JP2000341861A - Control method of power storage system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a control method of a power storage system, whereby the demand cutting-out effect of a power system can be exhibited and by recycling the regenerating power of its load its regenerating energy utilized effectively to reduce the power of its receiving end. SOLUTION: In this control method of a power storage system, a load demand WL obtained through integration of every arbitrary time interval the consuming power of a power regenerating load is compared with a preset desired demand WR, and there is compensated every arbitrary time a demand compensating power PC1, which is in matching with the demand difference obtained by the comparison of the load demand WL with the preset desired demand WR. Also, a load power PL of the power regenerating load is compared with a preset peak value PLM of the load power PL, and as a peak-cut power PC2, the exceeding portion is compensated which is obtained, when the load power PL of the power regenerating load exceeds its preset peak value PLM. Furthermore, by using the load power PL as an upper limit value, a compensating power PC equal to the demand compensating power PC1 plus the peak-cut power PC2 is so restricted that it does not exceed the load power PL, and the regenerating power generated in the power regenerating load by the restriction of the compensating power PC is absorbed in the power storage system.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a power storage system, and more particularly to a power storage system for reducing a peak of received power by charging and discharging a battery in a distribution system, for example.

[0002]

2. Description of the Related Art For example, a regenerative vehicle is used as an electric regenerative load,
As shown in FIG. 5, a railway power storage system 1 used in a distribution system that supplies power from a system power supply to a power regenerative load is provided between a system power supply 2 and a power regenerative load 3 (hereinafter, simply referred to as a load). A converter 4 and a battery 5 which is a secondary battery connected to the DC side of the converter 4 are provided as a system. The power storage system 1 employs a control method as shown in FIG. 6 in order to reduce the peak of the received power of the load 3 by charging and discharging the battery 5.

[0003] That is, the conventional control method, it compares the preset peak power setting P _LM as shown in FIG. And load power P _L, the load power P _L is the peak power setting P _LM If it exceeds, the excess is calculated by the arithmetic processing means 6, and the excess is compensated as the peak cut power _PC2 . As a result, the received power of the load 3 is suppressed to the peak power set value _PLM even at the maximum, and the peak of the received power of the load 3 is reduced.

[0004] Specifically, in the power storage system 1 charges the battery 5 via a converter 4 power from the system power supply 2 at light loads, the load power P _L as described above to the heavy load that shows the power peak exceeding the peak power setting P _LM, the battery 5 is discharged by supplying the discharge power to the converter 4 through the load 3, peak excess load power P _L to a peak power setting P _LM The cut power P _C2 is compensated for. In addition,
The power level at the time of heavy load is peak-shifted at the time of light load, thereby leveling the power.

[0005]

According to the conventional control method described above, the peak received power can be reduced by suppressing the received power of the load 3 to the peak power set value _PLM. Can be reduced, and
You can get the profit of electricity price day and night.

[0006] However, at present, it is difficult to obtain a demand reduction effect by demand control in the conventional control method. The demand control is to control the total amount of power in a certain time zone by controlling the power so as not to exceed the target amount by accumulating the power at certain arbitrary time intervals.

Further, in a distribution system in which a regenerative vehicle is used as a load 3, regenerative electric power generated by the load 3 flows backward to the system as it is, and there is a problem that regenerative energy is wasted.

Accordingly, the present invention has been proposed in view of the above-mentioned problems. It is an object of the present invention to achieve a demand reduction effect and to regenerate regenerative energy by reusing regenerative electric power. It is an object of the present invention to provide a control method for a power storage system which can reduce received power by effectively utilizing the power.

[0009]

As a technical means for achieving the above-mentioned object, a control method according to the present invention is provided in a distribution system in which a power regeneration load is connected to a power supply, and is provided on a DC side of a converter. In a power storage system provided with a battery, a load demand obtained by integrating the power consumption of the power regenerative load at an arbitrary time interval is compared with a preset target demand, and a load demand and a target demand obtained by the comparison are compared. The present invention is characterized in that power corresponding to the demand difference is compensated for every arbitrary time.

Further, the control method of the present invention is a power storage system provided in a distribution system in which a power regenerative load is connected to a power supply, and a battery is provided on a DC side of a converter. It is characterized in that the received power demand integrated at every arbitrary time is compared with a preset target demand, and feedback control is performed so that the demand difference between the received power demand and the target demand obtained by the comparison becomes zero. .

In these control methods, the load demand or the power receiving demand is compared with the target demand, and the error between the load demand or the power receiving demand and the target demand is made as small as possible based on the error signal obtained by the comparison. By performing the demand control as described above, the load demand or the power receiving demand can be reduced, and it is easy to realize the demand reduction effect.

In the control method described above, the load power or the received power of the power regeneration load is compared with a preset peak power set value, and the load power or the received power of the power regeneration load is set to the peak power set value. It is also possible to compensate for the excess when it exceeds, and to reduce the load power or the received power peak by suppressing the load power or the received power of the power regeneration load to the peak power set value. it can.

Further, in the control method described above, the compensation power is limited so as not to exceed the load power or the reception power by setting the load power or the reception power as an upper limit value, and the regenerative power generated in the power regeneration load due to the limitation of the compensation power. It is also possible to absorb in the power storage system, in this case, it is possible to prevent the regenerative power from flowing back to the grid,
The absorption of the regenerative power makes it possible to reuse the regenerative power, and the regenerative energy can be effectively used to reduce the load power or the received power.

[0014]

DESCRIPTION OF THE PREFERRED EMBODIMENTS Embodiments of the present invention will be described below in detail. In the following embodiment, for example, a regenerative vehicle is used as a load,
The present invention is applied to a power storage system for railways used in a distribution system that supplies power from a system power supply to a load.

An electric power storage system 1 to which the control method of the present invention is applied is provided between a system power supply 2 and a load 3 as in a conventional case, and is connected to a converter 4 and a DC side of the converter 4. The system is composed of a battery 5 as a secondary battery (see FIG. 5). The power storage system 1 of the present invention employs a control method as shown in FIG. 1 in order to reduce the peak of the load power or the received power of the load 3 by charging and discharging the battery 5.

FIG. 1 is a control block diagram for explaining a basic control method of the present invention. The load demand W _{L obtained} by integrating the power consumption of the load 3 at an arbitrary time interval is compared with a preset target demand W _R. Figure 2 is a characteristic diagram showing one example of a load demand W _L and the target demand W _R,
Load demand W _L and the target demand W load obtained by comparison with _R-demand W _L and power P _C1 commensurate with the demand difference ΔW between the target demand W _R compensates every arbitrary time. Load demand W _L and power P _C1 commensurate with the demand difference ΔW between the target demand W _R is output from the arithmetic processing unit 7 such as by an error amplifier or PI control, as shown in FIG.

For example, when there is a demand difference ΔW between the load demand W _L and the target demand W _R at a certain time, the aforementioned demand difference ΔW is compensated by discharging the charging power of the battery 5 at an arbitrary time in the demand control. Can be. When trying to compensate for this demand difference ΔW at a stretch,
It is necessary to increase the capacity of the converter 4 to some extent.

Therefore, it is preferable to divide and compensate the demand difference ΔW within an arbitrary time of the demand control. In particular,
This is suitable when the demand difference ΔW is expected to be large to some extent. For example, ΔW × (１ ／) is calculated after Δt ₁ (for example, 1 second) from the time when the demand difference ΔW occurs, ΔW × (１ ／) is calculated after Δt ₂ (for example, 2 seconds), and Δt ₃ is calculated. By calculating ΔW × (１ ／) after (for example, 3 seconds), the demand difference ΔW can be divided and compensated without increasing the capacity of the converter.

Here, the coefficient for dividing and calculating the demand difference .DELTA.W is divided into three times of 1/2 and 1/4 in the above-mentioned case, but this coefficient may be set arbitrarily. The number of divisions is arbitrary, and these coefficients and the number of divisions may be set so that the compensation operation can be completed at an arbitrary time in the demand control.

Further, when the demand difference ΔW continuously occurs, the demand difference ΔW starts from the time when the demand difference ΔW occurs.
t _k , Δt _{k + 1} , Δt _{k + 2} ,...
After _{Δt k (1/2) ΔW (k} ) + (1/4) ΔW
(K-1) + (1/4) ΔW (k−2), Δt _{k + 1}
Later, (1/2) ΔW (k + 1) + (1/4) ΔW
(K) + (1/4) ΔW (k−1), and after Δt _{k + 2} , (1/2) ΔW (k + 2) + (1/4) ΔW (k +
1) + (1/4) ΔW (k),... Can be divided and compensated.

FIG. 3 is a control block diagram for explaining a control method according to the embodiment of the present invention. This embodiment, the basic control method according to the control block 1, in which the load power P _L by adding a calculation loop (see FIG. 6) for suppressing below peak power setting P _LM.

That is, the load demand W_LAnd goal deman
De W_RExecute demand control based on demand difference ΔW
The load power P_LTo compensate for the load
Force P _LIs the peak power set value P_LMExceeds the peak
Power P_C2As compensation. That is, as shown in FIG.
Output from the arithmetic processing means 7 based on the demand difference ΔW.
Demand compensation power P_C1And the load power P_LPeak power
Force set value P_LMCalculation processing means 6 based on the excess of
Output power P_C2And output
You. Note that the peak cut power P_C2Is similar to the traditional method
A preset peak power set value P_LMAnd load power P_LWhen
And the load power P_LIs the peak power set value P_LMTo
If it exceeds, the excess is calculated by the calculating means 6 and
The excess is the peak cut power P_C2As compensation.

[0023] In the compensation operation described above, the compensation power P _C is greater than the load power P _L, the difference between the compensation power P _C and the load power P _L is likely to result in reverse flow to the system. Therefore, to limit the upper limit value by the load power P _L by the limit means 8 compensation power P _C of the load power P _L the combination of the peak shaving power P _C2 and demand compensation power P _C1 as the upper limit value as shown in FIG. 3 . Thereby, reverse power flow to the system can be prevented. Thus, the load power P
By compensating power P _C as the upper limit value is limited so as not to exceed the upper limit of the load power P _{L L,} and the automatically absorbed regenerative electric power generated by the load 3 is charged to the battery 5 of the power storage system 1 It is possible to do.

According to the present invention, in addition to the above-described embodiment, instead of the load demand W _{L obtained} by integrating the power consumption of the load 3 at an arbitrary time, the power receiving demand W obtained by integrating the received power of the load 3 at an arbitrary time is used. It is possible to use _S. In this case, a feedback control is performed so that the demand difference between the power receiving demand W _S and the target demand W _R becomes zero, thereby providing a control method for causing the power receiving demand W _S to follow the target demand W _R. In the case of this feedback control, the arithmetic processing means 7 shown in FIG.
Arithmetic processing is performed on the basis of the feedback loop as demand difference between the _S and the target demand W _R becomes zero.

FIG. 4 is an example of a power pattern in a distribution system for supplying power from the system power supply 2 to the load 3. In the power storage system 1, together with compensation by demand control,
At the time of light load, the battery 5 is charged with power from the system power supply 2 via the converter 4 (a hatched portion in the figure),
By charging the battery 5 with regenerative power (b in the figure)
By cutting off the peak power at the time of heavy load showing the power peak (hatched portion), the battery 5 is discharged and the charged power is supplied to the load 3 via the converter 4 to thereby provide a heavy load. The power peak at the time is shifted to the peak at the time of light load, and the power is leveled.

[0026]

According to the present invention, in a control method for a power storage system provided in a distribution system in which a power regenerative load is connected to a power supply and a battery is provided on the DC side of the converter, the load is controlled with respect to a target demand. By the demand control for compensating the demand or the power receiving demand, the load demand or the power receiving demand can be reduced, and it is easy to realize the demand reduction effect.

In addition to compensation by demand control,
By suppressing the load power or the received power of the power regeneration load to the peak power set value, it is possible to reduce the peak of the load power or the received power. Furthermore, by limiting the compensation power so as not to exceed the load power or the received power, it is possible to prevent the regenerative power from flowing back to the grid and to automatically absorb the regenerative power, thereby enabling the regenerative power to be automatically absorbed. Reuse of power becomes feasible, and regenerative energy can be used effectively to reduce load power or received power, which is of great practical value.

[Brief description of the drawings]

FIG. 1 is a basic control block diagram of a control method according to the present invention.

FIG. 2 is a characteristic diagram showing a target demand and a load demand in the control method of the present invention.

FIG. 3 is a control block diagram showing an embodiment of a control method according to the present invention.

FIG. 4 is a characteristic diagram showing an example of a power pattern.

FIG. 5 is a circuit diagram showing a configuration of a power storage system.

FIG. 6 is a control block diagram showing a conventional control method.

[Explanation of symbols]

1 power storage system 2 system power source 3 power regenerative load 4 converter 5 Battery P _L load power P _LM peak power setting P _C1 demand compensation power P _C2 peak shaving power P _C compensation power W _L load demand W _R target demand W _S powered demand

Claims (4)

[Claims] 1. A method for controlling a power storage system provided in a distribution system in which a power regenerative load is connected to a power supply and having a battery disposed on a DC side of a converter, comprising: The load demand integrated for each time is compared with a preset target demand, and the power corresponding to the demand difference between the load demand and the target demand obtained by the comparison is compensated for every arbitrary time. A method for controlling an electric power storage system. 2. A method for controlling a power storage system provided in a distribution system in which a power regenerative load is connected to a power source and a battery disposed on a DC side of a converter, comprising: Power storage characterized by comparing the power receiving demand integrated for each time with a preset target demand, and performing feedback control so that the demand difference between the power receiving demand and the target demand obtained by the comparison becomes zero. How to control the system. 3. The control method according to claim 1, wherein the load power or the received power of the power regeneration load is compared with a preset peak power set value, and the load power or the received power of the power regeneration load is compared. A control method for controlling a power storage system, wherein when the power exceeds a peak power set value, the excess is compensated. 4. The control method according to claim 1, wherein the compensation power is limited so as not to exceed the load power or the reception power with the load power or the reception power as an upper limit, and the power regeneration is performed by limiting the compensation power. A method of controlling a power storage system, wherein regenerative power generated by a load is absorbed in a power storage system.