JP7187973B2 - mobile terminal - Google Patents

Description

The present invention relates to a mobile terminal having a battery as a power supply source.

Conventionally, batteries, which serve as power sources for mobile terminals and the like, need to be charged according to power supplied from an external device such as a charging device. be. As a technique for suppressing such battery performance deterioration, for example, a portable device disclosed in Patent Document 1 below is known. In this portable device, if the battery temperature measured at the start of charging is less than 35° C. (normal temperature), 4.2 V is selected as the charging voltage in the high-voltage region. If so, 4.1V, which is lower than 4.2V, is selected as the charging voltage, although it is in the high voltage range. If the state of the high temperature region and the high voltage region continues for a predetermined time during charging, the charging voltage is lowered to 3.95 V, so that the battery life is significantly deteriorated due to the continuous high temperature region and high voltage region. are preventing.

JP-A-2008-067420

By the way, when a mobile terminal in a non-charged state performs a predetermined process and then is charged on a charging stand or the like, the charging circuit of the mobile terminal adjusts the battery voltage to the full charge voltage according to the power supply from the charging stand or the like. to charge the battery. At that time, it is necessary to set the full charge voltage high in order to increase the continuous use time of the mobile terminal when not charging, but the high full charge voltage tends to shorten the battery life. As a result, the battery tends to swell, resulting in a problem that the performance of the battery tends to deteriorate. In addition, simply setting the full charge voltage to a low value has the problem of shortening the continuous use time during non-charging.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-described problems, and an object thereof is to provide a configuration capable of suppressing deterioration in battery performance without shortening the continuous use time of a portable terminal. be.

In order to achieve the above object, the invention described in claim 1 of the scope of claims includes:
A mobile terminal (10) having a battery (31) as a power supply source,
a charging circuit (32) for charging the battery so that the battery voltage (Vb) of the battery reaches a full charge voltage value (Vm) according to power supply from the outside (1);
a battery voltage detection unit (33) for detecting the battery voltage;
A power supply state detection unit (34) capable of detecting a power supply possible state in which the power supply from the outside is possible and electrically connected to the outside and a power supply stop state in which the power supply from the outside is stopped. )When,
a non-charging time measuring unit (26) that measures the elapsed time from the detection of the change from the power supply possible state to the power supply stopped state by the power supply state detection unit as a non-charging time (T1);
a setting unit (21) capable of setting the full-charge voltage value to either a first voltage value (Vm1) or a second voltage value (Vm2) smaller than the first voltage value;
with
When the power supply state detection unit detects the power supply possible state after the non-charge time measurement unit starts measuring the non-charge time, the setting unit measures the non-charge time until the detection. When the non-charging time measured by the unit is equal to or longer than a predetermined time (T1th), the full-charge voltage value is set to the first voltage value, and the non-charging time clock unit counts the time until the detection. The full charge voltage value is set to the second voltage value when the non-charging time is less than the predetermined time.

The invention according to claim 2 ,
A mobile terminal (10) having a battery (31) as a power supply source,
a charging circuit (32) for charging the battery so that the battery voltage (Vb) of the battery reaches a full charge voltage value (Vm) according to power supply from the outside (1);
a battery voltage detection unit (33) for detecting the battery voltage;
A power supply state detection unit (34) capable of detecting a power supply possible state in which the power supply from the outside is possible and electrically connected to the outside and a power supply stop state in which the power supply from the outside is stopped. )When,
a non-charging time measuring unit (26) that measures the elapsed time from the detection of the change from the power supply possible state to the power supply stopped state by the power supply state detection unit as a non-charging time (T1);
a setting unit (21) capable of setting the full-charge voltage value to either a first voltage value (Vm1) or a second voltage value (Vm2) smaller than the first voltage value;
with
When the power supply state detection unit detects the power supply possible state after the non-charge time measurement unit starts measuring the non-charge time, the setting unit measures the non-charge time until the detection. When the non-charging time measured by the unit is equal to or longer than a predetermined time (T1th) or the battery voltage detected by the battery voltage detecting unit is less than a predetermined voltage value (Vo), the full charge voltage value is set to the first voltage value, and the non-charging time measured by the non-charging time measuring unit is less than the predetermined time and the battery voltage detected by the battery voltage detecting unit is the predetermined voltage value. is equal to or higher than the voltage value of , the full charge voltage value is set to the second voltage value.

In the first aspect of the present invention, when the power supply state detection unit detects the power supply possible state after the non-charge time measurement unit starts measuring the non-charge time, the non-charge time measurement unit measures the time until the detection. When the determined non-charging time is equal to or longer than the predetermined time, the setting unit sets the full-charge voltage value to the first voltage value, and the non-charging time clocked by the non-charging time clock unit until the detection is the predetermined time. If it is less than the full charge voltage value, the setting unit sets the full charge voltage value to a second voltage value that is smaller than the first voltage value.

As a result, when the non-charging time is relatively short, for example, when the mobile terminal removed from the charging stand is checked and put back on the charging stand after a short period of time, the non-charging time is relatively long. In this case, the full charge voltage value is set to a small voltage value (second voltage value). In such a case, there is no need to increase the full charge voltage value to increase the continuous use time during non-charging. can be done.

In the second aspect of the present invention, when the power supply state detection unit detects the power supply possible state after the non-charge time measurement unit starts measuring the non-charge time, the non-charge time measurement unit measures the time until the detection. When the detected non-charging time is equal to or longer than the predetermined time or the battery voltage detected by the battery voltage detection unit is less than the predetermined voltage value, the setting unit sets the full charge voltage value to the first voltage value, If the non-charging time counted by the non-charging time timer before the detection is less than the predetermined time and the battery voltage detected by the battery voltage detecting unit is equal to or higher than the predetermined voltage value, the full charge voltage value is set by the setting unit. is set to the second voltage value.

As a result, if the non-charging time is relatively short and the battery voltage is relatively high when charging is resumed, for example, the operation of confirming the mobile terminal removed from the charging base can be completed in a short period of time, and then the battery can be charged again. When the battery is replaced on the table, the full charge voltage value is set to a small voltage value (second voltage value) for the case where the non-charging time is relatively long or the battery voltage is relatively low. In such a case, there is no need to increase the full charge voltage value to increase the continuous use time during non-charging. can be done. In particular, since both the non-charging time and the battery voltage are taken into account, it is possible to detect when the non-charging time is relatively short but the battery voltage is relatively low, or when the battery voltage is relatively high but the non-charging time is relatively long. Since the full charge voltage value is not set to a small voltage value (second voltage value), it is possible to set a full charge voltage value that is more suitable for the actual situation.

In the third aspect of the present invention, when the power supply state detection unit detects that the power can be supplied after the non-charge time measurement unit starts measuring the non-charge time, the non-charge time measurement unit measures the time until the detection. Even if the detected non-charging time is longer than the predetermined time or the battery voltage detected by the battery voltage detecting unit is lower than the predetermined voltage value, the temperature of the battery measured by the temperature measuring unit is higher than the predetermined temperature. Then, the full charge voltage value is set to the second voltage value by the setting unit.

As a result, even if the non-charging time is relatively long and the battery voltage when charging is resumed is relatively low, if the temperature of the battery rises above the predetermined temperature, for example, if the battery is in a high-temperature environment, a short In the case of performing high-load processing in a short period of time, the full charge voltage value is set to a small voltage value (second voltage value). In this manner, the full charge voltage value is set in consideration of the temperature of the battery in addition to the non-charging time and the battery voltage, so that the full charge voltage value more suitable for the actual situation can be set.

In the invention of claim 4 , in a state in which the determination unit determines that the connection time is less than the second predetermined time, the setting unit sets the full charge voltage value to the first voltage value, and the determination unit sets the full charge voltage value to the first voltage value. When it is determined that the time is equal to or longer than the second predetermined time, the setting unit sets the full charge voltage value to the second voltage value. Further, when the full charge voltage value is set to the second voltage value by the setting unit, charging of the battery by the charging circuit is stopped when the battery voltage detected by the battery voltage detection unit is equal to or higher than the second voltage value. be. Then, in the processing unit, when the full charge voltage value is set to the first voltage value by the setting unit or the battery voltage detected by the battery voltage detection unit is less than the second voltage value, electric power is supplied from the outside. After receiving the supply, reading processing for reading the wireless tag is performed as a predetermined processing, the full charge voltage value is set to the second voltage value by the setting unit, and the battery voltage detected by the battery voltage detection unit is the above voltage value. If the voltage is equal to or higher than the second voltage value, power is supplied from the battery and reading processing for reading the wireless tag is performed as a predetermined processing.

As a result, when the connection time is equal to or longer than the second predetermined time, for example, when the state where the mobile terminal is placed on the charging base in a chargeable state continues for a long time, the full charge voltage value is small. (second voltage value). At this time, not only is charging of the battery by the charging circuit stopped, but also power is supplied from the battery until the battery voltage becomes less than the second voltage value, and the processing unit performs predetermined processing. As a result, the battery voltage quickly drops to the second voltage value, so that the time during which the full charge voltage value becomes unnecessarily high can be shortened. can be further suppressed.

1 is a perspective view showing a state in which a mobile terminal according to a first embodiment is placed on a cradle; FIG. 2A is a block diagram illustrating the electrical configuration of the mobile terminal in FIG. 1, and FIG. 2B is a block diagram schematically illustrating the wireless tag processing unit in FIG. 2A. FIG. 2(C) is a block diagram schematically illustrating the information code reading section of FIG. 2(A). 4 is a flowchart illustrating the flow of full-charge voltage setting processing performed by a control unit in the first embodiment; FIG. 4 is an explanatory diagram for explaining temporal changes in battery voltage that change according to the full charge voltage value set in the full charge voltage setting process of the first embodiment; FIG. 11 is a block diagram illustrating an electrical configuration of a mobile terminal according to a third modified example of the first embodiment; FIG. FIG. 7 is a block diagram illustrating an electrical configuration of a mobile terminal according to a second embodiment; FIG. 9 is a flowchart illustrating the flow of charging processing performed by a control unit in the second embodiment; FIG. 11 is an explanatory diagram for explaining a change in battery voltage over time in the charging process in the second embodiment;

[First embodiment]
DESCRIPTION OF THE PREFERRED EMBODIMENTS A first embodiment embodying a portable terminal of the present invention will be described below with reference to the drawings.
A portable terminal 10 according to the present embodiment is a portable information reading terminal that is carried by a user and used in various places, and is mounted on a cradle (charging base) 1 that functions as an external power supply device. By doing so, the battery 31 is configured to be charged. This portable terminal 10 functions as an information code reader for optically reading information codes such as bar codes and two-dimensional codes, and also stores data in wireless tags such as RFID tags via radio waves transmitted and received via an antenna. It has a function to read and write the information stored in it, and has a configuration that allows reading by two methods.

As shown in FIG. 1, the mobile terminal 10 has an outer shell formed by a longitudinal housing 11 configured by assembling an upper case and a lower case made of a synthetic resin material such as ABS resin. Further, the upper case is provided with a key operation unit 25 such as function keys and numeric keys that are operated when inputting predetermined information, a display unit 24 for displaying predetermined information, and the like. A reading port 12 that opens downward is formed in the lower case. A power receiving terminal electrically connected to the charging terminal of the cradle 1 placed thereon is arranged on the bottom surface of the housing 11 .

Next, an electrical configuration of the mobile terminal 10 will be described.
As shown in FIG. 2A, a control unit 21 that controls the entire mobile terminal 10 is provided inside the housing 11 of the mobile terminal 10 . The control unit 21 is composed mainly of a microcomputer, has a CPU, a system bus, an input/output interface, etc., and together with the storage unit 22 constitutes an information processing apparatus. The storage unit 22 stores in advance a predetermined program and information code for executing a full-charge voltage setting process (to be described later), a program for executing a reading process for reading a wireless tag, and the like so as to be executable by the control unit 21. there is

Electronic components such as an LED 23 , a display unit 24 , a key operation unit 25 , a timer 26 and a communication unit 27 are connected to the control unit 21 . The key operation unit 25 is configured to give an operation signal to the control unit 21, and the control unit 21 receives this operation signal and performs an operation according to the contents of the operation signal. Also, the LED 23 and the display unit 24 are configured to be controlled by the control unit 21, and operate upon receiving commands from the control unit 21, respectively. The timer 26 is composed of a known clock circuit, timer circuit, or the like, and can measure a plurality of types of elapsed times such as a non-charging time and a connection time, which will be described later, and outputs the time measurement results to the control unit 21. is configured as The communication unit 27 is configured as an interface for performing data communication with an external device such as a server by wired communication or wireless communication, and is configured to perform communication processing in cooperation with the control unit 21. .

A battery 31 serving as a power supply source for the mobile terminal 10 and a charging circuit 32 for charging the battery 31 are provided in the housing 11 . The battery 31 is a secondary battery capable of generating a predetermined DC voltage, for example, a lithium ion battery, and is detachably housed in a battery housing portion in the housing 11, thereby controlling the control unit 21 and each electronic component. , etc.

The charging circuit 32 is controlled by the control unit 21 so as to charge the battery 31 so that the battery voltage Vb of the battery 31 reaches the full charge voltage value Vm according to the power supply from the cradle 1 via the power receiving terminal. function. A full charge voltage setting process performed by the control unit 21 to set the full charge voltage value Vm will be described later.

Therefore, in this embodiment, a battery voltage detector 33 for detecting the battery voltage Vb and a power supply state detector 34 for detecting the power supply state using the cradle 1 are provided. The power supply state detection unit 34 detects a power supply possible state in which the cradle 1 is electrically connected to the cradle 1 and a state in which the power supply from the cradle 1 is possible, depending on the voltage of the power receiving terminal or the like. It is configured to be able to detect a stopped power supply stop state and to output the detection result to the control unit 21 .

The mobile terminal 10 also includes a wireless tag processing section 40 and an information code reading section 50 that function as information reading sections that are controlled by the control section 21 to read external information.

First, the wireless tag processing unit 40 will be described with reference to FIG. 2(B).
The wireless tag processing unit 40 cooperates with the antenna 44 and the control unit 21 to perform electromagnetic wave communication with the wireless tag T to read data stored in the wireless tag T or write data to the wireless tag T. It functions to do The wireless tag processing unit 40 is configured as a circuit that performs transmission by a known radio wave method, and as schematically shown in FIG. have.

The transmission circuit 41 is composed of a carrier oscillator, an encoding section, an amplifier, a transmission section filter, a modulation section, and the like, and has a configuration in which a carrier (carrier wave) of a predetermined frequency is output from the carrier oscillator. The encoder is also connected to the controller 21, encodes transmission data output from the controller 21, and outputs the encoded data to the modulator. The modulation section is a section to which the carrier (carrier wave) from the carrier oscillator and the transmission data from the encoding section are input. A modulated signal that is ASK (Amplitude Shift Keying) modulated by an encoded transmission code (modulation signal) output from the encoding unit is generated and output to an amplifier. The amplifier amplifies the input signal (the modulated signal modulated by the modulating section) with a predetermined gain and outputs the amplified signal to the transmitting section filter, which filters the amplified signal from the amplifier. A transmission signal is output to the antenna 44 via the matching circuit 43 . When the transmission signal is output to the antenna 44 in this manner, the transmission signal is radiated to the outside from the antenna 44 as a transmission radio wave.

On the other hand, the response signal received by the antenna 44 is input to the receiving circuit 42 via the matching circuit 43 . The receiving circuit 42 is composed of a receiving filter, an amplifier, a demodulator, a binarization processing unit, a decoding unit, and the like. , is amplified by an amplifier, and the amplified signal is demodulated by a demodulator. Then, the demodulated signal waveform is binarized by the binarization processing section, decoded by the decoding section, and then outputted to the control section 21 as received data.

Next, the information code reading section 50 will be described with reference to FIG. 2(C).
The information code reading unit 50 functions to optically read the information code C, and as shown in FIG. and lenses, etc., and cooperates with the control unit 21 to read the information code C (bar code or two-dimensional code) attached to the reading target R. Function.

When reading is performed by the information code reading unit 50, first, the illumination light Lf is emitted from the illumination unit 51 instructed by the control unit 21, and the illumination light Lf passes through the reading port 12 and irradiates the object R to be read. be. Reflected light Lr of the illumination light Lf reflected by the information code C is taken into the apparatus through the reading port 12 and received by the light receiving sensor 53 through the imaging lens 52 . An imaging lens 52 arranged between the reading port 12 and the light receiving sensor 53 forms an image of the information code C on the light receiving sensor 53, and the light receiving sensor 53 receives the image of the information code C. and outputs a light reception signal corresponding to the A light receiving signal output from the light receiving sensor 53 is stored in the storage unit 22 as image data, and is used for decoding processing for obtaining information included in the information code C. FIG. The information code reading unit 50 is provided with an amplifier circuit for amplifying the signal from the light receiving sensor 53 and an AD conversion circuit for converting the amplified signal into a digital signal. are omitted.

Next, the full-charge voltage setting process performed by the control section 21 for setting the full-charge voltage value Vm according to the charging state and the like will be described.
In this embodiment, as the full charge voltage value Vm, a normal voltage value (hereinafter also referred to as a first full charge voltage value Vm1) and a voltage value for battery protection smaller than the first full charge voltage value Vm1 (hereinafter , second full charge voltage value Vm2) are prepared. In order to increase the continuous use time of the mobile terminal 10 when not charging, it is necessary to set the full charge voltage value Vm high. 4.4V). On the other hand, depending on the charging situation, etc., a high charging voltage value may not be necessary, or the normal charging voltage value (first full charging voltage value Vm1) may accelerate the deterioration of the battery 31. There is Therefore, in this embodiment, in order to suppress deterioration of the battery 31 in such a case, the full charge voltage value Vm is set to the second full charge voltage value Vm2 (for example, 3.85 V). The first full-charge voltage value Vm1 can correspond to an example of a "first voltage value", and the second full-charge voltage value Vm2 can correspond to an example of a "second voltage value".

3 for the full charge voltage setting process for setting the full charge voltage value Vm to the first full charge voltage value Vm1 or the second full charge voltage value Vm2 according to the charging situation. specific details.
The full-charge voltage setting process in this embodiment is started when the power supply state detection unit 34 detects a change from the power supply enabled state to the power supply stopped state. That is, when the mobile terminal 10, which has been in a power supply enabled state by being placed on the cradle 1, is removed from the cradle 1 and enters a power supply stop state, the control unit 21 starts the full-charge voltage setting process. be.

First, the non-charging time clocking process shown in step S101 of FIG. 3 is performed. In this process, the timer 26 starts the process for measuring the elapsed time from when the power supply state detection unit 34 detects the change from the power supply possible state to the power supply stop state as the non-charging time T1. be done. That is, as can be seen from the time ta1 in FIG. 4, the elapsed time from when the power supply is stopped and the battery voltage Vb starts to decrease is counted as the non-charging time T1. Note that the timer 26 can correspond to an example of a "non-charging time measuring unit".

Subsequently, in the determination process of step S103, it is determined whether or not the cradle 1 is connected to the cradle 1 so as to be able to supply power, according to the detection result of the power supply state detection unit 34 . Here, if the power supply state detection unit 34 detects that the power supply is stopped because no voltage is applied to the power receiving terminal, it is determined that the power supply state is not connected, and the step S103 determines No. Processing from S101 is performed.

After that, when the portable terminal 10 is placed on the cradle 1, a voltage is applied to the power receiving terminal, and when the power supply state detection unit 34 detects the power supply possible state, the connection state is determined and the process proceeds to step S103. Yes. In this case, in the determination process of step S105, it is determined whether or not the battery voltage Vb detected by the battery voltage detection unit 33 is equal to or higher than the minimum operating voltage value Vo, which is the minimum voltage value at which operation is possible. Here, the minimum operating voltage value Vo can correspond to an example of a "predetermined voltage value" and is set to 3.6V, for example.

Here, since the reading process and the like are performed frequently during non-charging, as indicated by the dashed line Vb1 in FIG. If it is less than Vo, it is determined as No in step S105, and the full charge voltage value Vm is set to the first full charge voltage value Vm1 (S109).

On the other hand, if the battery voltage Vb is equal to or higher than the minimum operating voltage value Vo (Yes in S105), it is determined in step S107 whether the measured non-charging time T1 is equal to or shorter than the preset predetermined time T1th. A determination is made as to whether or not In the present embodiment, the predetermined time T1th is set to, for example, 24 hours, and the reading process and the like are not performed frequently. , the non-charging time T1 becomes equal to or longer than the predetermined time T1th (Yes in S107) at time ta4 when the power supply enabled state is detected, and the full charge voltage value Vm is set to the first full charge voltage value Vm1. (S109).

When the non-charging time T1 is relatively short, for example, when the mobile terminal 10 removed from the cradle 1 is checked and placed back on the cradle 1 in a short period of time, the thick line Vb3 in FIG. , the non-charging time T1 becomes less than the predetermined time T1th at the time ta3 when the power supply enabled state is detected, and it is determined as No in step S107. Thus, when the battery voltage Vb is equal to or higher than the minimum operating voltage value Vo and the non-charging time T1 is relatively short, the full charge voltage value Vm is set to the second full charge voltage value Vm2 (S111 ).

When the full charge voltage value Vm is set to the first full charge voltage value Vm1 or the second full charge voltage value Vm2 as described above, the timing of the non-charge time T1 ends (S113), and the full charge voltage is set. Processing ends. Note that the control unit 21 that performs the processes of steps S109 and S111 is an example of a "setting unit" that can set the full charge voltage value Vm to either the first full charge voltage value Vm1 or the second full charge voltage value Vm2. can be equivalent to

Then, the battery 31 is charged by the charging circuit 32 so that the battery voltage Vb of the battery 31 reaches the full charge voltage value Vm set as described above by the charging process separately performed by the control unit 21 .

As described above, in the mobile terminal 10 according to the present embodiment, when the power supply state detection unit 34 detects the power supply possible state after the non-charging time period T1 is started, time is measured until the detection. When the non-charging time T1 is equal to or longer than the predetermined time T1th (Yes in S107) or the battery voltage Vb detected by the battery voltage detection unit 33 is less than the minimum operating voltage value Vo (No in S105), the full charge voltage The value Vm is set to the first full charge voltage value Vm1, the non-charging time T1 counted until the detection is less than the predetermined time T1th, and the battery voltage Vb detected by the battery voltage detection unit 33 is the minimum operating voltage value If it is Vo or more, the full charge voltage value Vm is set to the second full charge voltage value Vm2.

As a result, when the non-charging time T1 is relatively short and the battery voltage Vb when charging is resumed is relatively high, for example, the confirmation operation of the mobile terminal 10 removed from the cradle 1 can be completed in a short time. When the non-charging time T1 is relatively long and the battery voltage Vb is relatively low, the full charge voltage value Vm is higher than the first full charge voltage value Vm1. It is set to a small second full charge voltage value Vm2. In such a case, it is not necessary to increase the full charge voltage value Vm in order to increase the continuous use time during non-charging. can be suppressed. In particular, since both the non-charging time T1 and the battery voltage Vb are considered, even if the non-charging time T1 is relatively short, the battery voltage Vb is relatively low, and even if the battery voltage Vb is relatively high, the non-charging time T1 is relatively long, the full charge voltage value Vm is not set to the second full charge voltage value Vm2, so the full charge voltage value Vm more suitable for the actual situation can be set.

As a first modification of the present embodiment, in the full charge voltage setting process, the determination process in step S105 may be eliminated, and the full charge voltage value Vm may be set according to the non-charging time T1. That is, when the power supply state detection unit 34 detects the power supply possible state after the non-charging time T1 starts to be measured, if the non-charging time T1 measured until the detection is equal to or longer than the predetermined time T1th, When the full-charge voltage value Vm is set to the first full-charge voltage value Vm1 and the non-charge time T1 measured until the detection is less than the predetermined time T1th, the full-charge voltage value Vm becomes the second full-charge voltage value. Set to Vm2.

Even in this way, when the non-charging time T1 is relatively short as described above, the second full-charging voltage Vm is smaller than the case where the non-charging time T1 is relatively long. By setting the voltage value Vm2, deterioration in the performance of the battery 31 can be suppressed.

Further, as a second modification of the present embodiment, in the full charge voltage setting process, the determination process in step S107 may be eliminated, and the full charge voltage value Vm may be set according to the battery voltage Vb. That is, if the battery voltage Vb detected by the battery voltage detection unit 33 is less than the minimum operating voltage value Vo when the power supply state detection unit 34 detects that the power can be supplied, the full charge voltage value Vm When the battery voltage Vb detected by the battery voltage detection unit 33 is set to the first full charge voltage value Vm1 and is equal to or higher than the minimum operating voltage value Vo, the full charge voltage value Vm is set to the second full charge voltage value Vm2. be.

Even in this way, when the battery voltage Vb is relatively high when charging is resumed as described above, the full charge voltage value Vm is a small voltage value compared to when the battery voltage Vb is relatively low. It is set to a certain second full charge voltage value Vm2, and deterioration of the performance of the battery 31 can be suppressed.

Further, as a third modified example of the present embodiment, as shown in FIG. 5, a temperature measurement unit 35 for measuring the temperature of the battery 31 is provided, and the measurement result of the temperature measurement unit 35 is further considered in the full charge voltage setting process. Then, the full charge voltage value Vm may be set. That is, when the power supply state detection unit 34 detects that the power can be supplied after the non-charging time T1 starts to be measured, the non-charging time T1 measured until the detection is equal to or longer than the predetermined time T1th or the battery voltage Even if the battery voltage Vb detected by the detection unit 33 is less than the minimum operating voltage value Vo, the temperature of the battery 31 measured by the temperature measurement unit 35 is a predetermined temperature (for example, 0° C. to 40° C. If the compensation temperature is about 45° C.) or higher, the full charge voltage value Vm is set to the second full charge voltage value Vm2.

As a result, even when the non-charging time T1 is relatively long and the battery voltage Vb when charging is restarted is relatively low, if the temperature of the battery 31 is equal to or higher than the predetermined temperature, for example, in a high-temperature environment, In the case of performing high-load processing in a short period of time under a low temperature condition, the full-charge voltage value Vm is set to a second full-charge voltage value Vm2 that is smaller than the first full-charge voltage value Vm1. In this way, the full-charge voltage value Vm is set in consideration of the temperature of the battery 31 in addition to the non-charging time T1 and the battery voltage Vb, so that the full-charge voltage value Vm that is more suitable for the actual situation can be set. can.

[Second embodiment]
Next, a portable terminal according to a second embodiment of the invention will be described with reference to the drawings.
In the second embodiment, when the power supply capable state continues, the main point is that the full charge voltage value Vm is switched from the first full charge voltage value Vm1 to the second full charge voltage value Vm2 during the charging process. It differs from the first embodiment. For this reason, the same reference numerals are assigned to substantially the same components as in the first embodiment, and the description thereof is omitted.

If the battery voltage Vb is maintained at the first full-charge voltage value Vm1 set as the full-charge voltage value Vm for a long time and the power supply enabled state continues for a predetermined time, the performance of the battery 31 may deteriorate. have a nature.

Therefore, in the present embodiment, in the charging process performed by the control unit 21 to charge the battery 31, if the power supply capable state continues for a predetermined time, the performance of the battery 31 is suppressed. The voltage value Vm is set to a second full charge voltage value Vm2 smaller than the first full charge voltage value Vm1.

In particular, in this embodiment, a discharge circuit 36 capable of discharging the battery 31 is newly provided as shown in FIG. 6 in order to lower the battery voltage Vb to the second full charge voltage value Vm2 more quickly. By using the discharge circuit 36, after the full charge voltage value Vm is set to the second full charge voltage value Vm2, the battery 31 is discharged until the battery voltage Vb reaches the second full charge voltage value Vm2. be done.

Furthermore, after the full-charge voltage value Vm is set to the second full-charge voltage value Vm2, until the battery voltage Vb reaches the second full-charge voltage value Vm2, the predetermined processing performed by the control unit 21, etc. A battery drive state is entered in which power is switched from the cradle 1 to the battery 31 . Normally, when carrying out a predetermined process such as a reading process for sequentially reading the information code C and the wireless tag T attached to the transported object while it is placed on the cradle 1, the power required for the operation is supplied not from the battery 31 but from the cradle 1. It will be in the external power drive state supplied from. In this embodiment, in order to more quickly lower the battery voltage Vb from the first full charge voltage value Vm1 to the second full charge voltage value Vm2, the electric power required for predetermined processing performed by the control unit 21 and the like is supplied to the cradle. 1 (external power drive state) to the supply from the battery 31 (battery drive state). Note that the predetermined processing that requires power may be, for example, imaging processing of a transported object or the like using the light receiving sensor 53, and the control unit 21 or the like that performs such predetermined processing may It can correspond to an example of "part".

Hereinafter, the charging process performed by the control unit 21 in this embodiment will be specifically described in detail with reference to the flowchart of FIG. 7 and the like.
The charging process in the present embodiment is started when the power supply state detection unit 34 detects a change from the power supply stop state to the power supply available state. That is, when the portable terminal 10, which has been in the power supply stop state by being removed from the cradle 1, is placed in the cradle 1 and is in the power supply enabled state, the control unit 21 starts the charging process.

First, when the full charge voltage value Vm is set to the first full charge voltage value Vm1 (S201 in FIG. 7), the battery voltage Vb of the battery 31 is set to the full charge voltage value Vm (first full charge voltage value Vm) set as described above. Charging of the battery 31 by the charging circuit 32 is started so as to reach the charging voltage value Vm1) (S203).

Subsequently, connection time counting processing shown in step S205 is performed. In this process, the timer 26 starts a process for measuring the elapsed time from when the power supply state detection unit 34 detects a change from the power supply stop state to the power supply available state as the connection time T2. be. That is, as can be seen from time tb1 in FIG. 8, the elapsed time from when the power supply becomes possible and the battery voltage Vb starts to rise is counted as the connection time T2. Note that the timer 26 may correspond to an example of a "connection time timer".

Subsequently, in the determination process of step S207, it is determined whether or not the connection time T2 is equal to or longer than a preset predetermined time T2th. In this embodiment, the predetermined time T2th is set to a time sufficiently longer than the time required to charge the battery voltage Vb to the first full charge voltage value Vm1 (see time tb2 in FIG. 8), for example, 24 hours. If the connection time T2 is less than the predetermined time T2th because it is immediately after the start of charging or the like, No is determined in step S207, and the processes from step S201 are repeated. It should be noted that during this repeated process, the power necessary for the operation of the portable terminal 10 is in an external power driven state in which the power is supplied from the cradle 1 instead of from the battery 31 . Further, the predetermined time T2th corresponds to an example of a "predetermined time" or a "second predetermined time", and the control unit 21 that performs the determination process in step S207 can correspond to an example of a "determination unit".

Since the charged state is maintained until the battery voltage Vb reaches the first full charge voltage value Vm1, when the connection time T2 becomes equal to or longer than the predetermined time T2th (see time tb3 in FIG. 8), the process proceeds to step S207. is determined as Yes, the full charge voltage value Vm is set to the second full charge voltage value Vm2 (S209), and the timing of the connection time T2 ends (S211).

When the full-charge voltage value Vm is set to the second full-charge voltage value Vm2 in this manner, the battery voltage Vb is lowered from the first full-charge voltage value Vm1 to the second full-charge voltage value Vm2 more quickly. The state is switched to the driving state (S213). Further, charging of the battery 31 by the charging circuit 32 is stopped (S215), and discharging of the battery 31 by the discharging circuit 36 is started (S217).

Subsequently, in the determination process of step S219, it is determined whether or not the battery voltage Vb is equal to or higher than the second full charge voltage value Vm2. Here, if the battery voltage Vb has not decreased to the second full charge voltage value Vm2, a determination of Yes is made in step S219, and the processing from step S213 is performed. That is, the battery driving state and the discharging state of the battery 31 by the discharging circuit 36 are maintained until the battery voltage Vb drops to the second full charge voltage value Vm2.

After that, when the battery voltage Vb, which has decreased due to the battery driving state and the discharging state of the battery 31 by the discharging circuit 36, becomes less than the second full-charge voltage value Vm2 (see time tb4 in FIG. 8), it is determined No in step S219. be. In this case, the state is switched to the external power drive state (S221), the discharge of the battery 31 by the discharge circuit 36 is stopped (S223), and the process for maintaining the battery voltage Vb at the second full charge voltage value Vm2 is performed. is done.

As described above, in the mobile terminal 10 according to the present embodiment, in the charging process performed by the control unit 21, when the connection time T2 is determined to be less than the predetermined time T2th, the full charge voltage value Vm is When the first full charge voltage value Vm1 is set and the connection time T2 is determined to be equal to or longer than the predetermined time T2th, the full charge voltage value Vm is set to the second full charge voltage value Vm2. Further, when the full charge voltage value Vm is set to the second full charge voltage value Vm2, when the battery voltage Vb detected by the battery voltage detection unit 33 is equal to or higher than the second full charge voltage value Vm2, the charging circuit 32 charges the battery 31 charging is stopped. Then, the controller 21 or the like sets the full charge voltage value Vm to the first full charge voltage value Vm1 or determines that the battery voltage Vb detected by the battery voltage detection unit 33 is less than the second full charge voltage value Vm2. , power is supplied from the cradle 1 and the predetermined processing is performed, the full charge voltage value Vm is set to the second full charge voltage value Vm2, and the battery voltage Vb detected by the battery voltage detection unit 33 is set to the second full charge voltage value Vm2. If it is equal to or higher than the 2 full-charge voltage value Vm2, power is supplied from the battery 31 and the predetermined processing is performed.

As a result, when the connection time T2 is equal to or longer than the predetermined time T2th, for example, when the state where the portable terminal 10 is placed on the cradle 1 in a chargeable state continues for a long time, the full charge voltage value Vm is a small voltage value. is set to the second full charge voltage value Vm2. At this time, not only is the charging of the battery 31 by the charging circuit 32 stopped, but also until the battery voltage Vb becomes less than the second full-charge voltage value Vm2, power is supplied from the battery 31, and the control unit 21 and the like control the above-mentioned predetermined voltage. is processed. Therefore, since the battery voltage Vb quickly drops to the second full charge voltage value Vm2, the time during which the full charge voltage value Vm becomes unnecessarily high can be shortened, and deterioration in the performance of the battery 31 can be suppressed.

In particular, when the full charge voltage value Vm is set to the second full charge voltage value Vm2 and the battery voltage Vb detected by the battery voltage detection unit 33 is equal to or higher than the second full charge voltage value Vm2, the discharge circuit 36 Battery 31 is discharged. As a result, the battery voltage Vb drops to the second full-charge voltage value Vm2 more quickly, so that the time during which the full-charge voltage value Vm becomes unnecessarily high can be further shortened, and the deterioration of the performance of the battery 31 can be further suppressed. can. It should be noted that in the case where the battery voltage Vb can be quickly lowered in the battery-operated state because of the high-load processing, the steps S217 and S223 do not have to be performed without using the discharge circuit 36. .

The present invention is not limited to the above-described embodiments and the like, and may be embodied as follows, for example.
(1) After performing the charging process described in the second embodiment, when the power supply state detector 34 detects that the power supply is stopped, the full charge voltage setting process described in the first embodiment is performed. may be performed. Further, by starting charging after the full charge voltage value Vm is set to the first full charge voltage value Vm1 in the full charge voltage setting process described in the first embodiment, The charging process described above may be performed.

(2) External power supply to the mobile terminal 10 is not limited to being performed via a charging stand such as the cradle 1 placed thereon, but is performed via an electrically connected AC adapter, for example. good too. Even with such a configuration in which electric power is supplied from the outside, deterioration in the performance of the battery 31 can be suppressed according to the setting of the full charge voltage value Vm as described above.

(3) The present invention is not limited to being applied to a portable terminal having a function of optically reading an information code and a function of reading and writing information stored in a wireless tag. It may be applied to a mobile terminal dedicated to a terminal or a wireless tag, or may be applied to a mobile terminal having other functions. Also, the present invention may be applied to a smart phone, a tablet terminal, or the like having a touch panel.

DESCRIPTION OF SYMBOLS 1... Cradle 10... Portable terminal 21... Control part (setting part, determination part, processing part)
26 timer (non-charging time measuring unit, connection time measuring unit)
31 Battery 32 Charging circuit 33 Battery voltage detection unit 34 Power supply state detection unit 35 Temperature measurement unit 36 Discharge circuit T1 Non-charging time T2 Connection time Vb Battery voltage Vm Full charge voltage value Vo Minimum operating voltage value (predetermined voltage value)
Vm1: first full charge voltage value (first voltage value)
Vm2: second full charge voltage value (second voltage value)

Claims (4)

A mobile terminal having a battery as a power supply source,
a charging circuit that charges the battery so that the battery voltage of the battery reaches a fully charged voltage value according to power supply from the outside;
a battery voltage detection unit that detects the battery voltage;
a power supply state detection unit capable of detecting a power supply possible state electrically connected to the outside so that power can be supplied from the outside and a power supply stopped state in which the power supply from the outside is stopped;
a non-charging time measuring unit that counts the elapsed time as a non-charging time after the change from the power supply possible state to the power supply stopped state is detected by the power supply state detection unit;
a setting unit capable of setting the full-charge voltage value to either a first voltage value or a second voltage value smaller than the first voltage value;
with
When the power supply state detection unit detects the power supply possible state after the non-charge time measurement unit starts measuring the non-charge time, the setting unit measures the non-charge time until the detection. When the non-charging time measured by the non-charging time measuring unit is equal to or longer than a predetermined time, the full-charge voltage value is set to the first voltage value, and the non-charging time measured by the non-charging time measuring unit until the detection is detected. The mobile terminal, wherein the full charge voltage value is set to the second voltage value when the time is less than the predetermined time. A mobile terminal having a battery as a power supply source,
a charging circuit that charges the battery so that the battery voltage of the battery reaches a fully charged voltage value according to power supply from the outside;
a battery voltage detection unit that detects the battery voltage;
a power supply state detection unit capable of detecting a power supply possible state electrically connected to the outside so that power can be supplied from the outside and a power supply stopped state in which the power supply from the outside is stopped;
a non-charging time measuring unit that counts the elapsed time as a non-charging time after the change from the power supply possible state to the power supply stopped state is detected by the power supply state detection unit;
a setting unit capable of setting the full-charge voltage value to either a first voltage value or a second voltage value smaller than the first voltage value;
with
When the power supply state detection unit detects the power supply possible state after the non-charge time measurement unit starts measuring the non-charge time, the setting unit measures the non-charge time until the detection. When the non-charging time measured by the unit is equal to or longer than a predetermined time or the battery voltage detected by the battery voltage detecting unit is less than a predetermined voltage value, the full charge voltage value is set to the first voltage. is set to a value, and the non-charging time measured by the non-charging time measuring unit is less than the predetermined time and the battery voltage detected by the battery voltage detecting unit is equal to or higher than the predetermined voltage value. and setting the full charge voltage value to the second voltage value. A temperature measurement unit that measures the temperature of the battery,
When the power supply state detection unit detects the power supply possible state after the non-charge time measurement unit starts measuring the non-charge time, the setting unit measures the non-charge time until the detection. Even if the non-charging time measured by the unit is equal to or longer than the predetermined time or the battery voltage detected by the battery voltage detection unit is less than the predetermined voltage value, the temperature measurement unit measures the 3. The portable terminal according to claim 2, wherein the full charge voltage value is set to the second voltage value when the temperature of the battery reaches or exceeds a predetermined temperature. a processing unit that performs reading processing for reading wireless tags as predetermined processing;
a connection time measuring unit that measures, as a connection time, the elapsed time from when the power supply state detection unit detects a change from the power supply stop state to the power supply enabled state;
a determining unit that determines whether the connection time measured by the connection time measuring unit is equal to or greater than a second predetermined time;
with
The setting unit sets the full-charge voltage value to the first voltage value when the determination unit determines that the connection time is less than the second predetermined time, and the determination unit sets the connection time to the first voltage value. setting the full charge voltage value to the second voltage value in a state where it is determined that the time is equal to or longer than the second predetermined time;
When the full charge voltage value is set to the second voltage value by the setting unit, the charging circuit is configured to charge the battery when the battery voltage detected by the battery voltage detection unit is equal to or higher than the second voltage value. stop charging the
If the full charge voltage value is set to the first voltage value by the setting unit or the battery voltage detected by the battery voltage detection unit is less than the second voltage value, receiving electric power from the outside and performing a reading process of reading a wireless tag as the predetermined process; setting the full charge voltage value to the second voltage value by the setting unit; When the detected battery voltage is equal to or higher than the second voltage value, reading processing for reading a wireless tag is performed as the predetermined processing by receiving power supply from the battery. The mobile terminal according to any one of the items.

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