A method of conducting an operation including a battery. The battery includes a cell having a voltage. Power is transferable between the cell and the electrical device. A controller is operable to control a function of the battery pack. The controller is also operable with a voltage at least one of
A method of conducting an operation including a battery. The battery includes a cell having a voltage. Power is transferable between the cell and the electrical device. A controller is operable to control a function of the battery pack. The controller is also operable with a voltage at least one of equal to and greater than an operating voltage threshold. The cell is operable to selectively supply voltage to the controller. The method includes the act of enabling the controller to operate when the voltage supplied by the cell is below the operating voltage threshold.
대표청구항▼
We claim: 1. A battery pack configured to supply power to a cordless power tool, the cordless power tool having a motor, the battery pack comprising: a plurality of battery cells operable to supply a battery pack discharge current to the motor of the cordless power tool, each of the battery cells h
We claim: 1. A battery pack configured to supply power to a cordless power tool, the cordless power tool having a motor, the battery pack comprising: a plurality of battery cells operable to supply a battery pack discharge current to the motor of the cordless power tool, each of the battery cells having a battery cell state of charge; a switch operable to be alternately positioned in one of a conducting state and a non-conducting state, the switch further operable to enable the supply of discharge current from the battery pack to the motor when the switch is positioned in the conducting state and operable to interrupt the supply of discharge current from the battery pack to the motor when the switch is positioned in the non-conducting state; a controller electrically connected to the switch and to each of the battery cells via a respective connection to each cell, operable to monitor the respective battery cell state of charge of each of the battery cells, operable to control operation of the battery pack, and operable to control the positioning of the switch, the controller including a microcontroller; and a plurality of electrical paths between the controller and the cell connections, each electrical path being associated with a different one of the cell connections, wherein each electrical path among the plurality of electrical paths is independent of the other electrical paths among the plurality of electrical paths, and wherein no two electrical paths share an electrically conductive component, wherein the controller modifies operation of the battery pack by causing the switch to move from the conducting state to the non-conducting state to interrupt the supply of discharge current from the battery pack to the motor when the monitored respective battery cell state of charge of one of the battery cells reaches a predetermined threshold. 2. The battery pack as set forth in claim 1 and wherein the controller modifies operation of the battery pack by varying the discharge current being supplied to the motor of the cordless power tool over a time period. 3. The battery pack as set forth in claim 1 and wherein the controller modifies operation of the battery pack by decreasing the discharge current being supplied to the motor of the cordless power tool over a time period. 4. The battery pack as set forth in claim 1 and wherein the controller modifies operation of the battery pack by interrupting the discharge current being supplied to the motor of the cordless power tool such that substantially no discharge current is supplied to the motor of the cordless power tool for a time period. 5. The battery pack as set forth in claim 1 and wherein the controller further modifies operation of the battery pack when the monitored respective battery cell state of charge of one of the battery cells reaches a second predetermined threshold, the second predetermined threshold being different than the predetermined threshold. 6. The battery pack as set forth in claim 5 and wherein the second predetermined threshold is greater than the predetermined threshold. 7. The battery pack as set forth in claim 5 and wherein the controller further modifies operation of the battery pack by causing the switch to move from the non-conducting state to the conducting state to conduct the discharge current when the monitored respective battery cell state of charge of one of the battery cells reaches the second predetermined threshold. 8. The battery pack as set forth in claim 7 and wherein the second predetermined threshold is greater than the predetermined threshold. 9. The battery pack as set forth in claim 1 and wherein the plurality of battery cells includes five battery cells. 10. The battery pack as set forth in claim 1 and wherein the plurality of battery cells includes seven battery cells. 11. The battery pack as set forth in claim 1 and wherein each of the battery cells has a battery cell chemistry that is Lithium-based. 12. The battery pack as set forth in claim 11 and wherein the battery cell chemistry of each of the battery cells is a Lithium-ion chemistry. 13. The battery pack as set forth in claim 11 and wherein the battery cell chemistry of each of the battery cells is a Lithium Manganese Spinel chemistry. 14. The battery pack as set forth in claim 11 and wherein the battery cell chemistry of each of the battery cells is a Lithium Cobalt chemistry. 15. The battery pack as set forth in claim 11 and wherein the battery cell chemistry of each of the battery cells is a Lithium Manganese Nickel chemistry. 16. An electrical combination of a cordless power tool and a battery pack, the electrical combination comprising: a plurality of battery cells included in the battery pack and operable to supply a battery pack discharge current to a motor of the cordless power tool, each of the battery cells having a battery cell state of charge; a switch operable to interrupt the supply of discharge current from the battery pack to the motor of the cordless power tool when the switch is positioned in a non-conducting state; a controller electrically connected to the switch and to each of the battery cells via a respective connection to each cell, operable to monitor the respective battery cell state of charge of each of the battery cells, and operable to control the supply of discharge current from the battery pack to the motor of the cordless power tool, the controller varying the discharge current being supplied to the motor when the monitored respective battery cell state of charge of one of the battery cells reaches a predetermined threshold; a plurality of electrical paths between the controller and the cell connections, each electrical path being associated with a different one of the cell connections, wherein each electrical path among the plurality of electrical paths is independent of the other electrical paths among the plurality of electrical paths, and wherein no two electrical paths share an electrically conductive component; and a plurality of transistors, each of the transistors included in a different one of the electrical paths, the transistors reducing parasitic current draw when a connection is not being used to monitor a battery cell state of charge, p1 wherein the controller is operable to control the switch to interrupt the supply of discharge current from the battery pack to the motor when the monitored respective battery cell state of charge of one of the battery cells reaches a predetermined threshold. 17. A method of operating a cordless power tool powered by a plurality of battery cells of a battery pack, the cordless power tool having a motor and a trigger switch, the method comprising: supplying a battery pack discharge current to the motor of the cordless power tool in response to a user activation of the trigger switch; monitoring a respective battery cell state of charge of each of the battery cells, by a microcontroller electrically connected to each of the battery cells via a respective connection to each cell, wherein a plurality of electrical paths exist between the microcontroller and the cell connections, each electrical path being associated with a different one of the cell connections, wherein each electrical path among the plurality of electrical paths is independent of the other electrical paths among the plurality of electrical paths, wherein no two electrical paths share an electrically conductive component, and wherein each electrical path includes a transistor to reduce parasitic current draw when a connection is not being used to monitor a battery cell; and controlling a controlled switch to interrupt the supply of discharge current from the battery pack to the motor when the monitored respective battery cell state of charge of at least one of the battery cells reaches a predetermined threshold, wherein the controlling of the controlled switch to interrupt the supply of discharge current is independent of a user deactivation of the trigger switch. 18. The method of operating a cordless power tool as set forth in claim 17 and further comprising: re-supplying the discharge current from the battery pack to the motor of the cordless power tool when the monitored respective battery cell state of charge of the at least one of the battery cells recovers to a second predetermined threshold, the second predetermined threshold being greater than the predetermined threshold.
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