JP7214823B1 - Energy management system - Google Patents

Abstract

An energy management system capable of stably supplying power to a power system is provided. A system includes an AC bus 50 composed of an output of a power generation means 40, a first power detection means 31 for detecting the output of the power generation means, a DC bus 51 configured using a DC power supply 10 as a power source, A power converter 22 for power generation drive connected to a generator motor for driving and braking a rotating machine shaft using a DC power supply as a power source, and an AC/DC bus power converter connecting an AC bus and a DC bus to convert power bi-directionally. 21, a second power detection means 32 for detecting the output of the AC/DC bus power converter, a first output value detected by the first power detection means and a second output value detected by the second power detection means are input. , a controller 30 for determining the power sharing amount of the AC bus power and the DC bus power, and the power to be supplied to the power converter for power generation driving when the output of the power generation means and the AC part of the AC/DC bus power converter are operated in parallel The adjustment amount is linked to the AC/DC bus power converter. [Selection drawing] Fig. 1

Description

The present invention relates to an energy management system in an electric power system.

As for a system stabilization method combining an electric power storage device and a motor-generator in a moving object, means as shown in Patent Document 1 has been proposed. Further, as for the power equipment and operation method of ships, equipment and methods as shown in Patent Document 2, which combines a power generating means and an energy storage device, have been proposed.

FIG. 11 shows a power system according to the prior art disclosed in Patent Document 1. In FIG. 110 is a first power storage device, 120 is a second power storage device, 121 is a first power converter, 122 is a second power converter, 123 is a third power converter, 124 is a fourth power converter, and 130 is 150 is an AC inboard bus; 151 is a DC intermediate bus; 160 is an inboard power load;

The AC inboard bus 150 composed of the main generator 140 is connected to the onboard power load 160, the first power storage device 110 via the first power converter 121 for power storage, and the A second power storage device 120 is connected. In addition, the propulsion motor generator 180 that drives the propeller 190 that is coaxially connected to the main engine 170 is also converted once to the DC intermediate bus 151 through the fourth power converter 124, and then through the third power converter. It is connected to the inboard bus 150 . The first power converter 121 and the second power converter 122 are charge/discharge controlled by the control system 130 .

Here, the first power converter 121 has higher energy density than the second power converter 122 and the second power converter 122 has higher power density than the first power converter 121 is selected.

In this power system, the first power storage device 110 is discharged preferentially over the second power storage device 120 so as to supply base power, and the second power storage device 120 is used for system stabilization during work involving load fluctuations. Charge/discharge control is performed so as to give priority to the first power storage device 110 . Also, when the main engine 170 fluctuates, charge/discharge control is performed so as to prioritize the second power storage device 120 over the first storage device 110 so as to adjust the drive or generated power of the propulsion motor generator 180 .

According to the above configuration, power can be supplied according to the energy density and output density of the power storage device in response to load fluctuations and main engine 170 fluctuations, and is well known as an energy sharing method in electric power systems.

FIG. 12 shows the power equipment and operation method according to the prior art disclosed in Patent Document 2. As shown in FIG.

210 is an energy storage means, 221 is a power converter, 222 is a starter, 230 is a first switching means, 231 is a second switching means, 232 is a third switching means, 240 is a main generator, 250 is an AC inboard bus, Reference numeral 260 denotes a first onboard power load, 261 a second onboard power load, and 262 a third onboard power load.

A first onboard power load 260 driven by a starter 222 and a second onboard power load 261 and a third onboard power load 262 via a first switching means 230 are connected to an AC onboard bus 250 composed of a main generator 240 . It is connected. Also, in order to store power, the AC inboard bus 250 is connected to the power converter 221 via the second switching means 231 , and the converted power is stored in the energy storage means 210 . Furthermore, the power converter 221 is connected to the AC inboard bus 250 via the third switching means 232 and the first switching means 230 .

Here, according to the comparison between the load factor of the main generator 240 and the load reference value and the comparison between the energy charge amount and the charge reference value of the energy storage means 210, when the power generation amount is small and the energy storage amount is large, the main power generation The main generator 240 is stopped and the energy storage means 210 operates the load power supply as an independent power supply mode. When the power generation amount is large and the energy storage amount is large, both the main generator 240 and the energy storage means 210 are operated as an assist mode in which load feeding is performed, and when the power generation amount is large and the energy storage amount is small, the energy storage is operated. The means 210 is deactivated and the generator 240 is operated so as to supply power to the load.

The above configuration is well known as an operation method that enables load feeding while effectively using stored energy by switching the circuit connected to the AC bus 250 according to the amount of power generation and the amount of stored energy.

Japanese Patent No. 6757570 Japanese Patent No. 5357526

However, the technique described in Patent Document 1 does not describe a load sharing method between DC bus devices such as rotating machines, batteries, and fuel cells via converters connected to the DC bus, and the load on the AC bus is not described. Although it is possible to use different power converters according to fluctuations, it is not possible to cope with load fluctuations of equipment connected to the DC bus. In addition, when the DC bus voltage is changed by selecting and operating the power converters corresponding to the AC load change, the AC bus may be changed.

In the technique described in Patent Document 2, a facility and an operation method for switching circuits according to the conditions of power generation means and energy storage means are shown. If there was, complicated judgments and procedures were required according to the operating conditions of each facility connected to the DC bus.

SUMMARY OF THE INVENTION An object of the present invention is to provide an energy management system capable of stably supplying electric power in a power system composed of an AC bus and a DC bus connected by a power converter.

In order to achieve the above object, the invention according to claim 1 is composed of an AC bus composed of the output of a power generation means, a first power detection means for detecting the output of the power generation means, and a DC power supply as power sources. a power converter for power generation drive connected to a generator-motor for driving and braking a rotating machine shaft using the DC power supply as a power supply; AC/DC bus power converter for conversion; second power detection means for detecting the output of the AC/DC bus power converter; first output value detected by the first power detection means and detection by the second power detection means The second output value is input, and the amount of power sharing of the power of the AC bus and the power of the DC bus is determined, and the power is supplied to each of the power generation means, the power converter for driving power generation, and the AC/DC bus power converter. a controller for instructing an adjustment amount, wherein the power adjustment amount to be given to the power generation driving power converter when the output of the power generating means and the AC section of the AC/DC bus power converter are operated in parallel, is controlled by the AC/DC bus power conversion; It is characterized by interlocking with the vessel.

The invention according to claim 2 is characterized in that, in the energy management system according to claim 1, the power generation means comprises an energy storage device and a charge/discharge power converter.

According to a third aspect of the present invention, there is provided the energy management system according to the first or second aspect, wherein the amount of power adjustment instructed by the controller is given by a pulse signal.

According to a fourth aspect of the present invention, in the energy management system of the first or second aspect, the power adjustment amount instructed by the controller is given as a continuous signal corresponding to the power.

The invention according to claim 5 is directed to the energy management system according to any one of claims 1 to 4, wherein the output of the AC/DC bus power converter is detected and a detected power signal is input to the controller. In the configuration in which a third power detection means is added, the power adjustment amount to be given to the power generation driving power converter instructed by the controller is set in proportion according to the number of devices connected to the DC bus. do.

The invention according to claim 6 is the energy management system according to any one of claims 1 to 5, wherein the power adjustment amount to the power generating means instructed by the controller is preferentially set. do.

The invention according to claim 7 is the energy management system according to any one of claims 1 to 4, wherein the amount of power adjustment to be given to the AC/DC bus power converter instructed by the controller includes: The power adjustment amount to be applied to the power converter is preferentially set.

The invention according to claim 8 is the energy management system according to any one of claims 1 to 4, wherein, of the power adjustment amount given to the AC/DC bus power converter instructed by the controller, the power for driving generation It is characterized by setting the amount of power adjustment applied to the converter to a minimum amount including zero.

According to a ninth aspect of the invention, in the energy management system according to any one of the first to fourth aspects, the power adjustment amount to be given to the power generation drive power converter instructed by the controller is preferentially set. In addition, the power adjustment amount to be applied to the power converter for driving power generation and the power adjustment amount to be applied to the AC/DC bus power converter are interlocked.

According to a tenth aspect of the present invention, there is provided an energy management system according to the ninth aspect, wherein the power adjustment amount given to the AC/DC bus power converter instructed by the controller is changed according to the load. .

The invention according to claim 11 is the energy management system according to any one of claims 1 to 4, wherein the amount of power adjustment indicated by the controller is changed by the charge/discharge amount of a battery connected to the DC bus. The output of the power generating means and the power converter for driving power generation are set to be distributed so as not to cause the power generation.

According to the energy management system of the present invention, it is possible to provide an energy management system capable of stably supplying electric power in a power system composed of an AC bus and a DC bus connected by a power converter.

The figure which shows the 1st Embodiment of this invention. The figure which shows the 2nd Embodiment of this invention. FIG. 11 is a diagram for explaining power adjustment amounts output from a controller according to the third embodiment of the present invention; 4 is a flowchart showing basic operation of power load sharing by a controller; FIG. 11 is a flow chart showing the operation of a controller according to the sixth embodiment of the present invention; FIG. FIG. 11 is a flow chart showing the operation of a controller according to the seventh embodiment of the present invention; FIG. FIG. 11 is a flow chart showing the operation of a controller according to an eighth embodiment of the present invention; FIG. FIG. 11 is a flow chart showing the operation of a controller according to the ninth embodiment of the present invention; FIG. 12 is a flow chart showing the operation of the controller according to the tenth embodiment of the present invention; FIG. 11 is a flow chart showing the operation of the controller according to the eleventh embodiment of the present invention; FIG. 1 illustrates a power system according to the prior art; FIG. The figure which shows the electric power equipment and operation method by a prior art.

<First embodiment>
(Constitution)
FIG. 1 is a diagram showing a first embodiment of the present invention. In FIG. 1, 10 is a first energy storage device, 21 is an AC/DC bus power converter, 22 is a power converter for power generation drive, 30 is a controller, 31 is first power detection means (power detector), and 32 is a first power detector. 2 power detection means (power detector), 40 power generation means (main generator), 50 AC bus, 51 DC bus, 60 power load, 70 main engine, 80 generator motor (rotating machine), 90 It is a rotating load machine. The power generating means includes, for example, a generator 402 driven by a diesel engine 401 or the like to generate power.
(action)
Power is supplied to the power load 60 by the AC bus 50 configured by the power generating means 40 . On the other hand, on the DC bus 51 composed of the first energy storage device 10, there is a power converter 22 for power generation drive for driving and braking control of the generator motor 80 coaxially connected to the main engine 70 and the rotating load machine 90. It is connected. Incidentally, the connection of the generator-motor 80 is not limited to the coaxial connection of the main machine 70 and the rotating load machine 90, but may be of an interlocking shaft configuration via a transmission. Also, the AC bus 50 and the DC bus 51 are connected by an AC/DC bus power converter 21 so that power conversion can be performed in both directions. The AC bus 50 operates in parallel with the power generating means 40 and the AC/DC bus power converter 21 , and shares the power supplied to the power load 60 according to the power adjustment amount instruction from the controller 30 .

In general, the power generating means 40 has a drooping characteristic in the speed governor, and the load sharing during parallel operation between the power generating means 40 and a different power generating means is, for example, the speed controlling operation of the diesel engine 401 (the speed control of the power generator 402 output frequency manipulation) or speed regulation manipulation of different power generation means (output frequency manipulation) or both in a manner that varies the power share.

The controller 30 receives the output power value (first output value) of the power generation means 40 detected by the first power detection means 31 and the output of the AC/DC bus power converter 21 detected by the second power detection means 32. A power value (second output value) is input, an output power value (third output value) of the power generation driving power converter 22 detected by the third power detection means 33 is input, and based on each output power value It instructs the power generation means 40, the AC/DC bus power converter 21, and the power generation drive power converter 22 to adjust the amount of power or increase/decrease the power. The second power detection means 32 may detect either the power of the AC section or the power of the DC section of the AC/DC bus power converter 21 . Further, the third power detection means 33 may measure the DC power between the DC bus 51 and the power converter for power generation drive 22 or the armature power of the generator motor (rotating machine) 80. An output value may be calculated from the rotation speed.

Here, the controller 30 in the first embodiment gives an instruction of the same amount of power to the power generation drive power converter 22 in conjunction with the power instructed to the AC/DC bus power converter 21 . By operating in this manner, when changing the power instructed to the AC/DC bus power converter 21 according to the change in the power load 60 connected to the AC bus 50, the power instructed to the power generation drive power converter 22 is changed to By interlocking the change rate and the amount so that the same amount of change occurs, the power recovered from the generator motor 80 coaxially connected to the main engine 70 is interlocked with the change in the power load 60 connected to the AC bus 50. . The same amount of power shown here ignores converter efficiency. Therefore, in order to make the input and output amounts exactly the same, the amount of loss may be added to the input in consideration of efficiency.

As a result, since the passing power on the AC side and the DC side of the AC/DC bus power converter 21 is the same, the power load 60 connected to the AC bus 50 can be changed smoothly while the DC bus 51 is kept stable. can respond.

(effect)
According to the first embodiment, by interlocking and changing the DC power according to the change in the AC load, load sharing can be performed while maintaining the stability of the AC bus and the DC bus without causing fluctuations in the voltage and current of the DC bus. can be done.

<Second embodiment>
(Constitution)
FIG. 2 is a diagram showing a second embodiment of the present invention. In this configuration, instead of the power generating means 40 in the first embodiment, the second energy storage device 20 is used as a power source and a power converter 23 for AC bus charging/discharging is connected. In addition, it has a plug-in line 45 that feeds the AC bus 50 with power from other generating means 24 (eg, generators, other energy storage devices, outboard power sources, etc.). Other constituent elements are the same as those of the first embodiment, so description thereof is omitted.

(Action)
The AC bus 50 is composed of a storage power source in which the AC bus charging/discharging power converter 23 is connected to the second energy storage device 20 . In addition, the AC bus 50 has a plug-in electric line 45 capable of supplying power from another power generating means 24, and the other power generating means 24 is connected to the plug-in electric line 45 to provide power for charging and discharging the AC bus. The second energy storage device 20 can be charged by charging the power converter 23 .

The power sharing of the power load 60 of the AC bus 50 is performed in accordance with the instruction of the power adjustment amount from the controller 30 as in the first embodiment. The AC bus charging/discharging power converter 23 has a drooping characteristic in the output frequency, and the load sharing during parallel operation with the AC/DC bus power converter 21 is between the AC bus charging/discharging power converter 23 and the AC/DC bus power. This is done by varying the amount of power sharing according to the droop characteristics of each of the converters 21 and the increase/decrease operation of the output frequency provided by the controller 30 .

As in the first embodiment, the controller 30 interlocks with the power instructed to the AC/DC bus power converter 21 and gives the power generation drive power converter 22 an instruction of the same amount of power. As a result, the passing power on the AC side and the DC side of the AC/DC bus power converter 21 becomes the same, so that changes in the power load connected to the AC bus can be smoothly handled while the DC bus 51 is kept stable. can be done. The same amount of power shown here ignores converter efficiency. Therefore, in order to make the input and output amounts exactly the same, the amount of loss may be added to the input in consideration of efficiency.

(effect)
According to the second embodiment, in the configuration in which the second energy storage device 20 and the AC bus charging/discharging power converter 23 are provided as power generation means, the DC It is possible to share the load while maintaining the stability of the AC bus and the DC bus without disturbing the voltage and current of the bus.

<Third Embodiment>
(Constitution)
The configuration of the third embodiment is the same as those of the first and second embodiments, so the description is omitted.

(action)
In the first embodiment and the second embodiment, when explaining the load sharing, only the configuration of the power generation means is different, and there is no influence on the operation of the sharing. do. Unless otherwise specified, the power generation means 40 may be read as storage means combining the second energy storage device 20 of the second embodiment and the AC bus charging/discharging power converter 23 . Moreover, in the configuration of the power generation means, a parallel combination of the power generation means 40, the second energy storage device 20, and the AC bus charging/discharging power converter 23 may be used.

The power adjustment amount output from the controller 30 to the power generation means 40, the AC/DC bus power converter 21, and the power generation driving power converter 22 is an increasing pulse signal shown in FIG. 3A and a decreasing pulse signal shown in FIG. A pulse signal is given. The controller 30 turns on the increasing pulse for a predetermined time when the load increases, and turns on the decreasing pulse for a predetermined time when the load decreases, thereby performing an increase/decrease operation.

Here, the reference value (power reference, rotation speed reference, or frequency reference) serving as a reference for increase or decrease shown in FIG. A set value is defined for each device of the bus power converter 21 and the power converter for power generation drive 22 . The set value may be a predetermined fixed value or an arbitrary set value by the user. Further, the pulse signal may be interfaced with a contact signal configured by a hardware device or a communication signal regardless of whether it is wired or wireless.

(effect)
According to the third embodiment, the load sharing operation of the power generation means connected to the AC bus can be performed by giving a pulse signal from the controller, and can be constructed with simple calculations, operations, and interfaces.

<Fourth Embodiment>
(Constitution)
The configuration of the fourth embodiment is the same as those of the first to second embodiments, so the description is omitted.

(Action)
The power adjustment amount output from the controller 30 to the power generation means 40, the AC/DC bus power converter 21, and the power generation driving power converter 22 is calculated by calculating a preset sharing ratio amount with respect to the sum of the total power generation output amount, Give a continuous power command signal (continuous signal). The controller 30 performs an increase/decrease operation by sending a power command signal (continuous signal) corresponding to the calculated allotted amount (power) to each of them.

For example, when the power generation means 40 and the AC/DC bus power converter 21 share 50% each of the outputs, power command signal=total power generation output/2 is calculated. Generally speaking, one power command signal=total power generation output×KP, and the other power command signal=total power generation output×(1−KP). KP is a ratio and takes a numerical value of 0-1.

Here, the power command signal may be interfaced with an analog signal configured by a hardware device or a communication signal regardless of whether it is wired or wireless. Further, by performing the calculation shown in FIG. 3 in the controller 30, an analog signal may be generated from the pulse signal as in the combination with the third embodiment. Furthermore, when there are two or more power generating means, the power may be arbitrarily distributed so that the sum of the ratios of the power shared by the power generating means becomes one.

(effect)
According to the fourth embodiment, a continuous power signal can be used to indicate the load sharing operation of the devices, the power to be shared can be determined immediately, and a system that hastened the response to load fluctuations is possible. Become.

<Fifth Embodiment>
(Constitution)
The configuration of the fifth embodiment is the same as that of the first embodiment, so the description is omitted.

(Action)
As in the description of the first embodiment, the AC bus 50 operates in parallel with the power generating means 40 and the AC/DC bus power converter 21, and the sharing of power supplied to the power load 60 is controlled by the controller 30. The power to be borne by the power generating means 40 and the AC/DC bus power converter 21 is determined by the controller 30, and an increase/decrease operation is performed for each.

Here, the controller 30 instructs to distribute the command value given to the power converter 22 for power generation driving to the first energy storage device 10 connected in parallel to the DC bus 51 .

Specifically, when the power is distributed in units of 50%, the power command given to the power converter 22 for power generation drive is a value obtained by multiplying the DC load sharing amount by 1/2. Generally speaking, one power command signal=DC load sharing amount×K, and the other power command signal=DC load sharing amount×(1−K). K is a ratio and takes a numerical value of 0-1.

The DC load sharing amount shown here is determined according to the sharing of the power generation means 40 and the AC/DC bus power converter 21 in the AC bus 50, and is the power passing through the AC/DC bus power converter 21, and K is the power for driving generation. It can be said that it is the distribution ratio of the power output from the converter 22 and the first energy storage device 10 . Furthermore, a plurality of energy storage devices may be provided.

The distribution ratio shown here may be a predetermined fixed value or an arbitrary value set by the user, or may be set according to the power recoverable from the generator motor 80 coaxially connected to the main engine 70 .

In this way, the power adjustment amount instructed to the power converter 22 for driving power generation is set in proportion to the first energy storage device 10 or a plurality of energy storage devices connected in parallel to the DC bus 51 according to the number of devices. By sharing the load in the DC bus system, the DC bus load is linked to the change in the AC load, and the load can be shared in the DC bus system while the DC bus 51 is kept stable.

(effect)
According to the fifth embodiment, the AC bus and the DC bus are stabilized without fluctuating the voltage and current of the DC bus by performing interlocking changes while sharing the load on the DC bus according to the change in the AC load. load sharing can be performed while maintaining In addition, even when the power recovered from the rotating machine shaft energy is limited or when the capacity of the rotating machine or converter is desired to be set small, it is possible to share the load within the DC bus while maintaining the stability of the DC bus.

<Sixth Embodiment>
(Constitution)
The configuration of the sixth embodiment is the same as those of the first to fifth embodiments, so the description is omitted.

(action)
As in the description of the first embodiment, the AC bus 50 operates in parallel with the power generating means 40 and the AC/DC bus power converter 21, and the sharing of power supplied to the power load 60 is controlled by the controller 30. The controller 30 determines the amount of power to be shared by the power generating means 40 and the AC/DC bus power converter 21, and increases or decreases each of them.

Here, the controller 30 preferentially instructs the command value given to the power generating means 40 to be a predetermined setting. Note that the power adjustment amounts to be given to the AC/DC bus power converter 21 and the power generation drive power converter 22 are the same as those described in the first to fifth embodiments, so description thereof will be omitted.

The basic operation of power load sharing by the controller 30 will be described with reference to the flowchart shown in FIG.

The controller 30 includes a first output state determination section that determines the output state of the power generation means 40 based on the output power value (first output value) of the power generation means 40 detected by the first power detection means 31; A power manipulation processing unit for 40 determines the output state of the AC/DC bus power converter 21 based on the output power value (second output value) of the AC/DC bus power converter 21 detected by the second power detection means 32 . It has two output state determination units, a first power operation unit for the AC/DC bus power converter 21 , and a second power operation unit for the power generation drive power converter 22 .

The first output state determination unit of the controller 30 compares the power A (the output state (first output power value) of the power generation means 40) with the set value 1, which is the preset target power setting of the power generation means 40. (Step 1A). If the electric power A is smaller than the set value 1 (A<1), the electric power operation processing unit performs electric power increasing operation on the power generation means 40 (step 1B1).

On the other hand, if the electric power A is greater than the set value 1, the electric power operation processing unit performs electric power reduction operation on the power generating means 40 (step 1B2). As a result, the output power of the power generating means 40 is brought closer to the target power.

Also, when the power A and the set value 1 match (“=”), the power operation processing unit does not perform the increase/decrease operation process.

Next, the first output state determination unit of the controller 30 determines the power B (the value obtained by subtracting the output of the power generating means 40 from the total load power) and the power C (the output state of the AC/DC bus power converter output 21 (the second output value)) (step 1C). If the power B is smaller than the power C (B<C), the first power operation unit performs a power increase operation on the AC/DC bus power converter 21 (step 1D1). Further, the second power operation unit performs a power increase operation on the power generation drive power converter 22 (step 1E1). The total load power shown here is obtained by summing the power generators connected to the AC bus 51 . Alternatively, the power consumed by the load power 60 may be directly measured and calculated.

On the other hand, if the power B is greater than the power C (B>C), the first power operation unit performs a power reduction operation on the AC/DC bus power converter 21 (step 1D2). Further, the second power operation unit performs power reduction operation on the power generation drive power converter 22 (step 1E2).

Also, when the power B and the power C match (“=”), the power manipulation processing unit does not perform the increase/decrease manipulation process. Such movements determine the load sharing.

FIG. 5 shows a flow chart showing the operation of the controller 30 according to the sixth embodiment.

Since the basic operation is the same as the flowchart shown in FIG. 4, detailed description is omitted. The difference is that the first output state determination section of the controller 30 sets the target power setting (the determination value in step 1A) of the power generating means 40 to the set value 1'. The set value 1' indicates that the electric power set value at which the power generating means 40 becomes a high efficiency point. According to this, it is possible to share the load while maintaining the power generating means 40 at high efficiency.

The target setting value may be a predetermined fixed value or an arbitrary setting value set by the user. Moreover, when there are a plurality of power generation means, the power may be distributed according to the rated capacity ratio or a predetermined ratio. Furthermore, a dead zone or a hysteresis may be provided for the comparison/determination section in order to avoid fine increase/decrease operations.

In this way, for the energy storage device combining the power generation means 40 or the second energy storage device 20 and the AC bus charging/discharging power converter 23, priority is given so that the output power value becomes a predetermined set value. While instructing the power adjustment amount, it is possible to stably supply power even in a power system configured with a DC bus.

(effect)
According to the sixth embodiment, by concentrating the load on the power generating means connected to the AC bus, it is possible to operate at the optimum efficiency point. In addition, if the energy storage device or the power generation means is combined with the energy storage device, the system can be configured as the base power generation means, which facilitates the setting of the system configuration and equipment capacity.

<Seventh Embodiment>
(Constitution)
The configuration of the seventh embodiment is the same as those of the first to fifth embodiments, so the description is omitted.

(action)
As in the description of the first embodiment, the AC bus 50 is operated in parallel with the power generating means 40 and the AC/DC bus power converter 21, and the power sharing for supplying power to the power load 60 is the power adjustment of the controller 30. The controller 30 determines the power to be shared between the power generating means 40 and the AC/DC bus power converter 21, and increases or decreases each of them.

Here, the controller 30 preferentially instructs the power adjustment amount to be given to the power generation driving power converter 22 among the power adjustment amounts to be given to the AC/DC bus power converter 21 to be a predetermined amount.

FIG. 6 is a flow chart showing the operation of the controller 30 in the seventh embodiment. Steps (including setting values) that execute the same processes as those in FIGS. 4 and 5 are denoted by the same reference numerals, and description thereof is omitted.

The control unit 30 in the seventh embodiment controls the power generation drive power converter 22 based on the output power value (third output value) of the power generation drive power converter 22 detected by the third power detection means 33 . further includes an output determination unit that determines the output state of the .

As in FIG. 4, power increase/decrease operations are performed on the power generating means 40 and the AC/DC bus power converter 21 according to the determination results in steps 1A and 1C. After the power operation of the AC/DC bus power converter 21 is performed by the first power operation unit, the output determination unit of the controller 30 determines the power D (the output state of the power generation drive power converter 22), which is set in advance. The setting value 2, which is the target power setting of the power converter 22 for driving power generation, is compared (step 1F).

As a result of comparing the power D and the set value 2, if the power D is greater than the set value 2 (D>set value 2), the second power operation unit performs the power increase operation on the power generation driving power converter 22. (Step 1E1), if the power D is smaller than the set value 2 (D<set value 2), the power reduction operation is performed on the power converter 22 for power generation drive (step 1E2).

Also, when the power D and the set value 2 match (“=”), the second power operation unit does not perform the increase/decrease operation process.

According to this operation, in the output state in which the power increase/decrease operation is performed on the AC/DC bus power converter 21 according to the determination result of step 1C, the power indicated by the set value 2 is preferentially converted to power generation drive power conversion. device 22 can be instructed.

The target setting value may be a predetermined fixed value or an arbitrary setting value set by the user. In addition, a dead zone or hysteresis may be provided for the comparison/determination section in order to avoid fine increase/decrease operations.

In this way, while giving priority to the output of the power generation driving power converter 22 among the power adjustment amounts given to the AC/DC bus power converter 21, stable Power feeding can be performed.

(effect)
According to the seventh embodiment, by preferentially instructing the output power of the power generation drive power converter that recovers the rotating shaft energy with respect to the power adjustment amount that is instructed to the AC/DC bus power converter, Optimal efficiency operation is possible in the power system connected to

<Eighth Embodiment>
(Constitution)
The configuration of the eighth embodiment is the same as those of the first to fifth embodiments, so the description is omitted.

(action)
As in the description of the first embodiment, the AC bus 50 operates in parallel with the power generating means 40 and the AC/DC bus power converter 21, and the sharing of the power supplied to the power load 60 is the power adjustment amount of the controller 30. In accordance with the instruction, the controller 30 determines the power to be shared between the power generating means 40 and the AC/DC bus power converter 21, and increases or decreases each of them.

Here, among the command values given from the controller 30 to the AC/DC bus power converter 21, the command value given to the power generation drive power converter 22 is set to any of the minimum quantities including zero, that is, zero or a predetermined minimum quantity. directed by

FIG. 7 is a flow chart showing the operation of the controller 30 in the eighth embodiment. Steps (including setting values) that execute the same processes as those in FIGS.

The set value 2' of step 1F shown in FIG. 7 indicates that the target power setting of the power converter 22 for power generation drive is zero or the minimum amount setting. According to this flow, the operation is performed so that the output of the power converter 22 for driving power generation is zero or minimized. That is, it operates so that the first energy storage device connected in parallel with the DC bus 51 mainly consumes the load power.

The target setting value may be a predetermined fixed value or an arbitrary setting value set by the user. It may also be set according to the discharge state of the energy storage device. Furthermore, it may be set in accordance with the limit of the power recovered from the rotating machine shaft energy. In addition, a dead zone or hysteresis may be provided for the comparison/determination section to avoid fine increase/decrease operations.

In this manner, while setting the output of the power converter 22 for power generation drive to be zero or the minimum amount of the power adjustment amount given to the AC/DC bus power converter 21, stable power supply to both the AC bus and the DC bus is performed. It can be performed.

(effect)
According to the eighth embodiment, with respect to the power adjustment amount instructed to the AC/DC bus power converter, by instructing the output power of the power generation drive power converter that recovers the rotating shaft energy to be zero or the minimum amount, It is possible to prevent in advance that the storage amount of the energy storage device reaches its capacity limit and power sharing in the DC bus system cannot be performed. Also, it is possible to deal with the case where the rotating machine shaft energy cannot be recovered.

<Ninth Embodiment>
The configuration of the ninth embodiment is the same as those of the first to fifth embodiments, so the description is omitted.

(Action)
As in the description of the first embodiment, the AC bus 50 is operated in parallel with the power generating means 40 and the AC/DC bus power converter 21, and the power sharing for supplying power to the power load 60 is the power adjustment amount of the controller 30. , the controller 30 determines the power to be shared between the power generation means 40 and the AC/DC bus power converter 21, and increases or decreases each of them.

Here, the controller 30 preferentially instructs the amount of power adjustment to be given to the power converter 22 for power generation driving to be a predetermined amount. At the same time, the change rate and amount are interlocked so that the power adjustment amount given to the AC/DC bus power converter 21 is the same as the power adjustment amount given to the power generation drive power converter 22 .

At this time, since the power supply to the power load 60 is determined by the load sharing between the power generating means 40 and the AC/DC bus power converter 21, the power borne by the power generation drive power converter 22 and the power borne by the AC/DC bus power converter 21 are interlocked. If so, the power generating means 40 will cover the remaining power, and all will operate in conjunction with each other.

Incidentally, when the power supplied by the power generation means 40 becomes negative, it means that the power from the power generation means 40 is unnecessary, so the power generation means 40 may be stopped. In addition, even when the electric power supplied by the power generation means 40 is operated at a light load, the power generation efficiency is significantly reduced, so the power generation means 40 may be stopped.

When the power generating means 40 is stopped, power is supplied exclusively to the AC/DC bus power converter 21, and in the DC bus system, power is mainly supplied by the power converter 22 for power generation driving, and the first energy storage device 10 covers the shortfall. becomes.

FIG. 8 is a flow chart showing the operation of the controller 30 in the ninth embodiment. Steps (including setting values) that execute the same processes as those in FIGS.

The set value 3 in step 1F shown in FIG. 8 is a high power setting (rated) that can be recovered by the generator motor (rotating machine) 80 (shaft recovery target power setting 2) as the target power setting of the power converter 22 for driving power generation. indicates that there is According to this flow, according to the result of comparison between the electric power D and the set value 3 (step 1F), the power converter for power generation drive 22 is subjected to an increase/decrease operation process, and the output is mainly used (step 1E1, 1E2), and in conjunction with this, the AC/DC bus power converter output 21 is increased or decreased to change the output (steps 1D1, 1D2). The power shortage in the power load 60 connected to the AC bus 50 is based on the comparison result of the power A and the power B2 (the value obtained by subtracting the output of the power converter 22 for power generation driving of the DC bus 51 from the total load power) ( Step 1A), it is covered by the power generation means 40 by the increase/decrease operation processing for the power generation means 40 (steps 1B1 and 1B2). The total load power shown here is obtained by summing the power generators connected to the AC bus 51 . Alternatively, the power consumed by the load power 60 may be directly measured and calculated.

The target setting value may be a predetermined fixed value or an arbitrary setting value set by the user. It may also be set according to the discharge state of the energy storage device. Furthermore, it may be set in accordance with the limit of the power recovered from the rotating machine shaft energy. In addition, a dead zone or hysteresis may be provided for the comparison/determination section to avoid fine increase/decrease operations.

In this way, the AC/DC bus power converter 21 is operated interlocked while giving priority to the power converter 22 for power generation drive, and furthermore, the power that is insufficient for the power load 60 is supplied from the power generation means 40. Power can be supplied.

(effect)
According to the ninth embodiment, by concentrating the load on the power converter for power generation driving that recovers the rotating shaft energy in the DC bus and interlocking the AC/DC bus power converter connected to the AC bus, the main engine is connected to the rotating shaft. The system can be operated at the optimum efficiency point when devices that have a large effect on efficiency, such as a system, are connected.

In addition, depending on the power load connected to the AC bus, if the load can be covered by the AC/DC bus power converter, the power generating means and the energy storage device connected to the AC bus can be stopped, and efficiency can be improved. Furthermore, when the power generation means is composed of a diesel engine, it can contribute to the suppression of exhaust gas.

<Tenth Embodiment>
(Constitution)
The configuration of the tenth embodiment is the same as those of the first to fifth embodiments, so the description is omitted.

(action)
As in the description of the ninth embodiment, the AC bus 50 is operated in parallel with the power generating means 40 and the AC/DC bus power converter 21, and the power sharing for supplying power to the power load 60 is the power adjustment of the controller 30. The controller 30 determines the power to be shared between the power generating means 40 and the AC/DC bus power converter 21, and increases or decreases each of them.

Here, the controller 30 preferentially instructs the power adjustment amount to be given to the power generation drive power converter 22 to be a predetermined amount. At the same time, the amount of power adjustment to be given to the AC/DC bus power converter 21 is individually instructed according to the power generating means 40 or the power load 60 . According to this, while preferentially using the power converter 22 for power generation drive, the power to be shared by the power generating means 40 of the power load 60 and the AC/DC bus power converter 21 is individually instructed, so that the shortfall is corrected to the first level. The energy storage device 10 operates to provide.

FIG. 9 is a flow chart showing the operation of the controller 30 in the tenth embodiment. Steps (including set values) that execute the same processes as those in FIGS.

The set value 4 in step 1C shown in FIG. 9 is the target power setting for the AC/DC bus power converter output 21 . The flow shown in FIG. 9 is a modification of the ninth embodiment (FIG. 8). By performing the operation processing (steps 1E1 and 1E2), while mainly using the output of the power converter 22 for power generation drive, according to the result of comparing the power C and the set value 4 (step 1C), the AC/DC bus By performing a power increase operation on the power converter output 21 (steps 1D1 and 1D2), by operating the output of the AC/DC bus power converter 21 on the power load 60 connected to the AC bus 50, power generation A load sharing of the means 40 and the first energy storage device 10 can be provided.

The target setting value may be a predetermined fixed value or an arbitrary setting value set by the user. It may also be set according to the discharge state of the energy storage device. Furthermore, it may be set in accordance with the limit of the power recovered from the rotating machine shaft energy. In addition, a dead zone or hysteresis may be provided for the comparison/determination section to avoid fine increase/decrease operations.

In this way, by manipulating the output of the AC/DC bus power converter 21 while preferentially instructing the power to be supplied to the power converter 22 for power generation drive, the power load 60 connected to the AC bus 50 is depleted. Electric power can be supplied while sharing the electric power generated by the power generation means 40 and the first energy storage device 10 connected to the DC bus 51 .

(effect)
According to the tenth embodiment, by concentrating the load on the generator drive power converter that recovers the rotating shaft energy in the DC bus, the equipment that is greatly affected by the efficiency, such as the main engine connected to the rotating shaft, can be adjusted to the optimum efficiency point. In addition, by controlling the sharing of the AC power load between the power generating means and the AC/DC bus power converter, it is possible to operate at the optimum efficiency point.

<Eleventh Embodiment>
(Constitution)
The configuration of the eleventh embodiment is the same as that of the first to fifth embodiments, so the description is omitted.

(action)
As in the description of the first embodiment, the AC bus 50 is operated in parallel with the power generating means 40 and the AC/DC bus power converter 21, and the power sharing for supplying power to the power load 60 is the power adjustment of the controller 30. The controller 30 determines the power to be shared between the power generating means 40 and the AC/DC bus power converter 21, and increases or decreases each of them.

Here, in the amount of power adjustment given from the controller 30 to the power generation means 40, the AC/DC bus power converter 21, and the power generation drive power converter 22, the passing power of the first energy storage device 10 is zero (both charging and discharging). do not). In fact, it may not be completely zero due to response delay of the controller or detection error.

FIG. 10 is a flow chart showing the operation of the controller 30 in the eleventh embodiment. Steps (including setting values) that execute the same processes as those in FIGS.

The set value 5 in step 1A shown in FIG. 10 indicates the target power setting of the power generation means 40,
It is a value set so that total load power=output of power generating means 40+output of power converter 22 for driving power generation. According to this flow, the power passing through the AC/DC bus power converter 21 becomes equal to that of the power generation drive power converter 22, and the first energy storage device 10 (battery) does not charge/discharge (charge/discharge amount changes). not).

The target setting value may be a predetermined fixed value or an arbitrary setting value set by the user. It may also be set according to the discharge state of the energy storage device. Furthermore, it may be set in accordance with the limit of the power recovered from the rotating machine shaft energy. In addition, a dead zone or hysteresis may be provided for the comparison/determination section to avoid fine increase/decrease operations.

In this manner, by manipulating the target power setting of the power generating means 40, it is possible to create a state in which no power passing through the first energy storage device 10 is generated.

(effect)
According to the eleventh embodiment, the power of the energy storage device can be effectively used when it is desired to conserve it. In addition, when the energy storage device is disconnected during operation for maintenance, the passing current can be made zero (small), and the circuit breaker and the switch can be easily disconnected.

In this way, according to the energy management system of the present embodiment, in the electric power system composed of the AC bus 50 and the DC bus 51 connected by the power converter, by realizing a DC change linked to the load fluctuation, A stable power supply system can be provided. In addition, it becomes possible to optimize by changing the load to be aggregated according to the state of the power generation means and the energy storage device.

It should be noted that the present invention is not limited to the above-described embodiments as they are, and can be embodied by modifying constituent elements without departing from the gist of the present invention at the implementation stage. Also, various inventions can be formed by appropriate combinations of the plurality of constituent elements disclosed in the above embodiments. For example, some components may be omitted from all components shown in the embodiments. Furthermore, components across different embodiments may be combined as appropriate.

REFERENCE SIGNS LIST 10 first energy storage device 20 second energy storage device 21 AC/DC bus power converter 22 power generation drive power converter 23 AC bus charging/discharging power converter 24 power generation means 30 controller 31 first power detection means 32 second power Detection means 33 Third power detection means 40 Power generation means (main power generator)
45 Plug-in electric circuit 50 AC bus 51 DC bus 60 Power load 70 Main machine 80 Generator motor 90 Rotating load machine 110 First power storage device 120 Second power storage device 121 First power converter 122 Second power converter 123 Third power Converter 124 Fourth Power Converter 130 Control System 140 Main Generator 150 AC Onboard Bus 151 DC Intermediate Bus 160 Onboard Power Load 170 Main Engine 180 Propulsion Motor Generator 190 Propeller 210 Energy Storage Means 221 Power Converter 222 Starter 230 Second 1 switching means 231 second switching means 232 third switching means 240 main generator 250 AC onboard bus 260 first onboard power load 261 second onboard power load 262 third onboard power load

Claims (11)

an AC bus composed of the output of the power generating means;
a first power detection means for detecting the output of the power generation means;
a DC bus configured with a DC power source as a power source;
a power converter for power generation drive connected to a generator motor for driving and braking a rotating machine shaft using the DC power supply as a power source;
an AC/DC bus power converter that connects the AC bus and the DC bus and converts power bidirectionally;
a second power detection means for detecting the output of the AC/DC bus power converter;
The first output value detected by the first power detection means and the second output value detected by the second power detection means are inputted to determine the power sharing amount of the power of the AC bus and the power of the DC bus. and a controller for instructing a power adjustment amount to each of the power generation means, the power converter for driving power generation, and the AC/DC bus power converter,
An energy characterized in that, when the output of the power generation means and the AC section of the AC/DC bus power converter are operated in parallel, the power adjustment amount to be given to the power generation driving power converter is linked to the AC/DC bus power converter. management system. 2. An energy management system according to claim 1, wherein said power generating means comprises an energy storage device and a charging/discharging power converter. 3. The energy management system according to claim 1, wherein the amount of power adjustment instructed by said controller is given by a pulse signal. 3. The energy management system according to claim 1, wherein the power adjustment amount instructed by the controller is given by a continuous signal corresponding to the power. The energy management system according to any one of claims 1 to 4, further comprising third power detection means for detecting the output of the AC/DC bus power converter and inputting a detected power signal to the controller. An energy management system according to the above configuration, wherein a power adjustment amount to be given to the power converter for driving power generation instructed by the controller is set in proportion according to the number of devices connected to the DC bus. 6. The energy management system according to any one of claims 1 to 5, wherein a power adjustment amount to said power generating means instructed by said controller is preferentially set. 5. The energy management system according to any one of claims 1 to 4, wherein the amount of power adjustment to be given to said power generation drive power converter among the power adjustment amounts to be given to said AC/DC bus power converter instructed by said controller. An energy management system characterized by preferentially setting 5. The energy management system according to any one of claims 1 to 4, wherein the power adjustment amount to be given to the power generation drive power converter among the power adjustment amounts to be given to the AC/DC bus power converter instructed by the controller is , is set to a minimum amount including zero. 5. The energy management system according to any one of claims 1 to 4, wherein a power adjustment amount given to said power generation driving power converter instructed by said controller is preferentially set, and said power generation driving power converter 2. An energy management system, characterized in that a power adjustment amount to be applied to a power converter and a power adjustment amount to be applied to the AC/DC bus power converter are interlocked. 10. The energy management system according to claim 9, wherein the amount of power adjustment given to said AC/DC bus power converter instructed by said controller is changed according to the load. 5. The energy management system according to any one of claims 1 to 4, wherein the power adjustment amount instructed by the controller is adjusted so that the charge/discharge amount of the battery connected to the DC bus does not change. and an energy management system, wherein the power converter for driving power generation is allocated and set.

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