Note: Descriptions are shown in the official language in which they were submitted.
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STATE DETECTING SYSTEM AND DEVICE EMPLOYING THE SAME
This is a division of co-pending Canadian Patent
Application No. 2,422,213 filed on March 14, 2003.
FIELD OF THE INVENTION
The present invention relates to a novel state
detecting device for detecting states (e.g. charge
condition, residual capacity in a power storage means
such as a lithium secondary battery, a nickel hydride
battery, a lead seal battery, and an electric double
layer capacitor).
BACKGROUND OF THE INVENTION
In a power source unit, a distribution type power
storage device and an electric vehicle employing power
storage means, (e.g. a battery), a state detecting device
is employed for detecting state of the power storage
means in order to safely and effectively use the power
storage means. The state of the power storage means
represents state of charge (hereinafter abbreviated as
"SOC" indicative of the amount of remaining charge,
residual capacity, or state of health (hereinafter
abbreviated as "SOH") indicative of amount exhausted or
degree of deterioration.
The SOC in the power source unit can be detected by
integrating a discharge current from a fully charged
state and calculating a ratio of a charge amount residing
in the power storage means (hereinafter referred to as
"residual capacity") versus a maximum charge amount
(hereinafter referred to as "full capacity"). However,
many power storage means vary the full capacities
depending upon SOH, temperature and so forth,
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making it difficult to accurately detect SOC with respect to
secular change and environmental variation.
In order to solve this problem, Japanese Patent
Application Laid-Open No. Heisei 10-289734 discloses a
conventional residual capacity predicting method for battery
deterioration. Fig. 10 is an illustration showing a residual
capacity predicting method of the above-identified
publication. In this method, an initial battery
characteristic is corrected by a temperature correction
coefficient derived on the basis of the temperature of the
battery and a deterioration correction coefficient derived
based on deterioration of the battery. A residual capacity of
the battery is derived on the basis of the corrected battery
characteristics, a discharge current during discharging and a
terminal voltage.
In Japanese Patent Application Laid-Open No. Heisei
11-218567, there is shown a method for deriving a battery
characteristic upon occurrence of deterioration by correcting
an initial battery characteristic in relation to a temperature
correction coefficient, an internal resistor deterioration
correction coefficient, a capacitor deterioration correction
coefficient.
In Japanese Patent Application Laid-Open No. 2000-166105,
there has been disclosed a control unit for detecting a charge
condition on the basis of charge and discharge current,
detecting a power storage condition on the basis of a voltage
and controlling a charge condition on the basis of such
detections.
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In Japanese Patent Application Laid-Open No. 2000-166109,
there has been disclosed a charge condition detecting device
for deriving an electromotive force based on a charge and
discharge current, and voltage and for deriving a charge
characteristic on the basis of the electromotive force.
In Japanese Patent Application Laid-Open No. 2001-85071,
there is disclosed a temperature detecting device predicting
respective temperatures of a set of battery modules on the
basis of voltages between terminals and currents flowing
therethrough.
In the residual capacity predicting method disclosed in
the foregoing Japanese Patent Application Laid-Open No. Heisei
10-289734, influences for temperature or deterioration are
taken in as temperature correction coefficient or
deterioration correction coefficient for correcting parameters
necessary for calculation of the residual capacity. These
correction coefficients are derived through complicated
derivation processes. Therefore, this method is concerned
with correctness of the value per se of the correction
coefficient and whether all battery characteristics are
corrected.
In addition, the power storage means also has
characteristics, (e.g. charge efficiency, memory effect, etc.)
and makes correction in consideration of these characteristics
in precision of residual capacity with high precision. On the
other hand, the initial characteristics of the power storage
means generally contain individual differences. Correction
for individual differences is also necessary in prediction of
residual capacity with high precision.
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Namely, in order to perform state detection, such as
prediction of residual capacity with high precision, it
becomes necessary to effect accurate modeling of the
characteristics to take in a plurality of parameters.
Furthermore, correction associated with secular change or
environmental variation of these parameters is performed.
Therefore, significant time and attention have to be paid
for obtaining the initial characteristics and plurality of
parameters of the power storage means. However, regardless of
the complexity, the result of arithmetic operation is
prediction on the basis of the theory or model of the battery
characteristics. Therefore, there is still the concern of the
correctness of the result of prediction with respect to a true
value.
It has been found that in order to realize high precision
state detection of the power storage means by simple
characteristic data calculations, comparison of the result of
state detection with the true value or logic and feeding this
back to subsequent arithmetic operations to learn the
difference provides correction. Since it is not possible to
directly measure the state of the battery, such as SOC or SOH,
an important problem is how to derive the true value or logic.
SUMMARY OF THE INVENTION
An object of the present invention is to provide a state
detection system to perform correction for feeding back
correction information to make characteristic data useful in
arithmetic operation for accurate detection of state.
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The present invention is directed to a state
detecting system comprising a storage means for storing
characteristic data with respect to a power storage means
arithmetically obtained on the basis of the measured
information obtained by measuring a measuring object with
respect to the power storage means by measuring means,
calculation information relating to the arithmetic
operation of the data, and set information preliminarily
set relating to the characteristic data and the
calculation information, an arithmetic means for
calculating state information indicative of state of the
power storage means on the basis of the measured
information and set information and calculating
correction information for performing correction by
comparing a calculation result calculated and the set
information, a first correcting means for correcting
input of the arithmetic means on the basis of correction
information obtained by the arithmetic means, or a second
correcting means for correcting information stored or set
in storage means based on correction information obtained
by the arithmetic means.
In accordance with one aspect of the present
invention there is provided a state detecting system for
an electric storage device comprising: a memory medium
storing storage information which includes characteristic
data of an electric storage device, calculation
information required for calculation for detection of a
state of the electric storage device, and set information
on a true set value or true logic based on a
characteristic of the electric storage device or a
phenomenon caused therein; a calculator which performs
the calculation for detection of the state of the
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electric storage device on the basis of measured
information obtained from a measuring instrument for
measuring a parameter of the electric storage device
required for detection of the state thereof and input
information including the storage information and outputs
correction information corresponding to the input
information when a discrepancy is found in state
detection information obtained by the calculation as a
result of comparison of the state detection information
and the set information; and a corrector correcting the
input information on the basis of the correction
information; wherein the correction information includes
internal resistance information of the power storage
device, the calculator outputs correction information
corresponding to at least the internal resistance
information when the discrepancy is found, and the
corrector corrects the internal resistance information on
the basis of the correction information corresponding
thereto.
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BRIEF DESCRIPTION OF THE DRAWINGS
The present invention will be understood more fully
from the detailed description given hereinafter and from
the accompanying drawings of the preferred embodiment of
the present invention, which, however, should not be
taken to be limitative to the invention, but are for
explanation and understanding only.
Fig. 1 is a constructional illustration of a power
source unit according to the present invention;
Fig. 2 is a block diagram showing a calculation
process of the power source unit according to the present
invention;
Fig. 3 is a circuit diagram showing an equivalent
circuit of a power storage means according to the present
invention;
Fig. 4 is a diagrammatic illustration showing a
relationship between SOC and allowable charge and
discharge current of power storage means according to the
present invention;
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Fig. 5 is a diagrammatic illustration showing a voltage
variation upon charging by a pulse current of the power
storage means according to the present invention;
Fig. 6 is a constructional illustration of the power
source unit according to the present invention;
Fig. 7 is a diagrammatic illustration showing a
relationship of OCV and SOC of the power storage means
according to the present invention;
Fig. 8 is a constructional illustration of a distributed
type power storage device of sunlight applied to the state
detection system and the power source unit according to the
present invention;
Fig. 9 is a constructional illustration of an automotive
vehicle applied to the state detection system and the power
source unit according to the present invention; and
Fig. 10 is a constructional illustration showing the
conventional residual capacity predicting method according to
the prior art.
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS
The present invention will be discussed hereinafter in
detail in terms of the preferred embodiment of the present
invention with reference to the accompanying drawings. In the
following description, numerous specific details are set forth
in order to provide a thorough understanding of the present
invention. It will be obvious, however, to those skilled in
the art that the present invention may be practiced without
these specific details. In other instance, well-known
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structures are not shown in detail in order to avoid
unnecessary obscurity of the present invention.
Fig. 1 is a constructional illustration of a power source
unit according to the present invention. In Fig. 1, the
reference numeral 101 denotes power storage means, 102 denotes
measuring means, 103 denotes storage means, 104 denotes
arithmetic means, 105 denotes communication means, 106 denotes
first correction means and 107 denotes second correction
means. The power storage means 101 is formed with a device
having a power storage function, such as a lithium secondary
battery, a nickel hydride battery, a lead seal battery, an
electric double layer capacitor and so forth.
The measuring means 102 is formed with a sensor or an
electric circuit measuring voltage, current, temperature,
resistance, battery electrolyte concentration and so forth, to
obtain measured information.
The storage means 103 is constructed with a memory
device, such as an EEPROM, flash memory, a magnetic disk and
so forth to store calculation information including at least
one of characteristic data, calculation coefficient and
calculation procedure, and set value to be considered as a
preliminarily set true value relating to the calculation
information or set information consisting of logic considered
as true phenomenori.
The arithmetic means 104 is formed with a microprocessor,
a computer or the like, and derives state information of the
power storage means 101 on the basis of a measuring value of
the measurement means 102 and a value of the storage means
103. On the other hand, the result of calculation and the set
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information are compared to calculate the correction
information for correction amounts. As state of the power
storage means 101, there are various abnormality, such as SOC,
SOH, allowable current, continuous charge and discharge
period, allowable temperature, overcharging, over discharging
and so forth.
The communication means 105 is constructed with a device
or circuit for communicating a serial number, such as CAN,
Bluetooth and so forth or a device or circuit communicating an
ON-OFF signal, such as photo-coupler, relay and so forth.
Then, the result of calculation by the arithmetic means 104 is
transmitted to other controller, display element or the like
(not shown).
The first correction means 106 is constructed with a
cache memory, a buffer memory, such as SRAM or the like, a
register. Correction is performed by varying a value of the
measuring means 102, a value of the storage means 103, a
result of calculation of the arithmetic means 104 on the basis
of a correction value derived by the arithmetic means 104.
The second correction means 107 is constructed with a
writing circuit of EEPROM, flash memory and so forth as the
storage means 103 or a writing circuit of the magnetic disk or
the like and re-writes the value in the storage means 103
based on the correction value calculated by the arithmetic
means 104.
While the first correction means 106 and the second
correction means 107 are employed in the shown embodiment, it
is possible to use one of these correction means or to employ
other construction. On the other hand, by employing a
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microcomputer, in which an A/D converter, a flash memory, a
microprocessor, a communication circuit are integrated on the
same device, the measuring means 102, the storage means 103,
the arithmetic means 104, the communication means, the first
correction means 106 and the second correction means 107 can
be integrated on the same device. On the other hand, these can
be used in common with another control unit.
With the shown embodiment, the result of calculation per
se is compared with the set value or the set information set
as logic to perform correction with feed back to subsequent
arithmetic operations learning the difference between the
result of calculation and the set value or the set
information. Therefore, it becomes possible to realize the
state detection method and state detection system of the power
storage means which is high accuracy with less accurate
characteristic data used in arithmetic operation.
Fig. 2 is a block diagram showing a state detection
method of the power storage means according to the present
invention. In Fig. 2, in a step of measuring and reading,
voltage, current, temperature, resistance, electrolyte
concentration and so forth of the power storage means 101 is
measured to read the measuring value of the first correction
means 106 or the arithmetic means 104 or a value of the
storage means 103. In calculation, the state of the power
storage means 101 is calculated on the basis of the read
value. In discrepancy judgment, the result of calculation and
the set value or logic is compared to make judgment of any
discrepancy. If no discrepancy is found, the process does end
to repeat the same sequence. If a discrepancy is found,
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related parameters are corrected at a step of correction and
writing to terminate writing in the memory. By repeating this
sequence, correction to feed back the discrepancy to
subsequent arithmetic operations can be performed.
Here, discrepancy between the result of calculation and
the set value or logic means that, for example, logic
naturally increases charge state during charging and any
discrepancy is found when the charge state is decreased during
charging. Similarly the charge state is decreased during
discharging, or charge state is not varied under the condition
where influence of self-discharge can be ignored during
resting. If there is disc=repancy, correction is effected.
Then, matrixing of such items may be performed to make
discrepancy judgments taking the matrix as a discrepancy
matrix.
While it is not possible to directly measure the state
of the power storage means, the foregoing obvious phenomenon
or characteristics are taken as set information to compare
with the result of calculation. If a discrepancy is found,
the value of the storage means and the input of the arithmetic
means are corrected with learning.
By this, it becomes possible to realize the state
detection system of the power storage means which is higher
accuracy than the'characteristic data used in arithmetic
operation.
Fig. 3 is a circuit diagram showing an equivalent circuit
of the power storage means. In Fig. 3, the reference numeral
201 denotes an electromotive force (OCV), 302 denotes an
internal resistor (R), 303 denotes an impedance (Z), 304
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denotes a capacitor component (C). There are illustrated a
parallel connection pair of the impedance 303 and the
capacitor component 304 and a series connection of the
internal resistor 302 and the electromotive force 301. When a
current I is applied to the power storage means, a voltage
(CCV) between the terminals of the power storage means is
expressed by an equation (1).
CCV = OCV + IR + Vp .....(1)
wherein Vp is polarized voltage, Z and C are voltages of
the parallel connection pair.
OCV is used for calculation of SOC or allowable charge
and discharge current. In the condition where the power
storage means is charged and discharged, it is not possible to
directly measure OCV. Therefore, OCV is derived by
subtracting IR drop and Vp from CCV as expressed by the
following equation (2).
OCV = CCV - IR - Vp ..... (2)
Fig. 4 is a diagrammatic illustration showing SOC, an
allowable charge current and allowable discharge current of
the power storage means. Associating with increase of SOC,
the allowable discharge current is increased and allowable
charge current is decreased. Assuming the maximum allowable
voltage of the power storage means is Vmax and minimum
allowable voltage is Vmin, the allowable charge current Icmax
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and allowable discharge current Idmax are respectively
expressed by the following equations (3) and (4).
Icmax = (Vmax - OCV)/Rz ..... (3)
Idmax = (OCV - Vmin)/Rz ..... (4)
wherein Rz is equivalent impedance of R, Z, C in Fig. 3.
Accordingly, a discrepancy is found in overcharging or
over discharging by detection upon charging and discharging at
a current smaller than or equal to Icmax and Idmax, the value
of Rz is corrected. For example, Rz is increased by 1%.
Fig. 5 is a diagrammatic illustration showing variation
of voltage during charging by a pulse current of the power
storage means. A curve of CCV shown by a solid line is risen
from a charge start timing (A) and abruptly drops at a charge
terminating timing (B). Dropping is due to IR drop.
Subsequently, CCV is decreased moderately to gradually
approach the set information of OCV shown by one-dotted line.
A voltage variation in this period mainly corresponds to Vp.
On the other hand, the set information of OCV not influenced
by the IR drop or Vp is increased from A to B during charging
but is not varied during a period between B where a current is
OA to D (under the condition where influence of self-discharge
or envirQnmental temperature can be ignored). In contrast to
this, the calculated value of OCV shown by the broken line is
not consistent with the set information of OCV, and shows a
moderately decreasing curve even from B to D.
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When the equation (2) is used in calculation of OCV, R
can be directly obtained by actually measuring CCV and I and
expressed by the following equation (5) using variation amount
dCCV and dI in a short period.
R = dCCV/dI ..... (5)
Therefore, with the present invention, taking the fact
that variation of OCV is OV at OA as set value, for example,
when the calculated value of OCV during this period is varied
as shown in Fig. 5, Vp is corrected.
On the other hand, when SOC is derived from OCV, the set
value or logic of SOC and the calculated value are also varied
as shown in Fig. 5. Even in this case, it becomes possible to
detect discrepancy of Vp. Then, after correction of Vp, it is
fed back to subsequent calculation.
The table 1 shows a relationship between variation of SOC
of the present invention and correction amount of Vp. With
taking a time scale as t, and taking a timing where the
current value becomes OA as t = 0, the correction amount of Vp
is determined from variation of SOC at t < 0 and variation of
SOC at t > 0. For example, if variation of SOC at t < 0 is
increased and variation of SOC at t > 0 is also increased, Vp
is decreased by 1%.
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TABLE 1
SOC Variation SOC Variation Vp Correction
(t<0) (t>O, Current OA)
Increase Increase -lo
Increase Decrease +1%
Decrease Increase +1%
Decrease Decrease -1%
Then, these calculations are repeated for a plurality of
times. By this, Vp gradually approaches the set value by
learning. Namely, Vp is automatically tuned.
While the absolute value of the correction amount is
uniform at 1% here, it is preferred that this value is
optimized depending upon the power storage means, current
pattern of the load, measurement error of the measuring means
and so forth. On the other hand, as shown, it is preferred to
apply Fuzzy theory for indicating direction of correction.
While state of the power storage means cannot be measured
directly similarly to SOC or OCV, according to the present
invention, the characteristics or normal phenomenon in the
period where the current value is less than or equal to a
predetermined value set forth above as set value or logic, the
correction amount is derived by Fuzzy theory by comparing the
result of calculation per se. This is fed back to the
subsequent calculation to repeat learning calculations.
Therefore, whenever a calculation is repeated, precision
can be improved. Due to the individual differences of the
initial characteristics, environment dependency, secular
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change and so forth are automatically tuned. Thus, these
plurality of parameters and data of correction coefficient can
be eliminated.
For example, in the foregoing example, Vp depends on a
S complicate parameter, such as individual difference or secular
change, and further individual difference of secular change
and so forth. Upon modeling and reproducing these parameters
accurately for taking in calculation, it becomes necessary to
obtain the initial characteristics, a plurality of parameters,
data to require substantial period and load. However, in the
present invention, as influence of these individual
differences, secular change and so forth are calculated with
learning under actual use environment, these parameters are
not required.
Fig. 6 is a constructional illustration of the power
source unit according to the present invention. In Fig. 6,
the reference numeral 701 denotes a calculation procedure A,
702 denotes a calculation procedure B, 703 denotes a
correction amount calculation procedure. The arithmetic means
104 shows a part of the calculation procedure, and the
arithmetic means have the arithmetic procedure A and the
arithmetic procedure B.
For example, the calculation procedure A 701 is taken as
arithmetic procedure of SOC (hereinafter referred to as SOCV)
derived from OCV set forth above, and the calculation
procedure B 702 is taken as calculation procedure of SOC
(hereinafter referred to as SOCi based on a current
integration. In calculation of SOCi, the equation (6) is
used.
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SOCi = SOCo + 100 X d I/Q ..... (6)
wherein SOCo is an initial value of SOC upon starting of
charging and discharging, d I is a various amount of the
current integrated value, Q is a maximum charge amount (full
capacity). Assuming a charge efficiency of the power storage
means as q, an integrated charge current as Ic and an
integrated discharge current as Id, d I is expressed by the
following equation (7).
d I=q x Ic - Id ..... (7)
SOCi is superior in indicating variation amount in a
short period, namely response characteristics, for directly
calculating the current. However, an absolute value is not
always correct due to individual differences or secular change
of Q, influence of q or erroneous accumulation of current
integrator.
On the other hand, SOCV can be calculated by the absolute
value with high precision by learning. However, as this takes
a little period in learning, response characteristics are
relatively low in comparison with SOCi. Therefore, by the
correction amount calculation procedure 703, variation of SOCV
and SOCi in relatively long period is compared to derive the
correction amount to correct the item of d I/Q of the equation
(6). On the other hand, SOCo is corrected with SOCV at
arbitrary timing.
By this, it becomes possible to achieve both response
characteristics of SOCi and high precision calculation of
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SOCV. On the other hand, the correction amount is derived by
comparing the results of calculation per se to feed back the
results of calculation for subsequent calculations to repeat
learning calculation. Furthermore, since the individual
difference of Q, secular change, influence of ~ and
accumulation of error in the current integrator can be
corrected by learning calculation based on SOCV, these
correction parameters are not required. Accordingly, it
becomes possible to eliminate significant periods and loads
spent for obtaining these parameters or data.
In addition, as the calculation procedure A 701, similar
effects can be obtained using SOC calculated from the
resistance of the power storage means or SOC calculated from
electrolyte concentration.
Fig. 7 is a diagrammatic illustration showing a
relationship between OCV and SOC of the power storage means.
Associating with increase of SOC, OCV is increased gradually.
Such relationship of SOC and OCV is shown in many power
storage means, such as lithium secondary battery, electric
double layer capacitor and so forth.
Using the characteristics of the power storage means of
Fig. 7, the maximum charge amount (full capacity) Q can be
derived. For example, assuming that two different charge
states are SOCl ana SOC2, residual capacity corresponding to
these are Ql and Q2 and current integrated value there between
is dQ (= d I), the following equations (8) to (11) are
established:
SOCl = 100 x Ql/Q ..... (8)
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SOC2 = 100 x Q2/Q ..... (9)
SOCl - SOC2 = 100 x(Ql - Q2)/Q
= 100 x dQ/Q ..... (10)
Q = 100 x dQ/(SOC1 - SOC2) ..... (11)
Thus, full capacity Q of the power storage means can be
derived. Similarly, full capacity Q can be derived using SOC
derived from the electrolyte concentration or internal
resistor and the current integration value.
Then, by feeding back Q thus derived to the equation (6),
influences of individual differences of Q and secular change
can be corrected to permit further precise state detection.
Correction parameters of the individual differences and
secular change becomes unnecessary to eliminate significant
time and load required for obtaining parameters and data.
Table 2 is a table showing a relationship of the
correction coefficient K of the full capacity Q relative to
the initial capacity QO of the power storage means. In this
embodiment, a ratio between the initial capacity of the power
storage means stored in the storage means and the full
capacity Q derived from the equation (11) is derived to obtain
a correction coefficient K depending thereon.
TABLE 2
Q/Qo 1.0 0.9 0.8 0.7 0.6 0.5
L K 1.0 0.81 0.64 0.49 0.36 0.25
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In general, the power storage means decreases the full
capacity associated with secular change. At the same time,
the internal resistance is increased. A continuous charge and
discharge period derived from the residual capacity, allowable
charge current and allowable discharge current derived from
equations (3) and (4) and allowable heat generation amount (or
cooling control) or allowable charge and discharge power and
so forth have to be corrected, the initial values depending
upon secular change. The foregoing correct coefficient is
used for correction of these. Then, these values are
preferably optimized depending upon the kind or system of the
power storage means.
As set forth above, with the present invention,
influences of individual differences or secular change of the
continuous charge and discharge period, allowable charge
current and allowable discharge current and allowable heat
generation amount (or cooling control) or allowable charge and
discharge power and so forth is corrected to permit more
precise state detection. On the other hand, these correction
parameters become unnecessary. Accordingly, it becomes
possible to eliminate significant period and load spent for
obtaining these parameters or data.
Fig. 8 is a constructional illustration of a photovoltaic
generation equipment, to which the state detection system and
the power source unit according to the present invention is
applied. In Fig. 8, the reference numeral 1001 denotes a
commercial power source, 1002 denotes a photovoltaic
generation equipment, 1003 denotes a load device, 1004 denotes
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a control converter, 1005 denotes a switch, 1006 denotes a
state detecting device and 1007 denotes a power source unit.
The state detecting device 1006 is constructed with the
measuring means 102, the storage means 103, the arithmetic
means 104, the communication means 105, the first correction
means 106 and the second correction means 107. On the other
hand, the power source unit 1007 is constructed with a series
connected circuit with a plurality of power storage means 101
connected in series, and the state detecting device 1006.
Both ends of the series connected circuit of the power
storage means 101 is connected to the control converter 1004.
The control converter 1004 is further connected to the
commercial power source 1001, the photovoltaic generation
equipment 1002 and the load device 1003 via the switches 1005
respectively. On the other hand, by a control of a main
control unit (MCU) of the control converter 1004, the
commercial power source 1001, the photovoltaic generation
equipment 1002, the load device 1003 are switched by the
switches 1005. Also, a command from the state detection
device 1005 is connected by bidirectional communication
between the communication means 105 and the MCU.
The photovoltaic generation equipment converts sun light
into a direct current by solar cells and outputs an
alternating current power by an inverter device. On the other
hand, the load device 1003 is household electric equipment,
such as an air conditioner, a refrigerator, an electronic
oven, lighting and so forth, an electric equipment, such as a
motor, an elevator, a computer, a medical equipment and so
forth, or a secondary power source unit. Then, the control
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converter 1004 is a charge and discharge device which converts
the alternating current power into the direct current power or
converts the direct current power into the alternating current
power, and also serves as a controller for controlling charge
and discharge and controlling the equipment, such as the
photovoltaic generation equipment 1002, the load device 1003
and so forth.
Here, this equipment may incorporate the switch 1005
therein. On the other hand, the power source unit according
to the present invention may take connections other than those
illustrated herein. With the shown embodiments, when
sufficient power required by the load device 1003 cannot be
supplied from the commercial power source 1001 or the
photovoltaic generation equipment 1002, the power is supplied
from the power storage means 101 via the control converter
1004. On the other hand, when power supply from the
commercial power source 1001 or the photovoltaic generation
equipment 1002 becomes excessive, the excessive power is
stored in the power storage means 101 via the control
converter 1004.
During these operations, the state detecting device 1007
may detect state of the power storage means 101 by each of the
first to the sixth embodiments or the combination thereof.
For combination of these, syllogism is applied. On the other
hand, the result of state detection is fed to the control
converter 1004 as a control amount for state or allowable
charge and discharge current and so forth of the power storage
means 101. The control converter 1004 controls charging and
discharging depending thereon. Particularly, since the state
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detection device 1007 can perform high precision state
detection, the power storage means 101 can be used safely and
effectively.
On the other hand, in the embodiment shown, it becomes
possible to lower contract demand or power consumption of the
commercial power source 1001 and to lower rated power to be
generated by the photovoltaic generation equipment 1002 to
permit reduction of investment or running cost. When power
consumption is concentrated to a certain time zone, the power
is supplied to the commercial power source 1001 from the power
source unit. During a time where power consumption is small,
power is accumulated in the power source unit to absorb
concentration of power consumption and to equalize power
consumption.
Furthermore, the control converter 1004 monitors power
consumption of the load device 1003 and controls the load
device 1003. Therefore, power saving and effective use of the
power can be achieved. As set forth above, with the shown
embodiment, the state detection method, the state detection
system of the power storage means in high precision and with
smaller number of characteristic data to be used for
calculation, and the power source unit, distribution type
power storage device employing the same can be realized.
Fig. 9 is a constructional illustration showing an
embodiment of an electric vehicle, to which the state
detection system and the power source unit according to the
present invention is applied. In Fig. 9, the reference
numeral 1101 denotes a motor generator, 1102 denotes a direct
current load device. The motor generator 1101 is connected to
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the series connected circuit of a plurality of power storage
means 101 via the control converter 1004. The motor generator
1101 is directly coupled with a wheel in case of the electric
vehicle. In case of a hybrid electric vehicle, an internal
combustion engine is further coupled for assisting start-up or
driving force (power running) and generation (re-generation).
During power running, power is supplied from the power source
unit 1007 to the motor generator 1101. During re-generation,
power is supplied from the power generator 1101 to the power
source unit 1007.
On the other hand, the direct current load device 1102 is
an electric load, such as electromagnetic value, audio unit
and so forth, or the secondary power source unit. The direct
current load device 1102 is connected to the series connected
circuit of the power storage means via the switch 1005.
Even in the shown embodiment, the state detection device
1007 may employ respective of the first to sixth embodiment or
combination thereof. Via the communication means, state of
the power storage means 101 or control amount of the allowable
charge and discharge current or the like is fed to the control
converter 1004 so that the control converter 1004 may control
charging and discharging depending thereon. Particularly,
since the state detection device 1007 may perform state
detection with high precision, the power storage means 101 may
be used safely and effectively.
By this, the hybrid electric vehicle which can assist to
a torque of the internal combustion engine upon star-running
and can accumulate kinetic energy by converting into electric
power, can be realized.
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More particularly, the state detecting system according
to the present invention comprises a measuring means for
measuring one or more of voltage, current, temperature,
resistance and electrolyte concentration of a power storage
means, a storage means for storing at least one of
characteristic data of the power storage means, calculation
coefficient and calculation procedure and preliminarily set
value to be considered as true value or set information to be
a logic considered as true phenomenon, an arithmetic means for
calculating state of the power storage means on the basis of
the measured value of the measuring means and the set
information of the storage means and calculating a correction
amount by comparing the calculation result and the set
information, and communication means for communicating the
calculation result of the arithmetic means to other device,
and a correcting means for correcting the value of the storage
means or input of the arithmetic means. By this, correction
can be performed by comparing the calculation result and set
information and feeding back the difference to subsequent
calculation. Therefore, the state detection system which can
detect state of power storage means achieving high accuracy
with less accurate characteristic data is realized.
The correction means according to the present invention
may determine a correction amount based on discrepancy of the
calculation result of the calculation means and set
information. For example, it is natural that charge state
increases during charging. If a discrepancy occurs in that
the charge state decreases during charging, this is corrected.
In addition, it is natural when charge and discharge is
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performed within the allowable charge and discharge current
value capable of charging and discharging the power storage
within allowable use voltage range. Thus, overcharging or
over discharging is not detected. If overcharging or over
discharging is detected, allowable charge and discharge
current is corrected. As set forth, according to the present
invention, normal characteristics or natural phenomenon is
taken as set information and compares with the calculation
result to correct the value of the storage means or input of
the arithmetic means is corrected with learning.
On the other hand, in the present invention, the value of
the measuring means, calculation result or calculation
procedure of the arithmetic means, when the current value is
smaller than or equal to the predetermined value, the
correction value may be the current value. For example, under
a condition where influence of self-discharge is small and if
current value is OA, charge state varies little. Namely, when
current value is OA, variation amount of charge state being 0
is taken as set value as true value. If current value is OA,
charge state is varied; correction is performed to feed back
the variation amount to the subsequent calculation with
learning.
The storage means of the present invention has two or
more mutually different calculation procedures. The
arithmetic means can derive the correction value from the
calculation results of the calculation procedures to perform
correction for feeding back the correction value to the
subsequent calculation with learning.
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On the other hand, the arithmetic means has the charge
state calculating means and current integration means of the
power storage means to calculate capacity of the power storage
means based on two different charge states and current
integration value during the period. In this case, the
storage means stores the initial capacity of the power storage
means, and correction means may determine the correction
information based on the capacity and initial capacity of the
power storage means_
With the present invention, by performing correction with
feeding back the correction information obtained by
predetermined arithmetic operation for the subsequent
calculation and storage information for calculation, it
becomes possible to provide the state detection system which
can detect state, such as state of charge or state of health
of the power storage means with high precision even when the
precision of characteristic data used for calculation is
small.
Correction is performed by comparing the calculation
result with the set information, such as set value or logic of
the calculation result feed back to the subsequent
calculation. Therefore, the state detecting system detecting
state information of the power storage means with high
precision with less precise characteristic data used for
calculation with using simple arithmetic expressions, can be
realized.