KR20200064352A - Electric power system for switchboard fail - Google Patents

Abstract

The present invention relates to an electric power system for preparing against a switchboard disorder, which comprises: a power generation means which includes a plurality of power generators; a first switchboard (20) which is connected to the plurality of power generators arranged on one side area of the power generation means, and includes a D/G panel (21) and a shared panel (25) for each power generator; a second switchboard (30) which is connected to a plurality of power generators arranged on the other side area of the power generation means, and includes a D/G panel (31) and a shared panel (35) for each power generator; and a control means (40) which controls the connection state of the first switchboard (20) and the second switchboard (30). Accordingly, the power generators and the electric power system can be simplified within a range of satisfying the regulations (the IGC code) in a ship such as the LNGC, the minimal power generation capacity can be secured even if a specific switchboard is out of order, and an efficient power generator capacity can be calculated, thereby increasing price competitiveness.

Description

{Electric power system for switchboard fail}

The present invention relates to a power system of a ship, and more specifically, to a power system in preparation for a switchboard failure maintaining stability in response to the simplification of a power supply system associated with multiple generators in LNGC and the like.

In recent years, as a part of strengthening the competitiveness of ships, there is a tendency to continuously reduce generators and power systems. However, there is a limit to the reduction in size, and the number of generators is reduced, but the capacity of the generator is increased, which is inefficient for ship owners who use the generator. In some ships, efficient load capacity calculation may not be possible as the load of compressors handling cargo is increased.

As a prior art document that can be referred to in this regard, Korean Registered Patent Publication No. 1103859 sets the power generation system of a large container ship to a 440V system instead of a 6600V system. It is expected to not only greatly reduce the equipment installed on the ship, but also contribute to the stability of the electric system on board.

However, this is because it is essential to exclude the reduced voltage transformer by lowering the generated voltage, so it is insufficient to cope with the simplification of the power supply system associated with the generator.

As another prior art document, Korean Patent Publication No. 2016-0036134 constructs an internal circuit breaker on a switchboard that supplies power to a plurality of uses from a plurality of generators, and performs mutually independent power supply to a plurality of uses. By doing so, even if a specific generator connected to one switchboard cannot be operated, it is expected to provide a smooth power supply to the maximum use except for the minimum use.

However, this is because it responds to some inoperability among a large number of generators, and thus has a limitation in responding to a failure of a switchboard in a specific ship.

Korean Registered Patent Publication No. 1103859 "Bow Thruster Single Generator Connected Distribution System for Large Container Ships" (published date: 2007.09.06.) Korea Patent Publication No. 2016-0036134, "Drilling Power Distribution Device" (published date: 2016.04.04.)

An object of the present invention for improving the conventional problems as described above is to share some of the plurality of generators connected to each switch board so that power can be used even if any one switch board fails, and the generator capacity is reduced and It is to provide a power system for a switchboard failure that can cope with the simplification of a power generation system.

In order to achieve the above object, the present invention provides a power system for a switchboard failure: a power generation means having a plurality of generators; A first switchboard connected to a plurality of generators arranged in one region of the power generation means, and having a D/G panel for each generator and a shared panel; A second switchboard connected to a plurality of generators arranged on the other side of the power generating means, and having a D/G panel for each generator and a sharing panel; And control means for controlling a connection state between the first switch board and the second switch board.

As a detailed configuration of the present invention, the first switchboard is connected to two generators via a synchro panel, and the second switchboard is connected to two generators via a synchropanel.

As a detailed configuration of the present invention, the first switchboard is characterized in that it is connected to one generator connected to the second switchboard via a shared panel and a sub-line.

As a detailed configuration of the present invention, the second switchboard is characterized by being connected to one generator connected to the second switchboard via a shared panel and a sub-line.

As a detailed configuration of the present invention, the control means is characterized in that it comprises a detector for detecting a failure of the switchboard, a circuit breaker installed on the sub line, and a controller that outputs to the circuit breaker in response to the signal of the detector.

According to the present invention as described above, it is possible to simplify the generator and power system in a range that satisfies the regulations (IGC code) in ships such as LNGC, and it is possible to secure a minimum power generation capacity even if a specific switchboard fails, and an efficient generator. It has the effect of increasing price competitiveness by calculating capacity.

1 is a circuit diagram showing a main part of a power system according to the present invention
2 is a circuit diagram showing the control means of the power system according to the present invention

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

The present invention proposes a power system against a switchboard failure mounted on a ship. In particular, as the compressor capacity in LNGC increases, the generator also naturally increases, and the application of the IG code rule improves the difficulty of continuously constructing an efficient generator.

In general, a power generation means of a ship including LNGC includes a plurality of diesel engine driven generators (D/G). In Fig. 1, the generator groups illustrated by reference numerals 11, 12, 13, and 14 constitute power generation means.

The first switchboard 20 according to the present invention is connected to a plurality of generators arranged in one region of the power generation means, and includes a D/G panel 21 and a sharing panel 25 for each generator. The first switchboard 20 is configured by connecting a number of panels to the main line 15, which is a busbar-type busbar. The D/G panel 21 is connected to receive power from each generator allocated to the first switch board 20. The sharing panel 25 is connected to receive power from an external generator that is not assigned to the first switchboard 20 as described later.

The second switch board 30 according to the present invention is connected to a plurality of generators disposed in the other side region of the power generation means, and includes a D/G panel 31 and a sharing panel 35 for each generator. Since the second switch board 30 is also configured to maintain the same as the first switch board 20, the configuration of the main line 15, the D/G panel 31, and the shared panel 35 also maintains the same.

At this time, each of the synchro panels 22 and 32 provided on the switchboards 20 and 30 on both sides induces synchronization in a situation in which a plurality of generators are simultaneously driven. The first switch board 20 and the second switch board 30 are connected by using separate lines and circuit breakers in each bus tie panel 23 and 33.

On the other hand, the bus tie panels 23 and 33 may control circuit interruptions for distributing supply power according to the sailing operation mode, ballast water treatment mode, and the like.

As a detailed configuration of the present invention, the first switch board 20 is connected to two generators via a synchro panel 22, and the second switch board 30 is provided with two synchro panel 32 generators. It is characterized by being interposed. In FIG. 1, while considering the four power generators in consideration of the optimized power system of LNGC, the generators of symbols 11 and 12 are connected to the first switchboard 20 and the generators of 13 and 14 are connected to the second switchboard 30. Illustrative, but not limited to. In this way, the power system using a total of four generators can also increase the reliability of the synchronization operation using the synchro panels 22 and 32 in the process of responding to fluctuations in load.

As a detailed configuration of the present invention, the first switchboard 20 is characterized in that it is connected to one generator connected to the second switchboard 30 via a shared panel 25 and a sub-line 41. Referring to FIG. 1, the first sub-line 41 is illustrated as connecting the generator of reference numeral 13 connected to the shared panel 25 and the second switch board 30 of the first switch board 20. Of course, it may be connected to the generator of reference numeral 14 instead of the reference numeral 13 in consideration of the location of the generator, the old state of the generator (engine). The sharing panel 25 may be provided with a circuit breaker (not shown) for passively controlling the circuit connection.

As a detailed configuration of the present invention, the second switchboard 30 is characterized in that it is connected to one generator connected to the second switchboard 20 via a shared panel 35 and a sub-line 42. Referring to FIG. 1, the second sub-line 42 is illustrated as connecting the generator of reference numeral 12 connected to the shared panel 35 and the first switch board 20 of the second switch board 30. The sharing panel 35 may be provided with a circuit breaker (not shown) for passively controlling the circuit connection.

According to the present invention, the control means 40 is a structure for controlling the connection state of the first switch board 20 and the second switch board 30. The control means 40 is a means to control the algorithm for setting the power supply through the sub lines 41 and 42.

As a detailed configuration of the present invention, the control means 40 is a detector 44 for detecting a failure of the switch board 20, 30, a breaker 45 installed on the sub-line 41, 42, detector It characterized in that it comprises a controller 48 for output to the circuit breaker 45 in response to the signal of (44). The detectors 44 are independently installed on the switchboards 20 and 30 and detect signals related to failures such as disconnection and heat generation of the main line 15. Circuit breakers 45 are installed on each sub-line 41 and 42, and the circuit is interrupted by an external electrical signal. When the controller 48 reads the signal of the breaker 45 and determines that the switchboard has failed, the controller 48 induces activation of the sublines 41 and 42.

In any of the regulations related to LNGC (IGC code), there is a requirement that the boiler off gas must be treated (discharged) even if a switchboard fails, but if it is reduced more than the current generator capacity, The rules cannot be met.

That is, in the conventional case, when the switchboards 20 and 30 on one side fail, two generators cannot be used.

On the other hand, in the case of the present invention, when it is determined that the first switchboard 20 is defective, the second sub-line 42 is activated to connect the generator of reference 12 to the second switchboard 30 side, and on the contrary, the second switchboard ( If 30) is determined to be a failure, the first sub-line 41 is activated to connect the generator of reference 13 to the second switch board 20 side.

It is apparent to those skilled in the art that the present invention is not limited to the described embodiments, and can be variously modified and modified without departing from the spirit and scope of the present invention. Therefore, such modifications or modifications will have to belong to the claims of the present invention.

11, 12, 13, 14: Generator 15: Main Line
17: breaker 20: first switchboard
21: D/G panel 22: Synchro panel
23: Bus tie panel 25: Shared panel
30: 2nd switch board 31: D/G panel
32: synchro panel 33: bus tie panel
35: shared panel 41, 42: sub-line
44: detector 45: breaker
48: controller

Claims (5)

For power systems against switchboard failure:
A power generation means having a plurality of generators;
A first switchboard 20 connected to a plurality of generators arranged in one region of the power generation means, and having a D/G panel 21 and a sharing panel 25 for each generator;
A second switchboard 30 connected to a plurality of generators arranged on the other side of the power generating means, and having a D/G panel 31 and a sharing panel 35 for each generator; And
And a control means (40) for controlling a connection state between the first switchboard (20) and the second switchboard (30). The method according to claim 1,
The first switch board 20 is connected to two generators via a synchro panel 22, and the second switch board 30 is connected to two generators via a synchro panel 32. Power system in case of switchboard failure. The method according to claim 1,
The first switchboard 20 is a power system for a switchboard failure characterized in that it is connected to one generator connected to the second switchboard 30 via a shared panel 25 and a sub-line 41. . The method according to claim 1,
The second switchboard 30 is a power system for a switchboard failure characterized in that it is connected to one generator connected to the second switchboard 20 via a shared panel 35 and a subline 42. . The method according to claim 1,
The control means 40 corresponds to the signals of the detector 44 detecting the failure of the switch board 20, 30, the circuit breaker 45 installed on the sub lines 41, 42, and the detector 44. The power system for a switchboard failure, characterized in that it comprises a controller 48 for outputting to the breaker (45).

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