초록 ▼

A number (uo) of healthy strings of one block in a sodium-sulfur battery is determined according to expression (1), and a failure of the sodium-sulfur battery is detected on the basis of the determination of the value of the uo. This method makes it possible to properly determine a failure of the so

A number (uo) of healthy strings of one block in a sodium-sulfur battery is determined according to expression (1), and a failure of the sodium-sulfur battery is detected on the basis of the determination of the value of the uo. This method makes it possible to properly determine a failure of the sodium-sulfur battery, which can be used to compensate for fluctuations of electric power generated by a renewable energy generating device. uo=(Qo/Qs)×us . . . (1) where Qs: used capacity of reference block; Qo: used capacity of target block; and us: number of healthy strings of reference block (us≦u).

대표청구항 ▼

1. A method for calculating the number of healthy strings of a sodium-sulfur battery, comprising: forming a string of the sodium-sulfur battery by connecting an S number of electric cells, which is a plural number, in series;connecting a U number of the strings, which is a plural number, in parallel

1. A method for calculating the number of healthy strings of a sodium-sulfur battery, comprising: forming a string of the sodium-sulfur battery by connecting an S number of electric cells, which is a plural number, in series;connecting a U number of the strings, which is a plural number, in parallel to form a block;connecting an N number of the blocks, which is a plural number, in series, anddetermining in a control unit a number uo of healthy strings of a block in a sodium-sulfur battery according to expression (1) given below: uo=(Qs/Qo)×us  (1)whereQs: used capacity of reference block;Qo: used capacity of target block; andus: number of healthy strings of reference block (us≦u). 2. The method for calculating the number of healthy strings of a sodium-sulfur battery according to claim 1, further comprising: calculating in the control unit a used capacity Qs of a reference block and a used capacity Qo of a target block after the completion of a charge/discharge using expressions (2) through (5) given below: Qs=Qsn−Qsc  (2)where: Qsn: depth of discharge of reference block;Qsc: residual capacity of reference block; and Qsn=us×f1(Vs(t,T,Icd))  (3)where: f1(Vs(t, T, Icd)) is a transform function for determining the depth of discharge of a block having a highest voltage on the basis of a voltage Vs of the block, wherein the voltage is obtained by converting an unstable open-circuit voltage measured t hours following completion of a charge/discharge in the single-phase region into a stable open-circuit voltage, and then correcting the converted stable open-circuit voltage on the basis of a temperature T upon completion of a charge/discharge and a charging/discharging current Icd upon completion of a charge/discharge; Qsc=f2(Cs)  (4)where: f2(Cs) is a transform function for determining a current reference block residual capacity Qsc on the basis of an equivalent cycle Cs of a current reference block; Qo=Qon−Qoc  (5)where: Qon: depth of discharge of target block;Qoc: residual capacity of target block; and Qon=us×f3(Vo(t,T,Icd))  (6)where: f3(Vo(t, T, Icd)) is a transform function for determining the depth of discharge of a block, the number of healthy strings of which is to be determined, on the basis of a voltage Vo of the block, wherein the voltage is obtained by converting an unstable open-circuit voltage measured t hours following completion of a charge/discharge in the single-phase region into a stable open-circuit voltage, and then correcting the converted stable open-circuit voltage on the basis of a temperature T upon completion of a charge/discharge and a charging/discharging current Ted upon completion of a charge/discharge; and Qoc=f4(Co)  (7)where: f4(Co) is a transform function for determining a residual capacity Qoc of a current target block on the basis of an equivalent cycle Co of the current target block. 3. A failure detection method for a sodium-sulfur battery, comprising determining in a control unit a value of a number uo of healthy strings in a block of sodium-sulfur batteries using the method according to claim 2 for calculating the number of healthy strings of a sodium-sulfur battery, anddetecting a failure of a sodium-sulfur battery from the determined value of the number uo of healthy strings in a block of sodium-sulfur batteries. 4. The failure detection method for a sodium-sulfur battery according to claim 3, wherein the control unit is detecting the failure of a sodium-sulfur battery which constitutes an electric power storage-compensation device to compensate for output fluctuations in an electric power generating device in an interconnected system, which combines the electric power generating device incurring output fluctuations and the electric power storage-compensation device to supply power to a power system. 5. A failure detection method for a sodium-sulfur battery, comprising determining in a control unit a value of a number uo of healthy strings in a block of sodium-sulfur batteries using the method according to claim 1 for calculating the number of healthy strings of a sodium-sulfur battery, anddetecting a failure of a sodium-sulfur battery from the determined value of the number uo of healthy strings in a block of sodium-sulfur batteries. 6. The failure detection method for a sodium-sulfur battery according to claim 5, wherein the control unit is detecting the failure of a sodium-sulfur battery which constitutes an electric power storage-compensation device to compensate for output fluctuations in an electric power generating device in an interconnected system, which combines the electric power generating device incurring output fluctuations and the electric power storage-compensation device to supply power to a power system.