Electric power conversion systems – Current conversion – With means to introduce or eliminate frequency components
Reexamination Certificate
2001-03-13
2002-08-06
Sterrett, Jeffrey (Department: 2838)
Electric power conversion systems
Current conversion
With means to introduce or eliminate frequency components
C363S071000, C363S097000
Reexamination Certificate
active
06430066
ABSTRACT:
BACKGROUND OF THE INVENTION
The present invention relates to an electric power system.
A conventional battery protective circuit for secondary batteries connected in series is disclosed in Japanese laid-open Patent Publication Hei 8-78060.
FIG. 11
is a view showing a modification of the conventional battery protective circuit of Japanese laid-open Patent Publication Hei 8-78060. In
FIG. 11
, reference numerals
1101
indicate secondary batteries,
1102
voltage detection circuits,
1103
resistors,
1104
comparators, and
1105
an FET.
The two secondary batteries
1101
are connected in series and the voltage detection circuits
1102
are connected across the respective secondary batteries
1101
. To each input of the comparators
1104
, a reference voltage by the divided voltage of the resistors
1103
connected in series and the output of the voltage detection circuits
1102
are connected respectively.
Both output of the comparators
1104
are connected to the gate of the FET
1105
inserted in series with the secondary batteries
1101
.
The voltage detection circuits
1102
detect the voltages of the secondary batteries
1101
respectively and the comparators
1104
compare the detected value with the reference voltage by the divided voltage of resistor. When any of the secondary batteries
1101
is fully charged and the detected value of any of the voltage detection circuits
1102
is more than the reference voltage, the output of any of the comparators
1104
becomes low revel, and the FET
1105
is turned off, and the charging is stopped.
The conventional battery protective circuit requires the exclusive voltage detection circuits
1102
respectively for the two secondary batteries
1101
connected in series. The reason is that the potential levels of the detected values of the voltage detection circuits
1102
are different from each other on the basis of the lowest negative terminal of the secondary batteries
1101
connected in series.
The voltage division resistors
1103
must be also installed exclusively for the secondary batteries
1101
respectively.
The values of the resistors
1103
are always varied from the nominal value within a certain range in the production process, so that the reference value for specifying full charging is also varied and the precision of the reference voltage is lowered.
Further, to make the different potential levels of detected values of the voltage detection circuits
1102
equal by level-shifting, the comparators
1104
must be installed exclusively for the secondary batteries
1101
respectively. Moreover, the withstand voltages of the comparators
1104
must be equal to the total voltage of the batteries connected in series.
Even if a circuit fulfills the same function for each of the secondary batteries like this, a circuit fit to each potential level is required for each of the secondary batteries. Accordingly, assuming that a plurality of batteries
1101
are additionally connected in series, the number of circuits increases and the cost, size, and power consumption also increase. Parts of the comparators
1104
having a withstand voltage meeting the total voltage of the batteries connected in series do not exist actually and it is difficult to realize this circuit.
SUMMARY OF THE INVENTION
The electric power system of the present invention has a plurality of capacitors connected in series, a plurality of DC-AC conversion circuits for converting and outputting each DC voltage of the plurality of capacitors to an AC signal that an AC component equivalent to the inter-terminal DC voltage of each of the capacitors is superimposed on the each DC voltage, a plurality of condenser couplers for breaking the each DC voltage from each output of the plurality of DC-AC conversion circuits and outputting the AC components respectively, and a processing circuit for selecting each output of the plurality of condenser couplers and detecting the inter-terminal DC voltage of the corresponding capacitor from the selected AC component.
The electric power system of the present invention has a plurality of capacitors connected in series, a plurality of DC-AC conversion circuits for converting and outputting each DC voltage of the plurality of capacitors to an AC signal that an AC component equivalent to the inter-terminal DC voltage of each of the capacitors is superimposed on the each DC voltage, a plurality of condenser couplers for breaking the each DC voltage from each output of the plurality of DC-AC conversion circuits and outputting the AC components respectively, a processing circuit for selecting each output of the plurality of condenser couplers, converting the selected AC component to a digital signal, and detecting the inter-terminal DC voltage of the corresponding capacitor from the digital signal, wherein the processing circuit has a selection circuit for selecting output from the plurality of condenser couplers, an A-D conversion circuit for converting the selected AC component to a digital signal, and a microcomputer for detecting the inter-terminal DC voltage of the corresponding capacitor from the digital signal.
The present invention is an electric power system, wherein the processing circuit has an AC-DC conversion circuit for converting the AC component selected by the selection circuit to a DC voltage which is full-wave rectified and supplies the converted DC voltage to the A-D conversion circuit.
The present invention is an electric power system wherein the plurality of DC-AC conversion circuits have a plurality of control power sources for outputting a voltage higher than the inter-terminal voltage of the plurality of capacitors and perform the conversion operation of the plurality of DC-AC conversion circuits by the output of the plurality of control power sources.
The present invention is an electric power system, wherein the control circuit has a plurality of voltage control voltage sources for outputting a voltage proportional to the inter-terminal voltage of each capacitor of the plurality of capacitors and the output of the plurality of voltage control voltage sources is used as a power source of the AC-DC conversion circuit, and wherein the control circuit has a storage circuit for storing a correction formula and the output of the A-D conversion circuit is correction-operated by the microcomputer on the basis of the storage contents of the storage circuit.
The present invention is an electric power system, wherein each circuit of at least a part of the DC-AC conversion circuit, condenser coupler, and control circuit is each enclosed by an insulating trench formed on the substrate.
REFERENCES:
patent: 4203151 (1980-05-01), Baker
patent: 4628438 (1986-12-01), Montague
patent: 4685043 (1987-08-01), Mehnert
patent: 5841645 (1998-11-01), Sato
patent: 6031738 (2000-02-01), Lipo et al.
patent: 6151227 (2000-11-01), Mizutani et al.
Emori Akihiko
Isogai Masato
Kinoshita Takuya
Sonobe Hisao
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