminal in the neural network Input text to extract an evaluation result vector value, calculate a rating corresponding to the evaluation result vector value from the table, and guide the calculated rating through an application running on the mobile terminal,

The power system inspection device, the ladder module provided to receive a predetermined control signal from the management server through the router; further comprising,

The ladder module is provided in the form of a box having an inner space, the upper surface is a footrest provided with glass; a leg portion extending from a lower side of the footrest unit and supporting the footrest unit at a predetermined height from the ground; a step part installed in the leg part so that a user can step on it and climb up to the footrest part; a light emitting unit provided with an LED light built into the scaffold unit to transmit light to the outside through the upper surface of the scaffold unit; and a control unit attached to the bottom surface of the scaffold, communicating with the management server through the router, and illuminating the light emitting unit by applying power to the light emitting unit when receiving a lighting signal from the management server ,

The management server may further include generating and transmitting the lighting signal to the control unit when a difference between the measured power amount and the design power amount is greater than or equal to a threshold value.

On the other hand, the step part is provided in the form of a plate of a predetermined thickness, an expansion part that forms an opening in the front surface and protrudes and retracts through the opening according to a user's manipulation;

The extension part is provided embedded in the step portion, the rail portion provided in contact with a surface opposite to the surface on which the opening is formed in the step portion; a moving block provided in a pair, provided to move away from or closer to each other along the rail part by a user's manipulation, and installed in a state coupled to the center of the rail part; a connection part for connecting a pair of moving blocks to the rail unit, respectively, and connecting the pair of moving blocks to be spaced apart from each other by an elastic restoring force when the pair of moving blocks coupled to each other is released; A pair of rotation units provided to be rotatably installed on each of the pair of moving blocks; and a plurality of extension plates that are provided in a form overlapping and accommodated in the step portion, and are sequentially drawn out while sliding forward through the opening to expand the width of the step portion; includes,

Each of the pair of rotating parts, one end is installed on the pair of moving blocks, and the other end is installed on the front end of the extension plate disposed at the lowest end among the plurality of extension plates, in a state in which the pair of moving blocks are coupled to each other When the pair of moving blocks are arranged to be spaced apart and moved to be spaced apart from each other, the plurality of extension plates are drawn out from the step portion by pulling the extension plate disposed at the bottom of the plurality of extension plates while rotating to be arranged in a gathered state. and,

The ladder module further includes; an installation part provided to install the step part in the leg part,

The installation part is provided in the central part at both ends of the step part, the installation block is provided in a form that is formed to be narrower toward the lower part, the installation block being inserted into the receiving groove provided in the leg part; an installation bar built in and installed at both ends of the step portion, the installation bar passing through the installation block and installed so that the end protrudes from the installation block, and when a pressing force is applied to the end portion, sliding to the inside of the step portion; It is provided in an installation space formed in the installation block, the installation bar is inserted, and the installation block is inserted into the receiving groove and a force is applied by the leg portion abutting the end of the installation bar, so that the installation bar is the step portion When sliding inward, it is contracted in the installation space, when the force applied to the end of the installation bar is removed, an elastic part for allowing the end of the installation bar to protrude from the installation block by an elastic force; and a moving pin installed on the outer circumferential surface of the other end of the installation bar and formed through the step portion so that a user can slide the installation bar.

According to the present invention described above, by guiding the inspection step and the method to the mobile terminal possessed by the inspector, it is possible to easily process the inspection of the electric power system even if the inspector is not skilled, and in particular, if there is an abnormality in the measured electric power In case of an important matter, a separate alarm is generated so that appropriate actions are taken accordingly.

In addition, according to the present invention, the reliability of the service can be secured and the performance improvement effect is achieved by calculating and sharing the service evaluation result through the deep learning neural network.

In addition, according to the present invention, by notifying the abnormal state of the amount of power measured through the ladder module, which is essentially used due to the characteristics of a ship having a plurality of switchboards, an accurate check can be made.

1 is a conceptual diagram of a power system inspection device according to an embodiment of the present invention.
2 is a view showing an example of use of the power system inspection device according to an embodiment of the present invention.
3 is a flowchart of a power system inspection method in the management server shown in FIG. 1 .
4 is a view showing an example of use of the power system inspection device according to another embodiment of the present invention.
5 is a flowchart of a method for checking a power system in a management server according to another embodiment of the present invention.
Figure 6 is a view showing a ladder module according to an embodiment of the present invention.

Advantages and features of the present invention and methods of achieving them will become apparent with reference to the embodiments described below in detail in conjunction with the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below, but will be implemented in a variety of different forms, and only these embodiments allow the disclosure of the present invention to be complete, and common knowledge in the technical field to which the present invention belongs It is provided to fully inform the possessor of the scope of the invention, and the present invention is only defined by the scope of the claims. Like reference numerals refer to like elements throughout.

The terminology used herein is for the purpose of describing the embodiments and is not intended to limit the present invention. As used herein, the singular also includes the plural unless specifically stated otherwise in the phrase. As used herein, "comprises" and/or "comprising" refers to the stated elements, steps, and acts do not exclude the presence or addition of one or more other elements, steps and acts.

1 is a conceptual diagram of a power system inspection device according to an embodiment of the present invention.

Referring to FIG. 1 , a power system inspection device 1000 according to an embodiment of the present invention is a device for inspecting a power system of a moored vessel, and includes a switchboard 100 , a router 150 , a management server 200 and It may include a mobile terminal 300 .

The switchboard 100 may be installed in the cabin of a ship, and may form a connection point between a common electric distribution network and an electric circuit.

For example, the switchboard 100 may include various electrical components such as a knockout, a circuit breaker, various terminals, a grounding bus, a grounding wire, a grounding, various lines, a joint, and a power supply table.

In this embodiment, a plurality of switchgear 100 may be provided, and each of the sensing nodes may be provided to obtain measurement data for the power system. Here, the measurement data may be information in which a unique number of each switchboard 100 and an installed location coordinate value may be stored in advance, and a current value, a voltage value, an active power amount, a reactive power amount, and a power factor of the load side are stored in real time.

The switchboard 100 may transmit the measurement data acquired through the sensing node to the management server 200 through the router 150 .

The router 150 may be provided as a conventional router device that is connected to a mobile communication network and provides an Internet network to a plurality of devices.

The router 150 is installed on one side of the cabin in which the plurality of switchboards 100 are installed, and enables the Internet network connection of the sensing nodes of the plurality of switchboards 100 respectively.

The management server 200 may be an operation server of the power system inspection application according to an embodiment of the present invention. Here, the power system inspection application is a program implemented to easily process a series of steps for inspection and management of a plurality of switchboards 100 provided in a ship, for example, guides a predetermined inspection step, and each step can provide an interface for input of data required in the , in particular, receive the measurement data of each switchboard 100 from a plurality of switchboards 100, compare it with the pre-stored design data for each switchboard 100, and compare the results We can guide you through the next inspection step. This power system inspection application makes it easy to handle the inspection of the power system even if you are not an expert.

The mobile terminal 300 is a device capable of communication and input/output of information, for example, a smart phone.

The mobile terminal 300 may install and execute the power system inspection application according to an embodiment of the present invention. The mobile terminal 300 executes the power system inspection application to receive various data for power system inspection from the user and transmit it to the management server 200, or by receiving various data for power system inspection from the management server 200. can be printed out. Here, the user may be an inspector who inspects the switchboard 100 .

2 is a view showing an example of use of the power system inspection device according to an embodiment of the present invention.

Referring to FIG. 2 , a user may carry the mobile terminal 300 and perform an inspection on the switchboard 100 . In this case, the mobile terminal 300 may output a predetermined inspection step and method received from the management server 200 by executing the power system inspection application. For example, the inspection step may include opening a door of the switchboard 100 , a power circuit breaker (VCB) inspection, cleaning, operation inspection, operation test, vacuum level test, and the like.

The user may perform the inspection of the switchboard 100 according to a predetermined step through the mobile terminal 300 .

3 is a flowchart of a power system inspection method in the management server shown in FIG. 1 .

Referring to FIG. 3 , the management server 200 may collect measurement data including the amount of power ( S10 ). The management server 200 may receive each measurement data from the plurality of switchboards 100 according to a predetermined cycle.

The management server 200 may compare the measured power included in the measured data with the design power of the corresponding switchboard 100 (S20). The management server 200 may request and receive a unique number of the switchboard 100 currently being inspected by the mobile terminal 300 , and may check the pre-stored design power amount by matching the unique number of the switchboard 100 . The management server 200 extracts measurement data including a unique number input through the mobile terminal 300 from among the measurement data received at a predetermined period from the plurality of switchboards 100, and the amount of measured power included in the measurement data and the You can compare the stored design power.

When the difference between the measured power amount and the design power amount is equal to or greater than the threshold (S30), the management server 200 may notify the mobile terminal 300 of an additional inspection request (S40). In this case, the mobile terminal 300 may output an additional inspection notification according to the measured electric energy or more through the pop-up screen of the electric power system inspection application. Accordingly, the user may recognize that there is an abnormality in the amount of power measured in the power system of the switchboard 100 and perform additional inspection.

When the difference between the measured power amount and the design power amount is less than the threshold value (S30), the management server 200 may continue to guide the next check step to the mobile terminal 300 (S50).

As described above, the power system inspection apparatus 1000 according to an embodiment of the present invention guides the inspection step and the method to the mobile terminal 300 possessed by the inspector, so that even an unskilled person can easily process the inspection of the power system. In particular, in the case of an important matter with an abnormality in the amount of power measured in the power system, a separate alarm is generated so that appropriate measures are taken accordingly.

4 is a view showing an example of use of the power system inspection device according to another embodiment of the present invention.

4, in addition to the configuration of the switchboard 100, the router 150, the management server 200 and the mobile terminal 300 shown in FIG. 1, the power system inspection apparatus according to another embodiment of the present invention includes, It may further include the configuration of the ladder module (500).

Ladder module 500 may be provided so that the user can step on and perform a predetermined operation. This ladder module 500 is arranged in the vertical direction to enable the inspection work of the installed switchboard 100.

The ladder module 500 may have a built-in communication module to connect to the router 150 , and may receive a predetermined control signal from the management server 200 through the router 150 . In this regard, it will be described below with reference to FIG. 5 .

5 is a flowchart of a method for checking a power system in a management server according to another embodiment of the present invention.

Referring to FIG. 5 , the management server 200 may collect measurement data including the amount of power ( S11 ). The management server 200 may receive each measurement data from the plurality of switchboards 100 according to a predetermined cycle.

The management server 200 may compare the measured power included in the measured data with the design power of the corresponding switchboard 100 ( S21 ). The management server 200 may request and receive a unique number of the switchboard 100 currently being inspected by the mobile terminal 300 , and may check the pre-stored design power amount by matching the unique number of the switchboard 100 . The management server 200 extracts measurement data including a unique number input through the mobile terminal 300 from among the measurement data received at a predetermined period from the plurality of switchboards 100, and the amount of measured power included in the measurement data and the You can compare the stored design power.

When the difference between the measured power amount and the design power amount is equal to or greater than a threshold (S31), the management server 200 may notify the mobile terminal 300 of an additional inspection request (S41). In this case, the mobile terminal 300 may output an additional inspection notification according to the measured electric energy or more through the pop-up screen of the electric power system inspection application. Accordingly, the user may recognize that there is an abnormality in the amount of power measured in the power system of the switchboard 100 and perform additional inspection.

In addition, the management server 200 may transmit a lighting signal to the ladder module 500 when the difference between the measured power and the design power is greater than or equal to the threshold (S31) (S42). The ladder module 500 may include a light emitting unit that lights when receiving a lighting signal, and emits light when the difference between the measured power and the design power is greater than or equal to a threshold so that the user can recognize that there is an abnormality in the measured power of the power system. do.

When the difference between the measured power amount and the design power amount is less than the threshold value (S31), the management server 200 may continue to guide the next check step to the mobile terminal 300 (S51).

Such a power system inspection device according to another embodiment of the present invention may additionally inform the abnormal state of the measured power amount of the power system through the ladder module 500 provided so that the user can step on it. In other words, the power system inspection device according to another embodiment of the present invention is an accurate inspection by notifying the abnormal state of the amount of power measured through the ladder module 500 that is essentially used due to the characteristics of a ship in which a plurality of switchboards 100 are provided. make it happen

Figure 6 is a view showing a ladder module according to an embodiment of the present invention.

Referring to FIG. 6 , the ladder module 500 according to an embodiment of the present invention includes a scaffold 510 , a leg 520 , a step 525 , a control unit 530 and a light emitting unit 550 . can do.

The footrest unit 510 may be provided in the form of a plate, and may be manufactured to have a sufficient width so that a user can step on it.

The leg unit 520 may extend from the lower side of the footrest unit 510 , and may support the footrest unit 510 at a predetermined height from the ground.

The step portion 525 may be provided in the form of a plate, and may be installed on the leg portion 520 so that the user can stand up to the footrest portion 510 in a bright manner.

The control unit 530 may be attached to the bottom surface of the footrest unit 510 and may be equipped with a microchip, a communication module, a power module, etc. in which a predetermined control algorithm is implemented. The control unit 530 may communicate with the management server 200 through the router 150 , and may receive a lighting signal from the management server 200 . When receiving the lighting signal, the controller 530 controls the light emitting unit 550 to be turned on. For example, when receiving the lighting signal, the control unit 530 causes power to be applied to the light emitting unit 550 so that the light emitting unit 550 is turned on.

The light emitting unit 550 may be provided with an LED light embedded in the footrest unit 510 . The light emitting unit 550 may be lit under the control of the controller 530 .

For example, the footrest unit 510 may be provided in the form of a box having an inner space, and the upper surface may be formed of glass. The light emitting unit 550 is provided in the inner space of the scaffold 510 , and may transmit light to the outside through the upper surface of the scaffold 510 made of glass.

Meanwhile, the step part 525 may include an extension part 560 provided to expand an area according to a user's manipulation. The step portion 525 is provided in the form of a plate having a predetermined thickness, and may include an extension portion 560 that forms an opening on the front surface and protrudes and retracts through the opening according to a user's manipulation.

The extension part 560 may include a rail part 561 , a connection part 562 , a moving block 563 , a rotation part 564 , and a plurality of extension plates 565 and 566 .

The rail portion 561 is provided to be built-in to the step portion 525 , and may be provided in contact with a surface opposite to the surface on which the opening is formed in the step portion 525 .

A pair of moving blocks 563 may be provided, and may be provided to move away from or close to each other along the rail unit 561 by a user's manipulation. To this end, a long hole may be formed on the upper surface of the step portion 525 to correspond to the built-in rail portion 561, and at least a portion of the pair of moving blocks 563 is disposed through the long hole, so that the user It is provided so that it can be moved along the rail part 561 by manipulating it.

The connection part 562 may connect the moving block 563 to the rail part 561 . That is, the pair of moving blocks 563 are installed in the central portion of the rail unit 561 , and may be disposed in a state where one side is coupled to each other. For example, the pair of moving blocks 563 may form a groove and a protrusion on one side, respectively, and may be coupled to each other by coupling the groove and the protrusion. In this case, the other side of each moving block 563 may be connected to both ends of the rail unit 561 through the connection unit 562 . The connection part 562 may be provided as an elastic spring. Accordingly, when the user releases the coupling of the rail parts 561 coupled to each other, they will be automatically separated from each other by the elastic restoring force of the connection part 562 .

A pair of rotation units 564 may be provided, and may be respectively installed to be rotatable on a pair of moving blocks 563 .

The plurality of extension plates 565 and 566 may be provided in a form to be accommodated while being overlapped with the step portion 525 . For example, the second extension plate 566 may be accommodated in the step portion 525 in a state where the second extension plate 566 is disposed below the first extension plate 565 .

The plurality of extension plates 565 and 566 may be accommodated in the step portion 525 to be drawn out through an opening provided in the step portion 525 . For example, the first extension plate 565 and the second extension plate 566 may be withdrawn while sliding toward the opening, and the second extension plate 566 may be drawn out forward while sliding with respect to the first extension plate 565 . , it is possible to expand the entire area of the step portion (525). In such a stretchable structure, it may include a normal departure preventing means provided with a locking protrusion, a guide groove, and the like to prevent separation in the direction of movement and the front.

The extension plate 566 disposed at the lowermost end among the plurality of extension plates 565 and 566 may be installed so that the other end of the rotation unit 564 is rotatable at its tip. That is, both ends of the rotating part 564 may be installed at the front ends of the moving block 563 and the expansion plate 566 , respectively. Accordingly, when viewed as a whole, the pair of rotating parts 564 may be arranged in an open state, and when the pair of moving blocks 563 are moved to be spaced apart from each other by a user's operation, the pair of rotating units It can be drawn out from the step portion 525 by pulling the extension plate 566 while rotating so that the 564 is collected.

On the other hand, the ladder module 500 may form a step portion 525 in a detachable structure with respect to the leg portion 520, and may further include an installation portion 540 for this purpose.

The installation part 540 is provided at both ends of the step part 525 so that both ends of the step part 525 can be easily installed between the leg parts 520 .

The installation unit 540 may include an installation block 541 , an installation bar 542 , an elastic unit 543 , and a moving pin 544 .

The installation block 541 may be provided in a central portion at both ends of the step portion 525 . The installation block 541 may be provided in a form in which the width becomes narrower toward the bottom.

The installation bar 542 may be installed to be installed at both ends of the step portion 525 , pass through the installation block 541 , and the end 542a may be installed to protrude from the installation block 541 . At this time, when a pressing force is applied to the end of the installation bar 542, the step portion 525 may form a moving space inside so that the installation bar 542 can slide to the inside of the step portion 525. .

The elastic part 543 may be provided as an elastic spring, and an installation bar 542 may be inserted thereinto. The elastic part 543 is provided in the installation space 541a formed in the installation block 541, and a force is applied to the end of the installation bar 542 so that the installation bar 542 slides inside the step portion 525. In this case, it is contracted in the installation space 541a, and when the force applied to the end of the installation bar 542 is removed, the end of the installation bar 542 protrudes from the installation block 541 by the elastic force.

The moving pin 544 may be installed on the outer peripheral surface of the other end of the installation bar 542 . The moving pin 544 may be formed through the front surface of the step portion 525 and allows the user to artificially move the installation bar 542 .

Meanwhile, the leg part 520 may form a receiving groove 521 for insertion of the installation block 541 and may form a receiving hole for inserting the installation bar 542 .

Briefly describing the installation of the step portion 525 through the installation portion 540 , when the installation block 541 is inserted into the accommodation groove 521 to be accommodated, the installation bar 542 is the leg portion 520 . When the pressing force is applied and sliding inward, and the installation block 541 is completely inserted into the receiving groove 521 , the installation bar 542 slides outward by the elastic force of the elastic part 543 to the receiving hole By being inserted into the step portion 525 can be installed and fixed to the leg portion (520). In addition, when removing the step part 525 , the step part is operated in such a way that the installation bar 542 is slid to the inside by operating the moving pin 544 , and then the installation block 541 is lifted from the receiving groove 521 . (525) can be removed.

At this time, the installation block 541 and the receiving groove 521 are fastened to the upper part of a large area, and the lower part is formed to be narrow, so that they are fixed without shaking.

Meanwhile, the power system inspection application according to an embodiment of the present invention may request and receive an evaluation of a service. The management server 200 may request and receive the evaluation result text for the service from the mobile terminal 300 , and may calculate the rating of the service by analyzing the evaluation result text.

For example, the management server 200 may construct a neural network for extracting context information from input data. Here, the input data may be evaluation result text.

The management server 200 may accumulate and store the evaluation result text received from the mobile terminal 300 , and may extract the stored evaluation result text as learning data.

The management server may build a neural network for extracting context information from input data by learning the learning data with the Word2Vec algorithm.

The Word2Vec algorithm may include a Neural Network Language Model (NNLM). The neural network language model is basically a Neural Network consisting of an Input Layer, a Projection Layer, a Hidden Layer, and an Output Layer. The neural network language model is what is used to vectorize words. Since the neural network language model is a known technology, a detailed description thereof will be omitted.

The Word2vec algorithm, for text mining, is an algorithm that determines the proximity by looking at the front and back relationships between each word. The Word2vec algorithm is an unsupervised learning algorithm. The Word2vec algorithm may be a metric that expresses the meaning of a word in a vector form, as the name indicates. The Word2vec algorithm can represent each word as a vector in a space of about 200 dimensions. Using the Word2vec algorithm, a vector corresponding to a word can be obtained for each word. The Word2vec algorithm may enable a dramatic improvement in precision in the field of natural language processing compared to other conventional algorithms. Word2vec can learn the meaning of a word by using the relationship between a word in the sentence of the input corpus and an adjacent word. The Word2vec algorithm is based on an artificial neural network, and it starts from the premise that words with the same context have close meanings. The Word2vec algorithm learns through a text document, and trains the artificial neural network to learn other words that appear nearby (about 5 to 10 words before and after) for one word as related words. Since words with related meanings are more likely to appear close to each other in the document, the two words can have vectors that are closer to each other in the process of repeating learning.

The learning method of the Word2vec algorithm includes a continuous bag of words (CBOW) method and a skip-gram method. The CBOW method predicts the target word using the context created by the surrounding words. The skip-gram method predicts words that can come around based on one word. The skip-gram method is known to be more accurate in large datasets.

Therefore, in the embodiment of the present invention, the Word2vec algorithm using the skip-gram method is used. For example, if learning is successfully completed through the Word2vec algorithm, similar words in a high-dimensional space may be located nearby. According to the Word2vec algorithm as described above, the closer the word distribution of the surrounding words in the learning document is, the more similar the calculated vector values may be, and the similarly the calculated vector values may be regarded as similar. Since the Word2vec algorithm is a well-known technique, a more detailed description related to vector value calculation will be omitted.

The management server 200 may store in advance a table in which a rating is given for each section of a vector value representing context information, and may extract an evaluation result vector value by inputting the evaluation result text received from the mobile terminal 300 into the neural network. .

The management server 200 calculates a rating corresponding to the evaluation result vector value from a table in which a rating is given for each section of a vector value representing context information, and guides the calculated rating through an application running in the mobile terminal 300 . have.

Although embodiments of the present invention have been described above with reference to the accompanying drawings, those of ordinary skill in the art to which the present invention pertains can realize that the present invention can be implemented in other specific forms without changing the technical spirit or essential features. you will be able to understand Therefore, it should be understood that the embodiments described above are illustrative in all respects and not restrictive.

1000: power system inspection device
100: switchboard
200: router
300: management server
400: mobile terminal

Claims (2)

In the power system inspection device,
a plurality of switchboards installed in the cabin of the ship and having parts for forming the power system of the ship; and
A management server that obtains measurement data for the power system from the plurality of switchboards, respectively, and provides information for checking the plurality of switchboards to a mobile terminal executing a power system check application;
The plurality of switchboards,
A sensing node for obtaining measurement data including a unique number and measured power amount, respectively; includes,
The power system inspection device,
A router provided in the cabin and configured to enable communication between a sensing node included in each of the plurality of switchboards and the management server;
The management server,
Receives measurement data from the plurality of switchboards according to a predetermined cycle, requests and receives the unique number of the switchboard currently being inspected by the mobile terminal, matches the received unique number, and confirms the pre-stored design power amount, Among the measurement data received from the switchboard, the measurement data including the unique number input through the mobile terminal is extracted, the measured power included in the extracted measurement data and the pre-stored design power amount are compared, and the difference between the measured power amount and the design power amount is When the threshold is greater than the threshold, an additional inspection notification according to the measured electric energy or more is output through the pop-up screen of the electric power system inspection application executed in the mobile terminal. Through the pop-up screen of the system inspection application, guide the next stage of the power system inspection according to a predetermined step,
The management server,
Request and receive the evaluation result text for the service from the mobile terminal, accumulate and store the evaluation result text received from the mobile terminal, extract the stored evaluation result text as learning data, and learn the learning data with the Word2Vec algorithm to construct a neural network that extracts context information from the input data, store in advance a table in which a rating is given for each section of a vector value representing context information, and input and evaluate the evaluation result text currently received from the mobile terminal in the neural network extracting a result vector value, calculating a rating corresponding to the evaluation result vector value from the table, and guiding the calculated rating through an application running in the mobile terminal,
The power system inspection device,
A ladder module provided to receive a predetermined control signal from the management server through the router; further comprising,
The ladder module is
Doedoe provided in the form of a box having an inner space, the upper surface is a footrest provided with glass;
a leg portion extending from a lower side of the footrest unit and supporting the footrest unit at a predetermined height from the ground;
a step part installed in the leg part so that the user can step on it and climb up to the footrest part;
a light emitting unit provided with an LED light built into the scaffold unit to transmit light to the outside through the upper surface of the scaffold unit; and
a control unit attached to the bottom surface of the scaffold, communicating with the management server through the router, and illuminating the light emitting unit by applying power to the light emitting unit when receiving a lighting signal from the management server; and
The management server,
When the difference between the measured power amount and the design power amount is equal to or greater than a threshold value, the power system inspection device further comprising generating the lighting signal and transmitting it to the control unit.
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