KR101279102B1 - Management method for the install information of shipboard cable - Google Patents

Abstract

PURPOSE: A cable installation administration method is provided to increase work efficiency by preparing cables in advance using pallet information. CONSTITUTION: Cable design information is confirmed which verifies the length of a cable(S10). A deck ranking is determined which decides the installation order of the cable(S20). The installation order of the cable is altered according to exceptional condition data. The installation order is determined which designates installation numbers(S40). Pallet information is generated along with the installation order(S50). [Reference numerals] (AA) Start; (BB) End; (S10) Step of confirming cable design information; (S20) Step of determining a deck ranking; (S30) Step of checking for exceptions; (S35) Step of applying exception conditions; (S40) Step of determining installation order; (S50) Step of generating pellet information

Description

Management method for the install information of shipboard cable}

The present invention relates to a method for managing cable installation information for ships that can generate pallet information including the wiring order of cables connected to the equipment in the block when the ship is built, and increase the cable installation efficiency in the field.

In general, the construction of large ships in shipyards is done by combining blocks. In other words, the ship is divided into a plurality of blocks and produced, and the blocks thus manufactured are combined according to design, thereby completing the ship.

On the other hand, a variety of equipments are individually mounted on the block which is separately manufactured. The equipment is an electronic device installed so that a ship can operate and operate normally, and may be various, such as a communication device, a ventilation device, and various power devices.

The equipment installed in this way must be powered for normal operation, or electrical connection must be made to communicate with each other. To do this, a wiring cable is installed to connect the equipment and power source (generator) or to connect the equipment to each other. Is required.

As mentioned above, shipbuilding is accomplished by combining multiple blocks. Therefore, the cable wiring for the equipment to be mounted on the block must be made in the form of via the neighboring blocks. As a result, most cables are routed over relatively long lengths and are installed on-site through the relevant blocks, depending on the design of the vessel.

Conventionally, as disclosed in Japanese Patent Laid-Open Publication No. 2003-0080670, an operator cuts and wires a cable directly to the length indicated in the design by an operator. However, this conventional method is inconvenient for the operator to obtain a cable from the drum, which is necessary for the operator in the field, and more importantly, it is essential that the operator check the wiring order of the cable in the blueprint in order to perform the optimized wiring work. There has been an unreasonable increase in the number of work processes unnecessarily.

In order to solve such a problem, a method of conventionally cutting a cable according to a design and providing it to a work site has been proposed, as disclosed in Korean Patent Publication No. 10-2010-0130496. However, if you simply cut the cable from the drum and transfer it to the shop floor according to the design, there is an additional work process that requires the operator to search only the cable of the required length among the numerous cables for the wiring work. There was a problem of cumbersome work. As a result, in the prior art, a process of searching for a cable is newly generated instead of omitting a cable cutting process in the field, and thus, fatigue of a field worker who feels for installing the cable has not changed or increased.

Accordingly, the present invention has been made to solve the above problems, the technical problem of the installation information management method for managing the cable installation information for ships to efficiently proceed in the field installation of the cable in the ship construction process as a technical problem. .

According to an aspect of the present invention,

A cable design information checking step of confirming, by the design analysis module, the ship design information and checking the type of cable to be wired to the ship and the length of the cable;

A deck ranking step of determining, by the ranking module, the deck position from the ship design information and determining the installation order of the cable based on the deck position according to the general condition data stored in the condition management module;

Changing, by the ranking module, an installation order of the cable determined in the deck ranking step according to the exception condition data input through the condition input module;

An installation order determining step of designating an installation number according to the installation order in which the ranking module is changed; And

A pallet information generating step in which the information generating module links the type and the length of the corresponding cable to the installation order in which the information generating module is changed and generates the pallet information as pallet information;

Ship cable installation information management method comprising a.

According to the present invention, the operator can prepare the cable in advance by preparing the pallet information, which is the cable information required for the construction according to the ship design, and through this, only the wiring and installation of the pre-prepared cable in a predetermined order through the site, There is an effect that the work efficiency for shipbuilding is significantly improved.

1 is a view schematically showing a state in which a cable is wired according to the management method according to the present invention,
2 is a block diagram showing a state of a management system for executing a management method according to the present invention;
3 is a flowchart sequentially illustrating a management method according to the present invention.

BRIEF DESCRIPTION OF THE DRAWINGS The above and other features and advantages of the present invention will become more apparent from the following detailed description of the present invention when taken in conjunction with the accompanying drawings, It will be possible. The present invention is capable of various modifications and various forms, and specific embodiments are illustrated in the drawings and described in detail in the text. It should be understood, however, that the invention is not intended to be limited to the particular forms disclosed, but includes all modifications, equivalents, and alternatives falling within the spirit and scope of the invention. The terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

1 is a view schematically illustrating a ship in which a cable is wired according to a management method according to the present invention, which will be described with reference to the drawing.

The present invention relates to a ship cable installation information management method for systematically preparing the pallet (Pallet) information for the cable wiring of the ship under construction, the operator can effectively install the cable in the field.

In more detail, at the ship construction site of the shipyard, the operator wires and installs the cables 31 to 35 on the vessel S in which the plurality of decks A to G are combined, and thus the decks A to G. The equipment 11 to 15 mounted to the power source 20 to be operated to operate. Here, the deck (A to G) is a unit for grouping the blocks constituting the ship (S), generally in the field 1 to 5 blocks according to the size of the ship (S) to build one deck (A to G) Group by). Thus, one block may be referred to as one deck, and a plurality of blocks may be referred to as one deck. Hereinafter, instead of the block name, it is referred to as a 'deck'.

Typically, decks A to G are combined in the order from the lower layer to the upper layer, and wiring to the main cables 31 to 35 can proceed simultaneously with the combination of decks A to G. On the other hand, in the case of the power source 20 is generally disposed on the deck (G) located in the lower floor with the engine. Therefore, in the case of the cables 31 to 35 to be connected to the power source 20, most of them are wired through the lower decks A to G in consideration of the deck installation order and the like except for the exceptional condition.

In the drawing showing an embodiment according to the present invention, the cables 31, 32, and 33, which are general wiring patterns, to which an exception condition is not applied, are shown via the lower decks A, B, and G. However, in the case of the cable 35 to which the exception condition is applied, it passes through the upper decks D, E, and F, which will be described in detail below.

As described above, in order to build the ship (S), it is necessary to basically combine a plurality of decks (A to G) and install the cables (31 to 35). Here, the management method according to the present invention allows the operator to quickly wire and install the cables (31 to 35) in a predetermined unit according to the pallet information in the field.

2 is a block diagram illustrating a management system for executing a management method according to the present invention, and FIG. 3 is a flowchart sequentially illustrating the management method according to the present invention.

As described above, the decks A to G are equipped with various equipments 11 to 15 according to the design of the ship S, and the cables 31 to 35 are wired to the equipments 11 to 15. The operator inputs the ship design information for the vessel (S) to the management system 40 in order to effectively provide the necessary amount of cables (31 to 35) to the site in the work order.

Here, the ship design information is deck information on the size and arrangement position of the decks (A to G) designed to build the ship (S), and the type of equipment (11 to 15) mounted on the decks (A to G) and Including cable information about the type and wiring location of the cable (31 to 35), the ship design information may be simply input to the management system 40 in the form of text, or in the form of a design-only program file such as CAD It may be entered into the management system 40.

On the other hand, the management system 40 is to generate the installation information of the cables (31 to 35), and receives the vessel design information to analyze the length of the cable (31 to 35) wired for each deck (A to G) A design analysis module 41 for calculating, a condition management module 42 for storing and managing general condition data for determining the installation order of the cables 31 to 35, and cables 31 to 35 according to the general condition data. A ranking module 43 for determining the installation rank of the controller, a condition input module 44 for inputting exception condition data to the ranking module 43 that does not conform to the installation rank of the general condition data, and cables 31 to 35. It consists of an information generation module 45 for generating the pallet information, including the installation order of. The management system 40 according to the present invention is a kind of program designed to manage the installation information of the cables 31 to 35 including the pallet information. As described above, when the vessel design information is input, Check the cables 31 to 35 to be wired, and determine the installation order of the cables 31 to 35 according to the general condition data and the exception condition data to finally generate the pallet information, through which the operator According to the information, cables 31 to 35 can be prepared and provided to the site.

More detailed descriptions of the management system 40 described above will be given while explaining the management method according to the present invention.

S10; Checking Cable Design Information

The operator generates pallet information in order to provide the cables 31 to 35 of a predetermined length and type according to the design to the site in an order in which efficient installation work can be performed, and for this, ship design information is transmitted to the management system 40. Enter it.

Here, the pallet information is information on the grouping of the cables 31 to 35, which are cut into a predetermined length and assembled in a designated unit. When the operator prepares the cables 31 to 35 in sequence according to the pallet information, (31 to 35) can be carried out immediately in accordance with the specified order without the need to separately check, through which unnecessary unnecessary work for cutting, checking, search, etc. in the field can be omitted.

Subsequently, the design analysis module 41 of the management system 40 checks the input vessel design information, and confirms the type and length of the wiring cables 31 to 35 for each deck A to G. For reference, since the size of the deck (A to G) and the wiring position of the cable is included in the ship design information, the design analysis module 41 of the cable (31 to 35) to be wired based on the ship design information The length can be calculated for each type and classified by the decks (A to G).

S20; Deck Ranking Steps

The ranking module 43 determines the installation order of the cables 31 to 35 based on the positions of the decks A to G.

In the general condition data stored in the condition management module 42, the conditions for the installation order of the cables 31 to 35 are recorded. For example, the most basic condition of the cable 31 to 35 arrangement order is that the cables 31 to 35 generally connect the power source 20 and the equipment 11 to 15, and thus the power source 20 is located. It may be exemplified to first install the corresponding cables 31 to 35 of the decks A to F located away from the deck G. In addition, since decks A to G are dried in the order from the lower layer to the upper layer, the cables 31, 32, and 33 of the decks A and B located in the lower layer are first installed according to the combination order of the decks A to G. Can be illustrated.

The ranking module 43 may determine the ranking of the decks A to G according to the general condition data of the condition management module 42 and determine the installation order of the corresponding cables 31 to 35 according to the determined ranking. .

When the installation order of the cables 31 to 35 is determined according to the general general condition data stored in the condition management module 42, in the embodiment according to the present invention, the lower deck and the farthest first deck A are located. The first cable 31 of the first outfit 11 is installed first, followed by the third cable 33 of the third outfit 13 in the third deck C, which is located in the middle and far away. The second cable 32 of the second article 12 in the second deck (B), which is lower and nearer, is installed in the third order, and then the fifth deck, which is upper and further away It may be determined that the fifth cable 35 of the fifth article 15 in (E) is installed in the fourth order. That is, when the standard of the general condition data is followed, the installation order of the first, second, third, and fifth cables 11, 12, 13, and 15 is determined according to the above-described order, and the worker in the field corresponds to the above order. If you install the cable, you will be able to install the cable in an optimized environment without interference or interference with parallel work.

S30; Exception Check Step

When an exception condition occurs in which the general condition data cannot be applied as it is due to the design of the construction vessel S, or an exception condition occurs in which the general condition data cannot be applied as it is due to the limitation of the work site, This is confirmed and the corresponding exception condition data is input through the condition input module 44.

The exception condition data is forcing the installation order of a specific cable to precede or subordinate the installation order of other specific cables, and the range for the input information may be a cable unit, a block unit, or a deck unit.

For reference, the exceptional condition data may be a method of forcibly inputting only the information of the target cable whose installation order is changed in the cable installation order previously determined by the ranking module 43, the cable that satisfies a specific criterion Instead of following general condition data, it may be a method of inputting information on the criterion to follow the condition of the exception condition data.

S35; Exception Condition Application Stage

The condition input module 44 inputs the exception condition data into the ranking module 43, and the ranking module 43 applies the exception condition data to the previously determined cable installation order so that the installation order of the target cable is adjusted. do.

For example, in more detail, when the exception condition data is not input, if the installation order of the cables 31 to 35 and 35 'is determined according to the general condition data presented above, the fourth cable before the change ( 34 '), the first cable 31, the third cable 33, the second cable 32 and the fifth cable 35 may be determined in order.

However, in the design of the vessel S, an exception condition occurs in which the sixth article 16 is mounted on the sixth deck F located on the upper floor and connected with the same cable as the fourth article 14. In this case, the operator inputs the exception condition data through the condition input module 44, and the ranking module 43 changes the installation order of the cable according to the input exception condition data.

As a result, the ranking module 43 determines the final installation order of the cables 31 to 35 and 35 'according to the exception condition data. The first cable 31, the third cable 33, the second cable 32, The fifth cable 35 and the fourth cable 34 are changed in this order.

S40; Determination of Installation Sequence

The ranking module 43 finally determines the installation order of the cables 31 to 35 on the basis of the general condition data and the exception condition data, and inputs the installation number according to the installation order. In this embodiment, the installation order is determined in units of cables, but the installation order of cables may be made in units of decks. At this time, when determining the installation order of the cable in the deck unit, the detailed installation order for the cable may be arbitrarily determined by the operator at the work site.

S50; Pallet information generation step

When the installation order of the cables 31 to 35 by the ranking module 43 is determined, the information about the length, type, etc. of the cables 31 to 35 identified in the design analysis module 41 is classified according to the installation order. The pallet information is completed by linking to the cable.

Pallet information may be divided by the cable (31 to 35), or may be divided by the deck (A to G), in addition may be divided according to the amount of work.

In more detail, when the pallet information is completed according to the management method according to the present invention, the operator purchases the cables 31 to 35 of the type described in the pallet information with a drum, and the length and order described in the pallet information. According to the drawing, the drum is taken out and cut. The cables 31 to 35 cut in this way are classified and grouped in the above order, and the corresponding cables specified in the installation order determination step S40 are labeled and labeled. Subsequently, the cables 31 to 35 divided in this manner are classified once again according to predetermined criteria according to the pallet information. The criterion may be a cable 31 to 35, a deck (A to G) or the amount of work.

The classification of the cables 31 to 35 is arranged so that the cables 31 to 35 are classified by the cables 31 to 35 as they are words so as to be identified in the field. As a result, the site operator may proceed with the installation work in units of cables 31 to 35 according to the set installation number.

The classification of the decks (A to G) is arranged so that the cables 31 to 35 are classified by the decks (A to G) as they are words so that they can be identified in the field. That is, by classifying the cables (31 to 35) by the deck (A to G) to allow the site operator to proceed with the installation work for each of the deck (A to G). As a result, when the deck (A to G) classification method is applied, one pallet information may include a plurality of cable (31 to 35) information.

As the amount of work is classified as words, the cables 31 to 35 are classified according to the amount of work and arranged so that an operator can identify them in the field. As a result, when applying the classification scheme for each workload, one pallet information may include information on a plurality of decks (A to G) for each cable (31 to 35).

While the present invention has been described in connection with what is presently considered to be practical exemplary embodiments, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims.

11 to 16; Equipment 20; Power sources 31 to 35; cable
40: management system 41; Design analysis module 42; Condition Management Module
43; Ranking module 44; Condition input module 45; Information generation module
A to G; Deck S; Ship

Claims (2)

A cable design information checking step of confirming, by the design analysis module, the ship design information and checking the type of cable to be wired to the ship and the length of the cable;
A deck ranking step of determining, by the ranking module, the deck position from the ship design information and determining the installation order of the cable based on the deck position according to the general condition data stored in the condition management module;
Changing, by the ranking module, an installation order of the cable determined in the deck ranking step according to the exception condition data input through the condition input module;
An installation order determining step of designating an installation number according to the installation order in which the ranking module is changed; And
A pallet information generating step in which the information generating module links the type and the length of the corresponding cable to the installation order in which the information generating module is changed and generates the pallet information as pallet information;
Ship cable installation information management method comprising a. The method of claim 1,
In the pallet information generating step, the pallet information is a cable installation information management method for ships, characterized in that the cable grouped by deck.

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