Serial multi-battery charger with independent simultaneous charge and discharge
First Claim
1. A serial battery charger comprising:
- a first power manager that generates a charging current from a power source, the charging current flowing into a first charging terminal and returning from a second charging terminal of a battery matrix;
a second power manager that receives a discharging current, the discharging current flowing from a first discharging terminal, through the second power manager and a load, and returning to a second discharging terminal;
the battery matrix having a first battery slot and a second battery slot each for receiving a battery, the battery being in a charging state when a voltage across the battery is less than a maximum voltage, the battery being in an over-charge-protected state when the voltage across the battery exceeds the maximum voltage, the battery being in an absent state when the battery is not present in the battery slot;
a microcontroller that reads voltages within the battery matrix to determine when the voltage across the battery exceeds or is less than the maximum voltage, the microcontroller determining states of batteries in the battery matrix and generating a switch configuration based on the states of the batteries;
a plurality of switches in the battery matrix, the plurality of switches being controlled by the switch configuration generated by the microcontroller,wherein the microcontroller generates the switch configuration to configure the plurality of switches to allow the discharging current to flow between the first and second discharging terminals, wherein the discharging current flows serially through all of the batteries in the charging state and all of the batteries in the over-charge-protected state that are installed in the battery matrix;
wherein the switch configuration also configures the plurality of switches to allow the charging current to flow between the first and second charging terminals, wherein the charging current flows serially through all of the batteries in the charging state and none of the batteries in the over-charge-protected state and none of the batteries in the absent state in the battery matrix;
wherein the battery matrix comprises;
a first battery in a first battery slot;
a second battery in a second battery slot;
an intermediate node between a negative terminal of the first battery and a positive terminal of the second battery;
wherein a positive terminal of the first battery is connected to the first discharging terminal;
wherein a negative terminal of the second battery is connected to the second discharging terminal,whereby the first battery and the second battery are connected in series between the first discharging terminal and the second discharging terminal;
wherein the plurality of switches in the battery matrix comprises;
a first switch coupled to conduct current between the first discharging terminal and the first charging terminal;
a second switch coupled to conduct current between the first charging terminal and the intermediate node;
a third switch coupled to conduct current between the intermediate node and the second charging terminal; and
a fourth switch coupled to conduct current between the second charging terminal and the second discharging terminal.
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Accused Products
Abstract
A serial battery charger has a battery matrix with switches that are configured by a microcontroller that reads voltages between batteries to determine if each battery is fully-charged, charging, or absent. A switch configuration allows charging and discharging currents to flow simultaneously, and allows discharging current but blocks charging current from fully-charged batteries to prevent over-charging. The charging current flows through all charging batteries in series while the discharging current flows from all fully-charged and charging batteries in series. Blocking and bypass switches route the charging current to all charging batteries in series, but bypass all fully-charged and absent batteries. The blocking and bypass switches route the discharging current serially through all fully-charged and charging batteries in the battery matrix while avoiding absent batteries. The switches are controlled by the switch configuration from the microcontroller. Larger battery matrixes have row and column lines that are connected by connecting switches.
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Citations
12 Claims
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1. A serial battery charger comprising:
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a first power manager that generates a charging current from a power source, the charging current flowing into a first charging terminal and returning from a second charging terminal of a battery matrix; a second power manager that receives a discharging current, the discharging current flowing from a first discharging terminal, through the second power manager and a load, and returning to a second discharging terminal; the battery matrix having a first battery slot and a second battery slot each for receiving a battery, the battery being in a charging state when a voltage across the battery is less than a maximum voltage, the battery being in an over-charge-protected state when the voltage across the battery exceeds the maximum voltage, the battery being in an absent state when the battery is not present in the battery slot; a microcontroller that reads voltages within the battery matrix to determine when the voltage across the battery exceeds or is less than the maximum voltage, the microcontroller determining states of batteries in the battery matrix and generating a switch configuration based on the states of the batteries; a plurality of switches in the battery matrix, the plurality of switches being controlled by the switch configuration generated by the microcontroller, wherein the microcontroller generates the switch configuration to configure the plurality of switches to allow the discharging current to flow between the first and second discharging terminals, wherein the discharging current flows serially through all of the batteries in the charging state and all of the batteries in the over-charge-protected state that are installed in the battery matrix; wherein the switch configuration also configures the plurality of switches to allow the charging current to flow between the first and second charging terminals, wherein the charging current flows serially through all of the batteries in the charging state and none of the batteries in the over-charge-protected state and none of the batteries in the absent state in the battery matrix; wherein the battery matrix comprises; a first battery in a first battery slot; a second battery in a second battery slot; an intermediate node between a negative terminal of the first battery and a positive terminal of the second battery; wherein a positive terminal of the first battery is connected to the first discharging terminal; wherein a negative terminal of the second battery is connected to the second discharging terminal, whereby the first battery and the second battery are connected in series between the first discharging terminal and the second discharging terminal; wherein the plurality of switches in the battery matrix comprises; a first switch coupled to conduct current between the first discharging terminal and the first charging terminal; a second switch coupled to conduct current between the first charging terminal and the intermediate node; a third switch coupled to conduct current between the intermediate node and the second charging terminal; and a fourth switch coupled to conduct current between the second charging terminal and the second discharging terminal. - View Dependent Claims (2, 3, 4, 5)
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6. A multiple battery charger comprising:
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a plurality of battery slots, each battery slot for accepting a battery; a plurality of blocking switches, each blocking switch being in series with a battery slot in the plurality of battery slots; a plurality of bypass switches, each bypass switch being in parallel with a battery slot in the plurality of battery slots; a charging current generator that uses a power source to generate a charging current that flows into a first charging node, in series through a plurality of charging batteries installed in the plurality of battery slots, and returning through a second charging node; a discharging current load that receives from a first discharging node a discharging current generated by the plurality of charging batteries and by a plurality of fully-charged batteries installed in the plurality of battery slots, and returns to the plurality of battery slots through a second discharging node; wherein the discharging current is routed in series through each battery of the fully-charged and charging batteries installed in the plurality of battery slots; a microcontroller that reads a first voltage of the first discharging node, and at least one intermediate voltage of an intermediate node between batteries, the microcontroller selecting a switch configuration based on voltages read, the switch configuration generating control signals to control the plurality of blocking switches and the plurality of bypass switches to route the charging current to all charging batteries and to none of the fully-charged batteries and to none of the plurality of battery slots missing a battery, and to route the discharging current to all charging batteries and to all of the fully-charged batteries in series and to none of the plurality of battery slots missing a battery; wherein the charging current and the discharging current flow at a same time, sharing at least some switches in the plurality of bypass switches and in the plurality of blocking switches; wherein the charging current is routed to charging batteries and bypassed around fully-charged batteries while the discharging current is routed to charging batteries and fully-charged batteries; wherein the charging current flows without a diode voltage drop due to a diode in a path of the charging current; wherein the discharging current flows without a diode voltage drop due to a diode in a path of the discharging current; whereby diode voltage drops are avoided and whereby simultaneous charging and discharging currents flow serially through batteries. - View Dependent Claims (7, 8)
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9. A multiple battery charger comprising:
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a plurality of battery slots, each battery slot for accepting a battery; a plurality of blocking switches, each blocking switch being in series with a battery slot in the plurality of battery slots; a plurality of bypass switches, each bypass switch being in parallel with a battery slot in the plurality of battery slots; a charging current generator that uses a power source to generate a charging current that flows into a first charging node, in series through a plurality of charging batteries installed in the plurality of battery slots, and returning through a second charging node; a discharging current load that receives from a first discharging node a discharging current generated by the plurality of charging batteries and by a plurality of fully-charged batteries installed in the plurality of battery slots, and returns to the plurality of battery slots through a second discharging node; wherein the discharging current is routed in series through each battery of the fully-charged and charging batteries installed in the plurality of battery slots; a microcontroller that reads a first voltage of the first discharging node, and at least one intermediate voltage of an intermediate node between batteries, the microcontroller selecting a switch configuration based on voltages read, the switch configuration generating control signals to control the plurality of blocking switches and the plurality of bypass switches to route the charging current to all charging batteries and to none of the fully-charged batteries and to none of the plurality of battery slots missing a battery, and to route the discharging current to all charging batteries and to all of the fully-charged batteries in series and to none of the plurality of battery slots missing a battery; wherein the charging current and the discharging current flow at a same time, sharing at least some switches in the plurality of bypass switches and in the plurality of blocking switches; wherein the charging current is routed to charging batteries and bypassed around fully-charged batteries while the discharging current is routed to charging batteries and fully-charged batteries; a first battery in a first battery slot; a second battery in a second battery slot; wherein the intermediate node is between a negative terminal of the first battery and a positive terminal of the second battery; wherein a positive terminal of the first battery is connected to the first discharging node; wherein a negative terminal of the second battery is connected to the second discharging node, whereby the first battery and the second battery are connected in series between the first discharging node and the second discharging node; wherein the plurality of blocking switches comprises; a first switch coupled to conduct current between the first discharging node and the first charging node; a fourth switch coupled to conduct current between the second charging node and the second discharging node; wherein the plurality of bypass switches comprises; a second switch coupled to conduct current between the first charging node and the intermediate node; and a third switch coupled to conduct current between the intermediate node and the second charging node; whereby simultaneous charging and discharging currents flow serially through batteries. - View Dependent Claims (10, 11, 12)
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Specification