JP2007037361A - Charging system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To prevent current from flowing to a charging terminal of a portable electronic apparatus at time except for charging, and to prevent corrosion due to leakage current. <P>SOLUTION: A reed switch 24 of a normally open contact point is formed between the charging terminal 23 and a charging circuit 22 of a battery charger pack 20. A charger 30 charging the battery charger pack 20 is provided with a magnet 33. When the battery charger pack 20 is inserted into the opening 31 of the charger 30 by the magnet 33, the contact point of the reed switch 24 is closed so as to perform charging. When the pack is not charged, the circuit is interrupted and current is prevented from flowing to the charging terminal 23 so as to prevent corrosion. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a charging system that enables prevention of deterioration of a charging terminal.

  In portable electronic devices (for example, portable wireless devices) that are assumed to be exposed to rainwater, seawater, etc., the case of both the wireless device main body and the rechargeable battery pack attached to the wireless device main body has a waterproof structure.

  By the way, in a charging system using a rechargeable battery pack in recent years, the rechargeable battery pack is placed on a charger (for example, credor), and the contact of the charging terminal of the rechargeable battery pack and the contact of the charging terminal of the charger are connected. Since the contact method is adopted, the charging terminals (charging positive / negative electrodes and voltage detecting terminals) of the rechargeable battery pack are inevitably exposed from the case.

  For this reason, even when such a rechargeable battery pack is attached to the wireless device main body, the charging terminal is exposed to the outside, so that it is exposed to rainwater, seawater, and the like during use. At this time, if the rechargeable battery pack is left exposed, a minute current flows between the charging terminals due to the exposed rainwater or seawater salt, causing electric corrosion. Fatigue will occur.

  For this reason, when charging is performed with this oxide film or metal fatigue placed on the charger, the contact of the charging terminal of the rechargeable battery pack and the contact of the charging terminal of the charger become poorly connected and normal. There is a problem that charging cannot be performed.

  As one method for solving such a problem, for example, Patent Document 1 discloses a portable electronic device used in an atmosphere in which an electrically conductive fluid such as a disinfectant as shown in FIG. Hereinafter, what prevents electrical corrosion between the charging terminal 3 of the handpiece 1 and the charging terminal 6 of the charger 2 is described.

  That is, as shown in FIG. 7, a backflow prevention diode 4 is provided between the charging battery of the handpiece 1 and the charging terminal 3, and the charging current flows from the charging terminal 3 to the charging battery by the diode 4. Permit and prohibit leakage current from charging battery to charging terminal 3. By doing so, the voltage of the rechargeable battery is applied between the charging terminals 3 when the diode 4 is not present, and the handpiece 1 is being used in an atmosphere where an electrically conductive fluid exists (remove from the charger 2). If a fluid film is generated between the charging terminals 3, a current flows through the fluid film, and the metal surface of the contact of the charging terminal 3 is corroded. On the other hand, when the backflow prevention diode 4 is provided between the charging battery and the charging terminal 3, the diode 4 does not flow current from the charging battery to the charging terminal 3, so that corrosion does not occur.

  Further, as shown in FIG. 7, a reed switch 7 having a normally open contact is provided between the charging circuit 9 and the charging terminal 6 of the charger 2, and the magnet 5 is provided in the other handpiece 1, and the magnet 5 is connected to the handpiece 1. Of the charging terminal 6 of the charger 2 used in an atmosphere in which an electrically conductive fluid is present so that the current flows by closing the contact of the reed switch 7 of the charger 2. It also prevents corrosion.

In FIG. 7, reference numeral 8 denotes an electronic switch, reference numeral 10 denotes a resistor, and reference numeral 11 denotes a control circuit. The control circuit 11 is connected to a central sensing pin sandwiched between the charging terminals 6. By doing so, the control circuit 11 applies a sensing voltage to the sensing pin before applying the charging voltage, detects whether or not an electrolytic current flows between the charging terminals 6, and if the electrolytic current flows, the electronic switch 8 is in an open state and current is prevented from flowing through the charging terminal 6.
JP 2004-342611 A

  However, in the above, a backflow prevention circuit using a diode is employed to prevent corrosion of the charging terminal of the handpiece. However, a leakage current flows slightly when a reverse voltage is applied to the diode. There is a problem that corrosion will occur.

  Accordingly, an object of the present invention is to prevent a current (even a minute current such as a leakage current) from flowing through a charging terminal of a portable electronic device other than charging.

  In order to solve the above-described problems, in the present invention, a reed switch having a normally open contact is provided between circuits for supplying a charging current from a charging terminal of a rechargeable battery pack to a rechargeable battery cell, while a magnet is provided in the charger. The configuration is such that when the rechargeable battery pack is inserted into the opening of the charger by the magnet, the contact of the reed switch is closed.

  By adopting such a configuration, when the battery is not charged, the circuit is cut off so that no current flows through the charging terminal. Here, it is conceivable to use a semiconductor for the open / close element that interrupts the circuit. However, since the semiconductor has an ON resistance (about 100 mΩ), an accurate voltage cannot be detected during charging, and an error occurs, causing a problem such as not being fully charged. At this time, by using a reed switch and a magnet, the circuit can be opened and closed without the need for a power source, and the circuit can be completely shut down when not charged. In addition, since the ON resistance value during charging can be lowered to 40 mΩ to 60 mΩ, an error in voltage detection during charging can be allowed.

  At this time, the reed switch is turned on before the charging terminal of the rechargeable battery pack comes into contact with the charging terminal of the charger, and the reed switch is turned off after separating the contacting charging terminal and the charging terminal. This prevents inrush current from flowing through the contact of the reed switch.

  Such a configuration can be applied to a portable electronic device in which a charging terminal connected to a rechargeable battery cell is exposed at one end of a case that houses the rechargeable battery cell.

  Since the present invention is configured as described above, for example, even when used in a place where rainwater or seawater is frequently applied, the charging terminal does not deteriorate. Therefore, repeated drying is possible if it is dried.

  Further, at that time, the reed switch employed for opening and closing the circuit does not require a power source, and the contact can be opened and closed without contact, so that no leakage current is generated.

  The best mode for carrying out the present invention will be described below with reference to the drawings.

  As shown in FIG. 1, the charging system of this embodiment includes a rechargeable battery pack 20 and a charger 30.

  The rechargeable battery pack 20 is for a portable wireless device. As shown in FIG. 1, the rechargeable battery pack 20 is provided at one end of a case containing a rechargeable battery cell 21, a charge / discharge protection circuit (hereinafter referred to as a charge circuit) 22, and a reed switch 24. The charging terminal 23 is exposed.

  Further, the rechargeable battery pack 20 employs a waterproof structure so that water does not enter the rechargeable battery pack 20 even if the rechargeable battery pack 20 may be splashed with water.

  At this time, rusting can be effectively prevented by using pure nickel material or gold-plated metal material for the charging terminal 23 of the exposed rechargeable battery pack 20 in order to prevent corrosion other than electrolytic corrosion. .

  As shown in the circuit block diagram of FIG. 2, the rechargeable battery pack 20 is configured such that the positive terminal and the negative terminal of the charging terminal 23 are connected to the rechargeable battery cell 21 via the charging circuit 22. In this embodiment, a circuit in which a charging current flows from the charging terminal 23 to the rechargeable battery cell 21, that is, a reed switch 24 is arranged between the plus terminal of the charging terminal 23 and the charging circuit 22.

  The reed switch 24 is a normally open (make) contact, and is provided above the charging terminal 23 as shown in FIG.

  In this embodiment, the rechargeable battery cell 21 is formed by connecting 2 pcs Li-ion cells in series.

  The charging circuit 22 is a protection circuit that manages charging / discharging for monitoring the voltage of the rechargeable battery cell 21 to prevent overcharging and overdischarging.

  Further, the rechargeable battery pack 20 is provided with a positive discharge terminal 25 and a negative discharge terminal 25, and the positive discharge terminal 25 is connected between the reed switch 24 and the charging circuit 22 as shown in FIG. 2. The negative discharging terminal 25 is connected to the charging circuit 22.

  On the other hand, as shown in FIG. 1, the charger 30 has a configuration in which an opening 31 is formed upward and a charging terminal 32 is provided in the opening 31 formed upward.

  The opening 31 is formed in a shape that fits with the rechargeable battery pack 20. When the exposed end of the charging terminal 23 of the rechargeable battery pack 20 is inserted downward, the opening 31 is for charging the exposed rechargeable battery pack 20. The terminal 23 and the charging terminal 32 provided in the opening 31 are in contact with each other.

  A magnet 33 is provided in the opening 31 above the charging terminal 32. The magnet 33 is for turning on the contact of the reed switch 24 of the rechargeable battery pack 20, and the magnet 33 may be embedded in the side wall of the opening 31 so as not to be visible or exposed. . Further, when the rechargeable battery pack 20 is inserted into the opening 31, the magnet 33 leads the lead of the rechargeable battery pack 20 before the charging terminal 23 of the rechargeable battery pack 20 contacts the charging terminal 32 in the opening 31. When the switch 24 is closed and the rechargeable battery pack 20 is taken out from the charger 30, the lead terminal 23 of the rechargeable battery pack 20 is separated after the charging terminal 23 and the charging terminal 32 that are in contact with each other are separated. It arrange | positions in the position which the switch 24 opens.

  Although not shown in the figure, the charger 30 is naturally provided with a charging power source and a charging control circuit.

  This embodiment is configured as described above, and when the rechargeable battery pack 20 is separated from the charger 30 (even when attached to a portable electronic device), as shown in FIG. Since the contact is open, no current flows through the charging terminal 23 and no corrosion occurs.

  Next, in order to perform charging, when the exposed one end of the charging terminal 23 of the rechargeable battery pack 20 is placed downward and fitted into the opening 31 of the charger 30, the magnet 33 provided in the opening 31 of the charger 30. First, as shown in FIG. 3, the contact of the reed switch 24 of the rechargeable battery pack 20 is closed. At this time, since the charging terminal 23 of the rechargeable battery pack 20 is not yet in contact with the charging terminal 32 of the charger 30, no inrush current flows through the contact of the reed switch 24 and the contact is not damaged. Furthermore, when the rechargeable battery pack 20 is inserted, the charging terminal 23 of the rechargeable battery pack 20 and the charging terminal 32 in the opening 31 come into contact with each other as shown in FIG.

  And when charging is completed and the rechargeable battery pack 20 is removed from the charger 30, immediately after the charging terminal 23 of the rechargeable battery pack 20 and the charging terminal 32 of the charger 30 are separated as shown in FIG. The contact of the reed switch 24 is kept closed by the magnet 33.

  After that, as shown in FIG. 6, when the rechargeable battery pack 20 is separated, the magnetic field of the magnet 33 does not act, and the contact of the reed switch 24 of the rechargeable battery pack 20 is opened. At this time, even if the reed switch 24 is opened, the charging terminal 23 of the rechargeable battery pack 20 and the charging terminal 32 of the charger 30 are separated from each other, so that no inrush current flows through the reed switch 24 and the contact is damaged. There is nothing.

  Thus, when the rechargeable battery pack 20 is removed from the charger 30, the contact of the reed switch 24 is open as shown in FIG. 1, so that no current flows through the charging terminal 23 and no corrosion occurs.

  Thus, the reed switch 24 can open and close the circuit without requiring a power source. Also, when not charging, the circuit can be completely shut off. At that time, since the ON resistance value during charging can be lowered to 40 mΩ to 60 mΩ, an error in voltage detection during charging can be allowed.

  In the embodiment, the reed switch 24 is provided only on the positive charging terminal 23. However, the present invention is not limited to this and may be provided on both sides of the positive terminal and the negative terminal.

  In the embodiment, the reed switch 24 is provided between the charging terminal 23 and the charging circuit 22, but the present invention is not limited to this. For example, in a rechargeable battery pack of a type in which the charging current from the charging terminal 23 flows directly to the rechargeable battery cell 21 (without passing through the charging circuit 22), a circuit that flows the charging current from the charging terminal 23 to the rechargeable battery cell 21; That is, the reed switch 24 is disposed between the charging terminal 23 and the rechargeable battery cell 21.

  In the embodiment, the voltage detection terminal that informs the charger 30 of the charging voltage of the rechargeable battery pack 20 is not described. However, when such a terminal is provided, the ON resistance of the reed switch 24 is low. The charging terminal 23 can also be used as a voltage detection terminal.

  By the way, a portable electronic device having the same configuration as the rechargeable battery pack 20 of this embodiment, that is, a charging terminal 23 connected to the rechargeable battery cell 21 via the charging circuit 22 is charged with the rechargeable battery cell 21. If it is the electronic device exposed to one end part of the case which accommodates the circuit 22, the charging system of this application can be comprised.

  That is, if a reed switch is provided between the charging terminal and the charging circuit and a magnet is provided in the charger of the electronic device, the charging system of the present application can be easily configured.

Block diagram of the embodiment Circuit block diagram of the embodiment Action explanatory diagram of the embodiment Action explanatory diagram of the embodiment Action explanatory diagram of the embodiment Action explanatory diagram of the embodiment Block diagram of conventional example

Explanation of symbols

20 rechargeable battery pack 21 rechargeable battery cell 22 charging circuit 23 charging terminal 24 reed switch 30 charger 31 opening 32 charging terminal 33 magnet

Claims (3)

A rechargeable battery pack with a charging terminal exposed at one end of a case containing a rechargeable battery cell;
An opening for fitting the rechargeable battery pack is formed facing upward, a charging terminal is provided in the opening formed upward, and one end of the rechargeable battery pack is fitted into the opening. Then, it consists of a charger that makes the exposed charging terminal of the rechargeable battery pack contact the charging terminal in the opening,
The rechargeable battery pack includes a reed switch with a normally open contact between circuits for supplying a charging current from the charging terminal to the rechargeable battery cell, and on the other hand, the charger includes a magnet, and the magnet opens the charger opening. A charging system that closes the contacts of the reed switch when the battery pack is inserted.   The rechargeable battery pack reed switch is disposed above the charging terminal, while the charger magnet is disposed above the charging terminal, and the rechargeable battery pack is inserted into the charger opening when the rechargeable battery pack is inserted into the charger opening. When the rechargeable battery pack reed switch is closed by the magnet before the charging terminal of the battery pack contacts the charging terminal in the opening of the charger, and when the rechargeable battery pack is removed from the charger The charging system according to claim 1, wherein after the charging terminal and the charging terminal that come into contact with each other are separated, the reed switch of the rechargeable battery pack is opened.   2. A portable electronic device in which a charging terminal connected to a rechargeable battery cell is exposed at one end of a case housing the rechargeable battery cell instead of the rechargeable battery pack. Or the charge system of 2.

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