JP2017118733A - Power supply and electronic apparatus - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a technology capable of highly efficiently using a battery.SOLUTION: Power supply comprising a plurality of batteries, and a selection circuit selecting the battery having a relatively high voltage from the plurality of batteries and supplying electric power to the outside by the selected battery is constituted.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a power supply and an electronic device.

  2. Description of the Related Art Conventionally, in an electronic device driven by a power source, techniques for performing various controls according to the state of the power source are known. For example, Patent Document 1 discloses a digital camera that enables selection of an operation mode that can be operated according to the number of attached batteries.

JP 2004-336096 A

In the conventional technology, the battery to be used cannot be switched according to the state of the battery. However, various inconveniences occur in the configuration in which all the batteries are uniformly used when the voltage difference is generated in the plurality of batteries. For example, in a configuration in which a plurality of batteries having a voltage difference are connected in series or in parallel and power is supplied to the outside, voltage non-uniformity between the batteries is eliminated when the plurality of batteries are connected. Charges move and power loss occurs. On the other hand, if a plurality of batteries having different output voltages are selected and used without any selection criteria, the potential difference between the batteries is not eliminated and the potential difference can be enlarged. Therefore, when it becomes necessary to connect the batteries in series in order to output a high voltage, the batteries after the potential difference is expanded are connected in series, and more power is lost.
An object of this invention is to provide the technique which uses a battery efficiently.

  A power supply for achieving the above object includes a plurality of batteries and a selection circuit that selects a battery having a relatively high voltage from the plurality of batteries and supplies power to the outside by the selected battery.

  In other words, for batteries with the same specifications, the higher the voltage, the greater the amount of remaining power. Generally, the use of a battery with a relatively high voltage power supply increases the potential difference between multiple batteries. It is possible to operate the power supply. In a configuration in which a plurality of batteries can be used at the same time, the greater the voltage difference between the batteries used, the greater the power loss when these batteries are connected. Therefore, by preventing an increase in the voltage difference, it is possible to suppress power loss when using a plurality of batteries and to effectively reduce the battery, compared to a configuration in which a large voltage difference can occur between the batteries. Can be used.

FIG. 1A is a block diagram illustrating a printing apparatus including a power supply according to an embodiment of the present invention, and FIG. 1B is a flowchart illustrating processing of a main body circuit. It is a figure which shows the structure of a power supply. It is a flowchart which shows the process of control IC. 4A to 4C are diagrams showing examples of battery pack selection. 5A to 5B are diagrams showing examples of battery pack selection. 6A to 6B are diagrams showing examples of battery pack selection. 7A to 7C are diagrams showing examples of battery pack selection. 8A to 8B are diagrams showing examples of battery pack selection. 9A to 9B are diagrams showing examples of battery pack selection.

Here, embodiments of the present invention will be described in the following order.
(1) Configuration of printing apparatus:
(2) Configuration of power supply:
(2-1) Main circuit processing:
(2-2) Control IC processing:
(3) Battery pack selection example:
(4) Other embodiments:

(1) Configuration of printing apparatus:
FIG. 1A is a block diagram showing a printing apparatus 10 driven by a power supply 20 according to an embodiment of the present invention. The printing apparatus 10 includes a mounting unit (not shown) to which the power source 20 can be mounted and a connection terminal for the AC adapter 80. Power is supplied from the power source 20 mounted to the mounting unit or the AC adapter 80 connected to the connection terminal. Received and driven.

  1A includes a power supply 20, a charging circuit 30, a booster circuit 40, a drive unit 50, a step-up / step-down circuit 60, and a main body circuit 70. The AC adapter 80 includes a circuit that receives supply of AC power from a commercial power source, converts the DC power into DC power of a predetermined voltage, and outputs the DC power.

  The power supply 20 includes battery packs 21 a to 21 d and a selection circuit 22. In this embodiment, the power supply 20 includes four battery packs 21a to 21d (see FIG. 2), and each battery pack 21a to 21d is connected to a plurality of cells (not shown) connected in series or in parallel (in this embodiment). A lithium ion battery as a secondary battery, but is not limited thereto. In the present embodiment, the four battery packs 21a to 21d have the same specifications, and can output DC power having a voltage within a predetermined range. That is, the output voltage of each of the battery packs 21a to 21d varies within a predetermined range according to the remaining power amount of each of the battery packs 21a to 21d.

  The selection circuit 22 includes a circuit for selecting a battery pack to be used, selects a battery pack to be used according to the voltage of the battery pack, and connects the selected battery pack in a predetermined connection mode. Thus, the circuit is switched (details will be described later). Therefore, in this embodiment, the power supply 20 outputs DC power having a voltage corresponding to the number of battery packs selected and the connection mode. The power supply 20 is connected to the booster circuit 40 and the step-up / step-down circuit 60 through a diode.

  The charging circuit 30 is connected to the AC adapter 80 and the power source 20 and includes a circuit for charging the battery pack using the power supplied from the AC adapter 80. The plurality of power sources 20 included in the power source 20 are charged based on the output of the charging circuit 30, but various triggers can be assumed as triggers for starting charging. For example, for an operation unit (not shown) The user's operation, the connection of the AC adapter 80 to the printing apparatus 10, the elapse of a predetermined time without printing in the state where the AC adapter 80 is connected to the printing apparatus 10, etc. It is possible.

  The booster circuit 40 is a circuit that boosts and outputs a voltage of input power to a predetermined voltage, and the AC adapter 80 and the output wiring of the power supply 20 are connected via a diode. The output wiring of the booster circuit 40 is connected to the drive unit 50, and the output power of the booster circuit 40 is supplied to the drive unit 50. In the present embodiment, the predetermined voltage is a voltage necessary for driving the drive unit 50 and is larger than the maximum voltage of the power supply 20 and the output voltage of the AC adapter 80. Therefore, in the present embodiment, the output voltage of the AC adapter 80 or the output voltage of the power supply 20 is boosted to a predetermined voltage via the booster circuit 40, and power of the predetermined voltage is supplied to the drive unit 50. The booster circuit 40 is configured to receive a control signal from the main body circuit 70, and the main body circuit 70 can stop the operation of the booster circuit 40 by the control signal.

  The drive unit 50 is a part that is driven to realize printing by the printing apparatus 10, and includes a print head, a carriage, a print medium transport device, and the like (not shown). In the present embodiment, the components of the driving unit 50 are driven by a piezo element, a motor, or the like. That is, each component is driven by supplying the output power of the booster circuit 40 to these components. The drive unit 50 receives a control signal from the main body circuit 70, and the drive timing and the like are controlled by the control signal.

  The step-up / step-down circuit 60 is a circuit that converts the input power voltage into a predetermined voltage (steps up or down) and outputs the voltage, and the AC adapter 80 and the output wiring of the power source 20 are connected via a diode. The output wiring of the step-up / step-down circuit 60 is connected to the main body circuit 70, and the output power of the step-up / step-down circuit 60 is supplied to the main body circuit 70. Therefore, the step-up / step-down circuit 60 boosts or steps down the output voltage of the AC adapter 80 or the output voltage of the power supply 20 and supplies power of a predetermined voltage to the main circuit 70. In the present embodiment, the predetermined voltage of power supplied to the main circuit 70 is smaller than the predetermined voltage of power supplied to the driving unit 50 (for example, the main circuit 70 is driven with respect to 3.3V). Part 50 is 42V, etc.).

  The main body circuit 70 includes a control unit having a CPU, a memory, and the like (not shown), and can execute a predetermined program for executing printing. In the present embodiment, the main body circuit 70 includes an operation unit and an external device interface (not shown), and acquires information indicating a print target from an external device (memory, computer, or the like) in accordance with a user operation on the operation unit. Then, a predetermined process is performed to generate a print image, and the drive unit 50 is appropriately controlled to print the print image on a print medium.

  When the drive unit 50 is driven to perform printing, the main circuit 70 does not stop the booster circuit 40 and supplies power of a predetermined voltage to the drive unit 50. In this specification, this state is referred to as a print mode. Call it. When a predetermined time elapses without driving the drive unit 50, the main body circuit 70 outputs a control signal to the booster circuit 40 to stop the booster circuit 40. In this case, power for generating a voltage that is relatively higher than the voltage supplied to the main circuit 70 is not supplied from the power supply 20 or the AC adapter 80 to the booster circuit 40. Therefore, this state is a state in which power consumption is suppressed as compared with the print mode, and this state is referred to as a power saving mode in this specification.

  The main circuit 70 can control the power supply 20 in addition to controlling the stop / non-stop of the booster circuit 40 and the drive timing of the drive unit 50 as described above. That is, the main body circuit 70 and the power source 20 are connected by a signal line, and the main body circuit 70 transmits a signal (print mode signal) indicating that the current print mode is being supplied to the power source 20 via the signal line. Can output a signal (power saving mode signal) indicating that is in the power saving mode.

(2) Configuration of power supply:
The power supply 20 includes a configuration for selecting a battery pack to be used in accordance with the battery packs 21a to 21d and the above-described modes (printing mode and power saving mode). FIG. 2 is a block diagram showing the internal configuration of the power supply 20. The power supply 20 includes battery packs 21a to 21d, a control IC 22a, and switches SW0 to SW7.

  The control IC 22a includes a control unit having a CPU, a memory, and the like (not shown), and can execute a predetermined function by executing a program recorded in advance in a ROM or the like. In the present embodiment, the program includes program modules such as a SW control unit 22a1 and a voltage detection unit 22a2, and the SW control unit 22a1 causes the control IC 22a to realize a function of controlling the switches SW0 to SW7. That is, the switches SW0 to SW7 are switches (eg, MOS-FETs) that can be switched on and off electrically, and the control IC 22a is switched by the SW control unit 22a1 through a signal line (not shown). ~ SW7 can be set on or off.

  The voltage detection unit 22a2 causes the control IC 22a to realize a function of detecting the voltages of the battery packs 21a to 21d. That is, the control IC 22a includes an A / D converter and a wiring (not shown), and the control IC 22a converts the battery packs 21a to 21a converted from analog values into digital values by the A / D converter by the processing of the voltage detection unit 22a2. A voltage of 21d can be obtained.

The switches SW0 to SW7 are wired so that electric power can be supplied to the outside by one or a plurality selected from the battery packs 21a to 21d. That is, the switches SW0, SW2, SW4, and SW6 are connected in series between the external terminals T _{1 to} T ₂ . The battery pack 21a, the switch SW1, the battery pack 21b, the switch SW3, a battery pack 21c, switch SW5, the battery pack 21d, the switch SW7 is connected in series between the external terminal T ₁ through T _2.

  Further, the wiring is provided so that the wiring between the switch SW0 and the switch SW2 is electrically connected to the wiring between the switch SW1 and the positive electrode of the battery pack 21b. Further, the wiring is provided so that the wiring between the switch SW2 and the switch SW4 is electrically connected to the wiring between the switch SW3 and the positive electrode of the battery pack 21c. Further, the wiring is provided so that the wiring between the switch SW4 and the switch SW6 is electrically connected to the wiring between the switch SW5 and the positive electrode of the battery pack 21d.

  In the present embodiment, the power source 20 switches the battery pack to be used according to the voltage of the battery packs 21a to 21d and the external load (either print mode or power saving mode) by the control IC 22a and the switches SW0 to SW7. . Therefore, the control IC 22a and SW0 to SW7 function as a selection circuit. Here, the switching of the battery pack will be described in detail by the processing of the main body circuit 70 and the processing of the control IC 22a.

(2-1) Main circuit processing:
FIG. 1B is a flowchart showing processing of the main circuit 70. When the printing apparatus 10 is activated, power of a voltage to be applied to the main body circuit 70 is generated by the step-up / step-down circuit 60 regardless of whether power is supplied from the power supply 20 or the AC adapter 80. When electric power is output from the step-up / step-down circuit 60, the main body circuit 70 executes the processing of the main body circuit shown in FIG. 1B.

  In this process, the main circuit 70 determines whether or not there is a print instruction (step S100). That is, when the user gives an instruction to start printing using an operation unit (not shown), the main circuit 70 determines that there has been a printing instruction. If it is not determined in step S100 that there is a print instruction, the main circuit 70 determines whether or not a predetermined time has passed without determining that there is a print instruction (step S110). That is, the main body circuit 70 starts measuring the elapsed time by using a clock circuit (not shown) when it is not determined in step S100 that a print instruction has been given. Then, when the measurement result is equal to or longer than a predetermined time (a time defined in advance as a standby time until shifting to the power saving mode), the main body circuit 70 determines that the predetermined time has elapsed.

  If it is not determined in step S110 that the predetermined time has elapsed, the main body circuit 70 repeats the processing after step S100. On the other hand, when it is determined in step S110 that the predetermined time has elapsed, the main circuit 70 outputs a power saving mode signal (step S120). That is, the main circuit 70 outputs a signal indicating that the current state is the power saving mode to the power supply 20. The main circuit 70 outputs a control signal to the booster circuit 40 and stops the booster circuit 40. After that, the main circuit 70 repeats the processes after step S100.

  On the other hand, when it is determined in step S100 that there is a print instruction, the main body circuit 70 outputs a print mode signal (step S130). That is, the main body circuit 70 outputs a signal indicating that the current print mode is to the power supply 20. Next, the main circuit 70 executes a printing process (step S140). That is, the main body circuit 70 outputs a control signal to the booster circuit 40 to make the booster circuit 40 non-stopped. As a result, power of a predetermined voltage is output from the booster circuit 40. Further, the main body circuit 70 specifies a print target in accordance with a user operation on the operation unit, and performs a predetermined process to generate a print image. Further, the main body circuit 70 outputs a control signal to the driving unit 50, drives a print head, a carriage, a print medium transport device, and the like to print the print image. When the printing process is completed, the main circuit 70 repeats the processes after step S100.

(2-2) Control IC processing:
FIG. 3 is a flowchart showing the processing of the control IC 22a. In the present embodiment, when the printing apparatus 10 is activated in a state where the power supply 20 is mounted on the printing apparatus 10, the processing of the control IC 22a is started. In the process of the control IC 22a, the control IC 22a compares the voltage of the battery pack (step S200). That is, the control IC 22a acquires the voltages of the battery packs 21a to 21d by the processing of the voltage detection unit 22a2, specifies the two combinations selected from the battery packs 21a to 21d in all cases, and sets the voltage for each case. Get the difference.

  Next, the control IC 22a determines whether or not a balanced battery pack exists (step S205). That is, the control IC 22a determines whether or not there is a combination of battery packs having a voltage difference equal to or less than a threshold value by the processing of the voltage detection unit 22a2. When there is a combination of battery packs whose voltage difference is equal to or less than the threshold, the control IC 22a regards the combination as a balanced battery pack.

  In addition, when the first battery pack is balanced with the second battery pack and the second battery pack is balanced with the third battery pack, the control IC 22a has the first to third battery packs balanced. The control IC 22a identifies even when there are three or more balanced battery packs by processing such as assuming that the battery pack is present. The threshold value is a value for determining whether or not the voltages are small enough to be regarded as the same, and is defined in advance.

  If it is not determined in step S205 that there is a balanced battery pack, the control IC 22a selects the battery pack having the highest voltage as the target of use (step S210). That is, when there is no balanced battery pack, the voltages of the four battery packs 21a to 21d are all different values. Therefore, the control IC 22a compares the voltages of the battery packs 21a to 21d, and the battery pack having the largest voltage is used. To be used.

  On the other hand, when it is determined in step S205 that a balanced battery pack exists, the control IC 22a determines whether or not the current mode is the print mode (step S215). That is, when the user gives an instruction to start printing through an operation unit (not shown), the main circuit 70 outputs a print mode signal to the power supply 20 through the processes of steps S100 and S130. If the received signal is a print mode signal, the control IC 22a determines that the current mode is the print mode, that is, the load of the printing apparatus 10 is high.

  If it is determined in step S215 that the current print mode is selected, that is, if it is determined that the load of the printing apparatus 10 is high (the outside of the power supply 20 is seeking a high voltage), the control IC 22a Then, the combination of the battery packs having the highest voltage is selected from the balanced battery pack combinations as the target of use (step S220). That is, step S220 is executed when there is at least one set of balanced battery packs. Therefore, if there is one set of balanced battery packs, the control IC 22a selects the combination and selects the battery pack. Select it for use. On the other hand, if there are a plurality of balanced battery packs (2 pairs in the present embodiment), the control IC 22a selects a set having a high voltage from these sets and selects the battery pack as an object to be used. To do.

  On the other hand, if it is not determined in step S215 that the current print mode is set, that is, if it is determined that the load of the printing apparatus 10 is low (the outside of the power supply 20 is seeking a low voltage), the control IC 22a. Selects the battery pack with the highest voltage as the target of use (step S225). That is, the control IC 22a compares the voltages of the battery packs 21a to 21d, and selects the battery pack having the highest voltage as the target of use. Since step S225 is executed when at least one set of balanced battery packs is present, when the battery pack having the highest voltage is included in the balanced battery pack, the control IC 22a displays the combination of the balanced battery packs. To be used.

  Next, the control IC 22a determines whether there are a plurality of battery packs to be used (step S230). When it is determined in step S230 that there are a plurality of battery packs to be used, or when step S220 is executed, the control IC 22a connects the battery packs to be used in series and outputs power (step). S235). In the present embodiment, a switch to be turned on and a switch to be turned off are specified in advance in order to connect any combination of battery packs in series.

  Therefore, the control IC 22a outputs a control signal to the switch that should be turned on in order to connect the battery packs to be used in series by the processing of the SW control unit 22a1, and sets the control signal to the switch that should be turned off. Is output and set to off. Note that the situation where it is determined that there are a plurality of battery packs to be used in step S230 occurs in a low-load (non-printing mode) situation and the required voltage is low, so the battery pack to be used in step S235. May be connected in parallel, or one of the battery packs with the highest voltage may be used.

  On the other hand, when step S210 is executed or when it is not determined in step S230 that there are a plurality of battery packs to be used, the control IC 22a outputs electric power using the battery pack to be used (step S240). That is, since step S240 is executed when there is one battery pack to be used, the control IC 22a controls the switch to be turned on in order to output power from the battery pack by the processing of the SW control unit 22a1. A signal is output and set to ON, and a control signal is output to the switch to be turned OFF and set to OFF.

  According to the above processing, when there is a balanced battery pack, the combination with the highest battery pack voltage among the balanced battery packs in the print mode is connected in series, and the battery with the highest voltage in the power saving mode. These batteries are connected in series when the pack is balanced. Therefore, when these batteries are connected in series, charge transfer between the batteries does not occur (or very little), and power loss due to charge transfer can be suppressed.

  In the present embodiment, the predetermined voltage applied to the drive unit 50 is higher than the maximum voltage of the power source 20 (voltage obtained by connecting the battery packs 21a to 21d in series). Therefore, in the printing mode with a high load, the output voltage of the power supply 20 is boosted by the booster circuit 40. And the voltage obtained by connecting the balanced battery packs in series is the maximum voltage among the voltages obtained using these battery packs. In the printing mode of the present embodiment, since the balanced battery packs are used in series, the maximum voltage that can be output by the combination of the balanced battery packs is output from the power supply 20. In the voltage conversion in the booster circuit 40, the smaller the voltage difference before and after the conversion, the higher the power conversion efficiency (there is less loss), so that the maximum voltage that can be output with a combination of balanced battery packs is output from the power supply. According to this embodiment, power can be supplied to the load by performing conversion with the highest power conversion efficiency obtained by the combination of the balanced battery packs.

  Furthermore, according to the above-described processing, if the battery pack is balanced, the battery pack having the maximum voltage is preferentially used in the power saving mode with a low load, and the battery pack having the maximum voltage is further balanced. If so, a plurality of balanced battery packs are used. That is, the battery having the highest voltage is selected in the power saving mode. With this configuration, in the power saving mode, it is possible to supply power to the outside with a battery that has the largest amount of remaining power and can be used for the longest time.

  Furthermore, according to the above-described processing, when a voltage decreases due to the use of a certain battery pack, and the voltage difference between the battery and the other battery becomes equal to or less than a threshold value, the battery and the other battery are Connected in series. Therefore, in the operation process of the power source, it is possible to shift to a state where power is supplied to the load by performing conversion with high power conversion efficiency while suppressing power loss.

(3) Battery pack selection example:
Next, a battery pack selection example will be described. 4A to 9B are diagrams showing the switches SW0 to SW7 and the battery packs 21a to 21d and their wirings extracted from the power supply 20 shown in FIG. In these drawings, the relative relationship of the voltage of the battery pack is illustrated in the block showing the battery pack. Moreover, the wiring currently connected by the thick line is shown.

  FIG. 4A shows an example in which the voltage of the battery pack 21a is the maximum value Vmax, and the voltages of the other battery packs 21b to 21d are the minimum value Vmin. When the situation of this example occurs in the power saving mode, in the process shown in FIG. 3, the control IC 22a determines that the battery packs 21b to 21d are balanced through steps S200 and 205, and is not in the print mode in step S215. judge.

  As a result, the control IC 22a selects the battery pack 21a having the highest voltage in step S225 as a usage target, and executes step S240 via step S230. That is, as shown in FIG. 4A, the control IC 22a sets the switches SW1, SW2, SW4, and SW6 to be on and sets the switches SW0, SW3, SW5, and SW7 to be off. As a result, the power supply 20 supplies power from the battery pack 21a to be used.

  On the other hand, when a situation occurs in which the voltage of the battery pack 21a is the maximum value Vmax and the voltages of the other battery packs 21b to 21d are the minimum value Vmin in the print mode, the control IC 22a in the process shown in FIG. After 205, it is determined that the battery packs 21b to 21d are balanced, and it is determined in step S215 that the printing mode is set.

  As a result, the control IC 22a selects the combination of the battery packs (battery packs 21b to 21d) having the highest voltage in step S220 as a use target, and executes step S235. That is, as shown in FIG. 4B, the control IC 22a sets the switches SW0, SW3, SW5, and SW7 to be on, and sets the switches SW1, SW2, SW4, and SW6 to be off. As a result, the power source 20 supplies power by connecting the battery packs 21b to 21d to be used in series.

  Further, when the situation shown in FIG. 4A realized in the power saving mode continues and the voltage of the battery pack 21a reaches Vmin, the control IC 22a in steps S200 and 205 in the process shown in FIG. Are determined to be balanced, and it is determined in step S215 that the print mode is not set.

  As a result, the control IC 22a selects the battery pack (battery packs 21a to 21d) having the highest voltage in step S225 as a use target, and executes step S240 via step S230. That is, as shown in FIG. 4C, the control IC 22a sets the switches SW1, SW3, SW5, and SW7 to on, and sets the switches SW0, SW2, SW4, and SW6 to off. As a result, the power supply 20 supplies power by connecting the battery packs 21a to 21d to be used in series.

  FIG. 5A shows an example in which the voltage of the battery pack 21a is the minimum value Vmin and the voltages of the other battery packs 21b to 21d are the maximum value Vmax. When the situation of this example occurs in the power saving mode, in the process shown in FIG. 3, the control IC 22a determines that the battery packs 21b to 21d are balanced through steps S200 and 205, and is not in the print mode in step S215. judge.

  As a result, the control IC 22a selects the battery packs 21b to 21d having the highest voltage in step S225 as the usage target, and executes step S235 through step S230. That is, as shown in FIG. 5A, the control IC 22a sets the switches SW0, SW3, SW5, and SW7 to on and sets the switches SW1, SW2, SW4, and SW6 to off. As a result, the power source 20 supplies power by connecting the battery packs 21b to 21d to be used in series.

  On the other hand, when a situation occurs in which the voltage of the battery pack 21a is the minimum value Vmin and the voltages of the other battery packs 21b to 21d are the maximum value Vmax in the print mode, the control IC 22a in step S200, After 205, it is determined that the battery packs 21b to 21d are balanced, and it is determined in step S215 that the printing mode is set.

  As a result, the control IC 22a selects the combination of the battery packs (battery packs 21b to 21d) having the highest voltage in step S220 as a use target, executes step S235, and realizes the situation shown in FIG. 5A. That is, when the voltage of only one battery pack is low and the voltages of the other battery packs are balanced, the control IC 22a supplies power by connecting the balanced battery packs in series regardless of the load of the printing apparatus 10. To do.

  Furthermore, when the situation shown in FIG. 5A continues and the voltage of the battery packs 21b to 21d reaches Vmin, in the process shown in FIG. 3, the control IC 22a balances the battery packs 21a to 21d through steps S200 and S205. And step S220 or step S225 is executed via step S215. Since the battery packs selected as the objects to be used in these steps are the battery packs 21a to 21d, the control IC 22a sets the switches SW1, SW3, SW5, SW7 to ON as shown in FIG. 5B in step S235, The switches SW0, SW2, SW4, SW6 are set off. As a result, the power supply 20 supplies power by connecting the battery packs 21a to 21d to be used in series.

  FIG. 6A shows an example in which the voltage of the battery packs 21a and 21b is the maximum value Vmax, and the voltages of the other battery packs 21c and 21d are V1 and V2. Here, Vmax> V1> V2. When the situation of this example occurs in the power saving mode, in the process shown in FIG. 3, the control IC 22a determines that the battery packs 21a and 21b are balanced through steps S200 and 205, and is not in the print mode in step S215. judge.

  As a result, the control IC 22a selects the battery packs 21a and 21b having the highest voltage in step S225 as usage targets, and executes step S235 through step S230. That is, as shown in FIG. 6A, the control IC 22a sets the switches SW1, SW3, SW4, and SW6 to be on, and sets the switches SW0, SW2, SW5, and SW7 to be off. As a result, the power supply 20 supplies power by connecting the battery packs 21a and 21b to be used in series.

  On the other hand, in the print mode, when the voltage of the battery packs 21a and 21b is the maximum value Vmax and the voltages of the other battery packs 21c and 21d are V1 and V2, the control IC 22a performs step in the process shown in FIG. Through S200 and 205, it is determined that the battery packs 21a and 21b are balanced, and it is determined in step S215 that the print mode is set.

  As a result, the control IC 22a selects the combination of the battery packs (battery packs 21a and 21b) having the highest voltage in step S220 as a use target, executes step S235, and realizes the situation shown in FIG. 6A. That is, when the voltage is balanced and the voltage of the other battery packs is lower than the maximum value of the plurality of battery packs, the control IC 22a selects the balanced battery pack regardless of the load of the printing apparatus 10. Connect power in series.

  Further, when the situation shown in FIG. 6A continues and the voltage of the battery packs 21a and 21b reaches V1, the control IC 22a balances the battery packs 21a to 21c through steps S200 and 205 in the process shown in FIG. And step S220 or step S225 is executed via step S215. Since the battery packs selected as the objects to be used in these steps are the battery packs 21a to 21c, the control IC 22a sets the switches SW1, SW3, SW5, and SW6 to ON as shown in FIG. 6B in step S235, The switches SW0, SW2, SW4, SW7 are set off. As a result, the power supply 20 supplies power by connecting the battery packs 21a to 21c to be used in series. That is, in this example, the control IC 22a starts using the battery pack balanced at the maximum voltage in series connection, and when the voltage is balanced with other battery packs, the battery pack is used in addition to the series connection.

  FIG. 7A shows an example in which the voltage of the battery packs 21a and 21b is V1, the voltage of the battery pack 21c is the maximum value Vmax, and the voltage of the battery pack 21d is V2. Here, Vmax> V1> V2. When the situation of this example occurs in the power saving mode, in the process shown in FIG. 3, the control IC 22a determines that the battery packs 21a and 21b are balanced through steps S200 and 205, and is not in the print mode in step S215. judge.

  As a result, the control IC 22a selects the battery pack 21c having the highest voltage in step S225 as a use target, and executes step S235 through step S230. That is, the control IC 22a sets the switches SW0, SW2, SW5, and SW6 to on and sets the switches SW1, SW3, SW4, and SW7 to off as shown in FIG. 7A. As a result, the power supply 20 supplies power by the battery pack 21c to be used.

  On the other hand, when the voltage of the battery packs 21a and 21b is V1, the voltage of the battery pack 21c is the maximum value Vmax, and the voltage of the battery pack 21d is V2 in the print mode, the control IC 22a performs the process shown in FIG. Through steps S200 and 205, it is determined that the battery packs 21a and 21b are balanced, and it is determined in step S215 that the printing mode is set.

  As a result, the control IC 22a selects the combination of the battery packs (battery packs 21a and 21b) having the highest voltage in step S220 as a use target, and executes step S235. That is, as shown in FIG. 7B, the control IC 22a sets the switches SW1, SW3, SW4, and SW6 to be on, and sets the switches SW0, SW2, SW5, and SW7 to be off. As a result, the power supply 20 supplies power by connecting the battery packs 21a and 21b to be used in series.

  Further, when the situation shown in FIG. 7B continues and the voltage of the battery pack 21c reaches V1, the control IC 22a determines that the battery packs 21a to 21c are balanced through steps S200 and 205 in the process shown in FIG. Then, step S220 is executed after step S215. Since the battery packs selected as the objects to be used in this step are the battery packs 21a to 21c, in step S235, the control IC 22a turns on the switches SW1, SW3, SW5, and SW6 as shown in FIG. SW0, SW2, SW4, and SW7 are set to OFF. As a result, the power supply 20 supplies power by connecting the battery packs 21a to 21c to be used in series. That is, in this example, when the number of balanced battery packs increases, the control IC 22a sequentially uses the battery packs in addition to the series connection.

  FIG. 8A shows examples in which the voltages of the battery packs 21a to 21d are Vmax, V1, V2, and V3, which are all different. Here, Vmax> V1> V2> V3. When the situation of this example occurs, the control IC 22a does not determine that the battery packs are balanced through steps S200 and 205 in the process shown in FIG. 3, and uses the battery pack 21a having the highest voltage in step S210 as the target of use. select. In step S240, the control IC 22a turns on the switches SW1, SW2, SW4, and SW6 and turns off the switches SW0, SW3, SW5, and SW7 as shown in FIG. 8A. As a result, the power supply 20 supplies power by the battery pack 21a to be used.

  Furthermore, when the situation shown in FIG. 8A continues and the voltage of the battery pack 21b reaches V1, the control IC 22a determines that the battery packs 21a and 21b are balanced through steps S200 and 205 in the process shown in FIG. Then, step S220 or step S225 is executed through step S215. Since the battery packs to be selected for use in these steps are the battery packs 21a and 21b, the control IC 22a sets the switches SW1, SW3, SW4 and SW6 to ON as shown in FIG. 8B in step S235, The switches SW0, SW2, SW5, SW7 are set off. As a result, the power supply 20 supplies power by connecting the battery packs 21a and 21b to be used in series. That is, in this example, when the number of balanced battery packs increases, the control IC 22a sequentially uses the battery packs in addition to the series connection.

  FIG. 9A shows an example in which the voltages of the battery packs 21a and 21b are the maximum value Vmax and the voltages of the battery packs 21c and 21d are the minimum value Vmin. When this example occurs, the control IC 22a determines that the battery packs 21a and 21b are balanced through steps S200 and 205, and the battery packs 21c and 21d are balanced, and executes step S220 or step S225 through step S215. To do. Since the battery packs selected as the objects to be used in these steps are the battery packs 21a and 21b, the control IC 22a sets the switches SW1, SW3, SW4, and SW6 to ON as shown in FIG. 9A in step S235, The switches SW0, SW2, SW5, SW7 are set off. As a result, the power supply 20 supplies power by connecting the battery packs 21a and 21b to be used in series.

  Further, when the situation shown in FIG. 9A continues and the voltage of the battery packs 21a and 21b reaches Vmin, the control IC 22a balances the battery packs 21a to 21d through steps S200 and 205 in the process shown in FIG. And step S220 or step S225 is executed via step S215. Since the battery packs selected as the objects to be used in these steps are the battery packs 21a to 21d, the control IC 22a sets the switches SW1, SW3, SW5, SW7 to ON as shown in FIG. 9B in step S235, The switches SW0, SW2, SW4, SW6 are set off. As a result, the power supply 20 supplies power by connecting the battery packs 21a to 21d to be used in series. That is, also in this example, when the number of balanced battery packs increases, the control IC 22a sequentially uses the battery packs in addition to the series connection.

(4) Other embodiments:
The above embodiment is an example for carrying out the present invention, and various other embodiments can be adopted as long as a relatively high voltage battery is selected from a plurality of batteries and used.

  The plurality of batteries may include a plurality of electrodes that generate potential differences and supply power to a circuit wired by wiring to the electrodes. Therefore, each battery may be constituted by a single cell, or a plurality of cells may be connected in series or in parallel. The battery may be a primary battery or a secondary battery. Furthermore, the type of battery, such as the mode of energy source and the mode of electrode, is not particularly limited, and various types may be adopted.

  The selection circuit only needs to be able to select a battery having a relatively high voltage from a plurality of batteries, and can be realized by a circuit that can select an arbitrary battery by a control unit that changes a wiring state by a switch or the like. That is, the selection circuit selects a battery to be used based on the voltage of the battery, and switches the switch on and off by the control unit, thereby allowing the selected battery to be connected in any connection mode (series connection or parallel connection). What is necessary is just to connect and supply electric power to the outside.

  The selected battery may be a battery having a relatively high voltage when compared with at least one other battery among the plurality of batteries, and may be a battery having the highest voltage. Of course, one or a plurality of batteries may be selected. When a plurality of batteries are selected, the selected batteries may be connected in series or in parallel. The former is a preferable configuration when a high voltage is required and the latter is required when a long-term power supply is required.

  Furthermore, as a configuration example when selecting a battery having a relatively high voltage, the selection circuit selects a plurality of batteries having a voltage difference equal to or less than a threshold value, and connects the plurality of selected batteries in series to power the outside. The structure which supplies may be sufficient. That is, a plurality of batteries having a voltage difference equal to or less than a threshold value have a balanced voltage, and even if these batteries are connected in series, no charge movement occurs between the batteries (or very little). Power loss can be suppressed. In addition, the threshold value should just be set so that the electric power by the movement of an electric charge can be disregarded (it is the same about the threshold value below). That is, it is only necessary that the threshold value is set so that a plurality of batteries having a voltage difference equal to or less than the threshold value can be regarded as having a uniform voltage.

  Note that the voltage (or voltage range) to be applied to an external load that is supplied with power from a power source is usually determined by specifications. Then, at least one of the plurality of voltages that can be output by combining the plurality of voltages is different from the voltage applied to the load. Therefore, when a voltage different from the voltage applied to the load is output from the power supply, the voltage is applied to the load after being converted by the step-up / down circuit. In such conversion, generally, the smaller the voltage difference before and after the conversion, the higher the power conversion efficiency (less loss).

  When configuring a system (electronic device or the like) including a power source and an external load, normally, the maximum value of the voltage that can be output by a plurality of batteries does not exceed the maximum value of the voltage to be applied to the load. Composed. Therefore, in such a configuration, when a configuration in which a plurality of relatively high voltage batteries are connected in series is adopted, the maximum voltage that can be output by the plurality of batteries can be supplied to the step-up / down circuit. Conversion can be performed with the highest power conversion efficiency obtained by a plurality of batteries to supply power to the load.

  Furthermore, the selection circuit may be configured to select a battery based on an external load. In this configuration, for example, when the selection circuit seeks a low voltage from the outside (the external load is low), the battery with the highest voltage is selected and power is supplied to the outside by the selected battery. When the external demands a high voltage (the external load is a high load), a combination of a plurality of batteries whose voltage difference is equal to or less than a threshold value is selected and selected. This can be realized by connecting a plurality of batteries in series and supplying power to the outside.

  In other words, when the external demands a low voltage, the battery with the highest voltage is selected, so when the external demands a low voltage, the remaining power is the largest and the battery that can be used for the longest time. Electric power can be supplied to the outside. Of course, in this case, if there are multiple batteries with the highest voltage (there are multiple batteries whose voltage difference is below the threshold and can be considered balanced), connect those batteries in series. Alternatively, they may be connected in parallel, or one of a plurality of batteries may be used alone.

  On the other hand, when the outside is seeking a high voltage, the selection circuit combines a plurality of batteries having a voltage difference equal to or less than a threshold value, that is, a plurality of balanced batteries, and connects them in series. Accordingly, power can be supplied to the outside by a battery that does not cause power loss due to charge transfer. The selection circuit selects the combination with the highest voltage from the combination of the balanced batteries. As a result, among the balanced battery combinations, the combination having the highest voltage is selected, and electric power can be supplied to the outside with the maximum voltage that can be output by the balanced battery pair by series connection. Therefore, even when power is converted by the step-up / down circuit, power can be supplied to the load by performing conversion with high power conversion efficiency.

  Further, when the voltage difference between the battery and the other battery becomes equal to or less than the threshold due to the supply of power from the battery, the selection circuit connects the battery and the other battery in series to supply power to the outside. A configuration may be adopted. That is, when the amount of power of the battery in use is reduced and the voltage is reduced and the voltage is balanced with another battery, the battery is connected in series with the other battery to supply power to the outside. According to this configuration, it is possible to shift to a state where power is supplied to the load by performing conversion with high power conversion efficiency while suppressing power loss in the operation process of the power source.

  Furthermore, an electronic device that includes the above-described power supply and operates with power supplied from the power supply may be configured. As the electronic device, various devices driven by a power source can be assumed, and examples thereof include a printing device, a scanner device, an imaging device, an arithmetic device, a portable terminal, and a multifunction device including these devices. . Furthermore, the method of the present invention that selects and uses a battery having a relatively high voltage from a plurality of batteries as described above can also be realized as a method.

DESCRIPTION OF SYMBOLS 10 ... Printing apparatus, 20 ... Power supply, 21 ... Battery pack, 21a-21d ... Battery pack, 22 ... Selection circuit, 22a ... Control IC, 22a1 ... SW control part, 22a2 ... Voltage detection part, 30 ... Charging circuit, 40 ... Boosting circuit, 50 ... Drive unit, 60 ... Buck-boost circuit, 70 ... Body circuit, 80 ... Adapter

Claims (5)

Multiple batteries,
A selection circuit that selects the battery having a relatively high voltage from a plurality of the batteries, and supplies power to the outside by the selected battery;
With power supply. The selection circuit includes:
Selecting a plurality of the batteries having a voltage difference equal to or less than a threshold, and connecting the plurality of selected batteries in series to supply power to the outside;
The power supply according to claim 1. The selection circuit includes:
If the outside wants a low voltage,
Select the battery with the highest voltage and have the selected battery supply power to the outside;
If the outside wants a high voltage,
A combination of a plurality of the batteries having a voltage difference equal to or less than a threshold value, selecting the combination of the batteries having the highest voltage, and connecting the selected plurality of batteries in series to supply power to the outside.
The power supply according to claim 1 or 2. The selection circuit includes:
When the voltage difference between the battery and another battery is equal to or less than the threshold due to the supply of power from the battery, the battery and the other battery are connected in series to supply power to the outside.
The power supply according to any one of claims 1 to 3.   An electronic apparatus comprising the power source according to claim 1 and operating with power supplied from the power source.

Images