An embodiment of the present invention relates to a battery assembly system and a control board for a battery assembly.
In the related art, a battery assembly in which a plurality of batteries are connected is known. It is important in deriving states of the batteries to ascertain temperatures of the batteries constituting the battery assembly. However, directly or indirectly, it is difficult to measure the temperatures of the batteries constituting the battery assembly. Also, in the related art, the temperatures of the batteries cannot be appropriately derived on the basis of the temperatures, which are indirectly measured, in some cases.
Japanese Unexamined Patent Application, First Publication No. 2010-220323
An object to be accomplished by the present invention is to provide a battery assembly system and a control board of a battery assembly which can derive temperatures of batteries constituting a battery assembly.
A battery assembly system of an embodiment includes: a battery assembly; a temperature measuring part; and a monitorer. The battery assembly includes a plurality of batteries connected in series. The temperature measuring part measures temperatures of connection parts used to connect electrodes of batteries included in the battery assembly. The monitorer derives temperatures of the batteries on the basis of the temperatures measured by the temperature measuring part.
Hereinafter, a battery assembly system and a control board of a battery assembly in an embodiment will be described with reference to the drawings.
The battery assembly system 1 includes, for example, the battery assembly 5 including batteries (cells) 10-1L and 10-1R to 10-12L and 10-12R and a control board 30. Batteries, in which numbers after hyphens are the same and letter parts after the hyphens such as L and R differ, are connected in parallel with each other and used such as a battery 10-1L and a battery 10-1R and a battery 10-2L and a battery 10-2R in the battery assembly 5. Hereinafter, when batteries need not be distinguished from each other, they are referred to simply as batteries 10.
The batteries 10 are, for example, preferably lithium ion batteries in which manganese is used for a positive electrode and lithium titanatc is used for a negative electrode. A rate of receiving charge can be improved and a likelihood of an internal short circuit being caused due to precipitation of lithium can be decreased by adopting such a configuration for the batteries 10. In the case of the batteries 10, a plurality of structures, in which positive electrodes and negative electrodes face each other with separators interposed therebetween, are stacked, and as shown in
The batteries 10 are connected to each other using bus bars (connection parts). A bus bar 20-0 connects the positive electrode 7p (a voltage taking-out part at the positive electrode) for the entire battery assembly 5 and positive electrodes of the battery 10-1L and the battery 10-1R. A bus bar 20-1 connects negative electrodes of the battery 10-1L and the battery 10-1R and positive electrodes of the battery 10-2L and the battery 10-2R. A bus bar 20-2 connects negative electrodes of the battery 10-2L and the battery 10-2R and positive electrodes of a battery 10-3L and a battery 10-3R. A bus bar 20-3 connects negative electrodes of the battery 10-3L and the battery 10-3R and positive electrodes of a battery 10-4L and a battery 10-4R. A bus bar 20-4 connects negative electrodes of the battery 10-4L and the battery 10-4R and positive electrodes of a battery 10-5L and a battery 10-5R. A bus bar 20-5 connects negative electrodes of the battery 10-5L and the battery 10-5R and positive electrodes of a battery 10-6L and a battery 10-6R. A bus bar 20-6 connects negative electrodes of the battery 10-6L and the battery 10-6R and positive electrodes of a battery 10-7L and a battery 10-7R. A bus bar 20-7 connects negative electrodes of the battery 10-7L and the battery 10-7R and positive electrodes of a battery 10-8L and a battery 10-8R. A bus bar 20-8 connects negative electrodes of the battery 10-8L and the battery 10-8R and positive electrodes of a battery 10-9L and a battery 10-9R. A bus bar 20-9 connects negative electrodes of the battery 10-9L and the battery 10-9R and positive electrodes of a battery 10-10L and a battery 10-10R. A bus bar 20-10 connects negative electrodes of the battery 10-10L and the battery 10-10R and positive electrodes of a battery 10-11L and a battery 10-11R. A bus bar 20-11 connects negative electrodes of the battery 10-11L and the battery 10-11R and positive electrodes of a battery 10-12L and a battery 10-12R. A bus bar 20-12 connects negative electrodes of the battery 10-12L and the battery 10-12R and the negative electrode 7m (a voltage taking-out part at the negative electrode) for the entire battery assembly 5. With such a connection structure, the battery assembly 5 is constituted as a battery assembly in which 2 batteries are in parallel and 12 batteries are in series. Hereinafter, when the bus bars need not be distinguished from each other, they are referred to simply as bus bars 20.
For example, the bus bars 20-0 to 20-12 are secured to the control board 30 using screws (or bolts or the like) 32-0 to 32-12. Temperature sensors 34-0 to 34-12 are attached to the screws 32-0 to 32-12 as a temperature measuring part. Hereinafter, when the screws and the temperature sensors need not be distinguished from each other, they are referred to simply as screws 32 and temperature sensors 34, respectively.
The monitoring device 36 is, for example, a microcomputer. Information of temperatures measured by the temperature sensors 34 is input to the monitoring device 36. The monitoring device 36 derives temperatures of the batteries 10 on the basis of the temperatures measured by the temperature sensors 34.
Hereinafter, a temperature monitoring method using the monitoring device 36 will be described.
T0=0.5×(Ttp+Tc1)
T1=0.5×(Tc1+Tc2)
T2=0.5×(Tc2+Tc3)
T3=0.5×(Tc3+Tc4)
T4=0.5×(Tc4+Tc5)
T5=0.5×(Tc5+Tc6)
T6=0.5×(Tc6+Tc7)
T7=0.5×(Tc7+Tc8)
T8=0.5×(Tc8+Tc9)
T9=0.5×(Tc9+Tc10)
T10=0.5×(Tc10+Tc11)
T11=0.5×(Tc11+Tc12)
T12=0.5×(Tc12+Ttm)
Here, if there is no particular abnormality in the battery assembly 5, a temperature Ttp of the positive electrode 7p and a temperature Ttm of the negative electrode 7m in the battery assembly 5 depend on a current with which the battery assembly 5 is charged and which is discharged from the battery assembly 5. Thus, these temperatures can be regarded as the same. If temperature Ttp=temperature Ttm=temperature Ttave is satisfied, an unknown number in the above-described simultaneous equations is 12. Thus, the temperature Tcn can be calculated. Furthermore, the simultaneous equations can be represented by a characteristic determinant of Expression (1).
The monitoring device 36 performs an inverse matrix operation on a characteristic determinant represented by Expression (2) to calculate a temperature Ttave of the positive electrode 7p and the negative electrode 7m in the battery assembly 5 and an average temperature Ten of the battery 10-nL and the battery 10-nR from temperatures Tk measured by the temperature sensors 34-k. The monitoring device 36 performs an inverse matrix operation by inputting the temperatures Tk measured by the temperature sensors 34-k to software information associated with the above-described inverse matrix operation already prepared in a storage device of the monitoring device 36 in a format such as, for example, a function or a table as an operand.
Note that, when abnormality occurs in any of the temperature sensors 34, a phenomenon in which “values of Ttp and Ttm significantly differ” or a “calculated value of Tc1 or Tc12 is an abnormal value” occurs. Thus, abnormality of the temperature sensors 34 can also be detected.
According to the battery assembly system and the control board of the battery assembly, which have been described above, related to the first embodiment, the temperature sensors 34 configured to measure the temperatures of the bus bars 20 connecting the electrodes of the batteries 10 included in the battery assembly 5 and the temperatures of the bus bars 20 connecting the batteries 10 and the voltage taking-out part of the battery assembly 5, and the monitoring device 36 configured to derive the temperatures of the batteries 10 on the basis of the temperatures measured by the temperature sensors 34 are provided so that the temperatures of the batteries 10 can be derived.
Also, according to the first embodiment, an inverse matrix operation on a characteristic determinant according to temperature transfer characteristics of the battery assembly 5 is performed so that the temperatures of the batteries 10 are derived. Thus, a calculating process can be simplified, and a processing load can be reduced.
According to the first embodiment, the characteristic determinant and the inverse matrix operation thereof are used so that a temperature measurement error (an offset error) due to the temperature sensors 34 can be offset.
Hereinafter, a battery assembly system and a control board of a battery assembly related to a second embodiment will be described. Although it is assumed that an inverse matrix operation is performed on a matrix based on Expressions (1) and (2) or the like and the temperatures Ttave and Ten are acquired under the assumption that the bus bar 20 has a temperature at which the temperature of the battery 10 connected to the bus bar 20 is uniformly reflected into the bus bar 20 in the first embodiment, an inverse matrix operation may be performed on a matrix based on an expression in which a bias is reflected so that the temperature Ttave and Ten are acquired when the bus bar 20 does not have the temperature at which the temperature of the battery 10 connected to the bus bar 20 is uniformly reflected into the bus bar 20 in the second embodiment.
For example, when the temperature of the bus bar 20-0 is more significantly affected by the temperature of the positive electrode 7p in the battery assembly 5 than the battery 10-1L and the battery 10-1R due to an attachment position, a size, a shape, or the like of the bus bar 20-0, a tendency thereof can be expressed in the following equation.
T0=0.7×Ttp+0.3×Tc1
Similarly, when the temperatures of the bus bars 20 are significantly affected by the temperatures of some of the connected batteries 10 due to attachment positions, sizes, shapes, or the like of the bus bars 20, for example, it can be estimated that the following simultaneous equations will be established.
T0=0.7×Ttp+0.3×Tc1
T1=0.6×Tc1+0.4×Tc2
T2=0.6×Tc2+0.4×Tc3
T3=0.5×Tc3+0.5×Tc4
T4=0.4×Tc4+0.6×Tc5
T5=0.4×Tc5+0.6×Tc6
T6=0.5×Tc6+0.5×Tc7
T7=0.6×Tc7+0.4×Tc8
T8=0.6×Tc8+0.4×Tc9
T9=0.5×Tc9+0.5×Tc10
T10=0.4×Tc10+0.6×Tc11
T11=0.4×Tc11+0.6×Tc12
T12=0.3×Tc12+0.7×Ttm
The monitorer 36 related to the second embodiment takes into account, for example, the above-described simultaneous equations, and the temperatures Ttave and Tcn are acquired by performing an inverse matrix operation on a characteristic determinant (3) established when Ttp=Ttm is assumed.
Note that, when a serial number is 4, the characteristic determinant is represented by, for example, Expression (4). An inverse matrix of a characteristic determinant (4) is represented by Expression (5).
According to the battery assembly system and the control board of the battery assembly, which have been described above, related to the second embodiment, the temperatures of the batteries 10 can be derived as in the first embodiment. Furthermore, according to the second embodiment, the temperatures of the batteries 10 can be appropriately derived even when the bus bar 20 does not have a temperature at which the temperature of the battery 10 connected to the bus bar 20 is uniformly reflected into the bus bar 20.
Hereinafter, a battery assembly system and a control board of a battery assembly related to a third embodiment will be described. In the third embodiment, a temperature sensor configured to measure a board temperature is provided, and temperatures of the batteries 10 are derived from temperatures measured by the temperature sensor are derived.
In this embodiment, when the bus bar 20 has the temperature at which the temperature of the battery 10 connected to the bus bar 20 is uniformly reflected into the bus bar 20 as in the first embodiment, the following simultaneous equations are estimated to be established. In the expression, α1 and α2 are coefficients obtained through experiments or the like, and for example, are set such that α1+α2=1 is satisfied.
In this case, the characteristic determinant is represented by, for example, Expression (6). The monitorer 36 related to the third embodiment performs, for example, an inverse matrix operation of a characteristic determinant (6) to acquire temperatures Ttave and Tcn.
Note that an influence on the batteries 10 due to the temperature of the control board 30 is not uniform, and may be different for each battery 10. If the influence on the batteries 10 due to the temperature of the control board 30 varies when the serial number is 4, the characteristic determinant is represented by, for example, Expression (7). An inverse matrix in this case is represented by Expression (8).
According to the battery assembly system and the control board of the battery assembly, which have been described above, related to the third embodiment, the temperatures of the batteries 10 can be derived as in the first embodiment. Furthermore, according to the third embodiment, the influence due to the temperature of the control board 30 is subtracted so that the temperatures of the batteries 10 are derived. Thus, the temperatures of the batteries 10 can be more accurately derived.
Hereinafter, a battery assembly system and a control board of a battery assembly related to a fourth embodiment will be described. In the fourth embodiment, temperatures of batteries 10 as well as an assumed generated heat value due to a current flowing through bus bars 20 are derived.
In this embodiment, when it is assumed that a current flowing through the bus bars 20 is I and the bus bars 20 have temperatures in which temperatures of the batteries 10 connected to the bus bars 20 are uniformly reflected into the bus bars 20 as in the first embodiment, the following simultaneous equations are estimated to be established. In the expressions, β0 to βn are coefficients based on a resistance value for each bus bar 20, and R is a reference resistance value.
In the case, a characteristic determinant is represented by, for example, Expression (9). The monitoring device 36 related to the third embodiment acquires temperatures Ttave and Tcn, for example, by performing an inverse matrix operation on a characteristic determinant (9).
Note that, when a serial number is 4, the characteristic determinant is represented by, for example, Expression (10). An inverse matrix of a characteristic determinant (10) is represented by Expression (11).
According to the battery assembly system and the control board of the battery assembly, which have been described above, related to the fourth embodiment, the temperatures of the batteries 10 can be derived as in the first embodiment. Furthermore, according to the fourth embodiment, an influence given to the temperature of the batteries 10 by a current value with which the battery assembly 5 is charged and which is discharged from the battery assembly 5 is added so that the temperatures of the batteries 10 are derived. Thus, the temperatures of the batteries 10 can be more accurately derived.
Hereinafter, a battery assembly system and a control board of a battery assembly related to a fifth embodiment will be described. In the fifth embodiment, temperatures of batteries 10 as well as resistance values of balance resistors for suppressing a variation of voltages of the batteries 10 are derived. The balance resistors are provided, for example, on a control board 30. Furthermore, a disposition and resistance values of the balance resistors are known, and are stored in a storage device of a monitoring device 36.
In this embodiment, when bus bars 20 have temperatures in which temperatures of the batteries 10 connected to the bus bars 20 are uniformly reflected into the bus bars 20 as in the first embodiment, the following simultaneous equations are estimated to be established. In the expression, γ0 to γn are coefficients of an influence on bus bar temperature due to balance discharge, and Ncell is the number of the batteries 10 in which balance discharge is performed
In this case, a characteristic determinant is represented by, for example, Expression (12). The monitoring device 36 related to the fifth embodiment acquires temperatures Ttave and Tcn, for example, by performing an inverse matrix operation on a characteristic determinant (12).
Note that, when a serial number is 4, the characteristic determinant is represented by, for example, Expression (13). An inverse matrix of a characteristic determinant (13) is represented by Expression (14).
Also, in the above-described example, a case in which balance discharge circuits are partially fixed is assumed, and calculation is performed in proportion to the number of cells to be discharged. Here, when the balance discharge circuits are distributed in an entire circuit, an influence of discharge can also be checked for each bus bar 20. For example, when discharging parts are distributed, the balance resistors influence the bus bars 20 as a matrix so that the temperatures Ttave and Tcn can be acquired. A characteristic determinant in this case is represented by, for example, Expression (15). Furthermore, an inverse matrix of a characteristic determinant (15) is represented by Expression (16).
According to the battery assembly system and the control board of the battery assembly, which have been described above, related to the fifth embodiment, the temperatures of the batteries 10 can be derived as in the first embodiment. Furthermore, according to the fifth embodiment, the temperatures of the batteries 10 are derived by subtracting the influence due to the balance resistors. Thus, the temperatures of the batteries 10 can be more accurately derived.
Hereinafter, a battery assembly system and a control board of a battery assembly related to a sixth embodiment will be described. In the sixth embodiment, a positive electrode 7p and a negative electrode 7m of a battery assembly 5 serve as temperature monitoring targets and a temperature monitoring target in which an abnormality has occurred among batteries 10 is extracted on the basis of a difference between temperatures calculated with respect to temperature monitoring targets which are adjacent to each other. In the first to fifth embodiments, the processes are performed under the assumption that temperatures of the positive electrode 7p and the negative electrode 7m of the battery assembly 5 are the same, but in the sixth embodiment, it can be determined whether abnormality occurs in any of the positive electrode 7p and the negative electrode 7m of the battery assembly 5.
An inverse matrix of Expression (2) will be described as an example. For example, when a temperature of the positive electrode 7p of the battery assembly 5 rises due to loosening of a terminal or the like, this temperature rise appears as a temperature rise of a bus bar 20-0. In this case, according to Expression (2), temperatures Ttave and Tc1 both increase, however, other than the relation of the temperatures Ttave and Tc1, alternating opposite effects appear such as a temperature Tc2 decreasing, a temperature Tc3 increasing, a temperature Tc4 decreasing, and a temperature Tc5 increasing.
According to the battery assembly system and the control board of the battery assembly, which have been described above, related to the sixth embodiment, a place at which abnormality occurs can be appropriately extracted, and support is performed so that abnormality can be found early.
The above-described processes of the embodiments can be appropriately combined. For example, in the third embodiment, calculation corresponding to a case in which a bus bar 20 does not have a temperature in which a temperature of a battery 10 connected to the bus bar 20 is uniformly reflected in the bus bar 20 may be performed as in the second embodiment. Furthermore, the process related to the sixth embodiment can be applied to the processes of the second to fifth embodiments as well as that of the first embodiment.
Also, a monitoring device 36 may decrease monitoring resolution so that a process transitions to a rough monitoring process when abnormality occurs in any of the temperature sensors 34.
According to at least one embodiment described above, a battery assembly 5 in which a plurality of batteries 10 are connected in series, temperature sensors 34 configured to measure temperatures of connection parts 20 used to connect electrodes of the batteries 10 are included in the battery assembly 5, and a monitoring device 36 is configured to derive temperatures of the batteries 10 on the basis of the temperatures measured by the temperature sensors 34 is provided so that the temperatures of the batteries 10 constituting the battery assembly 5 can be derived.
Although some embodiments of the present invention have been described, these embodiments are presented as examples, and are not intended to limit the scope of the present invention. These embodiments can be carried out in various other forms. In addition, various omissions, substitutions, or changes can be performed without departing from the gist of the present invention. These embodiments and modifications thereof are included in the scope or the gist of the present invention and are included in the scope of the appended claims and the equivalent scope thereof.
Number | Date | Country | Kind |
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2014-148341 | Jul 2014 | JP | national |
Filing Document | Filing Date | Country | Kind |
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PCT/JP2015/061351 | 4/13/2015 | WO | 00 |