JP2009044790A - Primary battery charger - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a primary battery charger having a simple structure which can be manufactured at low cost. <P>SOLUTION: The primary battery charger comprises a USB interface 22c performing serial data communication with a computer terminal 10 connected via a USB cable 6; battery sockets 25a and 25b, to which primary batteries 30a and 30b can be attached, charging circuit sections 29a and 29b for charging the primary batteries 30a and 30b by applying a charging voltage, based on a DC power supplied from the computer terminal 10 via the USB cable 6; and a means 22 for transmitting the charging information data, which is required to display information about charging on the computer terminal 10, through the USB interface 22c. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a primary battery charger for charging a primary battery such as a manganese battery or an alkaline battery.

  Conventionally, primary batteries such as manganese batteries and alkaline batteries, when excessively charged, may cause liquid leakage and corrode electrodes and circuits. In addition, even with the charger for the secondary battery, the attachment of these primary batteries is detected and cannot be charged, and therefore, the battery is discarded without being charged.

  However, these secondary batteries, like secondary batteries, are not completely in the state before discharge, but most of their battery capacity can be recovered by charging, and in recent years resource saving and improvement of recycling awareness have been achieved. Therefore, primary battery chargers that make it possible to charge and use these primary batteries multiple times are commercially available.

JP 2000-1116017 A JP-A-2005-39927

  These commercially available primary battery chargers are the same chargers as the above-described normal secondary chargers, and the primary battery can be charged by removing the detection function of the primary battery. There is a problem.

  First, as described in the above cited documents 1 and 2, these chargers are used by being directly connected to a household power outlet, and these AC currents can be used for charging. Since an AC / DC converter circuit for converting to a direct current is required, the structure of the charger itself becomes complicated.

  Secondly, as described above, the primary battery is more likely to generate heat or leak when charged as compared with the secondary battery. Although it is important to provide information by display or the like, if a display device is provided in the charger to provide such information, the cost of the charger will increase.

  Third, compared to secondary batteries, primary batteries are more susceptible to heat generation and liquid leakage during charging, as described above, so that sufficient monitoring is possible to respond quickly to unforeseen occurrences. Although it is desirable to be used in a situation, the conventional charger is used by being connected to a power outlet as described above, so it is easily left in the vicinity of the power outlet during charging. Monitoring tends to be insufficient.

  The present invention has been made by paying attention to such problems, and can be manufactured at a low cost with a simple structure, and can greatly increase the possibility of being used under the monitoring conditions of the user. The object is to provide a charger.

In order to solve the above-described problem, a primary battery charger according to claim 1 of the present invention provides:
A USB cable 6 for performing serial data communication based on the USB (Universal Serial Bus) standard is connected, and a USB interface unit for performing serial data communication with a computer terminal (personal computer 10) connected via the USB cable 6 ( USB serial interface (I / F) unit 22c),
Battery sockets (battery cases 25a, 25b) to which primary batteries 30a, 30b can be attached;
A charging circuit unit (charging transistor) for charging the primary battery by applying a charging voltage based on DC power supplied from the computer terminal 10 via the USB cable 6 to the primary battery mounted in the battery socket. 29a, 29b)
Charging information data transmitting means (S6, S10, S17, S18, S21, S21) for transmitting charging information data (various commands) for displaying charging information related to charging by the charging circuit unit through the USB interface unit. S26, S32),
It is characterized by having.
According to this feature, since charging is performed using DC power supplied from a computer connected via a USB cable, it is not necessary to provide an AC / DC converter circuit, etc., and the structure can be simplified. By transmitting the charging information data to the connected computer, the charging information related to charging is displayed on the computer and the charging status is provided to the user. Therefore, it is necessary to provide a display device in the charger. The charger can be manufactured at a low cost. Furthermore, since the DC power supplied via the USB cable is supplied only in the start-up state where the connected computer is used by the operator, there is a possibility that it will be used under the monitoring conditions of the user. Can greatly increase.

The primary battery charger according to claim 2 of the present invention is the primary battery charger according to claim 1,
A voltage measurement circuit unit (AD converter 22d) for measuring voltages of the primary batteries 30a and 30b mounted in the battery sockets (battery cases 25a and 25b);
Judgment means for determining whether or not the primary battery mounted in the battery socket is rechargeable or usable by charging based on the voltages of the primary batteries 30a and 30b measured by the voltage measurement circuit unit (microprocessing unit ( MPU) 22a),
Control means (microcomputer 22) for performing control to perform charging by the charging circuit section (charging transistors 29a, 29b) on the condition that the determination means determines that charging is possible;
With
The charging information data transmitting means (S18, S26) is characterized by transmitting determination result data for displaying the determination result of the determining means on the computer terminal as the charging information data.
According to this feature, charging is performed only on rechargeable or available batteries, so that overcharged primary batteries that cannot be charged can be prevented from being charged. However, it is possible to accurately grasp whether or not charging is possible.

The primary battery charger according to claim 3 of the present invention is the primary battery charger according to claim 2,
The determination means (microprocessing unit (MPU) 22a) is used for the primary batteries 30a and 30b newly attached to the battery sockets (battery cases 25a and 25b) measured by the voltage measurement circuit unit (AD converter 22d). When the voltage is equal to or higher than a predetermined chargeability determination voltage (1.00 V), it is determined that charging is possible.
According to this feature, even if a primary battery in an overdischarged state is attached, it is determined that charging is impossible. Therefore, charging of the primary battery in these overdischarged states can be prevented, and the primary in these overdischarged states can be prevented. The battery can be notified to the user as an unchargeable battery.

The primary battery charger according to claim 4 of the present invention is the primary battery charger according to claim 2 or 3,
The determination means (the microprocessing unit (MPU) 22a) is configured such that the voltage measurement circuit unit when a predetermined leaving time (10 minutes) elapses after the charging by the charging circuit unit (charging transistors 29a and 29b) is completed. When the voltage measured by the (AD converter 22d) is equal to or higher than a predetermined availability determination voltage (1.40V), the primary battery that has been charged is determined to be usable.
According to this feature, the voltage of the deteriorated primary battery drops suddenly after being charged, so that the deteriorated primary battery can be identified as an unusable primary battery. The battery can be notified to the user.

The primary battery charger according to claim 5 of the present invention is the primary battery charger according to claim 4,
The control means (microcomputer 22) has a predetermined overcharge time (10 minutes) after the voltage measured by the voltage measurement circuit unit (AD converter 22d) reaches a predetermined charging threshold voltage (1.58V). ) For the primary charging control (charging in the primary charging period in FIG. 5) for performing charging by the charging circuit unit (charging transistors 29a and 29b), and the elapse of the standing time after the completion of the primary charging. The charging is performed during a period from when the voltage measured by the voltage measurement circuit unit reaches the charging threshold voltage to a predetermined overcharge time on condition that the determination result at the time is available. The secondary charging control (charging in the secondary charging period of FIG. 5) for performing charging by the circuit unit is performed.
According to this feature, whether or not the primary battery can be used is determined by primary charging and subsequent determination, and secondary charging is performed only on the primary battery determined to be usable, so that the voltage improved by charging is increased. The primary battery, which tends to decrease in a short time after charging, can be charged with a higher capacity, and can prevent unnecessary charging of the unusable primary battery.

The primary battery charger according to claim 6 of the present invention is the primary battery charger according to any one of claims 1 to 5,
The charging information data transmitting means uses, as the charging information data, voltage information data for displaying on the computer terminal 10 the voltages of the primary batteries 30a and 30b measured by the voltage measuring circuit unit (AD converter 22d). It is characterized by transmitting.
According to this feature, the user can sequentially grasp the voltage of the primary battery being charged.

  Examples of the present invention will be described below.

  An embodiment of the present invention will be described with reference to the drawings. First, FIG. 1 is a diagram showing a use situation of the primary battery charger 1 of the present invention in the present embodiment.

  As shown in FIG. 1, the primary battery charger 1 of this embodiment includes a USB interface 15 that can be connected to a connection connector at one end of a USB cable 6 for performing serial data communication based on the USB (Universal Serial Bus) standard. It is used by being connected to a normal personal computer 10 (hereinafter abbreviated as a personal computer) comprising a main body 12 having a display 13 and a display 13.

  The primary battery charger 1 of this embodiment has an appearance similar to that of a USB mouse 11 that is an input device used in the personal computer 10, has a substantially front-rear shape in front view, and has a flat bottom surface. And a dome-shaped housing 2 covering the bottom surface.

  A main switch 3 for operating and stopping the primary battery charger 1 is provided on a side surface of the case, and a rectangular upper surface of the case 2 is provided inside the case 2. A transparent opening / closing cover 5 that covers an opening for inserting / removing batteries into / from battery cases 25a, 25b, which will be described later, is attached to the housing 2 so as to be opened and closed.

  Further, on the upper surface of the rear circle side of the housing, there are provided transmission windows 4 corresponding to the two LEDs 24 corresponding to the respective battery cases 25a and 25b mounted on the main board 20 described later. 4, the user can visually check the lighting state of the LED 24.

  Furthermore, a mounting port for mounting a connection connector at one end of the USB cable 6 to a USB connector 21 mounted on the main board 20 described later is provided at the rear circle side end of the housing 2. When the USB cable 6 is attached to the USB connector 21 via the attachment port, the primary battery charger 1 and the main body 12 of the personal computer 10 are connected by the USB cable 6, and the primary battery charger 1 and the personal computer 10 are connected. Can perform serial data communication based on the USB standard, and only when the personal computer 10 is in an activated state where it is used by an operator, a DC voltage of 5 V, which is a predetermined voltage, is supplied from the main body 12 through the USB cable 6. Supplied.

  FIG. 2 is a top view showing the main board 20 accommodated in the housing 2 of the primary battery charger 1 of the present embodiment.

  On the main board 20 of the present embodiment, as shown in FIG. 2, a USB connector 21 to which a connection connector at one end of the USB cable 6 can be attached is mounted at the narrow end position, Battery cases 25a and 25b capable of mounting two AA batteries are mounted in parallel at substantially the center, and the operation of the primary battery charger 1 is controlled between the USB connector 21 and the battery cases 25a and 25b. A microcomputer 22 is mounted for this purpose.

  The two LEDs 24 described above are mounted side by side in the side position of the microcomputer 22, and the main switch 3 fixed to the housing 2 is positioned at the opposite side of the LED 24. A connection terminal to which is connected is mounted.

  Note that reference numeral 23 in the figure denotes a vibrator for supplying a clock signal corresponding to the operating frequency of the microcomputer 22.

  In the present embodiment, battery cases 25a and 25b are provided so that two AA batteries can be charged simultaneously, and the battery cases 25a and 25b are attached to the battery cases 25a and 25b. Charge transistors 29a and 29b serving as switches for supplying a charging voltage to the primary battery, resistors 26a and 26b serving as loads for measuring the voltage of the primary battery, and the primary battery to the resistors 26a and 26b Load resistance switches 27a and 27b functioning as switches for supplying the voltage are mounted. Reference numerals 28a and 28b in the figure are diodes for preventing a reverse current flow due to reverse insertion of the positive and negative electrodes of the primary battery.

  In this embodiment, the back surface of the main board 20 is in close contact with a metal plate (not shown) having the same shape as that of the main board 20 with screws for the purpose of reinforcing mechanical strength and releasing heat. It is fixed to.

  Here, the configuration of the primary battery charger 1 of this embodiment will be described with reference to FIG. 4. A USB serial interface for performing serial data communication based on the USB standard is provided inside the microcomputer 22 used in this embodiment. (I / F) unit 22c, a P-ROM 22b in which a control program for carrying out a charging sequence described later is stored, and a microprocessing unit (MPU) 22a that executes the control program stored in the P-ROM 22b The AD converter 22d for measuring the voltage generated by the resistors 26a and 26b by quantization, and various I / Os and an internal memory (not shown) are built into a one-chip microcomputer, and a USB serial interface By connecting the (I / F) section 22c to the USB connector 21, the US The USB serial interface (I / F) unit 22c (that is, the microcomputer 22) can perform USB serial data communication with the personal computer 10 through the USB cable 6 attached to the connector 21, and the AD converter 22d includes battery cases 25a and 25b. Are connected to the positive terminals of the resistors 26a and 26b connected in parallel with the primary batteries 30a and 30b attached to the primary battery 30a, the voltage generated at both ends of the resistors 26a and 26b, that is, the voltage of the primary batteries 30a and 30b ( (Electromotive force) can be measured.

  The various LEDs I / O of the microcomputer 22 are connected to the LED 24 and the main switch 3, and are connected to the load resistance switches 27a and 27b and the charging transistors 29a and 29b. The microcomputer 22 can control ON / OFF of the transistors 29a and 29b.

  Although not shown in FIG. 4, the main switch 3 may include a reset circuit of the microcomputer 22 or a drive amplifier for driving the LED 24 may be provided.

  The ground terminal of the USB connector 21 is connected to the negative side of the primary batteries 30a and 30b, and the power supply terminal (+ 5V) is the charging transistor 29a and 29b connected to the positive side of the primary batteries 30a and 30b. When the charging transistors 29a and 29b are turned on by the microcomputer 22, the DC 5V voltage supplied via the USB cable 6 to the power supply terminal (+ 5V) of the USB connector 21 is supplied to the primary battery 30a. , 30b to be charged.

  Although not shown in FIG. 4, the DC voltage at the power supply terminal is also supplied to various devices mounted on the main board 20, and these various devices are operated by the DC voltage. . That is, the primary battery charger 1 according to the present embodiment is in a state where the main switch 3 is turned on, the primary battery charger 1 is not connected to the personal computer 10, and the personal computer 10 is not activated even if connected. Is not supposed to work.

  Next, display contents displayed on the display 13 of the personal computer 10 to which the primary battery charger 1 of this embodiment is connected will be described with reference to FIG.

  The personal computer 10 is preinstalled with a driver program including rules for communication contents for USB data communication with the microcomputer 22 mounted on the primary battery charger 1, and the primary battery is installed on the display 13. A utility program for displaying a charging window 14 for displaying a charging status in the charger 1 is installed, and these driver program and utility program are automatically activated and executed as the personal computer 10 is activated. .

  The charging window 14 displayed at the corner of the display 13 by the utility program of the present embodiment has a bar-shaped voltage indicator 42 for displaying the voltage of the primary battery to be charged, and an arrow as shown in FIG. A voltage indicator unit 43 and a status indicator unit 41 provided on an upper portion of the rod-shaped voltage indicator unit 42 for notifying the status of whether or not the corresponding battery can be charged or not, whether or not the battery is installed, by a display color, There is provided an operation unit 44 that is operated to stop charging or to start charging again after charging.

  Specifically, the voltage indicated by the voltage indicator sections 42 and 43 has a lower limit of 1.0 V, an upper limit of 1.6 V, and 1.6 V or higher is also displayed as 1.6 V. These voltage displays are based on the measured voltage data transmitted in steps S10, S21, and S32 of the control process shown in the process flow of FIG. 6 performed in the primary battery charger 1 of the present embodiment. By displaying, the voltage of the primary battery of each state accompanying charging is notified.

  Moreover, the status indicator part 41 alert | reports each condition accompanying charge with the color in the area | region made into the shape of a battery. Specifically, when a primary battery is not installed (when a battery-less command described later is received), white, when a primary battery is installed and charging (received a charging command described later is received) Yellow), when the primary battery is attached, but when it is determined that charging is not possible (NG) below the chargeability determination voltage (when a charge NG command to be described later is received), red, primary If it is determined that the battery is unusable because the voltage has dropped below the usability determination voltage (1.4 V) due to neglect after charging (when a use NG command described below is received), the battery is pink and the charge is good. When completed (when a charge end command described later is received), green is displayed according to various commands received from the primary battery charger 1.

  Further, the operation unit 44 is displayed with a yellow color on the status indicator unit 41, that is, when the battery is being charged, a character “cancel” is displayed, and the character “cancel” is displayed. When the displayed operation unit 44 is operated, charging is stopped by transmitting a charging stop command to the primary battery charger 1.

  Furthermore, the operation unit 44 displays green on the status indicator unit 41, that is, when the charging is completed (terminated) or is interrupted, the characters “recharge” are displayed. When the operation unit 44 on which the characters “recharge” are displayed is operated, charging is started by transmitting a recharge command to the primary battery charger 1. It becomes like this.

  In the present embodiment, since two batteries can be charged at the same time, in the transmission / reception of these various commands, the identification information of the target primary battery, specifically, the primary battery 30a attached to the battery case 25a is used. If there is a battery ID “A”, and if it is a primary battery 30b attached to the battery case 25b, a battery ID “B” is added and transmitted, so that the command relates to which primary battery. Can be identified.

  Hereinafter, based on the flowchart shown in FIG. 6, the processing content implemented in the primary battery charger 1 of a present Example is demonstrated.

  First, the primary battery charger 1 is connected to the personal computer 10 and the main switch 3 is turned on when the personal computer 10 is activated, or is connected when the main switch 3 is turned on. When the personal computer 10 is activated or is activated depending on whether it is connected to the personal computer 10 that is already activated in a state where the main switch 3 is ON, the activation process of S1 is performed.

  In this startup process, the microcomputer 22 reads and executes the control program stored in the P-ROM 22b, and also stores the status data of each battery case 25a, 25b stored in an internal memory (not shown) in the microcomputer 22, Initialization of various data such as registration of next charge and confirmation of connection with the personal computer 10 (actually confirmation of communication with a utility program running on the personal computer 10) are performed.

  After the start-up process, the process proceeds to step S2, and a load resistance voltage measurement process is performed. In the load resistance voltage measurement process in this embodiment, the voltage of the batteries 30a, 30b in the battery cases 25a, 25b is measured by the voltages generated in the resistors 26a, 26b, or the primary batteries 30a, 30b are mounted. This is processing for detecting presence or absence.

  Specifically, in the load resistance voltage measurement process, first, the load resistance switches 27a and 27b are turned on to connect the resistors 26a and 26b to the positive and negative electrodes of the battery cases 25a and 25b, and then the AD converter 22d. The voltage generated by the resistors 26a and 26b is quantized and measured.

  The control program in the P-ROM 22b includes a voltage table in which the quantized values and voltage values quantized by the AD converter 22d are stored in association with each other. A unique voltage value is specified as the measurement voltage, and the specified voltage value is temporarily stored in the internal memory.

  Then, after the quantization is performed by the AD converter 22d, the load resistance switches 27a and 27b are turned off.

  After performing the load resistance voltage measurement process, the process proceeds to step S3, and whether or not the voltage value measured (specified) in step S2 is equal to or higher than a predetermined mounting detection voltage (0.9 V in this actual example). Determine whether. That is, when the primary batteries 30a and 30b are attached to the battery cases 25a and 25b, the voltage is detected. Therefore, the attachment detection voltage is set to an appropriate voltage, specifically, a predetermined voltage equal to or lower than the electromotive force of the primary battery. It becomes possible to detect the attachment of the primary batteries 30a and 30b.

  In this embodiment, since the attachment detection voltage is 0.9 V, even if an overdischarge primary battery having an electromotive force of less than 0.9 V is attached, the overdischarge battery is attached. Is not detected, the charging of the overdischarged battery is not carried out, but the present invention is not limited to this, in this embodiment, in addition to the determination of the wearing detection, As will be described later, since it is determined whether or not charging is possible based on the chargeability determination voltage (1.0 V), the mounting detection voltage may be set to a lower level of about 0.5 V. When a primary battery having an electromotive force lower than a voltage (1.0 V) is attached, as described later, the inability to charge is displayed on the personal computer 10 so that the attached primary battery cannot be charged. Use that It will be able to reliably recognize.

  If it is determined in step S3 that the voltage value is not equal to or higher than the predetermined attachment detection voltage, the process proceeds to step S16, and the battery ID of the primary battery corresponding to the voltage value stored in the internal memory is set. The corresponding status data is updated to “not installed”, and after the LED 24 corresponding to the battery ID is turned off, a battery no command indicating that the primary battery is not installed is sent together with the battery ID to the USB serial interface (I / F) After transmitting to the personal computer 10 (utility program) from the part 22c, the process returns to the step S2.

  In other words, when the primary battery is not installed, S2 → S3 → S16 → S17 → S2 is circulated, and the primary battery is put on standby (idle state).

  In addition, when the battery-less command is received, the above-described status indicator unit 41 is updated to white (white is maintained for the first time), thereby notifying that no battery is installed.

  When the primary battery is mounted, in step S3, it is determined that the voltage value is equal to or higher than the predetermined mounting detection voltage, and the process proceeds to step S4, which corresponds to the voltage value stored in the internal memory. The status data corresponding to the battery ID of the primary battery that is to be updated is updated to “installed”, and the LED 24 corresponding to the battery ID is set to a continuously lit state.

  Then, the process proceeds to step S5, and it is determined whether or not the voltage value measured (specified) in step S2 is equal to or higher than the chargeability determination voltage (1.0 V).

  If the determination result is not equal to or higher than the chargeability determination voltage (1.0 V), the process proceeds to step S18, and a charge NG command indicating that the attached primary battery is a non-chargeable battery is sent to the USB together with the battery ID. The data is transmitted from the serial interface (I / F) unit 22c to the personal computer 10 (utility program), and the lighting state of the LED 24 corresponding to the battery ID is set to high-speed blinking lighting, and then the process returns to step S2.

  By receiving the charging NG command, the above-described status indicator unit 41 is updated to red, thereby informing that the attached primary battery is a battery that cannot be charged.

  On the other hand, if the determination result is equal to or higher than the chargeability determination voltage (1.0 V), the process proceeds to step S6, and the charging command indicating that charging is in progress is performed along with the battery ID and the USB serial interface (I / F). ) Part 22c transmits to the personal computer 10 (utility program), and the lighting state of the LED 24 corresponding to the battery ID is set to blink at medium speed.

  By receiving the charging command, the above-described status indicator unit 41 is updated to yellow, thereby informing that charging is in progress.

  Next, the charging transistors 29a and 29b are turned on (S7), and charging is started by applying a charging voltage to the primary battery that is attached and determined to be chargeable. In addition, when the charging transistors 29a and 29b are turned on and the countdown timer of the ON period is started to start counting down, the time when the charging transistors 29a and 29b are next turned off is started.

  Then, the process proceeds to step S8, and when the countdown of the countdown timer is completed, that is, when the ON period has elapsed, the charge transistors 29a and 29b are turned off, and then the same load resistance voltage measurement process as that in step S2 is performed. Then, the electromotive force (voltage) of the primary battery at that time during charging is measured, and the voltage data of the measured voltage together with the battery ID is sent from the USB serial interface (I / F) unit 22c to the personal computer 10 It transmits to (utility program) (S10).

  By receiving this voltage data, the voltage indicator 42 and 43 described above displays the voltage being charged specified from the voltage data.

  In step S11 and step S12, whether or not a charge stop command is received from the personal computer 10, and the voltage measured in step S9 is equal to or higher than a predetermined charge threshold voltage (1.58 V in this embodiment, see FIG. 5). It is determined whether or not.

  That is, when a charge stop command is transmitted from the personal computer 10 (utility program) by operating the above-described operation unit 44 on which “stop” is displayed during charging, the transmitted charge stop command is transmitted. Is detected in step S11 and the process proceeds to step S29 described later, whereby charging is terminated.

  If the voltage measured in step S9 is not equal to or higher than the charging threshold voltage, it is determined as “No” in step S12 and the process returns to step S7. The charging transistors 29a and 29b are turned on again to perform charging. Is done. That is, when the charging stop command is not received from the personal computer 10 and the electromotive force of the primary battery being charged is less than 1.58 V which is the charging threshold voltage, the steps S7 to S12 are repeatedly performed, so that the primary battery And the electromotive force of the primary battery being charged is transmitted to the personal computer 10 and displayed.

  When the electromotive force of the primary battery becomes equal to or higher than the charging threshold voltage of 1.58 V due to charging, it is determined as “Yes” in the determination of S12, and the process proceeds to S13. When the determination is made and the overcharge time timer is not counted up (including the case where the overcharge time timer itself is not counted), the process proceeds to step S14 to determine whether the overcharge time timer is counting. If the overcharge time timer is not counting, the overcharge time timer starts counting in step S15 and returns to step S7 again.

  That is, when the electromotive force of the primary battery exceeds the charging threshold voltage of 1.58 V for the first time due to charging, the overcharge time timer has not yet started counting, so the determination in S13 and S14 is “No”. As a result, the overcharge time timer is started in step S15 and the process returns to step S7, whereby charging is continued.

  If the overcharge time timer has not counted up, that is, if the overcharge time (in this embodiment, 10 minutes as shown in FIG. 5) has not elapsed, “No” is determined in S13. In addition, when the determination is “Yes” in S <b> 14, the processing of S <b> 7 to S <b> 14 is repeatedly performed, so that charging is further continued.

  Then, when the overcharge time has elapsed and the overcharge time timer has counted up, the count up is detected in step S13 and the process proceeds to step S19. Charging is terminated (see FIG. 5).

  Then, the process proceeds to step S20, where the same load resistance voltage measurement process as that in step S2 is performed, and the electromotive force (voltage) of the primary battery at that time during standing is measured, and the voltage data of the measured voltage is obtained. Along with the battery ID, the data is transmitted from the USB serial interface (I / F) unit 22c to the personal computer 10 (utility program) (S22).

  By receiving this voltage data, the above-mentioned voltage indicator units 42 and 43 display the voltage that is left as it is specified from the voltage data.

  Then, the process proceeds to step S22, where it is determined whether or not the leaving time timer that has started counting in step S19 has been counted up. If not, the process returns to step S20 to return to the leaving time ( Until 10 minutes elapses in this embodiment, the electromotive force (voltage) of the primary battery being left is measured and transmitted to the personal computer 10 (utility program) for display.

  When the leaving time has elapsed and the leaving time timer has counted up, the count up is detected in S22 and the process proceeds to step S23, and the voltage measured in the immediately preceding step S20 is determined as a predetermined availability determination. It is determined whether or not the voltage is 1.40 V or higher in this embodiment (see FIG. 5).

  Here, when the voltage measured in the immediately preceding step S20 is equal to or higher than 1.40V, which is a predetermined availability determination voltage, it is determined as “Yes” in the determination in the step S23, and the process proceeds to the step S24. It is determined whether or not there is a secondary charging registration indicating that secondary charging is being performed in the internal memory. If there is no secondary charging registration, after secondary charging is registered in the internal memory in step S25, Returning to S7 again, if there is a secondary charge registration, the process proceeds to step S29, where the charging is terminated.

  In other words, primary batteries that have deteriorated due to repeated charging have their electromotive force drastically reduced after charging even after charging. Therefore, in order to disable the use of these deteriorated primary batteries, If the voltage at the time when the time has passed is 1.40 V or higher, which is the availability determination voltage, that is, only if it is not a deteriorated primary battery, return to S7 and perform secondary charging by the same process as primary charging Thus, the charging is terminated (see FIG. 5).

  If the voltage at the time when the standing time after the primary charge has elapsed is less than 1.40 V, which is the availability determination voltage, the determination in step S23 is “No” and the process proceeds to step S26. By transmitting a use NG command indicating that the attached primary battery is a deteriorated battery that cannot be used together with the battery ID from the USB serial interface (I / F) unit 22c to the personal computer 10 (utility program). When the above-described status indicator unit 41 in the personal computer 10 is updated to pink, it is notified that the attached primary battery is a deteriorated battery that cannot be used.

  And the step of S27 which performs the load resistance voltage measurement process same as S2, and the step of S28 which determines whether the voltage value measured (specified) in the step of S27 is less than a predetermined mounting detection voltage. When it is not less than the predetermined attachment detection voltage, the process returns to S27 to shift to a standby state for taking out the primary battery determined to be unusable.

  When the primary battery determined to be unusable is removed from the battery cases 25a and 25b, “Yes” is determined in step S28, the process returns to step S2, and “No” is determined in step S3. As a result of the determination, the steps S16 and S17 are performed, so that the status data obtained by removing the primary battery is updated to the non-mounted state, and the display color of the status indicator 41 of the personal computer 10 is also white indicating no battery. Updated.

  On the other hand, when the secondary charging is completed and the neglected time after the secondary charging has elapsed, “Yes” is determined in step S24 and the process proceeds to step S29 to delete the secondary charging registration in the internal memory. After that, by sending a charge end command together with the battery ID from the USB serial interface (I / F) unit 22c to the personal computer 10 (utility program), the aforementioned status indicator unit 41 in the personal computer 10 is updated to green. Thus, it is notified that the charging has been completed (including the case where the charging is stopped). Note that when the charging end command is transmitted, the lighting state of the LED 24 corresponding to the battery ID is a low-speed blinking lighting.

  And it progresses to the step of S31, implements the load resistance voltage measurement process same as the step of S2, measures the electromotive force (voltage) of the primary battery at that time after the end of charging, and voltage data of the measured voltage Is transmitted to the personal computer 10 (utility program) from the USB serial interface (I / F) unit 22c together with the battery ID (S32), and the voltage value measured (specified) in the step of S31 is a predetermined wearing detection. The step of S33 for determining whether or not the voltage is less than the voltage and the step of S34 for determining whether or not a recharge command is received are performed. If no recharge command is received, the process returns to S31 to complete charging. The primary battery removal standby state and the recharge command reception standby state are entered. The voltage transmitted in step S32 is displayed on the personal computer 10 as the electromotive force (voltage) of the primary battery after the end of charging.

  When the primary battery that has been charged in this standby state is taken out of the battery cases 25a and 25b, “Yes” is determined in step S33, the process returns to step S2, and “No” is determined in step S3. As a result of the steps S16 and S17 being executed, the status data obtained by removing the primary battery is updated to the non-installed state, and the display color of the status indicator 41 of the personal computer 10 is also updated to white indicating no battery. Is done.

  On the other hand, in the standby state, when the recharge command is received by operating the above-described operation unit 44 on which “recharge” is displayed, the reception of the recharge command is performed in step S34. When the process proceeds to step S7, primary charging is started again.

  As described above, according to the primary battery charger 1 of the present embodiment, since charging is performed using the DC power supplied from the personal computer 10 connected via the USB cable 6, an AC / DC converter circuit and the like are provided. There is no need, the structure can be simplified, and the charging information data is transmitted to the connected personal computer 10 so that the charging information related to the charging is displayed on the personal computer 10 and the charging status is provided to the user. As a result, it is not necessary to provide a display device in the charger, and the charger can be manufactured at low cost. Furthermore, since the DC power supplied via the USB cable is supplied only in the start-up state where the connected computer is used by the operator, there is a possibility that it will be used under the monitoring conditions of the user. Can greatly increase.

  In addition, according to the primary battery charger 1 of this embodiment, charging is performed only on a rechargeable or usable primary battery, so that it is possible to prevent charging to an undischargeable overdischarged primary battery. The user can accurately grasp whether or not the primary battery to be charged is chargeable or usable.

  Further, according to the primary battery charger 1 of the present embodiment, even if an overdischarged primary battery is mounted, it is determined that charging is impossible, so that charging of the overcharged primary battery is prevented. The overcharged primary battery can be notified to the user as an unchargeable battery.

  In addition, according to the primary battery charger 1 of the present embodiment, the voltage of the deteriorated primary battery suddenly drops due to being left after charging, so that the deteriorated primary battery can be identified as an unusable primary battery. Thus, the degraded primary battery that cannot be used can be notified to the user.

  Moreover, according to the primary battery charger 1 of the present embodiment, whether or not the primary battery can be used is determined by primary charging and subsequent determination, and only the primary battery determined to be usable is subjected to secondary charging. As a result, it is possible to charge the primary battery whose voltage improved by charging is likely to decrease in a short time after charging, and to prevent unnecessary charging to the unusable primary battery.

  Further, according to the primary battery charger 1 of the present embodiment, the user can sequentially grasp the voltage of the primary battery being charged.

  Although the embodiments of the present invention have been described with reference to the drawings, the specific configuration is not limited to these embodiments, and modifications and additions within the scope of the present invention are included in the present invention. It is.

  For example, in the above embodiment, in order to display on the personal computer 10 whether or not the attached primary battery can be charged, separately from the attachment presence / absence determination based on the attachment detection voltage, the chargeability determination voltage (1.0 V). However, the present invention is not limited to this, and the electromotive force that is equal to or lower than the charge enable / disable determination voltage is set to the same voltage as the attachment detection voltage and the charge enable / disable determination voltage. Even if a primary battery is attached, invalidation of the attachment prevents the overcharged primary battery from being charged below the chargeability determination voltage, and simplifies the processing in the primary battery charger 1. You may make it.

  Moreover, in the said Example, although the primary battery charger 1 which can charge two primary batteries simultaneously was illustrated, this invention is not limited to this, The number of these rechargeable primary batteries is one. Alternatively, it may be three or more.

  Moreover, in the said Example, although only the AA type primary battery can be charged as a primary battery to charge, this invention is not limited to this, Other single type, single type 2 It is good also as a structure which can charge the primary battery of a single or a combination simultaneously.

  Moreover, in the said Example, although 0.9V is shown as a mounting | wearing detection voltage, 1.0V as a charge availability determination voltage, 1.40V as a usage availability determination voltage, and 1.58V as a charge threshold voltage, this invention is shown. The mounting detection voltage, the chargeability determination voltage, the useability determination voltage, and the charge threshold voltage may be appropriately set according to the purpose, such as a dip switch or a microcomputer P-ROM. By providing a device for rewriting an internal control program, the mounting detection voltage, the chargeability determination voltage, the availability determination voltage, and the charge threshold voltage may be changed and set.

  In the embodiment, the overcharge time and the leaving time are both 10 minutes. However, the present invention is not limited to this, and the overcharge time and the leaving time are specified by the charging transistors 29a and 29b. Or it may be selected as appropriate according to the capacity and type of the primary battery (single, single, single, etc.), and by providing a device for rewriting the control program inside the P-ROM of the microcomputer. The overcharge time and the leaving time may be changed and set.

  Further, in the embodiment, charging is performed by primary charging and secondary charging, but the present invention is not limited to this, and this is limited to primary charging, or conversely, tertiary charging or You may make it implement the charge of quaternary charge and ....

  Further, in the above embodiment, only the primary battery is charged, but the present invention is not limited to this. For example, the mounting detection voltage, the chargeability determination voltage, the availability determination voltage, and the charge threshold voltage are set. Select to select whether the type of battery to be installed is a primary battery or a secondary battery in order to change to each voltage for a secondary battery (becomes a lower voltage than the primary battery) When a secondary battery is selected by the selection switch, the primary battery is set by setting a mounting detection voltage, a chargeability determination voltage, a useability determination voltage, and a charge threshold voltage for the secondary battery. In addition to the battery, a rechargeable secondary battery may be charged.

It is a use situation figure of primary battery charger 1 in the example of the present invention. It is a top view which shows the main board | substrate 20 used for the primary battery charger 1 in the Example of this invention. It is a figure which shows the display content displayed on the display 13 of the personal computer 10 to which the primary battery charger 1 in the Example of this invention is connected. It is a block diagram which shows the structure of the primary battery charger 1 in the Example of this invention. It is explanatory drawing which shows the charge sequence of the primary battery charger 1 in the Example of this invention. It is a flowchart which shows the processing content of the control processing of the primary battery charger 1 in the Example of this invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Primary battery charger 2 Case 3 Main switch 4 Transmission window 5 Opening / closing cover 6 USB cable 10 Personal computer (PC)
11 Mouse 12 Body 13 Display 15 USB interface 20 Main board 21 USB connector 22 Microcomputer 25a, b Battery case 26a, b Resistance 27a, b Load resistance switch 29a, b Charging transistor 30a, b Primary battery

Claims (6)

A USB interface unit connected to a USB cable for performing serial data communication based on the USB (Universal Serial Bus) standard, and performing serial data communication with a computer terminal connected via the USB cable;
A battery socket in which a primary battery can be mounted;
A charging circuit unit for charging the primary battery by applying a charging voltage based on DC power supplied from the computer terminal via the USB cable to the primary battery mounted on the battery socket;
Charging information data transmitting means for transmitting charging information data for displaying charging information related to charging by the charging circuit unit through the USB interface unit;
A primary battery charger comprising: A voltage measurement circuit unit for measuring a voltage of a primary battery mounted in the battery socket;
Determination means for determining whether or not the primary battery mounted in the battery socket is rechargeable or usable by charging based on the voltage of the primary battery measured by the voltage measurement circuit unit;
Control means for performing control to perform charging by the charging circuit unit on the condition that the determination means determines that charging is possible;
With
2. The primary battery charger according to claim 1, wherein the charging information data transmission unit transmits determination result data for displaying the determination result of the determination unit on the computer terminal as the charging information data. .   The determination means determines that charging is possible when the voltage of the primary battery newly installed in the battery socket measured by the voltage measurement circuit unit is equal to or higher than a predetermined chargeability determination voltage. The primary battery charger according to claim 2.   When the voltage measured by the voltage measurement circuit unit at a time when a predetermined leaving time has elapsed after the charging by the charging circuit unit is finished is equal to or higher than a predetermined use determination voltage, The primary battery charger according to claim 2, wherein the primary battery that has been charged is determined to be usable.   The control means performs primary charge control for performing charging by the charging circuit unit for a predetermined overcharge time after the voltage measured by the voltage measurement circuit unit reaches a predetermined charging threshold voltage. In addition, the voltage measured by the voltage measurement circuit unit reaches the charging threshold voltage on condition that the determination result at the elapse of the standing time after the completion of the primary charging is usable. 5. The primary battery charger according to claim 4, wherein secondary charging control for performing charging by the charging circuit unit is performed during a period from the start to a predetermined overcharge time.   The charging information data transmitting means transmits voltage information data for displaying the voltage of the primary battery measured by the voltage measuring circuit unit on the computer terminal as the charging information data. The primary battery charger as described in 1-5.

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