JP7368981B2 - Battery packs and electronic equipment - Google Patents

Description

The present invention relates to a battery pack and an electronic device using the battery pack.

A battery pack is a package that houses one or more unit batteries (cells), peripheral circuits, etc., and is also called an assembled battery. The battery pack supplies power to electronic devices connected to power supply terminals (positive and negative terminals).

Conventionally, in order to prevent short-circuiting of the power supply terminals, a battery pack has been proposed that is configured to supply power to the power supply terminals on the condition that it is detected that the power supply terminals are attached to an electronic device (Patent Document 1) ).

Special table 2014-518058 public relations

In Patent Document 1, one of the plurality of pins included in the interface of the battery pack is used as a dedicated terminal for detecting an electronic device, thereby making it possible to detect that the battery pack is attached to the electronic device. . The use of such dedicated terminals increases the cost of the battery pack and imposes restrictions on the design of electronic devices using the battery pack.

The present invention has been made to alleviate such problems of the prior art. One of the objects of the present invention is to provide a battery pack that can detect whether it is attached to an electronic device without using a dedicated terminal.

The above object has a battery cell, a power supply terminal, and a first communication terminal, and supplies power from the battery cell to an electronic device detachably attached thereto through the power supply terminal, and also supplies power to the electronic device through the first communication terminal. a battery pack that communicates with the electronic device, comprising : a power supply means for providing a first logic level; a determination means for determining whether or not the battery pack is attached to an electronic device based on the level of the first communication terminal ; If the determination means does not determine that the battery pack is attached to the electronic device , the power supply means is connected to the first communication terminal and the connection between the battery cell and the power supply terminal is disconnected, and the determination means determines that the battery pack is attached to the electronic device. This is achieved by a battery pack characterized by having a first control means that connects the battery cell and the power supply terminal when it is determined that the battery cell is attached.

According to the present invention, it is possible to provide a battery pack that can detect whether it is attached to an electronic device without using a dedicated terminal.

A diagram showing a configuration example of a battery pack and an electronic device according to an embodiment. A diagram showing a configuration example of a battery pack and an electronic device according to an embodiment. Timing chart regarding the operation of the battery pack according to the embodiment Flowchart regarding the operation of the battery pack according to the embodiment Flowchart regarding the operation of the battery pack according to the embodiment

Hereinafter, the present invention will be described in detail based on exemplary embodiments thereof with reference to the accompanying drawings. Note that the following embodiments do not limit the claimed invention. Further, although a plurality of features are described in the embodiments, not all of them are essential to the invention, and the plurality of features may be arbitrarily combined. Furthermore, in the accompanying drawings, the same or similar components are designated by the same reference numerals, and redundant description will be omitted.

1A and 1B are diagrams showing a configuration example of a battery pack 101 according to an embodiment of the present invention and an electronic device 201 that can be operated by power supply from the detachable battery pack 101. Note that for the electronic device 201, only the configuration related to connection with the battery pack 101 is shown. The electronic device 201 may be any device that can be operated using power supplied by a battery.

The battery pack 101 is provided with power supply terminals 112 and 114 for supplying power, and a communication terminal 113 for communicating with the electronic device 201 to which the battery pack 101 is attached. An electronic device 201 using a battery pack 101 is provided with power terminals 202 and 204 and a communication terminal 203. The power supply terminals 202 and 204 and the communication terminal 203 are configured to be in contact with the power supply terminals 112 and 114 and the communication terminal 113 of the attached battery pack 101. Here, the power supply terminal 112 and the power supply terminal 202 are positive (+) terminals, and the power supply terminal 114 and the power supply terminal 204 are negative (-) terminals.

Generally, the battery pack 101 is removably attached to a battery accommodating portion of an electronic device 201, and the power terminals 202, 204 and the communication terminal 203 are provided in the battery accommodating portion. In addition, the power supply terminals 202 and 204 and the communication terminal 203 are biased by an elastic member such as a spring in order to realize stable electrical connection with the power supply terminals 112 and 114 and the communication terminal 113 that the battery pack 101 has. It's fine. The device control section 209 of the electronic device 201 can detect whether the lid of the battery storage section is opened or closed. Opening and closing of the lid can be detected, for example, by using a member that moves when the lid is opened and closed, or by using a contact whose contact state changes when the lid is opened and closed.

In the electronic device 201, the power terminal 204 is grounded. Further, the communication line grounding transistor 205 is a PNP transistor whose emitter is connected to the communication terminal 203 , whose base is connected to the device control unit 209 , and whose collector is connected to the power supply terminal 204 . The power supply circuit 207 is connected to the power supply terminal 202 and the device control section 209. The power supply circuit 207 supplies predetermined power to each part of the electronic device 201. A pull-up resistor 208 is provided between the communication terminal 203 and the power supply circuit 207. Further, a pull-down resistor 206 is provided between the base of the transistor 205 and the power supply terminal 204.

The device control unit 209 is a control unit of the electronic device 201, and includes, for example, a memory and a processor, and realizes various functions of the electronic device 201 by the processor executing a program stored in the memory. The device control unit 209 operates using power supplied from the power supply circuit 207. A device control unit 209 controls on/off of the transistor 205. Communication with the battery pack 101 through the communication terminal 203 is also executed by the device control unit 209 .

In the battery pack 101, the battery control unit 105 is a control unit for the battery pack 101, and includes, for example, a memory and a processor, and controls various functions of the battery pack 101 by the processor executing a program stored in the memory. Realize. The battery control unit 105 also performs communication with the electronic device 201 through the communication terminal 113. Further, the battery control unit 105 also controls on/off of the discharge switch 107, pull-up switch 108, and pull-down switch 111. The battery control unit 105 operates using power supplied from the power supply circuit 104. A power supply circuit 104 is connected to the battery cell 102 and supplies power to the battery control unit 105 and the like. The power supply circuit 104 also provides a "Hi" level to the communication terminal 113 when the pull-up switch 108 is on.

Similarly to the electronic device 201, the battery pack 101 is also provided with a pull-up resistor 109 between the communication terminal 113 and the power supply circuit 104. Further, a pull-down resistor 110 is provided between the communication terminal 113 and the power supply terminal 114 (ground line). Note that the resistance value of the pull-down resistor 110 is set to be sufficiently larger (for example, 10 times) than the pull-up resistor 208 of the electronic device 201. Further, a pull-up switch 108 is provided between the pull-up resistor 109 and the power supply circuit 104, and a pull-down switch 111 is provided between the pull-down resistor 110 and the ground line.

A current detection resistor 106 is provided between the negative terminal of the battery cell 102 and the power supply terminal 114. The battery control unit 105 can detect the power supply status from the battery pack 101 to the electronic device 201 by detecting the voltage drop across the current detection resistor 106.

FIG. 1A(a) shows a state in which the battery pack 101 is not attached to the electronic device 201, and the terminals of the battery pack 101 and the terminals of the electronic device 201 are not in contact. FIG. 1A(b) shows a state immediately after the battery pack 101 is attached to the electronic device 201 and the terminals are in contact with each other, after the state shown in FIG. 1A(a). FIG. 1B(a) shows a state in which power is being supplied from the battery pack 101 to the electronic device 201 after the state shown in FIG. 1A(b). Moreover, FIG. 1B(b) shows a state immediately after the battery pack 101 is removed from the electronic device 201 in the state shown in FIG. 1B(a). Note that in the following description, the "Hi" level and the "Lo" level are a predetermined first logic level and a predetermined second logic level, respectively.

In the state shown in FIG. 1A(a), power is not supplied to the electronic device 201 from the battery pack 101. Therefore, power is not supplied from the power supply circuit 207 to the pull-up resistor 208 provided between the communication terminal 203 and the power supply circuit 207 in the electronic device 201 . Furthermore, the base of the transistor 205 has the same potential as the power supply terminal 204 due to the pull-down resistor 206 . Therefore, when power is supplied to the communication terminal 203 in a state where no power is supplied to the power terminal of the electronic device 201 and the device control unit 209 is not operating, the transistor 205 operates in an on state. As a result, the potential of the communication terminal 203 becomes "Lo" level with respect to the potential of the power supply terminal 204. In this way, the transistor 205 functions as a connection means that connects the communication terminal 203 to the "Lo" level when power is supplied to the communication terminal 203 in a state where power is not supplied to the power supply terminals 202 and 204 of the electronic device 201. do.

On the other hand, when the electronic device 201 is not detected, the battery control unit 105 of the battery pack 101 controls the discharge switch 107 to be turned off, the pull-up switch 108 to be turned on, and the pull-down switch 111 to be turned off. Since the discharge switch 107 is off, no power is supplied to the power supply terminals 112 and 114. Since the pull-up switch 108 is on, power is supplied to the pull-up resistor 109 from the power supply circuit 104. However, since the pull-down switch 111 is off, no current flows through the pull-up resistor 109. Therefore, the potential of the receiving terminal RXD of the battery control unit 105 connected to the communication terminal 113 through the communication line 115 is maintained in the "Hi" state.

When the battery pack 101 is attached to the electronic device 201, as shown in FIG. 203 are in contact with each other and electrically connected. However, since the discharge switch 107 is off, power is not supplied to the power terminals 202 and 204 of the electronic device 201.

However, since the communication terminals 113 and 203 are connected, the pull-up power on the power supply circuit 104 side of the battery pack 101 is supplied to the emitter of the transistor 205 via the battery-side pull-up resistor 109 and the communication terminals 113 and 203. Since the transistor 205 is on, a current flows from the emitter to the collector, and the potential of the communication terminals 203 and 113 becomes the ground potential plus the base-emitter voltage of the transistor 205. As a result, the potential of the communication terminal 113 changes from the "Hi" level to the "Lo" level. Battery control unit 105 detects this potential change as a potential change of receiving terminal RXD connected to communication terminal 113.

When it is detected that the potential of the receiving terminal RXD changes from the "Hi" level to the "Lo" level, the battery control unit 105 determines that the electronic device 201 is connected to the battery pack 101. Then, as shown in FIG. 1B(a), the battery control unit 105 turns on the discharge switch 107. As a result, power from the battery cell 102 begins to be supplied to the power terminals 202 and 204 of the electronic device 201 through the power supply terminals 112 and 114.

When power is supplied to the power supply terminals 202 and 204, power supply from the power supply circuit 207 of the electronic device 201 to each part of the electronic device 201 is started. The device control unit 209 starts operating upon receiving power supply. When the device control unit 209 starts operating, it turns off the transistor 205 by setting the base potential of the transistor 205 to "Hi" potential.

When the transistor 205 is turned off, the potential of the communication terminal 203 changes from the ground potential plus the base-emitter voltage of the transistor 205 to the potential of the power supply circuit 207 via the pull-up resistor 208 . As a result, the potential of the receiving terminal RXD of the battery control unit 105 connected to the communication terminal 113 changes to the "Hi" level. Based on this potential change, the battery control unit 105 determines that the electronic device 201 (device control unit 209) has been activated. Then, the battery control unit 105 turns off the pull-up switch 108 and turns on the pull-down switch 111.

As a result, as shown by dotted lines in FIG. 1B(a), the power supply terminal 112 of the battery pack 101, the power supply terminal 202 of the electronic device 201, the power supply circuit 207, the communication terminal 203, the communication terminal 113 of the battery pack 101, the pull-down resistor 110 , current flows through a path called the ground wire. The resistance value of the pull-down resistor 110 is made sufficiently larger than that of the pull-up resistor 208 so that the voltage level of the receiving terminal RXD of the battery control unit 105 maintains the "Hi" level even if current flows through such a path. . For example, by setting the pull-down resistor 110 to approximately 10 times the resistance value of the pull-up resistor 208, the voltage drop across the pull-down resistor 110 will be approximately 1/11 of the voltage of the power supply circuit 207, so that the reception terminal RXD will be " It can be maintained at "Hi" level.

Thereafter, the device control section 209 and the battery control section 105 can exchange information through the communication terminals 203 and 113 by half-duplex communication using an open drain connection using a pull-up on the electronic device 201 side.

When the battery pack 101 is removed from the electronic device 201 in the state shown in FIG. 1B(a) and the state shown in FIG. 1B(b) is reached, the communication terminal between the power supply circuit 207 and the battery pack 101 is 113 is disconnected. As a result, the charge on the communication line 115 flows to the ground line via the pull-down resistor 110 and the pull-down switch 111, and the potential of the receiving terminal RXD of the battery control unit 105 becomes "Lo" level.

When the battery control unit 105 detects that the receiving terminal RXD is at the "Lo" level for a predetermined period of time or more, it determines that the battery pack 101 has been removed from the electronic device 201. Then, the battery control unit 105 turns off the discharge switch 107, turns on the pull-up switch 108, and turns off the pull-down switch 111, returning to the state before the connection shown in FIG. 1A(a). When the battery control unit 105 determines that the battery pack 101 has been removed from the electronic device 201, it turns off the discharge switch 107, thereby preventing a short circuit between the power supply terminals 112 and 114 when the battery pack 101 is not attached to the electronic device 201. can.

FIG. 2 is a timing chart of the operation described using FIGS. 1A and 1B, and shows changes over time in the states and levels of each switch, terminal, transistor, etc.
The period T0 indicates the state before the battery pack 101 and the electronic device 201 are connected, as shown in FIG. 1A(a). During period T0, the discharge switch 107 of the battery pack 101 is off, the pull-up switch 108 is on, the pull-down switch 111 is off, and the communication line 115 is at "Hi" level. Further, power is not supplied to the power terminal 202 of the electronic device 201, and power is not supplied by the power supply circuit 207. Further, the communication line 210 is at "Lo" level. Although the base of the transistor 205 is at "Lo" level, it is in an inactive state because no power is supplied to it.

Periods T1 and T2 indicate the state immediately after the battery pack 101 is attached to the electronic device 201 shown in FIG. 1A(b). The power supply circuit 104 of the battery pack 101 and the emitter of the transistor 205 are connected through the communication terminals 113 and 203, and the transistor whose base is at "Lo" level is turned on. As a result, the communication line 115 changes from the "Hi" level to the "Lo" level. Thereby, the battery control unit 105 determines that the battery pack 101 is attached to the electronic device 201.

The period T3 to T5 is a period during which an operation for starting power supply from the battery pack 101 to the electronic device 201 is executed. First, during period T3, the battery control unit 105 turns the discharge switch 107 from off to on. As a result, power supply from the battery cell 102 to the power supply terminals 202 and 204 of the electronic device 201 via the power supply terminals 112 and 114 is started. Furthermore, power supply from the power supply circuit 207 is started (period T4).

When the device control unit 209 starts operating with power from the power supply circuit 207, it sets the base to the “Hi” level in order to turn off the transistor 205 during a period T5. By turning off the transistor 205, the communication lines 115 and 210 are connected to the power supply circuit 207 through the pull-up resistor 208, and are set to "Hi" level (period T6). Thereby, the connection between the battery pack 101 and the electronic device 201 is established.

When battery control unit 105 detects activation of electronic device 201, it turns on pull-down switch 111 (period T7). If the communication line 115 maintains the "Hi" level even when the pull-down switch 111 is turned on, the battery control unit 105 turns off the pull-up switch 108 (period T8). As a result, the battery control unit 105 and the device control unit 209 are in a state where they can communicate.

When the battery pack 101 is removed from the electronic device 201 while the battery control section 105 and the device control section 209 are in a communicable state, the period shifts to period T9. From period T9 to period T10, communication lines 115 and 210 transition from "Hi" level to "Lo" level. Further, the states of each part connected to the power supply terminals 202, 204 and the communication terminal 203 also change.

When the battery control unit 105 determines that the battery pack 101 has been removed from the electronic device 201 during the period T11, it turns off the discharge switch 107 and turns on the pull-up switch 108. When the battery control unit 105 detects that the communication line 115 has changed to the "Hi" level during the period T12, it turns off the pull-down switch 111 during the period T13. As a result, the battery pack 101 and the electronic device 201 are in a disconnected state during the period T14.

FIG. 3 is a flowchart regarding the operation of the battery control unit 105 from period T0 to period T8 in FIG. The battery control unit 105 executes the operation shown in FIG. 3 by the processor executing a program stored in the memory.

In S302, the battery control unit 105 determines whether the level (potential) of the communication line 115 (or communication terminal 113) is at the "Lo" level. If the communication line 115 is not at the "Lo" level, the battery control unit 105 determines that the battery pack 101 is not attached to the electronic device 201, and periodically executes S302. Furthermore, if the communication line 115 is at the "Lo" level, the battery control unit 105 determines that the battery pack 101 is attached to the electronic device 201, and proceeds to S303.

In S303, the battery control unit 105 turns on the discharge switch 107, and proceeds to S304. As a result, power supply to the electronic device 201 via the power supply terminals 112 and 114 is started.
In S304, the battery control unit 105 determines whether the level of the communication line 115 is "Hi" level. If the communication line 115 is not at the "Hi" level, the battery control unit 105 determines that the electronic device 201 is not activated, and periodically executes S304. Further, if the communication line 115 is at the "Hi" level, the battery control unit 105 determines that the electronic device 201 has started up, and proceeds to S305.

In S305, the battery control unit 105 turns on the pull-down switch 111, and proceeds to S306.
In S306, the battery control unit 105 determines whether the level of the communication line 115 is "Hi" level. If the communication line 115 is no longer at the "Hi" level after turning on the pull-down switch 111, the battery control unit 105 determines that a connection error has occurred, turns off the discharge switch 107 in S309, and turns the other switches to the state before the connection. Return to the state and end the process. In this case, there is a possibility that the operation of the electronic device 201 is abnormal or that the electronic device 201 is not an appropriate device. On the other hand, if the communication line 115 maintains the "Hi" level even after turning on the pull-down switch 111, the battery control unit 105 proceeds to S307.

In S307, the battery control unit 105 turns off the pull-up switch 108, and proceeds to S308.
In S308, the battery control unit 105 determines whether the level of the communication line 115 is "Hi" level. If the communication line 115 is no longer at the "Hi" level after turning off the pull-up switch 108, the battery control unit 105 determines that there is a connection error and ends the process. In this case, there is a possibility that the operation of the electronic device 201 is abnormal or that the electronic device 201 is not an appropriate device. On the other hand, if the communication line 115 maintains the "Hi" level even after the pull-up switch 108 is turned off, the battery control unit 105 determines that the connection between the battery pack 101 and the electronic device 201 is normal. Finish the process. Thereby, the battery pack 101 and the electronic device 201 are in a communicable state (period T8).

FIG. 4 is a flowchart regarding the operation of the battery control unit 105 from period T8 to period T13 in FIG. The battery control unit 105 executes the operation shown in FIG. 4 by the processor executing a program stored in the memory.

In S402, the battery control unit 105 determines whether the level (potential) of the communication line 115 (or communication terminal 113) is at the "Lo" level. If the communication line 115 is not at the "Lo" level, the battery control unit 105 determines that the battery pack 101 is connected to the electronic device 201 and periodically executes S402. Furthermore, if the communication line 115 is at the "Lo" level, the battery control unit 105 determines that the battery pack 101 has been removed from the electronic device 201, and proceeds to S403. This is because the path between the communication terminal 113 and the power supply circuit 207 of the electronic device 201 is cut off, and the communication line 115 is connected to the ground potential through the pull-down resistor 110.

In S403, the battery control unit 105 turns off the discharge switch 107, and proceeds to S404. As a result, the electrical connection between the battery cell 102 and the power supply terminals 112 and 114 is cut off.
In S404, the battery control unit 105 turns on the pull-up switch 108, and proceeds to S405.

In S405, the battery control unit 105 determines whether the level of the communication line 115 is "Hi" level. The battery control unit 105 periodically executes S405 unless the communication line 115 is at a "Hi" level. Further, if the communication line 115 is at "Hi" level, the battery control unit 105 proceeds to S406.

In S406, the battery control unit 105 turns off the pull-down switch 111, and ends the process. By turning off the pull-down switch 111, current from the power supply circuit 104 to the ground wire is cut off, and unnecessary power consumption can be suppressed.

As described above, according to the present embodiment, it is detected that the battery pack is attached to the electronic device based on a change in the level of the communication terminal used for communication with the attached electronic device. Thereby, it is possible to realize a battery pack that can prevent short-circuiting of power supply terminals without providing a dedicated terminal for detecting that the battery pack is attached to an electronic device.

(Other embodiments)
The present invention provides a system or device with a program that implements one or more of the functions of the embodiments described above via a network or a storage medium, and one or more processors in the computer of the system or device reads and executes the program. This can also be achieved by processing. It can also be realized by a circuit (for example, ASIC) that realizes one or more functions.

The present invention is not limited to the contents of the embodiments described above, and various changes and modifications can be made without departing from the spirit and scope of the invention. Therefore, the following claims are hereby appended to disclose the scope of the invention.

DESCRIPTION OF SYMBOLS 101...Battery pack, 102...Battery cell, 105...Battery control part, 107...Discharge switch, 108...Pull-up switch, 111...Pull-down switch, 112, 114...Power supply terminal, 113, 203...Communication terminal, 201...Electronic device , 202, 204...power terminal, 209...control unit

Claims (10)

It has a battery cell, a power supply terminal, and a first communication terminal, and supplies power from the battery cell to an electronic device detachably attached thereto through the power supply terminal, and connects the electronic device to the electronic device through the first communication terminal. A battery pack for communication,
power supply means for providing a first logic level;
determining means for determining whether the battery pack is attached to the electronic device based on the level of the first communication terminal ;
If the determination means does not determine that the battery pack is attached to the electronic device , the power supply means is connected to the first communication terminal and the connection between the battery cell and the power supply terminal is disconnected; A battery pack comprising: first control means that connects the battery cell and the power supply terminal when the determination means determines that the battery pack is attached to the electronic device . When the determining means detects that the level of the first communication terminal changes from the first logical level to a second logical level lower than the first logical level, the determining means determines that the battery pack is attached to the electronic device. The battery pack according to claim 1 , characterized in that the battery pack makes a determination. After determining that the battery pack is attached to the electronic device, the determining means further detects that the level of the first communication terminal changes from the second logic level to the first logic level. Then, it is determined that the electronic device has started operating,
The first control means further disconnects the first communication terminal from the power supply means when the determination means determines that the electronic device has started operating.
The battery pack according to claim 2 , characterized in that: The first control means connects a pull-down resistor to the first communication terminal when the determination means determines that the electronic device has started operating;
The determining means further includes:
If the level of the first communication terminal maintains the first logic level after the pull-down resistor is connected to the first communication terminal, the connection between the battery pack and the electronic device is normal. It is determined that
After a pull-down resistor is connected to the first communication terminal, when it is detected that the level of the first communication terminal changes from the first logic level to the second logic level, the battery pack and the electronic device determine that the connection is abnormal,
The battery pack according to claim 3 , characterized in that: The first control means is characterized in that when the determination means determines that the connection between the battery pack and the electronic device is abnormal, the first control means disconnects the battery cell and the power supply terminal. The battery pack according to claim 4 . The first control means is characterized in that when the determination means determines that the connection between the battery pack and the electronic device is normal, the first control means communicates with the electronic device through the first communication terminal. The battery pack according to claim 4 or 5 . The determining means further comprises: after determining that the connection between the battery pack and the electronic device is normal, when detecting that the first communication terminal remains at the second logic level for a predetermined period of time or more; The battery pack according to any one of claims 4 to 6 , wherein it is determined that the battery pack has been removed from the electronic device. 8. The first control means disconnects the battery cell from the power supply terminal when the determination means determines that the battery pack has been removed from the electronic device. Battery pack listed. When the determination means determines that the battery pack has been removed from the electronic device, the first control means further connects the power supply means to the first communication terminal , and connects the pull-down resistor and the first control means to the first communication terminal . 9. The battery pack according to claim 8 , wherein the battery pack is disconnected from the first communication terminal. The battery pack according to any one of claims 1 to 9,
power terminal and
an electronic device having a second communication terminal connected to the first communication terminal and operable by supplying power to the power supply terminal from the battery pack,
connecting means for connecting the second communication terminal to a second logic level lower than the first logic level when power is supplied to the second communication terminal in a state where power is not supplied to the power supply terminal;
a second power supply unit that starts supplying power to each part of the electronic device when power supply to the power supply terminal starts, and also applies the first logic level to the second communication terminal;
a second control means that turns off the connection means when power supply to the power supply terminal is started;
An electronic device characterized by having.

Images