Cell site power system management, including battery circuit management
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
H02J-001/00
H02J-003/00
출원번호
US-0676022
(2012-11-13)
등록번호
US-8497600
(2013-07-30)
발명자
/ 주소
Fischer, Steve
출원인 / 주소
T-Mobile USA, Inc.
대리인 / 주소
Perkins Coie LLP
인용정보
피인용 횟수 :
4인용 특허 :
33
초록▼
Systems, apparatuses, and methods for managing battery circuits in systems such as wireless communications service base stations are disclosed. An example apparatus includes a battery circuit having multiple strings of one or more serially connected batteries. The apparatus may be configured to rota
Systems, apparatuses, and methods for managing battery circuits in systems such as wireless communications service base stations are disclosed. An example apparatus includes a battery circuit having multiple strings of one or more serially connected batteries. The apparatus may be configured to rotate between battery strings such that one or more strings are maintained at or near an upper threshold while other string(s) are disconnected from the maintained string(s). The apparatus may also be configured to charge the battery circuit, to test the battery circuit, and to handle power failures.
대표청구항▼
1. A system for providing supplementary or emergency power, the system comprising: a battery circuit connected to a battery circuit node, wherein the battery circuit node is configured to provide battery power, and wherein the battery circuit comprises— multiple battery strings, wherein each battery
1. A system for providing supplementary or emergency power, the system comprising: a battery circuit connected to a battery circuit node, wherein the battery circuit node is configured to provide battery power, and wherein the battery circuit comprises— multiple battery strings, wherein each battery string comprises: one or more batteries coupled in a series configuration; andat least one switch circuit configured to selectively couple the one or more batteries to the battery circuit node,wherein the battery circuit node is configured to provide power, and to receive a charging current for charging batteries; anda power controller configured to: selectively couple one or more of the multiple battery strings in the battery circuit to the battery circuit node, wherein a battery string coupled to the battery circuit node operates as an active battery string,wherein the active battery string provides via the battery circuit node, andwherein the active battery string actively receives the charging current to maintain the active battery string at or near a full charge;selectively decouple at least one of the one or more of the multiple battery strings in the battery circuit from the battery circuit node, wherein a battery string decoupled from the battery circuit node operates as a parked battery string,wherein the parked battery string does not actively receive the charging current; and,upon an occurrence of a battery change event, to— (i) couple the parked battery string to the battery circuit node to provide power and to actively receive the charging current; or(ii) decouple the active battery string from the battery circuit node and to no longer receive the charging current; or(iii) both (i) and (ii); and,wherein the battery change event includes at least one of a specified charging event, a specified testing event, or a power failure event. 2. The system of claim 1, further comprising: a rectifier and switch circuit configured to charge the battery circuit and to route power from the battery circuit to a load under control of the power controller. 3. The system of claim 1, wherein each battery string further includes an associated current sensor, and wherein the power controller is further configured to monitor each of the current sensors to determine a status of an associated battery string. 4. The system of claim 1, wherein the system is configured to test the battery circuit, charge the battery circuit, and provide power to radio and telecommunications circuitry to handle power failures. 5. The system of claim 1, wherein the power controller is further configured to select one or more of the multiple battery strings in the battery circuit to operate as active battery strings on the basis of: a function of time;a measured capacity of one or more battery strings;a calculated capacity of one or more battery strings; oran expected capacity of one or more battery strings. 6. A method, comprising: determining an indication that one or more operations related to management of a battery circuit is to be performed, wherein the battery circuit comprises multiple battery strings, and wherein each battery string in the battery circuit further comprises: two or more batteries arranged in a serial fashion and configured to provide backup power;a string connection switch configured to selectively couple and decouple the battery string from a battery circuit node; and,a sensor configured to provide a string sense signal indicating conditions relating to at least one state of the battery string; andwherein the determined indication comprises: a battery test event indicating that the battery circuit is to be tested;a battery rotation event indicating that at least one of the following is to be performed— (i) rotating one or more battery strings from a parked status into an active status,(ii) rotating one or more battery strings from an active status to a parked status, or(iii) both (i) and (ii);initiating a battery test process when the determined indication comprises the battery test event, wherein the battery test process comprises selectively coupling one or more battery strings to the battery circuit node for testing;initiating a battery rotation process when the determined indication comprises the battery rotation event, wherein the battery rotation process comprises at least one or both of— selectively coupling one or more battery strings to the battery circuit node and into the active status, andselectively decoupling one or more battery strings from the battery circuit node and into the parked status. 7. The method of claim 6, wherein the determined indication further comprises: a battery charging event indicating that the battery circuit is to be charged; anda power failure event indicating that an external power failure exists;and wherein the method further comprises—initiating a battery charging process when the determined indication comprises the battery charging event, wherein the battery charging process comprises selectively coupling one or more battery strings to the battery circuit node for charging; and,initiating a power failure handling process when the determined indication comprises the power failure event, wherein the power failure handling process comprises selectively coupling one or more battery strings in the parked status to the battery circuit node to provide backup power to the radio and telecommunications circuitry at the base station. 8. The method of claim 6, wherein a battery test process and a battery charging process are substantially simultaneously performed, and wherein the method further comprises: selecting a target battery string;adjusting a voltage applied to the battery circuit node to equalize a voltage across one or more active battery strings coupled to the battery circuit node and a voltage across the target battery string, wherein the voltage applied is selected based on at least one of the following: the voltage across the target battery string,the voltage across one or more active battery strings,environmental conditions near the battery circuit, ortypes of batteries in the battery circuit;selectively coupling the target battery string to the battery circuit node when the voltage across the one or more active battery strings approximately reaches the voltage across the target battery string;applying a charging voltage to the battery circuit node, wherein the charging voltage is based on a type of battery in the battery circuit or environmental conditions at or near the battery circuit; andutilizing the string sense signal associated with the target battery string to determine whether the target battery string experiences anomalous currents in response to the applied charging voltage. 9. The method of claim 6, wherein the determined indication comprises a battery charging event, and the detected battery charging event comprises a voltage of a battery string in the battery circuit falling below a threshold value, wherein the threshold value corresponds to a particular level of estimated charge stored in the battery string. 10. The method of claim 6, wherein the determined indication comprises the battery charging event, and the detected battery charging event comprises: a current time occurring within an off-peak time period when commercial utility power rates are lower than rates for other periods; anda voltage of a battery string in the battery circuit falling below a threshold value, wherein the threshold value corresponds to a selected level of estimated charge stored in the battery string. 11. The method of claim 6, wherein selectively coupling a battery string to the battery circuit node comprises: adjusting a voltage across one or more other battery strings coupled to the battery circuit node to approximately equal a voltage across the battery string to be selectively coupled; andutilizing a string connection switch to selectively couple the battery string to the battery circuit node when the voltage across the one or more other battery strings approximately equals the voltage across the battery string that is to be selectively coupled. 12. The method of claim 6, wherein initiating a battery test process further comprises: selecting a target battery string;selectively coupling the target battery string to the battery circuit node; andutilizing the string sense signal associated with the target battery string to determine whether the target battery string experiences anomalous currents in response to a charging source applied to the battery circuit node, and comparing currents in the target battery string to currents in other battery strings in the battery circuit. 13. The method of claim 6, wherein initiating a battery test process further comprises selecting a target battery string, selectively coupling the target battery string to the battery circuit node, and utilizing the string sense signal associated with the target battery string to determine whether the target battery string has a substantially different charging, discharging, or self-discharging rate as compared to one or more other battery strings in the battery circuit. 14. The method of claim 6, wherein initiating a battery test process further comprises selecting a target battery string via an electronically resettable breaker positioned in serial with the one or more batteries of the target battery string, selectively coupling the target battery string to the battery circuit node, and utilizing the electronically resettable breaker to determine whether the target battery string has failed. 15. The method of claim 6, wherein the determined indication comprises a battery test event, and the detected battery test event comprises a voltage of a battery string in the battery circuit falling below a threshold value, wherein the threshold value corresponds to a particular level of estimated charge stored in the battery string. 16. The method of claim 6, wherein initiating a battery rotation process further comprises selecting a battery string to rotate into an active status, wherein the battery string is selected by determining which battery string in the battery circuit has a lowest accumulated time in active status. 17. A non-transitory computer-readable medium carrying instructions that, when performed by a processor, perform a method for a battery circuit, the method comprising: determining an indication that at least one of multiple battery strings is to be charged and tested, wherein each battery string in the battery circuit further comprises: multiple batteries arranged in a serial fashion;a connection switch configured to selectively couple and decouple the battery string; anda sensor configured to provide a string sense signal indicating conditions relating to a state of the battery string; and,initiating battery test and charging processes, further comprising: selecting a target battery string having a voltage;adjusting a voltage applied so that a voltage across one or more active battery strings reaches the voltage across the target battery string, wherein the voltage applied is selected based on at least one of the following: the voltage across the target battery string,the voltage across one or more active battery strings,one or more environmental conditions at or near the battery circuit, ora type of at least one battery in the battery circuit;selectively coupling the target battery string to supply power, as needed, to radio and telecommunications circuitry at a base station when the voltage across the one or more active battery strings approximately reaches the voltage across the target battery string; and,utilizing the string sense signal associated with the target battery string to determine whether the target battery string experiences anomalous currents in response to the applied charging voltage. 18. The non-transitory computer-readable medium of claim 17, wherein a current sensor is coupled to and associated with each battery string; and the method further comprising: monitoring each of the current sensors to determine a status of an associated battery string;monitoring a particular current sensor associated with a particular battery string to determine a self-discharging rate of the particular battery string; andevaluating whether the determined self-discharging rate is anomalous as compared to other battery strings in the battery circuit or based on empirical data. 19. The non-transitory computer-readable medium of claim 17, wherein a current sensor is coupled to and associated with each battery string; and the method further comprising: monitoring each of the current sensors to determine a status of an associated battery string;monitoring a particular current sensor associated with a particular battery string to determine a charging or discharging rate of the particular battery string; andevaluating whether the determined charging or discharging rate is anomalous as compared to other battery strings in the battery circuit or based on empirical data. 20. The non-transitory computer-readable medium of claim 17, further comprising: beginning charging the battery circuit at a first voltage that is based on a voltage across a parked battery string having a lowest string voltage as compared to other parked battery strings,applying a second, higher charging voltage to the battery circuit, andrepeatedly coupling an additional battery string to the battery circuit as a voltage of the coupled battery strings rises to a voltage of the additional battery string due to the second, applied charging voltage.
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