KR102629112B1 - Ship and apparatus for testing electrical grid of the same - Google Patents

Abstract

Provided is a device for testing a ship and its power grid. The ship includes a hull, a power grid provided on the hull, an energy storage unit connected to the power grid to store or supply power, a power management unit that monitors and controls the operating status of the load and generator within the ship connected to the power grid, and It includes an energy management unit that controls charging or discharging of the energy storage unit according to the operation of the load within the ship, and a test device that tests control of the energy storage unit by the energy management unit using a virtual power grid corresponding to the power grid.

Description

Ship and apparatus for testing electrical grid of the same}

The present invention relates to a device for testing a ship and its power grid.

A device that stores unconsumed surplus power among the power produced by a generator and compensates for power shortage due to the load is called an energy storage system (ESS). In order to store surplus power and supplement power shortage, the energy storage system may be equipped with energy transmission/reception means and energy storage means.

Depending on the load usage status, the power energy storage system can store or release power.

Republic of Korea Patent Publication No. 10-2017-0065268 (2017.06.13)

The problem to be solved by the present invention is to provide a ship equipped with a battery.

Additionally, the problem to be solved by the present invention is to provide a device for testing a power grid installed on a ship.

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

In order to achieve the above task, one aspect of the ship of the present invention includes a hull, a power grid provided on the hull, an energy storage unit connected to the power grid to store or supply power, and an inside of the ship connected to the power grid. A power management unit that monitors and controls the operating status of the load and generator, an energy management unit that controls charging or discharging of the energy storage unit according to the operation of the load within the ship, and a virtual power grid corresponding to the power grid to the energy management unit. and a test device for testing control of the energy storage unit.

A plurality of energy storage units are provided, and the test device tests the energy management unit by applying the operation results of the energy storage unit to be tested among the plurality of energy storage units to the virtual power grid.

The operation result of the energy storage unit to be tested includes a discharge current value or a charging current value of the energy storage unit to be tested.

The test device ensures that the control command of the energy management unit is transmitted to the energy storage unit that is the test target among the plurality of energy storage units, and the control command of the energy management unit is not transmitted to the remaining energy storage units.

The test device includes an information selection switch that switches an information transmission path so that power information of the power grid or power information of the virtual power grid is selectively transmitted to the energy management unit.

One aspect of the test device of the present invention is an energy management unit that receives a virtual power grid created corresponding to the ship's power grid and the operation results of the energy storage unit included in the power grid, and manages the energy storage unit. An interface unit that transmits power information of the virtual power network, a power grid analysis unit that calculates power information of the virtual power grid to which the operation results of the energy storage unit are applied, and the energy storage by the energy management unit with reference to the calculated power information. It includes a control unit that tests negative control.

Specific details of other embodiments are included in the detailed description and drawings.

1 is a diagram showing a ship according to an embodiment of the present invention.
FIG. 2 is a diagram showing the detailed configuration of the test device shown in FIG. 1.
FIG. 3 is a diagram showing the test device shown in FIG. 2 connected to an energy management unit.
Figures 4 to 6 are diagrams showing the operation of the test device shown in Figure 3.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the attached drawings. The advantages and features of the present invention and methods for achieving them will become clear by referring to the embodiments described in detail below along with the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below and may be implemented in various different forms, and the present embodiments are merely provided to ensure that the disclosure of the present invention is complete and to be understood by those skilled in the art in the technical field to which the present invention pertains. It is provided to fully inform those who have 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 specification.

1 is a diagram showing a ship according to an embodiment of the present invention.

Referring to FIG. 1, the ship 10 includes a hull 20, a power grid 100, generators 210, 220, onboard loads 310, 320, energy storage units 410, 420, and a power management unit 500. , and includes an energy management unit 600 and a test device 800.

The power grid 100 is provided on the hull 20 and may include a first bus 110 and a second bus 120. The power grid 100 is connected to various power facilities installed on board and can exchange power between power facilities. The first busbar 110 and the second busbar 120 may be connected to various power facilities.

The first bus 110 and the second bus 120 may be provided for redundant operation of the ship 10. For example, in normal times, only the power equipment of the first bus bar 110 operates, and when the operation of the power equipment of the first bus bar 110 is stopped, the power equipment of the second bus bar 120 may start operating. It is possible. Alternatively, according to some embodiments of the present invention, the power equipment of the first bus bar 110 and the second bus bar 120 may operate simultaneously.

A bus tie 130 may be provided between the first bus 110 and the second bus 120. The bus tie 130 can connect or block the line between the first bus bar 110 and the second bus bar 120. When the bus tie 130 connects the lines, power from the first bus bar 110 may be transmitted to the second bus bar 120 or power from the second bus bar 120 may be transmitted to the first bus bar 110.

As shown in FIG. 1, the power grid 100 may be an alternating current power grid. Accordingly, the power produced by the generators 210 and 220 is directly supplied to the power grid 100, and the AC power of the power grid 100 is supplied to power converters 710 and 720, such as AC/DC converters and DC/AC inverters. It can be converted and distributed to power facilities. However, the power grid 100 of the present invention is not limited to an AC power grid and may be a DC power grid. In this case, the power converters 710 and 720 may be appropriately placed. Hereinafter, the description will focus on the fact that the power grid 100 is an alternating current power grid.

Generators 210 and 220 can produce power. For example, the generators 210 and 220 may be diesel generators that produce large power of 200 kW or more. A plurality of generators 210 and 220 may be connected in parallel to the power grid 100 to supply the produced power to the power grid 100.

The on-board loads 310 and 320 may operate using power supplied from the power grid 100. For example, the onboard loads 310 and 320 may be a thruster that generates propulsion, a temperature controller that controls the temperature of the cargo tank, a compressor that compresses the boil-off gas, or a re-liquefaction device that liquefies the compressed boil-off gas. Alternatively, fuel supply pumps, blowers, emergency control equipment, emergency lights, drainage pumps, GPS receivers, radar devices, wireless equipment, ship location transmitting devices, etc. may be included in the on-board loads (310, 320), which are described later. The power management unit 500, energy management unit 600, and test device 800 may be included in the onboard loads 310 and 320.

The energy storage units 410 and 420 may be connected to the power grid 100 to store or supply power. Specifically, the energy storage units 410 and 420 may store power produced by the generators 210 and 220 or supply the stored power to the onboard loads 310 and 320 through the power grid 100.

Basically, the first energy storage unit 410 provided in the first bus 110 receives power from the generator 210 of the first bus 110, and the onboard load 310 connected to the first bus 110 ) can supply power. Likewise, the second energy storage unit 420 provided in the second bus bar 120 receives power from the generator 220 of the second bus bar 120, and the in-ship load 320 connected to the second bus bar 120 ) can supply power. However, when the bus tie 130 connects the first bus bar 110 and the second bus bar 120, the first energy storage unit 410 receives power from the generator 220 of the second bus bar 120. , power can be supplied to the onboard load 320 of the second bus 120. Similarly, when the bus tie 130 connects the first bus bar 110 and the second bus bar 120, the second energy storage unit 420 supplies power from the generator 210 of the first bus bar 110. and can supply power to the on-board load 310 of the first bus 110.

The energy storage units 410 and 420 may include batteries 411 and 421 and converters 412 and 422. The batteries 411 and 421 may charge or discharge power, and the converters 412 and 422 may convert the power of the batteries 411 and 421. Hereinafter, the converters 412 and 422 provided in the energy storage units 410 and 420 are referred to as power converters.

The batteries 411 and 421 can charge or discharge direct current power. The power converters 412 and 422 convert alternating current power received from the power grid 100 into direct current power and deliver it to the batteries 411 and 421, or receive direct current power from the batteries 411 and 421 and transmit it to the power grid 100. can be supplied.

The energy storage units 410 and 420 of the present invention may be, but are not limited to, an Energy Storage System (ESS).

The power management unit 500 serves to monitor and control the operating status of the onboard loads 310 and 320 and the generators 210 and 220 connected to the power grid 100. For example, the power management unit 500 may check the power consumption status of the on-board loads 310 and 320 and, depending on the results, cause the generators 210 and 220 to produce power or stop power production. .

A plurality of generators 210 and 220 may be connected to the power grid 100. The power management unit 500 may allow only some generators to operate and prevent other generators from operating. Additionally, the power management unit 500 may control the load rate for each generator (210, 220). For example, the power management unit 500 may cause a specific generator to generate power at a load rate of 20% and cause another generator to generate power at a load rate of 80%. Here, the load factor represents the ratio of the power production currently being produced among the maximum power production of the generator.

The power management unit 500 may refer to the power production of other generators when controlling the power production of each generator (210, 220).

The energy management unit 600 controls the energy storage units 410 and 420 according to the monitoring information of the power management unit 500. For example, the energy management unit 600 may charge or discharge the energy storage units 410 and 420 so that the load factor of the generators 210 and 220 is 80% or within a certain range including 80%. Here, the specific value or specific range of the load ratio may be a load ratio (hereinafter referred to as the maximum load ratio) indicating the maximum operating efficiency of the generators 210 and 220. The generators 210 and 220 consume fuel to produce power, and when operating at the maximum load rate, the amount of power produced compared to the amount of fuel consumed by the generators 210 and 220 may be maximum.

Even if the amount of power consumed by the onboard loads 310 and 320 changes, the load ratio of the generators 210 and 220 can be maintained constant by the charging and discharging operations of the energy storage units 410 and 420. In particular, the load rate of the generators 210 and 220 can be maintained at the maximum load rate.

The test device 800 serves to test the power grid 100 provided on the ship 10. Specifically, the test device 800 can test the control of the energy storage units 410 and 420 by the energy management unit 600 using a virtual power grid corresponding to the power grid 100. The ship 10 may be provided with a plurality of energy storage units 410 and 420. Figure 1 shows two energy storage units 410 and 420, but three or more energy storage units may be provided in the ship 10, and one or more energy storage units may be provided for each mother ship. Hereinafter, the description will focus on the two energy storage units 410 and 420 provided in the ship 10.

In order to test the control of the energy storage units 410 and 420 by the energy management unit 600, operation of a plurality of energy storage units 410 and 420 is required. For example, the energy storage unit to be tested (hereinafter referred to as the test energy storage unit) must perform a discharging operation, and the remaining energy storage units must perform a charging operation. In this case, the operation of not only the test energy storage unit but also the remaining energy storage units are reflected in the power grid 100, so the control of the specific energy storage unit by the energy management unit 600 cannot be tested correctly.

The test device 800 according to an embodiment of the present invention can test the energy management unit 600 by applying the operation results of the test energy storage unit to the virtual power grid. The operation results of energy storage units that are not subject to testing (hereinafter referred to as non-test energy storage units) are not applied to the virtual power grid. Accordingly, control of a specific energy storage unit by the energy management unit 600 can be tested correctly.

The operation result of the test energy storage unit may be a discharge current value or a charging current value of the test energy storage unit. When testing the discharge control of the test energy storage unit, the test device 800 can receive a discharge current value, and when testing the charging control of the test energy storage unit, the test device 800 can receive a charging current value. The current of the energy storage units 410 and 420 can be measured by ammeters 910 and 920. The ammeters 910 and 920 may measure the current flowing in the power line between the energy storage units 410 and 420 and the power grid 100 and transmit the current to the test device 800.

The test energy storage unit and the non-test energy storage unit may perform opposite operations. For example, when the test energy storage unit performs a discharging operation, the non-test energy storage unit may perform a charging operation, and when the test energy storage unit performs a charging operation, the non-test energy storage unit may perform a discharging operation. The discharge power of the energy storage unit that performs the discharging operation is input to the energy storage unit that performs the charging operation. If the test energy storage unit and the non-test energy storage unit are provided in different busbars, a bus tie may connect the first busbar and the second busbar.

In reality, the operation results of the non-test energy storage unit are reflected in the power grid 100, but since only the operation results of the test energy storage unit are reflected in the virtual power grid, control of the test energy storage unit by the energy management unit 600 can be tested.

Hereinafter, the detailed configuration and operation of the test device 800 will be described through FIGS. 2 to 6.

FIG. 2 is a diagram showing the detailed configuration of the test device shown in FIG. 1.

Referring to FIG. 2, the test device 800 includes an interface unit 810, a virtual power grid 820, a power grid analysis unit 830, and a control unit 840.

The interface unit 810 receives the operation results of the energy storage units 410 and 420 and transmits power information of the virtual power grid 820 to the energy management unit 600. The interface unit 810 may receive only the operation results of the test energy storage unit among the plurality of energy storage units 410 and 420. For this purpose, the test device 800 may be equipped with a result selection switch 750.

The result selection switch 750 may switch the result transmission path so that the operation result of the test energy storage unit among the plurality of energy storage units 410 and 420 is delivered to the interface unit 810. The first storage power line 851 and the second storage power line 852 may be input to the result selection switch 750. The first storage power line 851 represents a power line leading to the first energy storage unit 410, and the second storage power line 852 represents a power line leading to the second energy storage unit 420. The result selection switch 750 may connect the first storage power line 851 and the interface unit 810 or connect the second storage power line 852 and the interface unit 810.

When the first storage power line 851 and the interface unit 810 are connected, the operation result of the first energy storage unit 410 is transmitted to the interface unit 810, and the second storage power line 852 and the interface unit ( When 810 is connected, the operation result of the second energy storage unit 420 may be transmitted to the interface unit 810.

The test device 800 may be equipped with an information selection switch 760. The information selection switch 760 functions to switch the information transmission path so that power information of the power grid 100 or power information of the virtual power grid 820 is selectively transmitted to the energy management unit 600.

A power grid signal line 861 and a virtual power grid signal line 862 may be input to the information selection switch 760. The power grid signal line 861 represents a signal line leading to the power grid 100, and the virtual power grid signal line 862 represents a signal line leading to the virtual power grid 820. The information selection switch 760 may connect the power grid signal line 861 and the energy management unit 600 or connect the virtual power grid signal line 862 and the energy management unit 600.

When the power grid signal line 861 and the energy management unit 600 are connected, power information from the power grid 100 is transmitted to the energy management unit 600, and when the virtual power grid signal line 862 and the energy management unit 600 are connected, the virtual power grid 820 ) power information may be transmitted to the energy management unit 600.

Power information of the virtual power grid 820 may be output through the interface unit 810. Power information may include power usage information and power supply information. Power usage information includes the amount or pattern of power consumed in the power grid 100 or virtual power grid 820, and power supply information includes the amount or pattern of power supplied to the power grid 100 or virtual power grid 820. can do.

The virtual power grid 820 is a virtual power grid created in response to the power grid 100. The virtual power grid 820 includes onboard loads 310, 320, generators 210, 220, and an energy storage unit connected to the power grid 100. A virtual load (not shown), a virtual generator (not shown), and a virtual energy storage unit (not shown) corresponding to (410, 420) may be included. The virtual load may operate with virtual power supplied from a virtual generator or a virtual energy storage unit. A virtual generator can produce virtual power. The virtual energy storage can supply virtual power to virtual loads or charge by receiving power from a virtual generator. The operation of the virtual energy storage unit may be performed according to the operation results of the energy storage units 410 and 420 received through the interface unit 810.

Only the operation results of the test energy storage unit can be input to the virtual power grid 820. To this end, the test device 800 may be equipped with result transfer switches 871 and 872 that determine the input of operation results to the virtual power grid 820.

Result transfer switches 871 and 872 may be provided to correspond to the energy storage units 410 and 420. Since there are two energy storage units 410 and 420, the result transfer switches 871 and 872 may include a first result transfer switch 871 and a second result transfer switch 872. The first result transfer switch 871 is connected to the first virtual power line 821 of the virtual power grid 820, and the second result transfer switch 872 is connected to the second virtual power line 822 of the virtual power grid 820. You can. It may be understood that the first virtual power line 821 is connected to a first virtual energy storage unit (not shown), and the second virtual power line 822 is connected to a second virtual energy storage unit (not shown). The first virtual energy storage unit represents a virtual energy storage unit corresponding to the first energy storage unit 410, and the second virtual energy storage unit represents a virtual energy storage unit corresponding to the second energy storage unit 420.

The operation of the virtual energy storage unit may be determined by the result transfer switches 871 and 872. When the first result transfer switch 871 is closed, the first virtual energy storage unit performs the same operation as the first energy storage unit 410, and when the first result transfer switch 871 is open, the first virtual energy storage unit performs the same operation as the first energy storage unit 410. The action can be performed. Likewise, when the second result transfer switch 872 is closed, the second virtual energy storage unit performs the same operation as the second energy storage unit 420, and when the second result transfer switch 872 is open, the second virtual energy storage unit performs the same operation as the second energy storage unit 420. The storage unit may perform virtual operations.

The power grid analysis unit 830 performs the role of calculating power information of the virtual power grid 820 to which the operation results of the energy storage unit are applied. Specifically, the power grid analysis unit 830 may calculate power information of the virtual power grid 820 by analyzing the operations of the virtual load, virtual generator, and virtual energy storage unit included in the virtual power grid 820. The calculated power information may be transmitted to the energy management unit 600 through the interface unit 810.

The control unit 840 may test the control of the energy storage unit by the energy management unit 600 with reference to the power information calculated by the power grid analysis unit 830. That is, the control unit 840 can determine whether the energy management unit 600 is operating normally. For example, the control unit 840 determines that the energy management unit 600 is operating normally when the calculated power information is within a preset threshold range, and when the calculated power information is outside the preset threshold range, the control unit 840 determines that the energy management unit 600 is operating normally. It may be determined that the management unit 600 is malfunctioning. The decision result of the control unit 840 may be output through a separate output means (not shown).

The control unit 840 may control the operations of the result selection switch 750, the information selection switch 760, and the result transfer switches 871 and 872. The control unit 840 controls the operation of the result selection switch 750, the information selection switch 760, and the result transfer switches 871 and 872 by referring to whether the test device 800 is operating and the operation result of the test energy storage unit. You can.

Additionally, the control unit 840 performs overall control over the interface unit 810, the virtual power grid 820, and the power grid analysis unit 830.

FIG. 3 is a diagram showing the test device shown in FIG. 2 connected to an energy management unit.

Referring to FIG. 3, the test device 800 may be connected to the energy management unit 600 through the information selection switch 760.

The energy management unit 600 may receive power information of the power grid 100 or power information of the virtual power grid 820. When a test for the energy management unit 600 is not performed, the information selection switch 760 may adjust a path so that power information of the power grid 100 is transmitted to the energy management unit 600. Meanwhile, when a test is performed on the energy management unit 600, the information selection switch 760 may adjust the path so that power information of the virtual power grid 820 is transmitted to the energy management unit 600.

The energy management unit 600 may control the energy storage units 410 and 420 according to the received power information. When a test on the energy management unit 600 is not performed, a control command of the energy management unit 600 may be transmitted to the first energy storage unit 410 and the second energy storage unit 420. Meanwhile, when a test is performed on the energy management unit 600, a control command of the energy management unit 600 may be transmitted to one of the first energy storage unit 410 and the second energy storage unit 420. When a test on the energy management unit 600 is performed, a control command may be transmitted only to one energy storage unit, which is the test energy storage unit.

To transmit selective control commands, command transmission switches 881 and 882 may be provided for each energy storage unit 410 and 420. The command transfer switches 881 and 882 may include a first command transfer switch 881 and a second command transfer switch 882. The first command transfer switch 881 may be connected to the first energy storage unit 410, and the second command transfer switch 882 may be connected to the second energy storage unit 420. Depending on the operation of the command transmission switches 881 and 882, the control command of the energy management unit 600 may be transmitted or prevented from being transmitted to each energy storage unit 410 and 420.

The operation of the command transmission switches 881 and 882 may be determined by the control unit 840. The control unit 840 may control the operation of the command transmission switches 881 and 882 depending on whether the energy management unit 600 is tested. Accordingly, the test device 800 transmits the control command of the energy management unit 600 to the energy storage unit to be tested among the plurality of energy storage units 410 and 420, and transmits the control command of the energy management unit 600 to the remaining energy storage units. The command transmission switches 881 and 882 can be controlled to prevent this from being transmitted.

Figures 4 to 6 are diagrams showing the operation of the test device shown in Figure 3.

Referring to FIG. 4, when a test on the energy management unit 600 is not performed, the energy management unit 600 may control the first energy storage unit 410 and the second energy storage unit 420.

When a test on the energy management unit 600 is not performed, the control unit 840 may control the information selection switch 760 and the command transmission switches 881 and 882.

The control unit 840 may control the information selection switch 760 so that power information (RG) of the power grid 100 is transmitted to the energy management unit 600. Under the control of the control unit 840, the information selection switch 760 may connect the power grid signal line 861 leading to the power grid 100 and the energy management unit 600.

The control unit 840 uses a first command transmission switch 881 and a second command transmission switch 881 to transmit the control commands BC1 and BC2 of the energy management unit 600 to the first energy storage unit 410 and the second energy storage unit 420. The command transmission switch 882 can be controlled to close. Under the control of the control unit 840, the first command transmission switch 881 connects the energy management unit 600 and the first energy storage unit 410, and the second command transmission switch 882 connects the energy management unit 600 and the first energy storage unit 410. The second energy storage unit 420 can be connected.

The energy management unit 600 may transmit control commands BC1 and BC2 to the first energy storage unit 410 and the second energy storage unit 420 according to the power information (RG) received from the power grid 100. . The control commands BC1 and BC2 may be discharge commands or charge commands.

Referring to FIGS. 5 and 6 , when a test is performed on the energy management unit 600, the energy management unit 600 may control the test energy storage unit. 5 and 6 show that the first energy storage unit 410 is a test energy storage unit.

When a test on the energy management unit 600 is performed, the control unit 840 controls the result selection switch 750, result transfer switches 871, 872, information selection switch 760, and command transfer switches 881, 882. can do.

The control unit 840 may control the result selection switch 750 so that the operation results (DA, CA) of the first energy storage unit 410 are input to the interface unit 810. Under the control of the control unit 840, the result selection switch 750 may connect the first storage power line 851 and the interface unit 810.

The control unit 840 may control the result transfer switches 871 and 872 so that the operation results (DA, CA) of the first energy storage unit 410 are input to the virtual power grid 820. Under the control of the control unit 840, the first result transfer switch 871 may be closed and the second result transfer switch 872 may be opened. The first result transfer switch 871 may connect the interface unit 810 and the first virtual power line 821.

The control unit 840 may control the information selection switch 760 so that power information (VG) of the virtual power grid 820 is transmitted to the energy management unit 600. Under the control of the control unit 840, the information selection switch 760 may connect the virtual power grid signal line 862 leading to the virtual power grid 820 and the energy management unit 600.

The control unit 840 may control the first command transmission switch 881 to be closed so that the control commands (DC, CC) of the energy management unit 600 are transmitted to the first energy storage unit 410. Under the control of the control unit 840, the first command transmission switch 881 may connect the energy management unit 600 and the first energy storage unit 410. At this time, the control unit 840 may control the second command transmission switch 882 to be opened so that the control command of the energy management unit 600 is not transmitted to the second energy storage unit 420. As the second command transmission switch 882 is opened under the control of the control unit 840, the connection between the energy management unit 600 and the second energy storage unit 420 may be released.

FIG. 5 is a diagram showing that the discharge operation control of the first energy storage unit 410 by the energy management unit 600 is tested.

The discharge current value (DA) of the first energy storage unit 410 input through the first storage power line 851 may be input to the virtual power grid 820 through the interface unit 810. The virtual power grid 820 may operate according to the input discharge current value (DA). That is, the virtual power grid 820 may operate after determining that the first virtual energy storage unit has output power corresponding to the discharge current value (DA).

The power grid analysis unit 830 may calculate power information (VG) of the virtual power grid 820. The calculated power information (VG) may be transmitted to the energy management unit 600 through the interface unit 810.

The energy management unit 600 may transmit a control command (DC) to the first energy storage unit 410 according to the power information (VG) received from the virtual power grid 820. The control command (DC) may be a discharge command.

The first energy storage unit 410 may perform a discharging operation according to a control command (DC) from the control unit 840. The discharge current value DA, which is a result of the operation of the first energy storage unit 410, may be input through the first storage power line 851.

Input of discharge current value, virtual power grid operation, virtual power grid analysis, and control of the first energy storage unit 410 may be performed cyclically, and the control unit 840 continuously observes the operation of the energy management unit 600 to control the energy management unit 600. The discharge control of 600 can be tested.

FIG. 6 is a diagram showing the charging operation control of the first energy storage unit 410 by the energy management unit 600 being tested.

The charging current value (CA) of the first energy storage unit 410 input through the first storage power line 851 may be input to the virtual power grid 820 through the interface unit 810. The virtual power grid 820 may operate according to the input charging current value (CA). That is, the virtual power grid 820 may determine that the first virtual energy storage unit has charged power corresponding to the charging current value (CA) and operate.

The power grid analysis unit 830 may calculate power information (VG) of the virtual power grid 820. The calculated power information (VG) may be transmitted to the energy management unit 600 through the interface unit 810.

The energy management unit 600 may transmit a control command (CC) to the first energy storage unit 410 according to the power information (VG) received from the virtual power grid 820. The control command (CC) may be a charging command.

The first energy storage unit 410 may perform a charging operation according to the control command (CC) of the control unit 840. The charging current value (CA), which is a result of the operation of the first energy storage unit 410, may be input through the first storage power line 851.

Charging current value input, virtual power grid operation, virtual power grid analysis, and control of the first energy storage unit 410 may be performed cyclically, and the control unit 840 continuously observes the operation of the energy management unit 600 to control the energy management unit 600. The charging control of 600 can be tested.

Although embodiments of the present invention have been described with reference to the above and the attached drawings, those skilled in the art will understand that the present invention can be implemented in other specific forms without changing the technical idea or essential features. You will understand that it exists. Therefore, the embodiments described above should be understood in all respects as illustrative and not restrictive.

10: vessel 20: hull
100: power grid 110: first bus
120: Second mothership 130: Bus tie
210, 220: generator 310, 320: load on board
410, 420: Energy storage unit 411, 421: Battery
412, 422: Power converter 500: Power management unit
600: Energy management unit 710, 720: Power converter
800: test device 810: interface unit
820: virtual power grid 821, 822: virtual power line
830: Power grid analysis unit 840: Control unit
850: result selection switch 851, 852: storage power line
860: Information selection switch 861: Power grid signal line
862: Virtual power grid signal line 871, 872: Result transmission switch
881, 882: command transmission switch 910, 920: ammeter

Claims (6)

hull;
a power grid provided on the hull;
An energy storage unit connected to the power grid to store or supply power;
A power management unit that monitors and controls the operating status of onboard loads and generators connected to the power grid;
an energy management unit that controls charging or discharging of the energy storage unit according to the operation of the load within the ship; and
A test device for testing control of the energy storage unit by the energy management unit using a virtual power grid corresponding to the power grid,
A plurality of energy storage units are provided,
The test device tests the energy management unit by applying the operation results of the energy storage unit to be tested among the plurality of energy storage units to the virtual power grid,
The test device ensures that the control command of the energy management unit is transmitted to the energy storage unit that is the test target among the plurality of energy storage units, and the control command of the energy management unit is not transmitted to the remaining energy storage units,
The test device is a ship including an information selection switch for switching an information transmission path so that power information of the power grid or power information of the virtual power grid is selectively transmitted to the energy management unit. delete According to claim 1,
The operation result of the energy storage unit to be tested includes a discharge current value or a charging current value of the energy storage unit to be tested. delete delete delete

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