JP6426014B2 - Bidirectional inverter and storage system using the same - Google Patents

Description

  The present invention relates to a bidirectional inverter for a storage system and a storage system using the same.

  FIG. 9 is a basic configuration diagram of a conventional power storage system. As shown in FIG. 9, the AC input / output side of bidirectional inverter Y is connected to an AC system power line (hereinafter simply referred to as “AC system”) 1 connecting electric power system 2 and load 3. The output side is connected to the storage battery 5 via a DC power line (hereinafter simply referred to as “DC system”) 4.

  Received power P1 is supplied from power system 2 in AC system 1; load power P2 is supplied from AC system 1 to load 3; reversely supplied from AC system 1 to power system 2 The tidal power P8. Power running power P3 is taken from the AC system 1 side of the bidirectional inverter Y, and regenerative electric power P7 is sent from the bidirectional inverter Y to the AC system 1 side. Further, the charging power P4 is supplied from the DC system 4 to the storage battery 5, and the discharging power P5 is supplied from the storage battery 5 to the DC system 4.

  This storage system is a general storage system in which the storage battery 5 is connected to the direct current side of the bidirectional inverter Y but a DC power supply such as a solar power generation device is not connected. In such a storage system, the following two control methods are generally used to control the powering operation and the regenerative operation of the bidirectional inverter Y.

(1) As an example when it is desired to control the power of the alternating current system 1 side, the bidirectional inverter Y is used while the storage battery SOC (State of Charge) falls within a predetermined range (for example, 10 to 90%). Power running and regenerative output as needed, such as peak shift and peak cut. In general, the true SOC can not be observed directly during charging and discharging. For this reason, although the charge and discharge current is integrated to calculate the SOC, the SOC calculated in this manner is not an accurate value, and control for reliably preventing overcharge and overdischarge can not be performed. Therefore, overcharge and overdischarge are prevented by observing the storage battery voltage instead of the charge and discharge current. Specifically, charging is stopped when storage battery voltage V _bat reaches charge inhibition voltage V _Cupp (not shown) during power running operation, and discharge inhibition voltage V _Dlow (not shown) is reached during regeneration operation. Stop the discharge when you do.

In more advanced systems, as shown in FIG. 10, several steps are provided for the command value of the charging power P4, and the limit power is changed stepwise (FIG. 10 shows the case of the upper limit variable). In this case, in a state where storage battery voltage _Vbat is rising with the progress of charging, charging power P4 (力 power running power P3) is lowered stepwise by one step (time t41). Then, the storage battery voltage V _bat also drops in a step-like manner by the function of the internal resistance of the storage battery 5 according to that. The reason for changing the command value of charging power P4 stepwise is to approach the target SOC (which correlates with the storage battery voltage when not being charged and discharged but does not know the correct value when charging and discharging) while preventing overcharging. This is not to stop the power running operation, but to continue charging even after a step-like decrease. Therefore, the remaining battery charge SOC continues to rise with the gradient made gentle. Such an operation is repeated several times as time elapses (time t42, t43), charging power P4 decreases stepwise in several steps, and storage battery voltage V _bat also repeatedly decreases rapidly and resumes rising stepwise. .

As described above, in the method (1), while monitoring the storage battery voltage V _bat , the battery voltage V _bat is output when it can be output, and is stopped when it can not be output, or the output is narrowed stepwise. As a result, it is possible to perform charging in a range that does not lead to overcharging in the storage battery 5. However, in the case of control to stop charging when the charge inhibition voltage is reached, charging is stopped before reaching the target SOC, so the storage battery capacity can not be effectively utilized. In the case of control that changes the limit power in stages, although the storage battery capacity can be used more effectively, the setting of the command value of the charging power P4 is accompanied by the complexity due to the stepwise control and the fluctuation of the charging power P4 is Unavoidable.

  In the case of the regenerative operation, the waveform diagram of FIG. 10 is shifted in the form just inverted around the horizontal axis, and the same problem as described above occurs at this time for the discharge power P5 and the regenerative power P7.

(2) If you want to control the value of storage battery voltage V _bat accurately, CCCV (C Control is performed using the onstant Current Constant Voltage method. This monitors the storage battery voltage _Vbat , and when the target voltage (generally correlated with the SOC) is reached, the constant voltage is maintained by throttling the charge / discharge current. In this case, since the control for _fixing the storage battery voltage _Vbat is central (full-time), accurate control of the values of desired powering power P3 and regenerative power P7 on the AC system 1 side, such as peak shift and peak cut Will not be able to The peak shift operation refers to an operation mode in which the storage battery is charged and discharged at a designated time in the state of power supply from the electric power system to the load. For example, by setting the charging time to night and setting the discharging time to daytime for load leveling, late-night power can be effectively used and daytime received power can be reduced. In addition, peak cut operation refers to an operation mode in which when the power consumption of the load exceeds a set value, the excess power is covered by discharge from the storage battery.

  FIG. 11 shows a conventional power storage system in which a DC power supply 6 such as a solar power generator is additionally connected to a DC system 4 connecting the bidirectional inverter Y and the storage battery 5 in the power storage system of FIG. In the storage system to which this DC power supply is connected, overcharging / overdischarging of storage battery 5 is prevented while controlling powering power P3 and regenerative power P7 on the AC system 1 side, and maximum charging / discharging of storage battery 5 (hunting If the battery capacity SOC is fully utilized up to the upper limit or lower limit without causing the problem, the following problems occur.

[1] In a system in which a DC power supply is not connected, bi-directional inverter Y can be used to continue to use storage battery voltage V _bat when discharge to discharge inhibiting voltage V _Dlow is performed in storage battery 5. There is no choice but to charge the battery. However, in the system to which the DC power supply 6 is connected, the storage battery 5 can be charged by the generated power P6 of the DC power supply 6 even without powering with the bidirectional inverter Y, so discharge can be performed again. . That is, it is possible to continue to regenerate the bidirectional inverter Y intermittently.

In this case, as shown in FIG. 12, when the discharge due to regeneration exceeds the charge due to power generation, storage battery voltage V _bat gradually decreases, and when discharge inhibition voltage V _Dlow is reached (time t51), regeneration is stopped. . Then, the storage battery voltage V _bat starts rising again due to charging by power generation. As a result of charging, when the storage battery voltage V _bat rises and reaches the discharge inhibition release voltage V _Dupp (time _t52 ), regeneration is started again. When the above operation is repeated, hunting occurs in the regenerative electric power P7 in accordance with the up and down movement of the storage battery voltage _Vbat . Therefore, in order to prevent or reduce such hunting of the regenerative power P7, it is necessary to appropriately provide hysteresis or an operation delay in the determination of discharge resumption. However, the setting to be able to cope with various and complicated fluctuations in the entire system is extremely difficult, and the practical solution for suppressing hunting occurrence is difficult. The cause is that the control mode is switched according to the result of the threshold determination, but the switching is repeated. In order to achieve the above-described purpose, while the control mode becomes unstable such as causing hunting, addition of various control elements is required to prevent hunting, and complication of the control mode is avoided. It has become impossible.

[2] In the storage system to which the DC power supply is not connected, there is no particular problem even if the bidirectional inverter Y is stopped until the next discharge is desired after charging up to the charge inhibition voltage V _Cupp . However, in the storage system to which the DC power supply 6 is connected, when the bidirectional inverter Y is stopped, the generated power P6 is wasted. In other words, when the storage battery 5 is not fully charged when the DC power supply 6 is generating power when the bidirectional inverter Y is stopped, the generated power P6 can be stored in the storage battery 5, but if the storage battery 5 is fully charged For example, the generated power P6 can not be used. Therefore, when it is not desired to waste the generated power P6, it is necessary to continuously operate the bidirectional inverter Y by some method to regenerate the generated power P6 by the DC power supply, but for that purpose, a special countermeasure is required.

As shown in FIG. 13, when the storage battery voltage V _bat reaches the charge inhibition voltage V _Cupp while the storage battery voltage V _bat is rising due to the generated power P 6 (time t 61), the output of the regenerative power P 7 is resumed. . Here, although the same amount of power as the generated power P6 is regenerated, the storage battery voltage V _bat starts to slightly decrease because of the conversion loss. When the storage battery voltage V _bat drops to the charge inhibition release voltage V _Clow (time t62), the output of the regenerative power P7 is stopped again, and as a result, the storage battery voltage V _bat resumes rising due to the generated power P6. That is, since the above operation is repeated, hunting occurs in the regenerative power P7. Therefore, in order to prevent or reduce such hunting of the regenerative electric power P7, it is necessary to appropriately provide hysteresis or an operation delay in the determination of discharge resumption as in the case of [1]. However, it is extremely difficult to cope with various complex fluctuations in the entire system, as described above, regarding the determination of regeneration start and the setting value of regenerative power P7, and it becomes difficult to solve practically a hunting solution. There is.

[3] CCCV (Constant Current Constant Voltage) control may be used to accurately control the storage battery voltage V _bat and discharge it to the discharge inhibition voltage V _Dlow and charge it to the charge inhibition voltage V _Cupp . However, this would make it impossible to control the AC side power as described above.

A specific operation example will be described with reference to FIG. The control is not to control the charge / discharge power through several steps for simplification but to control to stop the charge / discharge when the threshold is exceeded, but it is essentially the same. While generating electric power with the DC power supply 6, in the regenerative operation mode of the bidirectional inverter Y, a constant regenerative electric power P7 larger than the generated electric power P6 is output. Then, in the state where the detected value of storage battery voltage V _bat gradually decreases, when discharge inhibition voltage V _Dlow is reached (time t71), bidirectional inverter Y once completely stops regenerative operation itself. As a result, the regenerative electric power P7 sharply decreases to zero level. Then, the detected value of storage battery voltage _Vbat sharply rises due to the action of the internal resistance, and since the regenerative operation has already stopped, the detected value of storage battery voltage _Vbat gradually rises due to charging from DC power supply 6. Then, when the detected value of storage battery voltage V _bat rises to discharge inhibition release voltage V _Dupp (time t72), the regenerative operation which has been stopped until then is resumed, and the regenerative power P7 suddenly rises to the desired power value, The detected value of storage battery voltage V _bat falls rapidly. Again the detected value of the battery voltage V _bat reaches discharge inhibition voltage V _Dlow (time t73), the regenerative operation is stopped once fully again, the detected value of the battery voltage V _bat is soaring inverted. Since the above operation is repeated, hunting occurs in the regenerative power P7. Further, if appropriate hysteresis is not provided in the response reaction, immediately after time t71, the detected value of the storage battery voltage V _bat repeatedly travels between the discharge inhibition voltage V _Dlow and the discharge inhibition release voltage V _Dupp. Can cause hunting. Further, even if the discharge inhibition release voltage V _Dupp is set to be high to provide an appropriate hysteresis, the hunting itself can not be prevented although it has the effect of prolonging the hunting cycle. Such hunting is performed by switching the operation mode instantaneously and explicitly in response to the result of comparing and detecting the detected value of storage battery voltage V _{bat with} the threshold value of discharge inhibition voltage V _Dlow and discharge inhibition release voltage V _Dupp. Attributable to

  As described above, in the conventional method, when the detection value of the voltage state of each part and the detection value of the current state are compared with the threshold value of each comparison standard and the determination condition is met, switching of the operation mode, that is, digital Switching control was performed. In addition, in order to utilize the maximum charge and discharge of the storage battery while preventing overcharge and overdischarge, it is necessary to appropriately provide hysteresis and operation delay considering the entire system, but such a setting is realistic. It was difficult and practically impossible to solve it.

  The present invention has been made in view of such circumstances, and in a storage system to which a DC power supply such as solar power generation is connected, the maximum charge and discharge of a storage battery can be achieved while preventing overcharge and overdischarge of the storage battery. The purpose is to make it available.

  The present invention solves the above-mentioned problems by taking the following measures.

The bidirectional inverter for the storage system according to the invention is
A bidirectional inverter including an inverter control unit that performs powering and regeneration control between an AC system connected to a power system and a load and a DC system connected to a storage battery and a DC power supply,
A variable power running limiter capable of changing a variable power running limit value to a power command value according to an optimum power running limit value, and a variable regenerative limiter capable of changing a variable regeneration limit value to the power command value according to an optimum regeneration limit value Power running and regenerative power limit control means having
Continuously changing in real time determined so as to fall within the range defined by the variable power running limit value and the variable regeneration limit value corresponding to the detected value reflecting the change in the operating condition on the AC system side and the DC system side Optimal powering limit value determining means for determining the optimal powering limit value and feeding back the optimal powering limit value to the variable powering limiter.
Continuously changing in real time determined so as to fall within the range defined by the variable power running limit value and the variable regeneration limit value corresponding to the detected value reflecting the change in the operating condition on the AC system side and the DC system side Optimal regenerative limit value determining means for determining the optimal regenerative limit value and feeding back the optimal regenerative limit value to the variable regenerative limiter;
The electric power command value limited by the optimal powering limit value and the optimal regeneration limit value is sent to the inverter control unit.

  In the above configuration, the variable powering limit value is changed in real time to the optimum state in real time according to the optimum powering limit value given from the optimum powering limit value determining means to the variable powering limiter in the powering and regenerative power limit control means The variable regeneration limit value is changed to the optimum state in real time according to the optimum regeneration limit value given from the optimum regeneration limit value determining means to the formula regeneration limiter, and the obtained final power command value is sent out to the inverter control unit. Here, the optimum powering limit value and the optimum regeneration limit value given as feedback signals are both narrowed down to the critical limit and continuously change. Therefore, even if the storage battery is charged and discharged to the full upper and lower limits, the control operation does not cause hunting, and it is possible to realize the maximum charging and discharging while preventing overcharging and overdischarging of the storage battery. Become. Therefore, it becomes possible to realize seamless and stable powering control and regeneration control for the storage battery without interference from other various types of power.

Bi-directional inverter for the power storage system according to the present invention, in the above configuration, that is configured further in the following manner.
The optimum powering limit value determining means applies the upper limit and the lower limit to the deviation of the detected value of the storage battery voltage from the charge inhibition voltage with respect to the first limit value as a result and the command value of the powering power from the bidirectional inverter. Configured to select a minimum limit value from among one or more second limit values as a result of applying the upper limit limit, and outputting the selected value as the optimum power running limit value,
The optimum regeneration limit value determining means applies a fourth limit value as a result of applying the upper and lower limits to the deviation of the detected value of the storage battery voltage from the discharge inhibition voltage and the command value of the regenerative power from the bidirectional inverter. It is characterized in that the maximum limit value is selected from among one or more fifth limit values as a result of applying the lower limit limit, and the maximum limit value is output as the optimum regeneration limit value .

  In the configuration of this aspect, the first limit value obtained by applying the upper and lower limits to the deviation of the detected value of the storage battery voltage with respect to the charge inhibition voltage is mainly used to prevent overcharging of the storage battery. Further, the second limit value obtained by applying the upper limit to the command value of the powering power from the bidirectional inverter is used to prevent the powering power from exceeding the following power value. Specifically, it is used to ensure that the charging power for the storage battery does not exceed the maximum charging power value of the storage battery, or that the received power from the power system does not exceed the maximum received power value.

  Further, a fourth limit value obtained by applying the upper and lower limits to the deviation of the detected value of the storage battery voltage with respect to the discharge inhibition voltage is mainly used to prevent overdischarge of the storage battery. The fifth limit value, which is the result of applying the lower limit to the command value of the regenerative power from the bidirectional inverter, is used to prevent the regenerative power from exceeding the following power value. Specifically, it is used to prevent reverse flow power to the power system from exceeding the reverse flow limit power value.

  That is, since a limit is applied to the deviation of the storage battery voltage with respect to the charge inhibition voltage, it is possible to prevent overcharging of the storage battery. Further, since a limit is applied to the deviation of the storage battery voltage with respect to the discharge inhibition voltage, it is possible to prevent overdischarge in the storage battery.

Bi-directional inverter for power storage system of another arrangement according to the invention constitutes a contact Keru the optimum power running limit value determining means and the optimum regeneration limit value determining means to the arrangement as follows.

About the said optimal powering limit value determination means,
First subtraction means for calculating a deviation between the charge inhibition voltage and the detected value of the storage battery voltage;
A first limiter which applies upper and lower limits to the output of the first subtracting means and outputs a first limit value candidate;
Second subtracting means for calculating a deviation between the maximum charge power value and the detected value of the generated power;
A second limiter which applies an upper limit to the output of the second subtracting means and outputs a second limit value candidate;
Third subtraction means for calculating a deviation between the maximum received power value and the detected load power value;
A third limiter which applies an upper limit to the output of the third subtracting means and outputs a third limit value candidate;
Wherein selects the smallest one from among the first to third limit value candidate, it is configured to have a minimum value selection means for outputting as said optimum power running limit value.

Moreover, about the said optimal regeneration limit value determination means,
A fourth subtraction means for calculating a deviation between the discharge inhibition voltage and the detected value of the storage battery voltage;
A fourth limiter which applies an upper and lower limit to the output of the fourth subtracting means and outputs a fourth limit value candidate;
Fifth subtraction means for calculating a deviation between the reverse flow limit power value and the detected value of the load power;
A fifth limiter which applies a lower limit to the output of the fifth subtracting means and outputs a fifth limit value candidate;
Select the maximum one from among the fourth to fifth limit value candidate, is configured to have a maximum value selection means for outputting as the optimum regeneration limit value.

  The minimum value selecting means and the maximum value selecting means respectively select the smallest one and the largest one from the plurality of limit value candidates, and use them as the optimum powering limit value and the optimum regeneration limit value of the obtained result. Each of the plurality of limit value candidates is continuously generated in real time. When one limit value candidate crosses another limit value candidate in the magnitude relationship, and the smallest or largest one switches from one limit value candidate to another limit value candidate, Therefore, the smallest ones and the largest ones become continuous ones (connected seamlessly) (see FIG. 8).

  Therefore, similar to the above, even if the storage battery is charged and discharged to the full upper and lower limits, the control operation does not cause hunting, and maximum charging and discharging is realized while preventing overcharging and overdischarging of the storage battery. It is possible to realize seamless and stable power running control and regeneration control for the storage battery without interference from various other electric powers.

  The storage system according to the present invention has a configuration in which any one of the bidirectional inverters described above is interposed between an AC system connected to a power system and a load, and a DC system connected to a storage battery and a DC power supply.

  According to the present invention, overcharging and overdischarging of the storage battery can be prevented while enabling charging and discharging of the storage battery to the full upper and lower limits against various and complicated fluctuations in the entire storage system, as in the prior art By eliminating step-like fluctuation of the direction inverter output, hunting of the control operation can be prevented. That is, as in the prior art, addition of various control elements for preventing hunting caused by switching of the control mode according to the result of threshold determination, and switching control for preventing overcharge / overdischarge It can be unnecessary.

Basic configuration diagram of a power storage system to which the bidirectional inverter of the present invention is applied Basic configuration diagram showing an example of the basic configuration of the bidirectional inverter of the present invention A configuration diagram showing in more detail the configurations of the optimum powering limit value determining means and the optimum regeneration limit value determining means in the configuration of FIG. 2 A configuration diagram of an embodiment showing in more detail the configurations of the optimum powering limit value determining means and the optimum regeneration limit value determining means in the configuration of FIG. 3 A waveform chart showing the operation of the regenerative operation of the bidirectional inverter for the storage system of the embodiment of the present invention A waveform chart showing the operation of the regenerative operation of the bidirectional inverter for the storage system of the embodiment of the present invention The wave form diagram which shows the operation | movement when solving a subject in the bidirectional | two-way inverter for the electrical storage system of the Example of this invention The wave form diagram which shows the operation | movement when solving a subject in the bidirectional | two-way inverter for the electrical storage system of the Example of this invention Basic configuration diagram of conventional DC power supplyless type storage system A waveform chart showing the operation of the conventional power running operation Basic configuration diagram of a conventional power storage system additionally connected with a DC power supply A waveform chart showing the operation of the conventional regenerative operation corresponding to FIG. A waveform chart showing the operation of the conventional regenerative operation corresponding to FIG. A waveform chart showing the problem of the conventional example corresponding to FIG.

  Hereinafter, embodiments of a bidirectional inverter for a storage system to which a DC power supply is connected according to the present invention and a storage system to which the bidirectional inverter is applied will be described.

  FIG. 1 is a schematic configuration diagram of a storage system to which a DC power supply is connected, to which the bidirectional inverter of the present invention is applied. FIG. 2 is a basic configuration diagram showing an example of a basic configuration of the bidirectional inverter of the present invention. .

  In FIG. 1, 1 is an AC system connected to the electric power system 2 and the load 3, 4 is a DC system connected to the storage battery 5 and the DC power supply 6, and X is powering and regeneration between the AC system 1 and the DC system 4. Is a bidirectional inverter that controls the Here, the DC power supply 6 is configured to include two solar power generation devices independently controlled as an example. Each solar power generation device includes a solar cell and a step-up chopper. However, the DC power supply 6 may be a DC power supply other than a solar power generation device. Moreover, the number is arbitrary, and a plurality of types may be combined (details will be described later). The present invention may be applied to a storage system to which a DC power supply configured as shown in FIG. 11 is connected.

  The AC system 1 receives the received power P1 from the power system 2 and supplies the received power P1 to the load 3 as load power P2. In the power running mode, the bidirectional inverter X performs AC-DC conversion on the power of the AC system 1 and supplies it to the DC system 4 side. At this time, the power supplied from the AC system 1 is the powering power P3. The power driven to the DC system 4 by the bidirectional inverter X is supplied to the storage battery 5 as charging power P4. In the regenerative operation mode, the bidirectional inverter X causes the storage battery 5 to perform discharge, performs DC-AC conversion on the discharge power P5 generated on the DC system 4, and supplies it to the AC system 1 side. Further, the bidirectional inverter X DC-AC converts the generated power P6 generated by the DC power supply 6 and supplies it to the AC system 1 side. The power provided to the AC system 1 in the regenerative operation mode is the regenerative power P7. When regenerative electric power P7 is sent to electric power system 2 in AC system 1, the electric power becomes reverse flow electric power P8.

  In FIG. 2 showing the configuration of bidirectional inverter X, bidirectional inverter X controls inverter control unit 11 in addition to inverter control unit 11 described above interposed between AC system 1 and DC system 4. As components of the control unit 10, a power running / regenerative power limit control means 10, an optimum power running limit value determining means 20, and an optimum regeneration limit value determining means 30 are provided.

  The powering / regenerative power limit control means 10 has a variable powering limiter 10A and a variable regenerative limiter 10B. In the illustrated example, the variable power limiter 10A is located at the front stage, and the variable regeneration limiter 10B is located at the rear stage, but the positional relationship may be reversed.

The variable power running limiter 10A receives the power command value P _ip and the optimal power running limit value BL _pow as inputs. The optimum powering limit value BL _pow reflects the change in operating conditions in AC system 1 and DC system 4 in real time, and optimizes the powering limit for electric power command value P _{ip in} real time according to the aforementioned change in operating conditions. Function (optimized adjustment function of variable power running limit value L _pow ). The optimum powering limit value BL _pow is generated by the optimum powering limit value determining means 20. The optimization of the powering limit performed by the optimum powering limit value determining means 20 may be automated according to the switching of the operation mode at the design stage of the bidirectional inverter X, or the user may optionally give an instruction. It may be possible to Variable powering limiter 10A changes variable powering limit value L _pow with respect to electric power command value P _ip according to optimum powering limit value BL _pow while reflecting the change in operating conditions in AC system 1 and DC system 4 in real time. That is, when the operating condition is a steady state, variable power running limit value L _pow , which is the upper limit value (upper limit), is 1.0 [pu] (per-in unit method notation (notation with relative value to reference value) unit), but when it is out of the steady state, it changes to a level smaller than 1.0 [pu] (value varies depending on the situation). Also, when it is larger than 1.0 [pu], it is forcibly fixed to 1.0 [pu]. Accordingly, when it is determined that the driving condition is excessive (too large), the upper limit value is suppressed to a smaller value, and excessive responsiveness, that is, hunting is suppressed.

On the other hand, the variable regeneration limiter 10B receives the power command value P _ip ′ from the variable power running limiter 10A and the optimum regeneration limit value BL _reg . The optimum regeneration limit value BL _reg reflects the change in operating conditions in AC system 1 and DC system 4 in real time, and the regeneration limit for power command value P _ip ′ is optimized in real time in accordance with the above change in operating conditions. It has a function to control (optimization adjustment function of variable regeneration limit value _Lreg ). The optimal regeneration limit value BL _reg is generated by the optimal regeneration limit value determining means 30. The optimization of the regeneration limit performed by the optimum regeneration limit value determining means 30 may be automated according to the switching of the operation mode at the design stage of the bidirectional inverter X, or the user arbitrarily gives an instruction. It may be possible to The variable regeneration limiter 10B changes the variable regeneration limit value L _reg with respect to the electric power command value P _ip 'according to the optimum regeneration limit value BL _reg while reflecting the operation situation change in the AC system 1 and the DC system 4 in real time. . That is, if the operating condition is in the steady state, the variable regeneration limit value L _reg which is the lower limit (lower limit) is −1.0 [pu], but when it is out of the steady state Change to a higher level (the value may differ depending on the situation). In addition, when it is smaller than -1.0 pu, it is forcibly fixed to -1.0 pu. As a result, when the power command value P _ip is determined to be too small (too small) in the driving situation, the lower limit value is suppressed to a smaller value, and excessive responsiveness, that is, hunting is suppressed.

  Next, the operation of the bidirectional inverter X for a storage system to which the DC power supply of this embodiment configured as described above is connected will be described.

  To conclude, this bi-directional inverter X makes it possible to perform the transition of the operation mode seamlessly (in an uninterrupted state / consistent / unified state). A change is made in the operation mode, but there is no need to perform the respective threshold determination and the accompanying digital switching of the control signal (so that the operation mode changes to another mode), and it is gentle each time The mode of operation changes seamlessly with various transitions. Thus, hunting can be prevented.

The control in the powering / regenerative power limit control means 10 for generating the final power command value P _op which is finally fed into the inverter control unit 11 is the powering limit for the power command value P _ip by the variable power limiter 10A. The value (upper limit value) L _pow is changed, and the regeneration limit value (lower limit value) L _reg with respect to the power command value P _ip is changed by the variable regeneration limiter 10 _{B. The} optimum powering limit value used for the change control The BL _pow and the optimal regeneration limit value BL _reg are generated by the optimal powering limit value determination means 20 and the optimal regeneration limit value determination means 30, respectively.

Since the variable power running limiter 10A and the variable regenerative limiter 10B change the variable power running limit value L _pow and the variable regeneration limit value L _reg with respect to the power command value P _ip independently of each other, in other words, they simply Since it is only a transition to increase or decrease the aperture ratio (see FIG. 8), it is intrinsically different from the prior art in which digital switching (such as changing the operation mode to another mode) is performed. Switching the upper limit value / lower limit value of the limit control for the power command value P _ip under seamless (continuous) and gentle change.

There are various control elements for preventing overcharge and overdischarge of the storage battery 5 and maximizing utilization of the storage battery SOC. Particularly important control elements are the storage battery voltage V _bat . From a command value, a command value of powering power P3 to be sent to storage battery 5 from AC system 1 connected with power system 2 and load 3 via bidirectional inverter X, from DC system 4 connected with storage battery 5 and DC power supply 6 It is a command value of regenerative electric power P7 sent to alternating current system 1 via bidirectional inverter X. These command values are adjusted based on various detection signals for feedback control detected in real time. It is important that the power command value P _ip be adjusted in response to such real time adjusted signals. That is, when the power command value P _ip is input, upper and lower limit values are set in real time.

That is, instead of transmitting the power command value P _ip to the inverter control unit 11 as it is, the power running / regenerated power limit control means 10 is interposed. In the powering / regenerative power limit control means 10, upper and lower limits are set by the variable powering limiter 10A and the variable regenerative limiter 10B with respect to the input power command value _Pip , and the obtained final power command The value P _op is sent to the inverter control unit 11.

In the above configuration, the optimum powering limit value determining means 20 is determined corresponding to the detected value within the range of the maximum powering / regenerative power value in order to realize desired operation characteristics for the powering control operation by the bidirectional inverter X. Generate the optimal power-running limit value BL _pow . Here, how to generate the optimum powering limit value BL _pow is not particularly limited. There are various control modes depending on the aspect of the storage system to which the DC power supply is connected, but the control modes may be determined appropriately according to the needs of each. Then, the optimum powering limit value BL _pow is fed back to the variable powering limiter 10A in the powering and regenerative power limit control means 10.

On the other hand, the optimum regeneration limit value determination means 30 is an optimum determined corresponding to the detected value within the range of the maximum power running / regenerative power value in order to realize desired operation characteristics for the regeneration control operation by the bidirectional inverter X. Generate regeneration limit value BL _reg . Here, how to generate the optimum regeneration limit value BL _reg is not particularly limited. There are various control modes depending on the aspect of the storage system to which the DC power supply is connected, but the control modes may be determined appropriately according to the needs of each. Then, the optimum regeneration limit value BL _reg is fed back to the variable regeneration limiter 10 B in the power running / regeneration power limit control means 10.

The feedback of the above-described optimal powering limit value BL _pow and optimal regenerative limit value BL _reg is independent of each other and occurs in principle separately in terms of timing, but may occur simultaneously in some situations.

As described above, the bidirectional inverter X for a storage system to which the DC power supply of the embodiment of the present invention is connected is
(1) A powering / regenerative power limit control means 10 having a variable powering limiter 10A capable of changing the variable powering limit value L _pow and a variable regenerative limiter 10B capable of changing the variable regenerative limit value _Lreg.
(2) Optimal powering limit value determining means 20 for feeding back the optimal powering limit value BL _pow obtained corresponding to the detected value to the variable powering limiter 10A
(3) Optimal regeneration limit value determining means 30 for feeding back the optimal regeneration limit value BL _reg determined corresponding to the detected value to the variable regeneration limiter 10B
Is equipped.

Thus, unlike the determination based on the digital threshold value comparison as in the prior art and the digital switching of the operation mode, the change in operating conditions in the AC system 1 and the DC system 4 before and after the bidirectional inverter X Of the optimal powering limit value BL _pow and the optimal regenerative limit value BL _reg that can respond in real time, and the generated optimal powering limit value BL _pow and optimal regenerative limit value BL _reg are respectively generated by the powering and regenerative power limit control means 10 It feeds back to the variable powering limiter 10A and the variable regenerative limiter 10B. As a result, in variable power running limiter 10A, variable power running limit value L _pow is set to optimum power running limit value BL _pow , and power command value P _ip immediately responds to the current situation in AC system 1 or DC system 4 in real time. Then, the limit is set with the optimum power running limit value BL _pow . Moreover, in the variable regeneration limiter 10B, the variable regeneration limit value L _reg is set to the optimum regeneration limit value BL _reg , and the power command value P _ip is in real time in the current situation in the optimum AC system 1 or DC system 4 In response, the limit is set with the variable regeneration limit value _Lreg .

  As a result, in the storage system to which the DC power supply is connected, it is possible to realize the maximum charging and discharging of the storage battery 5 while preventing overcharging and overdischarging of the storage battery 5.

  FIG. 3 is a configuration diagram showing in more detail the configurations of the optimum powering limit value determining means 20 and the optimal regeneration limit value determining means 30 in the configuration of FIG.

As shown in FIG. 3, the optimum powering limit value determining means 20 includes a subtracting means 41, a PI control unit 51, a limiter 61, a powering power level adjusting means 60a, and a minimum value selecting means 71. The subtracting means 41 has a function of calculating the deviation ΔV ₁ between the charge inhibition voltage V _Cupp and the detected value of the storage battery voltage V _bat . PI control unit 51 has a function of executing PI control (proportional integral control) to the deviation [Delta] V _1. The limiter 61 performs limit setting on the value ΔV ₁ 'obtained by PI control with the upper limit value and the lower limit value of the maximum powering and regenerative power values, and sends the obtained limit value candidate L _p1 to the minimum value selecting means 71 Have a function to The limit value candidate L _p1 is mainly used to prevent overcharging of the storage battery 5. The power running power level adjustment means 60a sets the upper limit value and the lower limit value of the maximum power running / regenerated power value in the limiter 62 'for the value Pa for which the power running power P3 on the AC system 1 side regarding output power to the DC system 4 is to be limited. It has a function of performing limit setting based on the value and sending out the obtained limit value candidate L _p2 'to the minimum value selection means 71. The limit value candidate L _p2 'is used to prevent the power P3 from exceeding the maximum power value. For example, it is used to make sure that charging power P4 for storage battery 5 does not exceed the maximum charging power value or that receiving power from power system 2 does not exceed the maximum receiving power value. The minimum value selecting means 71 selects the smallest one among the plurality of limit value candidates L _p1 and L _p2 '(see FIGS. 8A and 8B), and _{changes the} variable powering as the optimum powering limit value BL _pow. It has a function of sending to the limiter 10A.

The optimum regeneration limit value determination means 30 includes a subtraction means 44, a PI control unit 52, a limiter 64, a regenerative power level adjustment means 60b, and a maximum value selection means 72. Subtracting means 44 has a function of calculating the deviation [Delta] V ₄ between the detection value of the discharge inhibition voltage V _Dlow and battery voltage V _bat. PI control unit 52 has a function of executing the PI control on the deviation [Delta] V _4. The limiter 64 limits the value ΔV ₄ 'obtained by PI control with the upper limit value and the lower limit value of the maximum powering and regenerative power values, and sends out the obtained limit value candidate L _r4 to the maximum value selecting means 72 It has a function. The limit value candidate L _r4 is mainly used to prevent overdischarge of the storage battery 5. Regenerative power level adjustment means 60b is the upper limit value and the lower limit value of the maximum charging power value in limiter 65 'for the value Pb for limiting the level of regenerative power P7 on the AC system 1 side regarding the output power from DC power supply 6 It has a function of applying a limit and sending the obtained limit value candidate L _r5 'to the maximum value selecting means 72. The limit value candidate L _r5 'is used to prevent the regenerative power P7 from exceeding the maximum regenerative power value. Alternatively, it is used to prevent reverse flow power P8 to power system 2 from exceeding the reverse flow limit power value. The maximum value selection means 72 selects the largest one among the plurality of limit value candidates L _r4 and L _r5 '(see FIGS. 8 (c) and (d)), and the variable regeneration is performed as the optimum regeneration limit value BL _reg. It has a function of sending to the limiter 10B.

  The DC power source 6 may be a solar power generator, a wind power generator, a hydro power generator or the like that generates electric power using renewable energy, a diesel engine generator, a fuel cell, a micro gas turbine generator, etc. It may be one that rectifies the AC power generated by The number thereof used may be singular or any plural, and may be a combination of the same system or a combination of different systems.

  An embodiment of the bidirectional inverter for a storage system to which the DC power supply of the present invention of the above configuration is connected will be described in detail on the level of a specific example.

  FIG. 4 is a block diagram showing in more detail the configurations of the optimum powering limit value determining means 20 and the optimum regeneration limit value determining means 30 in the configuration of FIG. 3, ie, the configurations of the powering power level adjusting means 60a and the regenerative power level adjusting means 60b. In more detail.

As shown in FIG. 4, the optimum powering limit value determining means 20 includes a first subtracting means 41, a PI control unit 51, a first limiter 61, a second subtracting means 42, a second limiter 62, and a third. A subtracting means 43, a third limiter 63, and a minimum value selecting means 71 are provided. The first subtraction means 41 has a function of calculating a deviation ΔV ₁ between the charge inhibition voltage V _Cupp and the detected value of the storage battery voltage V _bat . The first limiter 61 has a function of setting upper and lower limits for the output ΔV ₁ ′ of the PI control unit 51 and outputting a first limit value candidate L _p1 . The second subtraction means 42 has a function of calculating a deviation ΔP ₂ between the maximum charging power value P _Cmax and the detection value P _C of the generated power P 6 from the DC power supply 6. The second limiter 62 has a function of setting an upper limit for the output ΔP ₂ of the second subtracting means 42 and outputting a second limit value candidate L _{p 2} . Third subtracting means 43 has a function of calculating the deviation [Delta] P ₃ between the detection value P _F of the maximum received power value P _Fmax and load power P2. The third limiter 63 has a function of setting the upper limit of the output ΔP3 of the _third subtracting means 43 and outputting a third limit value candidate _Lp3 . The minimum value selecting means 71 has a function of selecting the minimum among the first to third limit value candidates L _{p1 to} L _p3 and outputting the selected one as the optimum powering limit value BL _pow .

The optimum regeneration limit value determining means 30 includes a fourth subtracting means 44, a PI control unit 52, a fourth limiter 64, a fifth subtracting means 45, a fifth limiter 65, and a maximum value selecting means 72. Fourth subtracting means 44 has a function of calculating the deviation [Delta] V ₄ between the detection value of the discharge inhibition voltage V _Dlow and battery voltage V _bat. The fourth limiter 64 has a function of setting upper and lower limits for the output ΔV ₄ ′ of the PI control unit 52 and outputting a fourth limit value candidate L _r4 . Fifth subtraction means 45 has a function of calculating the deviation [Delta] P ₅ between the detection value P _G of backward flow power limit value P _Glim and load power P2. The fifth limiter 65 has a function of setting an upper limit for the output ΔP5 of the _fifth subtraction means 45 and outputting a _fifth candidate limit _Lr5 . The maximum value selecting means 72 has a function of selecting the largest one of the fourth to fifth limit value candidates L _{r4 to} L _r5 and outputting the selected one as the optimal regeneration limit value BL _reg .

In the first limiter 61, the upper limit value "1.0" and the lower limit value "-1.0" are positive and negative areas (power running and regenerative operation) in the deviation ΔV _{1 with} respect to the storage battery voltage V _bat . Corresponds to the maximum and minimum values. Here, the reason why the negative regeneration side ("-1.0") is present in the first limiter 61 is to prevent overcharging of the storage battery 5 when powering is performed in a state where power is generated by the solar cell G. In addition to reducing the power running power to zero, it is necessary to regenerate. The positive value corresponds to the power running operation (charging), and the negative value corresponds to the regenerative operation (discharging). "0.0" means that neither charging nor discharging is performed.

In the second limiter 62, the upper limit value "1.0" and the lower limit value "0.0" are the maximum value and the minimum value in the positive region (powering operation) in the deviation ΔP _{2 with} respect to the generated power P6 It corresponds to Here, the reason why the second limiter 62 does not have the negative regeneration side ("-1.0") is that it is assumed that the maximum charging power is larger than the generated power P6. "0.0" means that neither charging nor discharging is performed.

In the third limiter 63, the upper limit "1.0" and the lower limit "0.0" are the maximum in the positive range (powering operation) in the deviation ΔP _{3 with} respect to the deviation ΔP ₃ of the load power P 2 Corresponds to the value and the minimum value. "0.0" means that neither charging nor discharging is performed.

In the fourth limiter 64, the upper limit value "0.1" and the lower limit value "-1.0" are in the negative range (regenerative operation) and slightly positive in the deviation ΔV _{4 with} respect to the storage battery voltage V _bat . It corresponds to the maximum value and the minimum value in the region (power running). The negative value corresponds to regenerative operation (discharge), and the positive value corresponds to powering power (charging). “0.1” is the meaning of supplementary charging for suppressing a complete discharge or a shift to a negative value due to the self-discharge of the storage battery 5. "0.0" means that neither charging nor discharging is performed.

In the fifth limiter 65, the upper limit value "0.0" and the lower limit value "-1.0" are the maximum value and the minimum value in the negative range (regenerative operation) in the deviation ΔP _{5 with} respect to the load power P2 Corresponds to the value. "0.0" means that neither charging nor discharging is performed.

Although the first limiter 61 and the fourth limiter 64 _relate to the deviation between the storage battery voltage V _bat and the reference value, the first limiter 61 has “−1.0” to “1.0”, The fourth limiter 64 has “−1.0” to “0.1” and is asymmetric, but in the storage battery 5, it is a bidirectional power of the charging power P4 and the discharging power P5. The reason is that the DC power supply 6 is one-way power of the generated power P6.

In the optimum powering limit value determining means 20, the first limiter 61 limits the signal corresponding to the deviation ΔV ₁ of the detected value of the storage battery voltage V _bat with respect to the charge inhibition voltage V _Cupp , and limits the first limit value candidate L Output _p1 . The second limiter 62 outputs the second limit value candidate L _p2 and the upper limit of the signal corresponding to the deviation [Delta] P ₂ between the detection value P _C of the maximum charge power P _Cmax and generated power P6. The third limiter 63 outputs a third limit value candidate L _p3 a signal corresponding to the deviation [Delta] P ₃ between the detection value P _F of the maximum received power value P _Fmax and load power P2 to the upper limit. Then, the minimum value selection means 71 selects the smallest one of the first to third limit value candidates L _{p1 to} L _p3 and changes it as the optimum power running limit value BL _pow in the power running / regenerated power limit control means 10. It feeds back to the powering limiter 10A.

On the other hand, in the optimum regeneration limit value determining means 30, the fourth limiter 64 limits the signal corresponding to the deviation ΔV ₄ between the discharge inhibition voltage V _Dlow and the detected value of the storage battery voltage V _bat to the fourth limit The value candidate L _r4 is output. Fifth limiter 65 outputs a fifth limit value candidate L _r5 a signal corresponding to the deviation [Delta] P ₅ of the backward flow power limit value P _Glim and the detected value of the load power P2 in lower limit. Here, since the reverse flow direction is the negative direction, the upper limit value (absolute value) of the regenerative power P7 is the sum (sum) of the reverse flow limited power value _PGlim and the load power P2.
Then, the maximum value selection means 72 selects the largest one of the fourth to fifth limit value candidates L _{r4 to} L _r5 , and changes it as the optimum regeneration limit value BL _reg as the power running / regeneration power limit control means 10. It feeds back to the regenerative limiter 10B.

  Next, the operation of the bi-directional inverter X for the storage system connected with the DC power supply configured as shown in FIG. 4 will be described.

  FIG. 5 is a waveform chart starting from a state in which the DC power supply 6 is in the operating state to generate the generated power P6, and the regenerative operation is performed in the bidirectional inverter X and the regenerative power P7 is generated. This figure shows that hunting does not occur as in the conventional example shown in FIG.

As shown in FIG. 5, it is assumed that the detected value of storage battery voltage V _bat decreases while the storage battery 5 is discharging, and the storage battery SOC also decreases accordingly. At this stage, the generated power P6 and the regenerated power P7 hold constant values (time t0 to t1). The detected value of the battery voltage V _bat reaches the discharge inhibition voltage V _Dlow in reduced (time t1), the output deviation [Delta] V ₄ of the fourth subtraction means 44 is zero at the optimal regeneration limit value determining means 30, PI control unit The output value ΔV ₄ ′ of 52 also becomes zero, and the fourth limit value candidate L _r4 output from the fourth limiter 64 also becomes zero. As a result, the detected value of storage battery voltage V _bat settles at a constant value and discharge power P5 from storage battery 5 disappears, and storage battery SOC gradually decreases to settle at a constant value, even if generated power P6 is constant. Regenerative power P7 gradually decreases smoothly. In other words, control is performed such that the detected value of storage battery voltage V _bat becomes constant while squeezing regenerative power P 7 slowly. That is, hunting as in the prior art is prevented. Moreover, overdischarge in the storage battery 5 is also prevented. When a predetermined time has elapsed, the state is stabilized in a state where the regenerated power P7 is supplied by the generated power P6. Because of the conversion loss in the bidirectional inverter X, the regenerative power P7 is slightly smaller than the generated power P6, and the charge and discharge of the storage battery 5 converge to zero. This becomes an operation waveform after time t2. According to the conventional example, hunting is caused. However, in the embodiment of the present invention, hunting is not caused because the shortage of the regenerative power P7 is compensated by the generated power P6 by the above-mentioned operation mechanism. Since charge and discharge with respect to storage battery 5 is zero control, the detected value of storage battery voltage V _bat is stabilized at a constant value. This behavior corresponds to so-called constant current constant voltage charging (CCCV charging).

  FIG. 6 is a waveform starting from a state in which the DC power supply 6 is in operation to generate the generated power P6, and the regenerative operation is not performed in the bidirectional inverter X and the regenerative power P7 is at zero level. FIG. This figure shows that hunting does not occur as in the conventional example shown in FIG.

As shown in FIG. 6, it is assumed that the detected value of the storage battery voltage V _bat is rising while the storage battery 5 is charging, and the storage battery SOC is also rising accordingly. At this stage, the generated power P6 and the regenerated power P7 hold constant values (time t10 to t11). When the detected value of storage battery voltage V _bat reaches charging inhibition voltage V _Cupp (time t11), the output deviation ΔV ₁ of the first subtraction means 41 in the optimum powering limit value determination means 20 falls below zero, and PI control The output value ΔV ₁ ′ of the unit 51 is less than zero, and the first limit value candidate L _r1 output from the first limiter 61 is also less than zero. As a result, the detected value of storage battery voltage V _bat settles at a constant value. While the storage battery 5 maintains the charge inhibition voltage V _Cupp , the regenerative electric power P7 is output, and the regenerative electric power P7 gradually rises (after time t11). In addition, the storage battery SOC gradually increases so as to settle at a constant value, and even if the generated power P6 is constant, the regenerative power P7 gradually and smoothly increases. In other words, control is performed such that the detected value of storage battery voltage V _bat becomes constant while gradually increasing regenerative power P7. That is, hunting as in the prior art is prevented. In addition, overcharging of storage battery 5 is also prevented. After a predetermined time passes, the generated power P6 stabilizes in a state where the regenerative power P7 is supplied, and hunting does not occur. Since charge and discharge with respect to storage battery 5 is zero control, the detected value of storage battery voltage V _bat is stabilized at a constant value. This behavior corresponds to so-called constant current constant voltage charging (CCCV charging).

FIG. 7 shows an operation mode for increasing the regenerative power P7 from a certain time. It is assumed that a command to increase regenerative electric power P7 is issued at time t21 in a process in which the detected value of storage battery voltage _Vbat is gradually decreasing because regenerative operation is being performed. Then, the detected value of storage battery voltage V _bat drops sharply due to the internal resistance of storage battery 5, but if discharge inhibition voltage V _Dlow is reached in the course of the drop (time t22), storage battery voltage V _bat the detected values different from the upturn in Figure 14 of the prior art, transitions while keeping the discharge prohibition voltage V _Dlow. Therefore, it is possible to realize as much output as possible just before overdischarge without falling into overdischarge. The state transition of the regenerative electric power P7 after time t22 can be a gradual and asymptotic state transition. In the case of the prior art, there is a dramatic change in the operation mode of instantaneous stop of regenerative operation (see FIG. 14), while in the embodiment of the present invention, the regenerative power P7 is accompanied by a gradual decrease. However, the lowering operation of the regenerative electric power P7 is gradual, and the regenerative operation itself is continued. Although the state transition after this depends on the situation change in AC system 1 and DC system 4, favorable conditions are met such that generated power P6 generated by DC power supply 6 can be increased to cover regenerative power P7. If this is the case, it is possible to make the regenerative power P7 reversely increase from the gradual decrease to the desired power value as shown by the broken line. That is, it is not necessary to adopt a control form of switching the operation mode instantaneously and explicitly in response to the result of comparison and determination as in the prior art, and hunting of the control operation of the bidirectional inverter X can be prevented. Here, seamless state transition is the point. In addition, it is possible to realize maximum charge and discharge while preventing overcharge and overdischarge of the storage battery 5. That is, waste of power consumption can be avoided as much as possible.

  FIG. 8 is a waveform diagram showing operations of the optimum powering limit value determining means 20 and the optimum regeneration limit value determining means 30. As shown in FIG.

FIG. 8A shows how the minimum value selection means 71 selects the minimum among the first to third limit value candidates L _{p1 to} L _p3 . The selected result is the optimal powering limit value BL _pow represented by a thick solid line. In order to make it easy to understand the selected result, a thick solid line is shown below the selected result, and in actuality, it is controlled by the values of L _{p1 to} L _p3 . Is one example, time to t31 is the first limit value candidate L _p1 is minimum, the first limit value candidate L _p1 Any time t33~t34 even time t31~t33 is minimal, at time t34~t35 a second limit value candidate L _p2 is a minimum, a second limit value candidate L _p2 even time t35~t38 minimum, at the time t38 after a third limit value candidate L _p3 minimum. Seamlessly connecting the minimum values in these time sections is the optimal powering limit value BL _pow .

FIG. 8 (b) shows the effective _peak value of the positive region of the optimal powering limit value BL _pow .

FIG. 8C shows how the maximum value selection means 72 selects the largest one of the first and second two limit value candidates L _{r4 to} L _r5 . The selected result is the optimal regeneration limit value BL _reg represented by a thick solid line. Incidentally, to make it easier to understand the results that are selected, represents the thick solid line above the selected result, actually being controlled by the value of L _p1 ~L _p3. As an example, the fourth limit value candidate L _r4 is the largest until time t32, the fifth limit value candidate L _r5 is the largest at time t32 to t36, and the fourth limit value at time t36 to t37. The candidate L _r4 is the largest, and the fifth limit value candidate L _r5 is the largest after time t37. Seamlessly linking the maximum values in these time sections is the optimal regeneration limit value BL _reg .

FIG. 8D shows the effective _peak value in the negative region of the optimum regeneration limit value BL _reg .

In FIG. 8 (e), the optimum powering limit value BL _pow having the effective _peak value in the positive region of FIG. 8 (b) and the optimal regenerative limit value BL _reg having the effective _peak value in the negative region of FIG. The optimization power running / regeneration limit value BL is shown. The optimization power running / regeneration limit value BL controls the overall upper / lower limit control operation on the power command value P _ip in the power running / regeneration power limit control means 10 as a whole. The optimization power running / regeneration limit value BL is accompanied by an effective total peak value ranging from the positive region to the negative region. The effective total peak value at each timing changes continuously. Also, the upper limit value point of the effective total peak value changes its position in real time. Similarly, the lower limit point in the effective total peak value changes its position in real time. The change of the upper limit point and the change of the lower limit point are independent of each other.

  With such a function, it is possible to realize seamless and stable powering control and regeneration control for the storage battery 5 while reflecting the change in operating conditions in the AC system 1 and the DC system 4 in real time.

As described above, the upper limit is executed in real time by the optimum powering limit value BL _pow given from the detection system to the variable powering limiter 10A in the powering and regenerative power limit control means 10, and the variable regenerative limiter 10B is The lower limit is executed in real time by the optimum regenerative limit value BL _reg given from the detection system, and the obtained final power command value P _op is sent to the inverter control unit 11. Here, the optimal powering limit value BL _pow and the optimal regeneration limit value BL _reg given as feedback signals are both severely limited. Therefore, even if the storage battery 5 is charged and discharged to the full upper and lower limits, the control operation of the bidirectional inverter X does not cause hunting, and maximum charge and discharge is prevented while preventing overcharge and overdischarge of the storage battery 5 It is possible to realize Therefore, power running control and regeneration control for storage battery 5 can be realized without interference from other various types of power.

  The present invention prevents the overcharge and overdischarge of the storage battery in the storage system, and eliminates the need for addition of various control elements for preventing hunting, overcharge and overdischarge, and stepwise switching control. The present invention is useful as a technology for realizing the maximum utilization of the state of charge of the storage battery without causing hunting in regenerative operation or power running operation against various complex fluctuations throughout.

DESCRIPTION OF SYMBOLS 1 AC system 2 electric power system 3 load 4 DC system 5 storage battery 6 DC power supply 10 powering and regenerative power limit control means 10A variable power running limiter 10B variable type regenerative limiter 11 inverter control part 20 optimal powering limit value determination means 30 optimal regenerative limit value Determination means 41 first subtraction means 42 second subtraction means 43 third subtraction means 44 fourth subtraction means 45 fifth subtraction means 60a powering power level adjustment means 60b regenerative power level adjustment means 61 first limiter 62 2nd limiter 63 3rd limiter 64 4th limiter 65 5th limiter 71 minimum value selection means 72 maximum value selection means BL _pow optimum power running limit value BL _reg optimum regeneration limit value L _pow variable power running limit value L _reg regeneration limit value L _p1 first limit value candidate L _p2 second limit value candidate L _p3 3 limits the candidate L _r4 fourth limit value candidate L _r5 fifth limit value candidate P1 received power P2 load power P3 running power P4 charge power P5 discharging power P6 generated power P7 regenerative power P8 backward flow power P _ip power command Value P _Cmax maximum charge power value P _Fmax maximum received power value P _Glim reverse flow limit power value V _Dupp discharge prohibition release voltage (storage battery voltage upper limit value)
V _bat battery voltage V _Dlow discharge prohibition voltage (battery voltage lower limit)
X bidirectional inverter

Claims (3)

A bidirectional inverter including an inverter control unit that performs powering and regeneration control between an AC system connected to a power system and a load and a DC system connected to a storage battery and a DC power supply,
A variable power running limiter capable of changing a variable power running limit value to a power command value according to an optimum power running limit value, and a variable regenerative limiter capable of changing a variable regeneration limit value to the power command value according to an optimum regeneration limit value Power running and regenerative power limit control means having
Continuously changing in real time determined so as to fall within the range defined by the variable power running limit value and the variable regeneration limit value corresponding to the detected value reflecting the change in the operating condition on the AC system side and the DC system side Optimal powering limit value determining means for determining the optimal powering limit value and feeding back the optimal powering limit value to the variable powering limiter.
Continuously changing in real time determined so as to fall within the range defined by the variable power running limit value and the variable regeneration limit value corresponding to the detected value reflecting the change in the operating condition on the AC system side and the DC system side Optimal regenerative limit value determining means for determining the optimal regenerative limit value and feeding back the optimal regenerative limit value to the variable regenerative limiter;
The electric power command value limited by the optimal powering limit value and the optimal regeneration limit value is sent to the inverter control unit .
further,
The optimum powering limit value determining means applies the upper limit and the lower limit to the deviation of the detected value of the storage battery voltage from the charge inhibition voltage with respect to the first limit value as a result and the command value of the powering power from the bidirectional inverter. Configured to select a minimum limit value from among one or more second limit values as a result of applying the upper limit limit, and outputting the selected value as the optimum power running limit value,
The optimum regeneration limit value determining means applies a fourth limit value as a result of applying the upper and lower limits to the deviation of the detected value of the storage battery voltage from the discharge inhibition voltage and the command value of the regenerative power from the bidirectional inverter. Bi-directionally , wherein the maximum limit value is selected from one or more fifth limit values as a result of applying the lower limit limit, and output as the optimal regeneration limit value. Inverter. A bidirectional inverter including an inverter control unit that performs powering and regeneration control between an AC system connected to a power system and a load and a DC system connected to a storage battery and a DC power supply,
A variable power running limiter capable of changing a variable power running limit value to a power command value according to an optimum power running limit value, and a variable regenerative limiter capable of changing a variable regeneration limit value to the power command value according to an optimum regeneration limit value Power running and regenerative power limit control means having
Continuously changing in real time determined so as to fall within the range defined by the variable power running limit value and the variable regeneration limit value corresponding to the detected value reflecting the change in the operating condition on the AC system side and the DC system side Optimal powering limit value determining means for determining the optimal powering limit value and feeding back the optimal powering limit value to the variable powering limiter.
Continuously changing in real time determined so as to fall within the range defined by the variable power running limit value and the variable regeneration limit value corresponding to the detected value reflecting the change in the operating condition on the AC system side and the DC system side Optimal regenerative limit value determining means for determining the optimal regenerative limit value and feeding back the optimal regenerative limit value to the variable regenerative limiter;
The electric power command value limited by the optimal powering limit value and the optimal regeneration limit value is sent to the inverter control unit.
further,
The optimal powering limit value determining means
First subtraction means for calculating a deviation between the charge inhibition voltage and the detected value of the storage battery voltage;
A first limiter which applies upper and lower limits to the output of the first subtracting means and outputs a first limit value candidate;
Second subtracting means for calculating a deviation between the maximum charge power value and the detected value of the generated power;
A second limiter which applies an upper limit to the output of the second subtracting means and outputs a second limit value candidate;
Third subtraction means for calculating a deviation between the maximum received power value and the detected load power value;
A third limiter which applies an upper limit to the output of the third subtracting means and outputs a third limit value candidate;
Minimum value selecting means for selecting the smallest one of the first to third limit value candidates and outputting it as the optimum powering limit value;
The optimum regeneration limit value determining means
A fourth subtraction means for calculating a deviation between the discharge inhibition voltage and the detected value of the storage battery voltage;
A fourth limiter which applies an upper and lower limit to the output of the fourth subtracting means and outputs a fourth limit value candidate;
Fifth subtraction means for calculating a deviation between the reverse flow limit power value and the detected value of the load power;
A fifth limiter which applies a lower limit to the output of the fifth subtracting means and outputs a fifth limit value candidate;
A bi-directional inverter comprising: a maximum value selecting means for selecting the largest one of the fourth to fifth limit value candidates and outputting it as the optimum regeneration limit value . A storage system in which the bidirectional inverter according to claim 1 or 2 is interposed between an AC system connected to a power system and a load, and a DC system connected to a storage battery and a DC power supply .

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