JP2005348468A - Charger and charging set comprising it - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To save waiting power while making possible to detect connection of a battery pack when the temperature switch of a battery pack is turned on/off. <P>SOLUTION: Since a connection detecting terminal 12 is opened during waiting period where a battery pack 2 is not connected with a charger 3, a high level signal of an internal power supply voltage E1 is obtained as a connection detection signal S3. When the battery pack 2 is connected with the charger 3 and a temperature switch 71 is turned on, the terminal 12 is short-circuited to the ground potential and a low level signal is obtained as signal S3. Since DC voltage Vout is sufficiently high during waiting period, a transistor 38 is turned on when the battery pack 2 is connected with the charger 3 even if the temperature switch 71 is turned off, and a low level signal S3 is obtained. An output control circuit 50 controls a switching element 24 to generate a pulse of primary current Iin intermittently during the waiting period thus saving waiting power. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a charger for charging a battery by detachably connecting a battery pack containing a battery, and a charging device including the charger and the battery pack.

2. Description of the Related Art Conventionally, a charging device including a battery pack containing a battery (that is, a module incorporating a circuit associated with the battery) and a charger for charging the battery pack is widely known. Patent Document 1 listed below discloses a battery charger of this type configured to charge the battery pack using electromagnetic coupling while keeping the battery pack and the charger in a non-contact state. In addition, the charging device disclosed in Patent Document 1 is configured such that when the charging load is light, the switching power supply provided on the charger side automatically operates intermittently. The standby power is reduced.
JP 2000-166129 A

  However, in the non-contact type charging device, it is not easy for the charger to obtain information such as the voltage and temperature of the battery from the battery pack, and for this reason, it is easy to appropriately adjust the charging current according to the state of the battery. There was a problem that it was not. In contrast, in a contact-type charging device in which a battery pack and a charger are electrically connected through contact between terminals, the charger can easily detect the state of the battery through the terminals. There is an advantage that appropriate charging according to the state can be realized. For example, a battery having a large charge capacity, such as a battery used as a power source for an electric tool, is expensive and therefore needs to be appropriately charged so as to keep the battery life as long as possible. For this reason, a contact-type charging mode is particularly suitable for a battery pack for an electric tool.

  In the contact type charging device, the charger can detect whether or not the battery pack is connected through the potential of the terminal. However, as a safety measure to avoid charging the battery when the battery temperature is excessively high, such as immediately after the battery built in the battery pack is overworked, use a bimetal etc. for the battery charging path It is desirable to provide a temperature switch (a switch that turns off when the temperature rises above a certain limit and is also referred to as a thermoswitch or thermostat). Thereby, even if the battery pack is connected to the charger in a state where the temperature of the battery is abnormally rising, the temperature switch cuts off the charging path, so that charging of the battery can be avoided.

  On the other hand, if the charging path is interrupted by the operation of the temperature switch, the connection of the battery pack cannot be detected. Therefore, the battery pack is configured such that the charger always outputs a voltage at a predetermined height to the pair of charging terminals, and a predetermined potential is applied to another connection detection terminal when the battery pack is attached. Accordingly, it is possible to assume a charging device that detects whether or not the battery pack is connected through the potential of the connection detection terminal. In the charging device configured as described above, it is necessary to output a considerably high voltage to the charging terminal even during a standby period in which the battery pack is not connected, and a problem that standby power cannot be ignored is expected.

  The present invention has been made in view of the above problems, and can detect whether or not the battery pack is connected even when the temperature switch of the battery pack is operated, and can reduce standby power. It aims at providing the charging device which contains a charger and the said charger in a component.

  In order to solve the above problems and achieve the above object, a first aspect of the present invention is a charger for charging a battery by detachably connecting a battery pack containing the battery. In addition, first to third terminals for electrical connection to the battery pack, and a primary current of the transformer is generated in a pulse shape by the switching operation of the switching element, and the second current of the transformer induced by the primary current is generated. DC voltage is generated by rectifying the secondary current to supply the DC voltage to the first and second terminals, and detection that a voltage within a predetermined range is applied to the third terminal A connection detecting means for detecting that the battery pack is connected; and an output control means for controlling the switching element, wherein the output control means Standby control means including charge control means for controlling the switching element so as to repeatedly generate a pulse, and intermittent pulse generation means for controlling the switching element so as to intermittently generate the pulse of the primary current; In a period in which the connection detection unit does not detect connection of the battery pack, the standby control unit controls the switching element, and in a period after the connection detection unit detects connection of the battery pack, the charge control unit. And control switching means for controlling the switching element.

  The battery charger which concerns on the 1st aspect of this invention assumes what was comprised as follows as a battery pack which is charge object. That is, the battery pack includes fourth to sixth terminals for connecting to the first to third terminals, respectively, and a temperature switch that turns off when the temperature of the battery exceeds a predetermined temperature. And a temperature switch are connected to the fourth and fifth terminals. The sixth terminal is connected to the connecting portion between the temperature switch and the battery.

  Due to the function of the output control means, the DC voltage for charging is supplied to the first and second terminals even during a period when the connection detection means does not detect that the battery pack is connected to the charger, that is, during the standby period. The When the temperature switch does not operate, that is, when the temperature switch is not turned off, the potential of the third terminal matches the potential of the first or second terminal by connecting the battery pack to the charger. When the temperature switch is operating, that is, when the temperature switch is off, the potential of the third terminal is in a certain range determined by the potential of the first or second terminal and the voltage of the battery. The connection detection means detects that the battery pack is connected by detecting that the potential of the third terminal is at any one of these potentials. In this way, the charger can detect whether the battery pack is connected whether the temperature switch is operating or not.

  Further, by the operation of the control switching unit, the standby control unit controls the switching element of the DC power supply so as to intermittently generate the primary current pulse during the standby period. For this reason, power consumption in the standby period, that is, standby power is reduced. As described above, the charger according to the first aspect of the present invention can detect whether or not the battery pack is connected even when the temperature switch of the battery pack is activated while reducing standby power. To do.

  According to a second aspect of the present invention, there is provided the charger according to the first aspect, wherein the control switching unit is configured to operate for a predetermined period even after the connection detection unit detects the connection of the battery pack. Until the time elapses, the standby control means controls the switching element.

  Even after the connection detecting means once detects the connection of the battery pack, the detection signal may not be stable for a certain period due to a transient phenomenon. Similarly, the voltage between the first and second terminals may not be stable for a certain period. On the other hand, according to the charger according to the second aspect of the present invention, the standby control means controls the switching element until a predetermined period has elapsed even after the connection detecting means detects the connection of the battery pack. Therefore, after the connection of the battery pack is sufficiently confirmed, or after the voltage between the first and second terminals is stabilized, the charging control can be performed. Thereby, appropriate charge control can be performed.

  According to a third aspect of the present invention, there is provided the battery charger according to the first aspect, wherein the control switching unit is configured such that the connection detection unit detects the connection of the battery pack after the connection detection unit detects the connection of the battery pack. The standby control means controls the switching element until a determination result indicating that there is no abnormality is obtained.

  According to the charger according to the third aspect of the present invention, it is possible to avoid the inconvenience of starting charging while leaving the abnormal state. As an abnormality, an abnormal potential detected through the first to third terminals or a non-connected state of some terminals can be exemplified. Alternatively, when the charger has another terminal in addition to the first to third terminals and is configured to obtain the temperature information of the battery pack through the another terminal, An abnormal potential detected through a terminal, or a disconnected state of the other terminal can be exemplified as an abnormality.

  According to a fourth aspect of the present invention, there is provided the charger according to any one of the first to third aspects, wherein the DC power supply supplies the DC voltage to the first and second terminals. Output voltage detecting means for detecting the output voltage, and the standby control means further includes adjusting means for controlling the switching element so as to suppress fluctuations of the DC voltage detected by the output voltage detecting means from a predetermined voltage. It is a waste.

  According to the charger of the fourth aspect of the present invention, since the switching element is controlled by the adjusting means so as to suppress the fluctuation of the DC voltage from the predetermined voltage, the charger is turned on or the temperature of the charger is changed. Even if there is a DC voltage variation factor, a stable DC voltage that is close to or converges to a predetermined voltage set in advance can be obtained.

  According to a fifth aspect of the present invention, there is provided a charger according to any one of the first to fourth aspects, wherein the output control means further includes a human sensor for detecting the approach of a human body, The control switching means pauses the generation of the primary current pulse when the connection detecting means is in a period when the connection of the battery pack is not detected and the human sensor does not detect the approach of the human body. The standby control means is controlled.

  If the battery pack is not connected to the charger and there is no person in the vicinity of the charger, it can be said that there is a low possibility that the battery pack is connected to the charger thereafter. According to the charger according to the fifth aspect of the present invention, the generation of the primary current pulse is suspended in such a case, so that wasteful standby power can be more effectively reduced.

  According to a sixth aspect of the present invention, there is provided the charger according to any one of the first to fifth aspects, wherein the output control means further comprises time measuring means for measuring time, and the control The switching means refers to the time measured by the time measuring means, so that when the period during which the connection detecting means does not detect the connection of the battery pack has exceeded a predetermined standby time, the pulse of the primary current is The standby control means is controlled so as to pause the generation.

  When the state where the battery pack is not connected to the charger continues for a long time, it can be said that the possibility that the battery pack is connected to the charger is low. According to the charger according to the sixth aspect of the present invention, the generation of the primary current pulse is suspended in such a case, so that wasteful standby power can be more effectively reduced.

  According to a seventh aspect of the present invention, there is provided a charging device comprising the charger according to the present invention and a battery pack that includes a battery and is detachably connected to the charger, wherein the battery pack includes: 4th to 6th terminals for connecting to the 1st to 3rd terminals, respectively, and a temperature switch that is turned off when the temperature of the battery exceeds a predetermined temperature, and the battery and the temperature switch Is connected to the fourth and fifth terminals, and the sixth terminal is connected to the connection between the temperature switch and the battery.

  According to the charger of the seventh aspect of the present invention, since the charger according to the present invention and the battery pack assumed by the charger are provided, the operation of the temperature switch of the battery pack is performed while saving standby power. Even at times, it is possible to detect whether or not a battery pack is connected.

  As described above, according to the charger and the charging device of the present invention, it is possible to detect whether or not the battery pack is connected even when the temperature switch of the battery pack is operated, and this is necessary. Standby power can be saved.

(Appearance structure of the charging device)
FIG. 1 is a schematic diagram of an external appearance of a charger that constitutes a charging device 1 of the present embodiment, a battery pack suitable for the charger, and an appliance equipped with the battery pack. As shown in FIG. 1A, the battery pack 2 to be charged by the charger 3 is provided at the lower end of the holding portion 100a in the electric appliance main body 100 (an electric tool is illustrated in FIG. 1A). In addition to being used by being mounted, as shown in FIG. 1 (b), a configuration is adopted in which charging is possible by mounting the charger 3 as it is after detachment. In general, the battery pack to be charged by the charger according to the present invention is not limited to the one attached to the electric tool, but may be one attached to an electric appliance that can be driven by a battery such as a personal computer or a mobile phone. Including. The battery 70 (see FIG. 3) built in the battery pack 2 is, for example, a nickel cadmium battery or a nickel hydride battery. The battery voltage can vary, for example, 12V, 18V, 24V.

  The battery pack 2 illustrated in FIG. 1 includes a main body portion 4 that holds a battery 70 and a connector portion 5 for establishing electrical connection between the electric appliance main body 100 and the charger 3. The charger 3 is provided with a connector portion 6 having an opening. By attaching the connector portion 5 of the battery pack 2 to the connector portion 6 of the charger 3, the battery pack 2 and the charger 3 are connected to each other. An electrical connection is established.

  More specifically, the battery pack 2 and the charger 3 have an appearance as shown in FIG. In this example, as shown in FIG. 2A, the connector portion 5 of the battery pack 2 has a shape protruding from the main body portion 4 so that the terminals 7, 8, 9, and 10 are exposed on the side surfaces. It is arranged. As shown in FIG. 2B, the connector portion 6 of the charger 3 has a recess into which the connector portion 5 of the battery pack 2 can be inserted, and terminals 7 and 8 of the battery pack 2 are formed on the inner surface thereof. , 9, 10 are provided with terminals 11, 12, 13, 14 for electrical connection. For example, terminals 8 and 14 are positive charging terminals, terminals 7 and 11 are negative charging terminals, terminals 9 and 13 are terminals for transmitting control signals such as temperature detection signals, and terminals 10 and 12 are connected to battery pack 2. It is a terminal for detecting that it is attached to the charger 3.

  If the battery pack 2 is not attached to the charger 3, the charger 3 cannot be charged, and if it is attached, it can be charged. Of the terminal 7, the portion of the terminal 7a and the portion of the terminal 7b are connected to the terminal 11a and the terminal 11b, respectively. For example, if the battery pack 2 incorporates a battery 70 having a large capacity (the capacity of the battery is expressed in ampere / time, the larger the value, the larger the capacity), both the terminal 7a and the terminal 7b are provided. If a small capacity battery 70 is incorporated, only the terminal 7a is provided (including a form in which the terminal 7b is covered with an insulating member). The terminal 11b can detect whether or not the terminal 7b is provided, whereby the battery capacity of the battery pack 2 can be detected. For this reason, it is not necessary to provide a separate charger due to the difference in battery capacity of the battery pack 2, and the charger can be used for charging the battery pack 2 having different battery capacities.

  The battery pack 2 and the charger 3 are provided with, for example, slit-shaped air holes 15 and 16 at positions on the surfaces facing each other when they are combined. The charger 3 has a built-in cooling fan, and the air flow created by the cooling fan is also supplied to the battery 70 in the battery pack 2 being charged through the vent holes 15 and 16. In the charger 3, a charging status display unit 17 that displays the charging status of the battery pack 2 is provided on the side of the vent hole 16. The charging status display unit 17 includes a plurality of lamps made of LEDs, for example, arranged in a line, and a character “empty” indicating that the charging amount is substantially 0 is attached according to the charging amount of the battery pack 2. The lamps are lit in order from the lamps to the lamps marked with “full” indicating that the charge amount is approximately 100%.

  Returning to FIG. 1B, the charger 3 includes a plug 18 and a cable 19. When the plug 18 is connected to a commercial power source, the charger 3 is connected to the commercial power source via the plug 18 and the cable 19. Receive power supply. The supplied electric power is converted into electric power suitable for charging the battery 70 by a DC power supply 20 (see FIG. 3) included in the charger 3.

(Internal structure of the charging device)
FIG. 3 is a block diagram showing the configuration of the charging device 1. The charger 3 includes a DC power supply 20, a connection detection circuit 35, an output control circuit 50, and a signal transmission circuit 32. On the other hand, the battery pack 2 includes a battery 70, a temperature switch 71, a diode 72 as a temperature sensor, and a resistance element 73.

  In the battery pack 2, a series circuit of the battery 70 and the temperature switch 71 is connected to the charging terminals 7 a and 8. The temperature switch 71 uses, for example, bimetal. The temperature switch 71 is installed at a location where the temperature of the battery 70 can be detected, and turns off when the detected temperature exceeds a predetermined limit. The connection detection terminal 10 is connected to a connection portion between the battery 70 and the temperature switch 71. Further, a connection circuit of a diode 72 and a resistance element 73 is interposed between the connection portion and the terminal 9. The diode 72 is used as a temperature sensor that detects the temperature using the temperature dependence of the forward voltage.

  Next, the charger 3 side will be described. The DC power source 20 is configured as an AC-DC converter, receives power from the commercial power source 21, converts the DC power into a DC voltage suitable for charging the battery 70, and supplies it to the pair of charging terminals 11 a and 14. Output. For example, the DC power supply 20 includes a rectifier circuit 22, a switching control circuit 23, a switching element 24, a transformer 25, a diode 26, a smoothing capacitor 27, an output current detection circuit 28, a current detection resistance element 29, and an output voltage detection circuit 30. Have.

  The rectifier circuit 22 is a known circuit that converts a commercial AC voltage into a DC voltage, and includes, for example, a diode that forms a bridge and a smoothing capacitor. The switching element 24 is a transistor, for example, and is inserted in the path of the primary current Iin between the rectifier circuit 22 and the transformer 25. The switching control circuit 23 is a circuit that drives the switching element 24 on and off in response to a control signal S6 sent from the output control circuit 50. As a result, a pulsed current is generated as the primary current Iin.

  A secondary current is induced on the secondary side of the transformer 25 by the pulsed primary current Iin. This secondary current is rectified by the diode 26 and further charges the smoothing capacitor 27. As a result, the smoothed DC voltage Vout is output to the charging terminals 11a and 14. The output current detection circuit 28 detects the output current Iout flowing through the charging terminals 11 a and 14 by detecting a voltage drop generated in the current detection resistor element 29. The output current detection circuit 28 inputs the detection result to the output control circuit 50 as a current detection signal S1. The output voltage detection circuit 30 detects a DC voltage Vout that is an output voltage. The output voltage detection circuit 30 inputs the detection result to the output control circuit 50 as a voltage detection signal S2. The output current detection circuit 28 and the output voltage detection circuit 30 can be configured by a known voltage detection circuit.

  Although not shown, the charger 3 further includes a DC internal circuit power supply for supplying power for operating the output circuit 50, the connection detection circuit 35, and the like separately from the DC power supply 20. Have. Therefore, even when the DC power supply 20 is not operating, these internal circuits can operate as long as the charger 3 is powered on. DC internal power supply voltages E1 and E2 described later are generated by the internal circuit power supply.

  The connection detection circuit 35 is a circuit that detects that the battery pack 2 is connected by detecting that a voltage within a predetermined range is applied to the terminal 12. For this reason, the connection detection circuit 35 includes, for example, resistance elements 36, 37, 42, and 43, a transistor 38, diodes 39 and 40, and a Zener diode 41. The internal power supply voltage E1 is set to 5 V, for example. In the standby period in which the battery pack 2 is not connected to the charger 3, the connection detection terminal 12 is in an open state. For this reason, the connection detection circuit 35 inputs, for example, a high level signal of 5V to the output control circuit 50 as the connection detection signal S3. Thereby, the output control circuit 50 grasps that the battery pack 2 is not connected.

  On the other hand, when the battery pack 2 is connected to the charger 3, when the temperature switch 71 does not operate, that is, when the temperature switch 71 is on, the connection detection terminal 12 becomes the charging terminal of the battery pack 2. 7a, the temperature switch 71 and the connection detection terminal 10 are short-circuited to the charging terminal 11a which is the ground potential. As a result, the potential at the connection between the resistance element 36 and the resistance element 37 is pulled down to the vicinity of the ground potential through the diode 39. Thereby, the connection detection circuit 35 outputs a low level signal near the ground potential as the connection detection signal S3. Since the input resistance of the output control circuit 50 with respect to the connection detection signal S3 is sufficiently high, the voltage drop generated in the resistance element 37 can be ignored.

  When the temperature switch 71 is operating when the battery pack 2 is connected to the charger 3, that is, when the temperature switch 71 is off, the connection detection terminal 10 is not short-circuited to the ground potential. Also in this case, the output control circuit 50 allows the switching element 24 to output the DC voltage Vout to the charging terminals 11a and 14 even in the standby period so that the connection detection circuit 35 can detect the connection of the charger 3. To control. The voltage of the battery 70 built in the battery pack 2 depends on the type of the battery 70 and the state of charge, and can take a value in the range of 0 to 32V, for example. For this reason, in the standby period when the battery pack 2 is not connected, the DC voltage Vout is set to 40 V, for example. Then, even when the temperature switch 71 is off, when the battery pack 2 is connected to the charger 3, a potential of 8 V or more is applied to the connection detection terminal 10. At this time, the Zener voltage of the Zener diode 41 and the resistance values of the resistance elements 42 and 43 are set so that the transistor 38 is turned on.

  When the transistor 38 is turned on, the potential at the connection portion between the resistance element 36 and the resistance element 37 is lowered to the vicinity of the ground potential through the transistor 38 and the diode 40. The diode 40 is provided so that the same voltage as that when the connection detection terminal 12 is short-circuited to the ground potential appears in the connection detection signal S3. As a result, the connection detection circuit 35 outputs a low level signal near the ground potential as the connection detection signal S3. As described above, by maintaining the DC voltage Vout in the standby period sufficiently high, it is possible to detect the connection of the battery pack 2 to the charger 3 even when the temperature switch 71 is operating. Since the direct-current voltage Vout in the standby period is high, the standby power becomes excessive as it is. In order to solve this problem, as described later, the output control circuit 50 controls the switching element 24 so as to intermittently generate a pulse of the primary current Iin in the standby period.

  As described above, when the battery pack 2 is connected to the charger 3, the connection detection terminal 12 has a ground potential depending on whether or not the temperature switch 71 is operating (turned off). Alternatively, a positive potential of a certain height or higher (for example, 8 V or higher) is applied. This potential is input to the output control circuit 50 as the temperature switch operation detection signal S10. The output control circuit 50 not only knows whether or not the battery pack 2 is connected to the charger 3 through the connection detection signal S3, but when the battery pack 2 is connected to the charger 3, the temperature switch 71 It is also necessary to obtain information about whether or not it is operating. This is why the connection detection terminal 10 on the battery pack 2 side to be connected to the connection detection terminal 12 on the charger 3 side is connected to the connection between the temperature switch 71 and the battery 70.

  When the battery pack 2 is connected to the charger 3, the ground potential of the charging terminal 11a is applied to the terminal 11b through the terminal 7b. The voltage input to the terminal 11b is transmitted to the output control circuit 50 as a signal S4. The output control circuit 50 can grasp the battery capacity of the battery 70 based on the signal S4.

  When the battery pack 2 is connected to the charger 3, a series circuit of a diode 72 and a resistance element 73 is connected to the temperature detection terminal 13 through the temperature detection terminal 9. The series circuit is supplied with a current from an internal circuit power supply that generates an internal power supply voltage E <b> 2 through the resistance element 44. As a result, a voltage depending on the forward voltage of the diode 72 is applied to the temperature detection terminal 13. This voltage is input to the output control circuit 50 as the temperature detection signal S5.

  The output control circuit 50 generates a control signal S6 for on / off control of the switching element 24 based on the signals S1 to S5 and S10. The output control circuit 50 outputs a control signal S6 of a high level and a low level, for example, corresponding to turning on and off of the switching element 24, for example. The control signal S6 is transmitted to the switching control circuit 23 as the control signal S7 through the signal transmission circuit 32.

  The signal transmission circuit 32 is a circuit that transmits the control signal S6 as the control signal S7 while maintaining electrical insulation. A known circuit using inductive coupling such as a transformer or optical coupling such as a photorelay can be used. . For example, the switching control circuit 23 converts the control signal S7 into a control signal S8 having a voltage and current suitable for on / off control of the switching element 24, and inputs the control signal S8 to the switching element 24. As the switching control circuit 23, for example, a known amplifier circuit can be used.

(Configuration of output control circuit)
FIG. 4 is a block diagram showing the internal configuration of the output control circuit 50. The output control circuit 50 includes a standby control unit 51, a charge control unit 55, a control switching unit 56, a time measurement unit 57, and a human sensor 58. A part or all of the output control circuit 50 can be constituted by a microcomputer incorporating a CPU and a memory for storing a program for defining the operation of the CPU. For example, the standby control unit 51, the charging control unit 55, and the control switching unit 56 can be easily realized by a microcomputer.

  The standby control unit 51 outputs the control signal S6 so that the DC voltage Vout having a predetermined height is generated by referring to the control signal S2 mainly during the standby period. A normal pulse generator 53 and an intermittent pulse generator 54 are provided. The intermittent pulse generation unit 54 outputs a control signal S6 so as to generate a pulse of the primary current Iin intermittently while keeping the pulse width to a minimum. The normal pulse generator 53 generates the control signal S6 so as to repeatedly generate a pulse of the primary current Iin, for example, while keeping the pulse width to a minimum. Here, the intermittent pulse is obtained by intermittently outputting repetitive pulses as will be described later, so to speak, it is a pulse obtained by thinning out repetitive pulses.

  The standby control unit 51 normally activates the intermittent pulse generation unit 54 and outputs a control signal S6 so that an intermittent primary current Iin pulse is obtained. Thereby, the effective value (that is, effective value) or average value of the primary current Iin is reduced, so that standby power is saved. As described in Patent Document 1, there is a minimum value that cannot be further narrowed in the pulse width of the primary current Iin. In the standby period in which the battery pack 2 is not connected, the large output current Iout is not required, so the effective value of the primary current Iin may be sufficiently low. For this purpose, the standby control unit 51 generates an intermittent primary current Iin pulse by activating the intermittent pulse generation unit 54.

  The charging control unit 55 generates a control signal S6 so as to repeatedly generate a pulse of the primary current Iin in the charging period after the battery pack 2 is connected with reference to the signals S1, S2, S4, and S5. To do. The control switching unit 56 controls the standby control unit 51 and the charging control unit 55 by referring to the signals S2, S3, S5, and S10 and referring to signals from the time measurement unit 57 and the human sensor 58. The time measuring unit 57 measures time, and a conventionally known timer circuit can be used. The human sensor 58 is a known sensor that detects the approach of a human body through infrared rays or the like. Details of the operation of each part of the output control circuit 50 will be described below with reference to the drawings.

(Operation of output control circuit)
FIG. 5 is a flowchart showing an operation procedure of the output control circuit 50. 6 to 8 are explanatory diagrams of the operation of the output control circuit 50. FIG. As shown in FIG. 5, the processing of the output control circuit 50 starts when the power of the charger 3 is turned on by the user. When the process starts, first, the control switching unit 56 determines whether or not the battery pack 2 is connected to the charger 3 by referring to the connection detection signal S3 (ST1). If the battery pack 2 is not connected (No in ST1), the control switching unit 56 determines whether or not to stop the output of the DC voltage Vout (ST2).

  For example, if the human sensor 58 has not detected the approach of the human body, the control switching unit 56 controls the standby control unit 51 so that the pulse of the primary current Iin is not generated (ST3). That is, the control switching unit 56 controls the standby control unit 51 so as to output a control signal S6 that always turns off the switching element 24. In addition, the control switching unit 56 refers to the time measured by the time measuring unit 57, so that when the battery pack 2 is not connected after the power is turned on and a predetermined standby time is passed, the control switching unit 56 similarly performs switching. The standby control unit 51 is controlled to output a control signal S6 that always turns off the element 24 (ST3).

  In step ST2, the process repeats the loop of ST1, ST2, and ST3 until the control switching unit 56 determines that the output of the DC voltage Vout should not be paused. When the battery pack 2 is not connected to the charger 3 and there is no person in the vicinity of the charger 3, the possibility that the battery pack 2 will be connected to the charger 3 after that is low. Even when the battery pack 2 is not connected to the charger 3 for a long time, the possibility that the battery pack 2 is connected to the charger 3 is low. In such a case, the control switching unit 56 effectively reduces useless standby power by pausing the generation of the pulse of the primary current Iin.

  When determining that the output of the DC voltage Vout should not be stopped in step ST2, the control switching unit 56 causes the standby control unit 51 to generate the control signal S6 (ST7). In step ST7, the output voltage determination unit 52 first compares the DC voltage Vout with a predetermined reference voltage Vth by referring to the voltage detection signal S2 (ST8). The reference voltage Vth is set to, for example, a target value (for example, 40 V) of the DC voltage Vout or a value in the vicinity thereof. If DC voltage Vout is not lower than reference voltage Vth (No in ST8), output voltage determination unit 52 causes intermittent pulse generation unit 54 to generate control signal S6 (ST9). On the other hand, when DC voltage Vout falls below reference voltage Vth (Yes in ST8), output voltage determination unit 52 causes normal pulse generation unit 53 to generate control signal S6 (ST10).

  6B and 6C illustrate output patterns of the control signal S6. 6B and 6C, the switching element 24 is turned on when the control signal S6 is 1, and is turned off when it is 0. Therefore, the pulse waveform of the control signal S6 corresponds to the pulse waveform of the primary current Iin. As shown in FIG. 6B, the control signal S6 generated during the charging period by the charging control unit 55 described later has a pulse repeated every certain period T1, and the required output current Iout is large. Accordingly, the pulse width, that is, the duty is adjusted. That is, the charging control unit 55 adjusts the effective value of the output current Iout by PWM (pulse width modulation). FIG. 6B schematically illustrates a case where the pulse width is the minimum at an early time (left side in the figure) and the pulse width is the maximum at a later time (right side in the figure).

  The control signal S6 generated by the normal pulse generator 53 in the standby period is equivalent to that drawn on the left side of FIG. That is, a pulse having the minimum width is repeatedly generated in the period T1. On the other hand, the control signal S6 generated by the intermittent pulse generator 54 in the standby period is depicted in FIG. That is, the intermittent pulse generation unit 54 repeatedly generates a pulse having the minimum width at a period T2 longer than the period T1. In other words, the intermittent pulse generator 54 intermittently generates a pulse having the minimum width. In the example of FIG. 6C, the period T2 is set to be twice the period T1, and the intermittent pulse generation unit 54 outputs the pulse on the left side of FIG. Is equivalent to

  Instead of generating intermittent pulses having a period T2 longer than the period T1 as shown in FIG. 6 (c), a group of repetitive pulses having the period T1 shown on the left side of FIG. 6 (b) is generated over a certain period. Then, an intermittent pulse may be generated by repeating the operation of pausing for another certain period. In either case, there is no change in intermittently generating pulses, and there is no change in that the effective value of the primary current Iin can be kept low by intermittently generating pulses of the primary current Iin.

  Returning to FIG. 5, when the process of step ST9 or ST10 is performed, the process returns to step ST1. In this way, the processes of steps ST1, ST2 and ST7 are repeated during the standby period. Unless it is determined in step ST2 that the output of the DC voltage Vout should be paused, either the intermittent pulse generator 54 or the normal pulse generator 53 selectively outputs the control signal S6 according to the DC voltage Vout. Generate. As a result, a stable DC voltage Vout that is close to or converges to the reference voltage Vth can be obtained even if there is a variation factor of the DC voltage Vout, such as when the charger 3 is turned on or the temperature of the charger 3 changes. In addition, since the control signal S6 is generated as an intermittent pulse by the intermittent pulse generation unit 54, the effective value of the primary current Iin is kept low, thereby reducing standby power.

  The output voltage determination unit 52 may selectively activate the normal pulse generation unit 53 and the intermittent pulse generation unit 54 according to the determination result, but always operates the normal pulse generation unit 53 and the intermittent pulse generation unit 54. Then, a signal generated by one of them according to the determination result may be selected as the control signal S6. In any case, either the normal pulse generation unit 53 or the intermittent pulse generation unit 54 selectively generates the control signal S6.

  Note that the output voltage determination unit 52 and the normal pulse generation unit 53 correspond to an embodiment of the adjustment unit of the present invention. Other forms may be employed as the adjusting means for suppressing fluctuations of the DC voltage Vout from the reference voltage Vth. For example, instead of the normal pulse generator 53, a second intermittent pulse generator that generates an intermittent pulse shorter than the cycle T2 and longer than the cycle T1 may be used. Alternatively, the output voltage determination unit 52 may change the pulse width of the control signal S6 generated by the intermittent pulse generation unit 54 in accordance with the determination result.

  If the control switching unit 56 determines in step ST1 that the battery pack 2 is connected to the charger 3 (Yes in ST1), the control switching unit 56 determines whether the battery pack 2 can be charged (ST5). . As illustrated in FIG. 7, it is assumed that the battery pack is connected at time x2 after the power of the charger 3 is turned on at time x1. At this time, as schematically shown in FIG. 8, immediately after the battery pack 2 is connected, a transient fluctuation appears in the voltage detection signal S2. A similar variation appears in the connection detection signal S3. Therefore, the control switching unit 56 determines that charging is not possible until a predetermined time set in advance as a sufficient time for these fluctuations to converge (No in ST5).

  As illustrated in FIG. 7B, the standby control (ST7) continues during the period when the control switching unit 56 determines that charging is not possible. In FIG. 7B, the predetermined time corresponding to the period from time x2 to x3 is set to about 1 second, for example. The control switching unit 56 determines whether or not a predetermined time has elapsed by referring to the time measured by the time measuring unit 57.

  As shown in FIG. 7A, the control switching unit 56 starts to determine abnormality of the battery pack 2 at time x3 when the signal is sufficiently stabilized. The abnormality is, for example, an abnormal potential detected through the terminals 11a, 11b, 12 to 14, or a disconnected state (open state) of some terminals. More specifically, when the temperature switch 71 is operating, that is, in an off state, or when an abnormal temperature is detected by the temperature detection diode 72, the battery 70 is in an open state or a short circuit state. In this case, when the temperature detection diode 72 or the resistance element 73 is in an open state or a short circuit state, if the wiring in the battery pack 2 is disconnected, the terminals 11 to 14 of the charger 3 and the terminals of the battery pack 2 Connection failure between 7 and 10 can be given as an example of abnormality. The control switching unit 56 can acquire information regarding the on / off state of the temperature switch 71 by referring to the temperature switch operation detection signal S10.

  More desirably, as shown in FIG. 7C, the control switching unit 56 determines that charging is possible only after the time x4 at which these abnormality determinations are completed (Yes in ST5). The period of time x2 to x4 is, for example, about 3 seconds. As described above, the battery pack 2 can be appropriately charged by waiting for the start of charging until the signal is stabilized or until it is confirmed that there is no abnormality.

  Returning to FIG. 5 again, if the control switching unit 56 determines that charging is possible in step ST5 (Yes in ST5), the control switching unit 56 generates a control signal S6 in the charging control unit 55 instead of the standby control unit 51. (ST6). Thereby, the battery pack 2 is charged. The charge control unit 55 refers to the current detection signal S1 and the temperature detection signal S6 to realize a pattern of the output current Iout as exemplified in FIG. 6A, for example. It is assumed that the control switching unit 56 determines that charging is possible at time t1. Then, when the battery pack 2 is used immediately and the temperature of the battery 70 is considerably high, the charging control unit 55 generates the control signal S6 so that the output current Iout becomes a relatively low current I2. When the temperature of the battery 70 becomes sufficiently low at time t2, the charging control unit 55 generates the control signal S6 so that the output current Iout becomes a relatively high current I3. As already described, the charging control unit 55 controls the output current Iout by PWM control (see FIG. 6B).

  When time t3 is reached and the charging of the battery 70 approaches completion, the temperature of the battery 70 rises again. As a result, the charging control unit 55 generates the control signal S6 so that the output current Iout becomes a current I4 lower than the current I2, for example. Thereafter, the charging control unit 55 reduces the output current Iout to a current I1 close to 0 at time t4 when charging is completed. The time t4 when the charging is completed is, for example, the time when the battery voltage, that is, the DC voltage Vout exceeds the peak and the battery voltage is lowered by the reference value given from the peak voltage, and the time when the battery reaches the fully charged state. The charging completion time t4 may be determined.

  Even after the charging is completed, the minute current I1 is continuously supplied in order to prevent the self-discharge of the battery 70 that has been charged once and to maintain the fully charged state. The current I1 is set to about 150 mA, for example. Charging with a small current I1 is referred to in the art as “trickle charging”. Thereafter, when the battery pack 2 is removed from the charger 3, it is determined in step ST1 that there is no battery pack, and the process returns to the standby control ST7.

  When the process of step ST6 ends, the process returns to step ST1. Therefore, in the charging period, the loop of steps ST1, ST2, ST5 and ST6 is repeatedly executed. In addition, when the output current Iout becomes abnormally large by referring to the current detection signal S1, the charging control unit 55 generates the control signal S6 so as to reduce the output current Iout. Thus, the charger 3 is provided with multiple safety means so as not to apply an excessive load to the battery 70.

  Returning to FIG. 4, the control switching unit 56 has shown an example in which the standby control unit 51 and the charging control unit 55 are selectively activated according to the determination result, but the standby control unit 51 and the charging control unit 55 are switched on. A signal that is always operated and that is generated according to the determination result may be selected as the control signal S6. In any case, the control switching unit 56 still performs these controls so that either the standby control unit 51 or the charging control unit 55 selectively generates the control signal S6.

It is the schematic of the external appearance of the battery suitable for the charger which comprises the charging device which concerns on embodiment of this invention, and the said charger. It is a figure which shows the external appearance of the battery pack and charger of FIG. It is a block diagram which shows the structure of the charging device of FIG. FIG. 4 is a block diagram showing an internal configuration of the output control circuit of FIG. 3. 5 is a flowchart showing an operation procedure of the output control circuit of FIG. 4. FIG. 5 is an operation explanatory diagram of the output control circuit of FIG. 4. FIG. 5 is an operation explanatory diagram of the output control circuit of FIG. 4. FIG. 5 is an operation explanatory diagram of the output control circuit of FIG. 4.

Explanation of symbols

2 Battery pack 3 Charger 11a, 14 Charging terminal (first and second terminals)
12 Connection detection terminal (3rd terminal)
7a, 8 Charging terminals (fourth and fifth terminals)
10 Connection detection terminal (6th terminal)
7b, 11b Terminal 9, 13 Temperature detection terminal 20 DC power supply 24 Switching element 27 Transformer 28 Output current detection circuit (output voltage detection means)
35 Connection detection circuit (connection detection means)
50 Output control circuit (output control means)
51 Standby control unit (standby control means)
54 Intermittent pulse generator (intermittent pulse generator)
55 Charging control unit (charging control means)
56 Control switching part (control switching means)
52 Output voltage determination unit (adjustment means)
53 Normal pulse generator (adjustment means)
57 Time measuring unit (time measuring means)
58 Human sensor 70 Battery 71 Temperature switch Iout Primary current Vout DC voltage

Claims (7)

A battery pack for charging the battery by detachably connecting a battery pack containing the battery,
First to third terminals for electrical connection to the battery pack;
A primary current of the transformer is generated in a pulse shape by the switching operation of the switching element, and a DC voltage is generated by rectifying the secondary current of the transformer induced by the primary current, to the first and second terminals A DC power supply for supplying the DC voltage;
Connection detecting means for detecting that the battery pack is connected by detecting that a voltage within a predetermined range is applied to the third terminal;
Output control means for controlling the switching element,
The output control means includes
Charging control means for controlling the switching element to repeatedly generate the pulse of the primary current;
Standby control means including intermittent pulse generation means for controlling the switching element to intermittently generate pulses of the primary current;
In a period in which the connection detection unit does not detect connection of the battery pack, the standby control unit controls the switching element, and in a period after the connection detection unit detects connection of the battery pack, the charge control unit. And a control switching means for controlling the switching element.   2. The charger according to claim 1, wherein the control switching unit causes the standby control unit to control the switching element until a predetermined period has elapsed even after the connection detection unit detects the connection of the battery pack.   The control switching means determines whether or not the battery pack is abnormal after the connection detecting means detects the connection of the battery pack, and continues to the standby control means until obtaining a determination result that there is no abnormality. The charger according to claim 1, wherein the switching element is controlled. The DC power supply has output voltage detection means for detecting the DC voltage supplied to the first and second terminals,
4. The standby control unit according to claim 1, further comprising an adjustment unit that controls the switching element so as to suppress a variation from a predetermined voltage of the DC voltage detected by the output voltage detection unit. Charger. The output control means further includes a human sensor for detecting the approach of the human body,
The control switching means pauses the generation of the primary current pulse when the connection detecting means is in a period when the connection of the battery pack is not detected and the human sensor does not detect the approach of the human body. The charger according to any one of claims 1 to 4, which controls the standby control means. The output control means further comprises time measuring means for measuring time,
The control switching means refers to the time measured by the time measuring means, so that when the period during which the connection detecting means does not detect connection of the battery pack has exceeded a predetermined standby time, the primary current The charger according to any one of claims 1 to 5, wherein the standby control unit is controlled so as to pause generation of pulses. A charging device comprising: the charger according to any one of claims 1 to 6; and a battery pack that includes a battery and is detachably connected to the charger.
The battery pack is
Fourth to sixth terminals for connecting to the first to third terminals,
A temperature switch that turns off when the temperature of the battery exceeds a predetermined temperature;
A battery charger in which a series circuit of the battery and the temperature switch is connected to the fourth and fifth terminals, and the sixth terminal is connected to a connection between the temperature switch and the battery.

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