JP2001333539A - Battery charger - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a charger that efficiently charges a plurality of batteries, whose residual capacities are different. SOLUTION: This charger, which charges a plurality of batteries one after the other, is provided with a plurality of charging ports, each having a charging terminal to which a battery is connected, a voltage detecting part that detects the voltage of the connected battery, a charging part that charges the connected battery, and a display part that detects the state of the charging part and displays the charged condition of the battery. The charger is also provided with a CPU and a memory, that control the operations of the charging ports. Charging is effected in order of the batteries-having larger voltage, by making the CPU control the operation of the charging part of each charging port, based on the voltage data detected by the voltage detecting part of each charging port.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

[0001] 1. Field of the Invention [0002] The present invention relates to a charger for sequentially charging a plurality of batteries efficiently.

[0002]

2. Description of the Related Art In a conventional charger, when a plurality of batteries having different remaining discharge capacities are sequentially charged, the charging order is arbitrary. That is, in a charger having a plurality of charging ports, when sequentially charging the batteries set in the charging ports, charging is performed in the order in which the batteries are set in the charging ports, or a charging switch is provided in each charging port to artificially charge the batteries. A switch is operated to perform charging, or a charging order is previously set in a charging port, and charging is performed according to the charging order. Further, in the battery charger according to the related art, by repeatedly charging the battery having the remaining discharge capacity, a memory effect occurs in the charged battery, and the amount of power that can be actually extracted from the battery in which the memory effect has occurred decreases. There was a problem.

[0003]

When a plurality of batteries having different remaining discharge capacities are sequentially charged, the time required to finish charging all the batteries does not depend on the charging order of the batteries. Because of the remaining discharge capacity of the battery, the charging time of the battery, which is charged first, depends on the charging sequence of the battery. For example, when the charge time of a battery with a large remaining discharge capacity is A and the charge time of a small battery is B in two batteries (A <B), the time until one of the batteries ends charging depends on the charging order. A difference of B-A occurs. Therefore, charging is not efficient because the charging order of the batteries is arbitrary, such as when the user wants to use the charged battery immediately.

Further, as a charger for preventing the occurrence of a memory effect caused by repetitive charging of a battery having a remaining discharge capacity, a charge with a discharge function for charging after completely discharging the remaining discharge capacity of the battery. Although a memory effect can be prevented by this, a battery having a large remaining discharge capacity is charged after discharging, for example, so that the charging time becomes long, and unnecessary (large-capacity) discharging is repeated. Battery life was shortened.

[0005]

SUMMARY OF THE INVENTION The present invention has been made to make up for the drawbacks of the prior art and to efficiently charge a plurality of batteries having different remaining discharge capacities.
Is a charger for sequentially charging a plurality of batteries, a charging terminal for connecting the batteries, a voltage detecting unit for detecting a voltage of the connected batteries, and a charging for charging the connected batteries. Unit, and a plurality of charging ports having a display unit that detects the state of the charging unit and displays the state of charge of the battery, and includes a CPU and a memory that controls the operation of the plurality of charging ports. The operation of the charging unit of each charging port is controlled based on the voltage data detected by the voltage detection unit of each charging port, and charging is performed sequentially from the battery with the highest battery voltage. According to a second aspect of the present invention, there is provided the charger according to the first aspect, wherein a discharging unit is provided at each charging port of the charger according to the first aspect. By controlling the operation of the charging unit of each charging port, charging is performed sequentially from the battery with the highest battery voltage, discharging the battery to be charged for a certain period of time to obtain discharge characteristic data, and determining the discharge characteristic of the battery. A battery having a small remaining discharge capacity is charged after discharging.

[0006]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The configuration of a charger according to a first embodiment of the present invention will be described with reference to the block diagram of FIG. A charger according to a first embodiment of the present invention includes a charging terminal for connecting a battery, a voltage detecting unit for detecting a voltage of the connected battery, a charging unit for charging the connected battery, and a state of the charging unit. And a plurality of (1 to n) charging ports each having an LED display unit for detecting the charging status of the battery and detecting the charging status of the battery.
To n) and a memory for controlling the operations. That is, a plurality of batteries (not shown) having different remaining discharge capacities are connected to the charging terminals (1 to n), respectively, and the voltages of the batteries are detected by the voltage detection units (1 to n). The CPU controls the operation of the charging units (1 to n) of each charging port based on the voltage data (1 to n) of each battery detected at each charging port (1 to n). Charge the battery sequentially.

Further, an LED display section (1) of each charging port
To n) are charging units (1 to n) controlled by the CPU.
And displays the charging status of the battery set in the charging port. For example, the LED of the charging port in which the charging unit is activated and the battery is in the charging state is turned on, and the LED of the charging port in which the charging of the battery is completed is performed.
The display part blinks, the charging part does not operate, the battery is in the standby state, and the LED display part of the charging port turns off. It can be displayed by a putter of a desired color. Note that a liquid crystal display or the like can be used as the display unit in addition to the LED display unit.

A charging method using a charger according to a first embodiment of the present invention will be described with reference to a flowchart of FIG. A plurality of batteries (1 to n) having different remaining discharge capacities are respectively connected to charging terminals (1 to n) of respective charging ports of the charger. That is, a battery is set in each charging port (1 to n) (step S1). At this time, the voltage of each battery is detected by the voltage detectors (1 to n) of each charging port, and the voltage data (1 to n) is transmitted to the CPU (step S2). Next, the CPU sets the battery (1) set in each of the charging ports (1 to n).
To n) are determined from the charging end recognition data stored in the memory as to whether or not the battery is already charged (step 3), and is obtained at the charging port determined to have the charged battery set. Excluded voltage data (step 4). The voltage data acquired at the charging port determined to have an uncharged battery set therein proceeds to the next step, where the voltage data is compared (step S5). By comparing the voltage data by the CPU (step S5), the battery (b) having the largest voltage data is obtained.
(i.e., the first charging port) is set (step S6), and under the control of the CPU, the charging section of the selected charging port is activated to charge the battery set in this charging port (step S9). ).
At this time, the charge display of the battery is displayed on the LED display section of the selected charging port (step S10). on the other hand,
By comparing the voltage data by the CPU (step S
5) The charging port (other) not selected is
The charging unit does not operate under the control of the CPU, and the battery set in the charging port enters a charging standby state (step S7). At this time, a charging standby display is displayed on the LED display unit of the charging port (step S8). The battery set in the selected charging port is charged until the voltage (V) of the battery reaches the set voltage (V _MAX ) (step S11), and when the charging is completed (step S12), the charging of the charging port is started. A charge completion display is displayed on the LED display unit (step S13). In addition, charge recognition data for recognizing that the charging of the battery connected to the charging port has been completed is stored in the memory, thereby preventing double charging of the charged battery. The charge completion recognition data is reset when the charged battery set in the charging port is removed from the charging terminal of the charging port.

When the charging of the batteries set in the selected charging port is completed, the voltage data of the battery set in each charging port is detected again, and the charging section of the charging port is controlled based on the voltage data. (Steps S2 to S14). By repeating this process, the batteries set in the charging port are sequentially charged in ascending order of the battery voltage.

Each time charging of a battery set in one charging port is completed, voltage data of the battery set in each charging port is detected again, and charging of each charging port is performed based on this voltage data. To control the operation of the unit, before all batteries have been charged,
Even if you replace the battery in the charging port where charging has been completed,
The CPU detects the replaced battery and charges the battery sequentially from the battery with the highest battery voltage, regardless of the timing of setting the battery.

Next, a charger according to a second embodiment of the present invention will be described. The configuration of the charger according to the second embodiment of the present invention will be described with reference to the block diagram of FIG. The charger according to the second embodiment of the present invention includes a charging terminal for connecting a battery, a voltage detecting unit for detecting a voltage of the connected battery, a discharging unit for discharging the connected battery, and a charging unit for charging. A plurality of (1 to n) charging ports each having a display unit for detecting the state of the charging unit and displaying the state of charge of the battery, and controlling the operation of the plurality of charging ports (1 to n) , Memory and clock. Similar to the charger according to the first embodiment, the battery charger according to the second embodiment sequentially starts with a battery having a larger battery voltage based on voltage data of a plurality of batteries (not shown) having different remaining discharge capacities. In addition to performing charging, each charging port is provided with a discharging unit, the battery to be charged is discharged for a certain period of time, and the remaining discharge capacity of the battery is confirmed by acquiring discharge characteristic data. By charging after fully discharging the capacity, the occurrence rate of the memory effect is reduced for multiple batteries that have been repeatedly charged, and the charging time is shortened by not discharging batteries with a large remaining discharge capacity. It is intended to prevent unnecessary discharge of the battery.

FIG. 4 is a graph showing the discharge characteristic data of the battery. As shown in the graph of FIG. 4, the discharge curve of the discharge characteristic data of the battery can be roughly classified into three patterns of an initial discharge, a middle discharge, and a late discharge. That is, the battery is kept for a certain time (T time)
Discharged, when the discharge data obtained, corresponding to the remaining discharge capacity of the battery (residual power state), as shown in the discharge data in the figure T ₁ times (initial discharge), decrease the reduction rate of the battery voltage and when going to (discharge curve becomes gradually gentle), as shown in the discharge data in the figure T ₂ hours (discharge metaphase), there is little change in the reduction rate of the battery voltage (discharge curve is gentle ) in the case, as shown in the discharge data in the figure T ₃ hours (discharge late), the reduction rate is gradually increased (battery voltage of the battery voltage suddenly drops) there are three patterns of cases. That is, the discharge data of the battery having a small remaining discharge capacity is T _{3 in} the figure in the latter half of the discharge.
As shown by the time discharge data, the battery voltage decreases at an increasing rate, and the battery voltage decreases at an increasing rate (battery voltage sharply decreases).

Therefore, in the charger according to the second embodiment, the battery is charged sequentially from a battery having a large battery voltage, and
When charging each battery, the discharge characteristics of the battery to be charged are individually determined, and only the battery (discharge data) having a small remaining discharge capacity is discharged and then charged, so that a memory effect is generated for a plurality of repeatedly charged batteries. By reducing the rate and not discharging the battery having a large remaining discharge capacity, the charging time is shortened and the battery is prevented from being discharged wastefully. The display unit of each battery may be formed of a liquid crystal display, and the remaining discharge capacity may be displayed, or the required charging time calculated based on the remaining discharge capacity may be displayed.

The discharge method based on the determination of the discharge characteristics according to the second embodiment will be described with reference to the flowchart of FIG. In the second embodiment according to the present invention, similarly to the charging method according to the above-described first embodiment, the voltage data of a plurality of batteries is detected, and the batteries are sequentially charged in descending order of the battery voltage. When charging the battery at the charging port (steps S1 to S6) selected by the comparison, the battery set in the selected port is discharged for a certain period of time (step S21), and the discharge characteristics are determined (step S22). ). This determination (step S2
When it is determined by 2) that the battery has a small remaining discharge capacity (discharge data), the remaining discharge capacity of the battery is completely discharged (steps S23 to S2).
7) After that, charging is performed (steps S9 to S14).
As a result of the determination (step S22), only the charging is performed on the battery determined to have a small remaining discharge capacity (discharge data) (steps S9 to S14) to prevent useless discharge.

[0015]

As described above, in the battery charger for sequentially charging a plurality of batteries according to the present invention, the batteries are sequentially charged in descending order of battery voltage based on the voltage data of each battery. In response to the need to use a battery, a plurality of batteries having different remaining discharge capacities can be charged efficiently. Therefore, the present invention is effective in efficiently charging a plurality of batteries in a charger having a low charging capability (a large amount of power cannot be used) and incapable of charging a plurality of batteries at once. Further, in a charger provided with a discharging portion at each charging port of the charger, a battery having a small remaining discharge capacity is charged by completely discharging the remaining discharge capacity and then charging the battery based on the discharge characteristic data of the battery. By reducing the rate of occurrence of the memory effect for multiple batteries and not discharging batteries with a large remaining discharge capacity, the charging time is shortened, the battery is discharged unnecessarily, and the battery is discharged. Prevents shortening of service life.

[Brief description of the drawings]

FIG. 1 is a block diagram showing a configuration of a charger according to a first embodiment of the present invention.

FIG. 2 is a flowchart illustrating a method of charging a battery of a charger according to a first embodiment of the present invention.

FIG. 3 is a block diagram showing a configuration of a charger according to a second embodiment of the present invention.

FIG. 4 is a diagram showing discharge characteristic data of a battery.

FIG. 5 is a flowchart showing a discharge method based on a determination of a discharge characteristic.

 ──────────────────────────────────────────────────続 き Continuing on the front page (72) Inventor Yasunori Eda 1-111-15 Higashi-Gotanda, Shinagawa-ku, Tokyo Inside Densei Lambda Co., Ltd. (72) Inventor Shigehisa Kikuchi 1-1-11 Higashi-Gotanda, Shinagawa-ku, Tokyo No. 15 Inside Densei Lambda Co., Ltd. (72) Inventor Shinji Taguchi 1-111 Higashi Gotanda, Shinagawa-ku, Tokyo 11-15 Inside Densen Lambda Co., Ltd. (72) Toshiyuki Nagase 1-chome, Higashi Gotanda, Shinagawa-ku, Tokyo No. 11-15 F-term in Densei-Lambda Corporation (reference) 5G003 AA01 BA02 CA14 CB08 EA05 GC05 5H030 AA01 AS20 BB01 DD06 FF41 FF66

Claims (4)

[Claims] 1. A charger for sequentially charging a plurality of batteries, a charging terminal for connecting the batteries, a voltage detecting unit for detecting a voltage of the connected batteries, and a charging unit for charging the connected batteries. A plurality of charging ports having a display unit for detecting the state of the charging unit and displaying the state of charge of the battery; and a CPU and a memory for controlling the operation of the plurality of charging ports. A charger for controlling operation of a charging unit of each charging port based on voltage data detected by a voltage detection unit of a port, and performing charging sequentially from a battery having a large battery voltage. 2. A charger having a discharging unit at each charging port of the charger, wherein the CPU operates the charging unit of each charging port based on voltage data detected by a voltage detecting unit of each charging port. Control, charging is performed sequentially from the battery with the highest battery voltage, and the battery to be charged is discharged for a certain period of time to acquire discharge characteristic data, and the discharge characteristic of the battery is determined. The battery charger according to claim 1, wherein charging is performed later. 3. Whenever charging of a battery set in one charging port is completed, voltage data of the battery set in each charging port is detected, and a charging unit of each charging port is detected based on the voltage data. The charger according to claim 1, wherein operation of the charger is controlled. 4. The battery charger according to claim 1, wherein a remaining discharge capacity of a battery connected to the charging port is displayed on a display section of each charging port.