JP2011217554A - Power circuit and power supply apparatus - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a power circuit, along with a power supply apparatus, having high user-friendliness.SOLUTION: The power circuit 103 includes a power supply unit which is connected to a motor-driven working machine 104 and converts a DC current from a battery 101 connected to a first connection unit into an AC current and supplies the converted AC current to the connected motor-driven working machine 104, and a charge unit which charges the battery 101 connected to the first connection unit, based on the DC current supplied from a commercial power supply 150 connected to a second connection unit. When the commercial power supply 150 is connected to the second connection unit, the charge unit charges the battery 101. When the commercial power supply 150 is not connected to the second connection unit, the power supply unit supplies the DC power to the motor-driven working machine 104.

Description

  The present invention relates to a power supply circuit and a power supply apparatus.

  As the above power supply device, for example, Patent Document 1 discloses a storage case with an electric tool in which an AC-driven electric tool is attached to a box-shaped storage case, and the storage case stores a power storage unit. And an AC supply unit connected to the electric tool to supply the electric power stored in the electric storage unit to the electric tool as an alternating current, and the storage case further charges the electric storage unit. A storage case with a power tool is disclosed that stores a charging unit to be performed, and the charging unit is connected to an external power source through a power cord.

JP 2007-15032 A

  However, since the storage case with the electric power tool described in Patent Document 1 is configured to manually switch between charging the power storage unit and supplying electric power to the electric power tool, the convenience for the user is poor.

  The present invention has been made in view of such problems, and an object thereof is to provide a power supply circuit and a power supply apparatus that are highly convenient for the user.

In order to achieve the above object, a power supply circuit according to a first aspect of the present invention includes:
First connection means connected to the battery;
An electric power supply means connected to an AC electric work machine, and to the connected electric work machine, DC power from the battery connected to the first connection means is converted into AC electric power and supplied;
A second connection means connected to the AC power source;
Charging means for charging the battery connected to the first connection means based on AC power supplied from an AC power source connected to the second connection means;
With
The charging means is configured to charge the battery when the AC power source is connected to the second connection means; and
The power supply means is configured to supply the AC power to the electric working machine when the AC power supply is not connected to the second connection means.

  The first connection means and the battery may be connected or disconnected.

The first connection means and the battery may be connectable and non-connectable,
The second connection means and the AC power supply may be connectable and non-connectable,
The power supply circuit is
When the connection between the first connection means and the battery is detected, and the connection between the second connection means and the AC power supply is detected, the charging means is operated, and the charging means is connected to the battery. Let's charge
When the connection between the first connection means and the battery is detected and the connection between the second connection means and the AC power supply is not detected, the power supply means is operated to operate the power supply means. The apparatus may further comprise control means for causing the electric power from the battery to be supplied to the electric working machine.

The power supply circuit may further include switching means for switching between supply and non-supply of power from the battery to the electric working machine,
When the control means detects that the AC power supply is connected to the second connection means, the control means may not supply the power by the switching means, and may cause the charging means to charge the battery.

  The switching means may be disposed between the first connection means and the power supply means.

  The control means operates with power from the battery connected to the first connection means when the AC power supply is not connected to the second connection means, and the AC power supply is connected to the second connection means. When it is connected, it may operate with power from the AC power source.

A power supply device according to a second aspect of the present invention provides:
The power supply circuit is provided.

  ADVANTAGE OF THE INVENTION According to this invention, the power supply circuit and power supply device with a high user's convenience can be provided.

It is a figure showing circuit composition, such as a power circuit concerning one embodiment of the present invention. It is a figure which shows the external appearance of the power supply device etc. which concern on one Embodiment of this invention. It is a flowchart of the power supply control process which the control part of the power supply circuit which concerns on one Embodiment of this invention performs.

  A power supply device according to an embodiment of the present invention will be described with reference to the drawings. In addition, this invention is not limited by the following description and drawing. It goes without saying that changes (including deletion of components) can be added to the following description and drawings. Moreover, in the following description, in order to make an understanding of this invention easy, description of a known technical matter is abbreviate | omitted suitably.

  Hereinafter, a power supply circuit, a power supply device, and the like according to an embodiment of the present invention will be described with reference to FIGS. 1 to 3.

  First, a circuit configuration and the like of the power supply circuit 103 included in the power supply device 1 according to the present embodiment will be described with reference to FIG. In addition, the following connection means an electrical connection.

  A battery 101 is connected to the power supply circuit 103. An electric work machine 104 is also connected to the power supply circuit 103. In addition, a commercial power supply 150 (which is an AC power supply) is also connected to the power supply circuit 103. In the following, the former stage refers to the battery 101 side on the circuit. The latter stage refers to the electric work machine 104 side or the commercial power supply 150 side on the circuit.

  When the battery 101 and the electric work machine 104 are connected to the power supply circuit 103 and the commercial power supply 150 is not connected to the power supply circuit 103, the power supply circuit 103 supplies the electric power from the battery 101 to the electric work machine 104. When the battery 101 and the electric work machine 104 are connected to the power supply circuit 103 and the commercial power supply 150 is also connected to the power supply circuit 103, the power supply circuit 103 stops supplying power to the electric work machine 104. The battery 101 is charged with power from the commercial power source 150.

  In the present embodiment, the power supply circuit 103 converts DC power supplied from the battery 101 into AC power, and supplies the converted AC power to the electric work machine 104. The electric work machine 104 is an apparatus for AC power. The electric work machine 104 has a built-in motor 104a, and drives the motor 104a with electric power supplied from the power supply circuit 103 (an AC voltage or the like is appropriately converted into a DC voltage or the like by a circuit or the like not shown). The electric working machine 104 is an electric tool (electric drill, grinder, etc.) having a brushless motor or the like.

  Here, the battery 101 is a battery pack.

  The battery 101 includes a plurality of unit cells 101a, a temperature detection element 101b, a protection circuit 101c, a positive terminal (+), a negative terminal (−), a first output terminal (LD), and a second output terminal ( TH).

  The plurality of unit cells 101a are connected in series. Here, the unit cell 101a is a lithium ion battery. The positive electrodes of the plurality of unit cells 101a connected in series are connected to the positive electrode terminal (+). The negative electrode is connected to one end of the temperature detection element 101b and the negative electrode terminal (−). The other end of the temperature detection element 101b is connected to the second output terminal (TH).

  The temperature detection element 101b is for detecting the temperature of the plurality of unit cells 101a, and is disposed in the vicinity of the plurality of unit cells 101a. In the present embodiment, the temperature detection element 101b is configured by a thermistor whose resistance value varies depending on the temperature of the plurality of unit cells 101a.

  The protection circuit 101c is connected to the unit cell 101a and the like, and detects overdischarge, overcurrent, overcharge, and the like in the battery 101. The protection circuit 101c is also connected to the first output terminal (LD), and outputs a control signal to the outside of the battery 101 via the first output terminal (LD) when detecting overdischarge, overcurrent, overcharge, or the like. This control signal is, for example, a High signal.

  Next, the circuit of the power supply circuit 103 in the power supply device 1 will be described with reference to the circuit diagram of FIG.

  The power supply circuit 103 includes a control unit 126. The control unit 126 is configured by, for example, a microcomputer including a RAM (Random Access Memory), a ROM (Read Only Memory) that stores programs, a CPU (Central Processing Unit), and the like. The CPU of the microcomputer operates according to a program stored in the ROM. Accordingly, the control unit 126 performs power supply control processing described later to control the power supply circuit 103 and operate the power supply circuit 103.

  The power supply circuit 103 includes a positive terminal (+) and a negative terminal (−). These are connected to the positive electrode terminal (+) and the negative electrode terminal (−) of the battery 101, respectively. As a result, the battery 101 is connected to the power supply circuit 103. In addition, the power supply circuit 103 includes a first input terminal (LD). The first input terminal (LD) is connected to the first output terminal (LD) of the battery 101 when the battery 101 is attached to the power supply device 1. In addition, the power supply circuit 103 includes a second input terminal (TH). The second input terminal (TH) is connected to the second output terminal (TH) of the battery 101 when the battery 101 is attached to the power supply device 1.

  In the present embodiment, at least the positive electrode terminal (+) and the negative electrode terminal (−) constitute a first connection portion connected to the battery 101.

  The first input terminal (LD) and the control unit 126 are connected. A control signal output from the first output terminal (LD) of the battery 101 is input to the control unit 126 via the first input terminal (LD). When this control signal is input, the control unit 126 performs a predetermined process. The second input terminal (TH) and the control unit 126 are connected. The control unit 126 detects the temperature of the plurality of unit cells 101a by detecting the resistance value of the temperature detection element 101b via the second input terminal (TH). The control unit 126 performs a predetermined process based on the detected temperature.

  The power supply circuit 103 includes a first wiring L1, a second wiring L2, a third wiring L3, and a fourth wiring L4. Elements constituting the power supply circuit 103 are appropriately connected to these wirings or arranged in the middle of these wirings.

  One end of the first wiring L1 is connected to the positive terminal (+) of the battery 101 via the positive terminal (+) of the power supply circuit 103, and the other end is connected to the AC conversion unit 160 (described in detail later). Is done. One end of the second wiring L <b> 2 is connected to the negative terminal (−) of the battery 101 via the negative terminal (−) of the power supply circuit 103, and the other end is connected to the AC conversion unit 160. One end of the third wiring L3 is connected to the output part on the positive side of the step-down circuit 153 (described in detail later), and the other end is connected to the first wiring L1. The fourth wiring L4 has one end connected to the negative-side output part of the step-down circuit 153 and the other end connected to the second wiring L2.

  The power supply circuit 103 includes a switch 106B disposed in the middle of the first wiring L1. By turning ON / OFF the switch 106B, power supply / non-supply to a power supply unit (described later in detail) at the subsequent stage is switched. ON / OFF of the switch 106B is controlled by the control unit 126 via a coil 106A (described in detail later). The switch 106B and the coil 106A constitute a relay switch. In the present embodiment, the switch 106B is a normally closed switch that is normally ON.

  In the middle of the first wiring L1 before the switch 106B, the third wiring L3 is connected via the node N1. The power supply circuit 130 includes a diode 161, and the diode 161 is disposed in the middle of the third wiring L3. The diode 161 is an example of a first backflow prevention unit that prevents a current from flowing backward from the battery 101 to the step-down circuit 153 and the like.

  The power supply circuit 103 includes a regulator 108, a capacitor 109, a capacitor 110, a diode 160, and a diode 162. The power supplied from the battery 101 or the AC power supply 150 is supplied to the regulator 108. That is, the voltage output from the battery 101 or the voltage output from the step-down circuit 153 is applied to the regulator 108. The regulator 108 generates a predetermined constant voltage Vcc (here, 5 V) based on the supplied power, and outputs it to a predetermined component (such as the control unit 126) of the power supply circuit 103. In particular, the regulator 108 is connected to the control unit 126 and outputs a constant voltage Vcc to the control unit 126.

  The regulator 108 is connected to the first wiring L1 (after the switch 106B) via the diode 160 and is also connected to the second wiring L2. The diode 160 is an example of a second backflow prevention unit that prevents a backflow of current from the step-down circuit 153 to the battery 101. One end of the diode 162 is connected to a node N3 that connects the diode 160 and the regulator 108, and the other end is connected to a node N4 that is arranged in the middle of the third wiring L3 and at the subsequent stage of the diode 161. The diode 162 is an example of a third backflow prevention unit that prevents backflow of current from the battery 101 to the step-down circuit 153.

  The regulator 108 also outputs the constant voltage Vcc as appropriate to other elements in the power supply circuit 103.

  Each of the capacitor 109 and the capacitor 110 has one end connected to the regulator 108 and the other end connected to the second wiring L2. The capacitors 109 and 110 are for smoothing the voltage (input voltage) applied to the regulator 108 and the constant voltage Vcc output from the regulator 108, respectively.

  In the present embodiment, the regulator 108, the capacitor 109, and the capacitor 110 constitute a constant voltage power source that outputs a constant voltage based on the power supplied from the battery 101 or the AC power source 150.

  The power supply circuit 103 further includes a resistor 111 and a resistor 112. A resistor 111 and a resistor 112 connected in series are connected to the first wiring L1 and the second wiring L2. Between them (the node N5 connecting both) is connected to the control unit 126. The output voltage of the battery 101 is divided by the resistor 111 and the resistor 112, and the divided voltage is input to the control unit 126 as an electric signal (first divided signal). The presence / absence of connection of the battery 101 to the first connection portion and the output voltage of the battery 101 (in this case, it may be expressed by a voltage after voltage division) are specified by the first voltage division signal. In the present embodiment, the resistor 111 and the resistor 112 serve as a first detection unit for detecting the presence or absence of the connection and the output voltage of the battery 101.

  Note that the first detection unit is arranged in front of the switch 1B, that is, in this embodiment, the resistor 111 is connected to the node N2 on the first wiring L1 in front of the switch 1B. Accordingly, the control unit 126 can detect the presence / absence of the connection regardless of the ON / OFF state of the switch 1B.

  The power supply circuit 103 further includes an inductor 113, a diode 114, a FET (Field Effect Transistor) 115, a capacitor 116, a resistor 117, and a resistor 118. The inductor 113, the diode 114, the FET 115, and the capacitor 116 are boosting units that boost the input voltage, and the resistor 117 and the resistor 118 are boosting voltage detection units that detect the boosted voltage. Become.

  The inductor 113 is arranged in the middle of the first wiring L1 and after the switch 106B. The diode 114 is disposed in the middle of the first wiring L1 and after the inductor 113, and one end thereof is connected to the inductor 113 and the drain of the FET 115. The other end of the diode 114 is connected to one end of the capacitor 116.

  The FET 115 has a source connected to the second wiring L2, a gate connected to the control unit 126, and a drain connected to the first wiring L1 (inductor 113 and diode 114). The capacitor 160 is connected to the first wiring L1 and the second wiring L2. The capacitor 160 is located at the subsequent stage of the FET 115 via the diode 114.

  Here, the FET 115 is an n-channel power MOSFET (Metal Oxide Semiconductor Field Effect Transistor). When a high signal is supplied from the control unit 126 to the gate of the FET 115, the FET 115 is turned on, a current flows between the source and drain of the FET 115, and when a low signal is supplied to the gate of the FET 115b, the FET 115 is turned off. Current does not flow between the source and drain of each other.

  The inductor 113 causes a flyback effect when the FET 115 is switched ON / OFF. When the flyback effect occurs, the voltage between the terminals of the inductor 113 increases. As a result, the input voltage to the booster (input voltage from the battery 101) is boosted, and a voltage having a predetermined voltage value is generated.

  The diode 114 rectifies the voltage (boosted voltage) generated by the inductor 113 and the like. The capacitor 116 smoothes the voltage rectified by the diode 114.

  With the above configuration, the booster boosts the input voltage and outputs the boosted voltage to the AC converter 160 (described in detail later) as the boosted voltage.

  A resistor 117 and a resistor 118 connected in series are connected to the first wire L1 and the second wire L2. Between them (node N7 connecting both) is connected to the control unit 126. The boosted voltage is divided by the resistors 117 and 118, and the divided voltage is input to the control unit 126 as an electric signal (boosted voltage divided signal).

  The control unit 126 controls the switching timing of the High signal and the Low signal supplied to the gate of the FET 115 based on the voltage indicated by the input boosted voltage divided signal (that is, based on the boosted voltage). Is controlled so that the boosted voltage becomes a predetermined voltage.

  The power supply circuit 103 further includes an AC conversion unit 160 that converts the boosted voltage into an AC voltage, and output terminals 105 a and 105 b (output units) connected to the AC conversion unit 160. Here, the AC conversion unit 160 includes an FET 119, an FET 120, an FET 121, an FET 122, an inductor 123, an inductor 123, a capacitor 125, and a gate driver 127. The FET 119, the FET 120, the FET 121, the FET 122, and the gate driver 127 constitute an inverter circuit that converts the boosted voltage into a sine wave output voltage. The inductor 123, the inductor 113, and the capacitor 125 constitute a filter circuit that shapes the sine wave output voltage converted by the inverter circuit into an AC voltage.

  Each of the FETs 119 to 122 is an n-channel type power MOSFET here. Each gate of the FETs 119 to 122 is connected to the gate driver 127. The drains of the FETs 119 and 120 are connected to the first wiring L1. The source of the FET 119 is connected to one end of the inductor 123 and the drain of the FET 121. The source of the FET 120 is connected to one end of the inductor 113 and the drain of the FET 122. The sources of the FETs 121 and 122 are connected to the second wiring L2. The other end of the inductor 123 and the other end of the inductor 124 are connected to the capacitor 125. The other end of the inductor 123 and the other end of the inductor 124 are connected to the output terminal 105a and the output terminal 105b, respectively.

  The output terminal 105a and the output terminal 105b constitute a connection terminal in the outlet of the outlet. The electric work machine 104 (particularly, the motor 104a) is connected to the output terminal 105a and the output terminal 105b (output unit).

  The FET 119 and the FET 122 form a first set. Further, the FET 120 and the FET 121 form a second set. The gate driver 127 is controlled by the control unit 126 and supplies a High signal or a Low signal for each of the first group and the second group, thereby turning ON / OFF the FETs of each group. As a result, positive and negative voltages are generated in the AC converter 160. The control unit 126 controls the gate driver 127, controls the timing of the High signal and the Low signal, and controls the ON duty ratio of the FET so that the positive / negative voltage becomes a sine wave. In this manner, a sine wave voltage (output voltage) is output from the inverter circuit.

  The output voltage output from the inverter circuit is input to the filter circuit, and is shaped into an AC voltage by the inductor 123, the inductor 113, and the capacitor 125. The shaped AC voltage is output to the electric working machine 104 via the output terminal 105a and the output terminal 105b (output unit).

  As described above, AC conversion unit 160 converts the boosted voltage into an AC voltage and outputs it to electric work machine 104. That is, the AC conversion unit 160 converts DC power supplied from the boosting unit (that is, DC power amplified in accordance with the boosting) into AC power, and supplies the converted AC power to the electric work machine 104. In the present embodiment, the AC converter 160, the output unit, and the booster unit constitute a power supply unit.

  The power supply circuit 103 includes a coil 106A. One end of the coil 106 </ b> A is connected between the regulator 108 and the control unit 126 (node N <b> 8), and the other end is connected to the control unit 126. The controller 126 is configured to allow a current to flow through the coil 106A. When a current flows through the coil 106A, magnetism is generated in the coil 106A. With this magnetism, the switch 106B moves and the switch 106B is turned OFF. In the circuit of FIG. 1, the coil 106 </ b> A and the switch 106 </ b> B are separated from each other, but in an actual arrangement, both constitute a relay switch and are arranged close to each other. Since the control unit 126 can control whether or not the current flows through the coil 106A, it can control ON / OFF of the switch 106B.

  The power supply circuit 103 includes an input terminal 171a and an input terminal 172a. For example, one end of a cord is connected to the input terminal 171a and the input terminal 172a. The other end of the cord is connected to a commercial power source 150. In this embodiment, the input terminal 171a and the input terminal 172a are thereby connected to the commercial power source 150. In the present embodiment, the input terminal 171a and the input terminal 172a constitute a second connection unit connected to the commercial power supply 150.

  The power supply circuit 103 includes a diode bridge 151 including four diodes, a capacitor 152, a step-down circuit 153, and a control circuit 154.

  The input side of the diode bridge 151 is connected to the input terminal 171a and the input terminal 172a. The output side of the diode bridge 151 is connected to the capacitor 152 and the step-down circuit 153. The AC power supplied from the commercial power supply 150 via the second connection unit is rectified by the diode bridge 151, smoothed by the capacitor 152, and supplied to the step-down circuit 153. That is, the step-down circuit 153 is supplied with DC power obtained by converting AC power from the commercial power supply 150 into DC. That is, a DC voltage is applied to the step-down circuit 153.

  A control circuit 154 is connected to the step-down circuit 153. Control circuit 154 is connected between capacitor 152 and step-down circuit 153 (node N9). The control circuit 154 is connected to the control unit 156. The control unit 156 controls the control circuit 154. The control circuit 154 controls the step-down circuit 153. The step-down circuit 153 lowers the input DC voltage to a predetermined voltage value under the control of the control circuit 154 (that is, under the control of the control unit 156) and outputs the voltage. Thereby, the step-down circuit 153 steps down the supplied power.

  A third wiring L3 and a fourth wiring L4 are connected to the step-down circuit 153. A resistor 165 and a resistor 166 connected in series are connected to the fourth wire L4 and the third wire L3 subsequent to the node N4. A control unit 126 is connected between the two (node N10 connecting both). The output voltage of the step-down circuit 153 is divided by the resistors 165 and 166, and the divided voltage is input to the control unit 126 as an electric signal (second divided signal). The presence or absence of connection to the second connection portion of the commercial power supply 150 and the output voltage of the step-down circuit 153 (in this case, it may be expressed by a divided voltage) are specified by the second divided signal. In the present embodiment, the resistor 165 and the resistor 166 serve as a second detection unit for detecting the presence or absence of the connection and the output voltage of the step-down circuit 153. Based on the second divided signal, the control unit 126 controls the control circuit 154 so that the output voltage of the step-down circuit 153 becomes a predetermined voltage, thereby controlling the step-down circuit 153.

  The voltage output from the step-down circuit 153 is applied to the battery 101. As a result, power is supplied to the battery 101 and the battery 101 is charged.

  In the present embodiment, the voltage step-down circuit 153, the control circuit 154, the diode bridge 151, the capacitor 152, the resistor 165, and the resistor 166 constitute a charging unit. The charging unit charges the battery 101 connected to the first connection unit based on the AC power supplied from the AC power source 150 connected to the second connection unit.

  1 is an example of the power supply circuit according to the present invention, and the circuit configuration can be changed as appropriate. In particular, the circuit configuration of each unit described above (the first detection unit, the second detection unit, the AC conversion unit, the boosting unit, the AC conversion unit 160, the charging unit, etc.) is changed to another configuration having the same function. It can be changed. In addition, each unit may take part of the function of the control unit 126.

  In FIG. 2, the external appearance of the power supply device 1 and the battery 101 is shown. The power supply circuit 103 is housed in the housing 1 a of the power supply device 1. A battery 101 is mounted on the power supply device 1 and both are connected. The housing 1a of the power supply device 1 is provided with a socket outlet 105, and two connection terminals in the socket 105 become an output terminal 105a and an output terminal 105b, respectively. Further, a connection port (portion for attaching and connecting the cord) 171 is provided in the housing 1a. An input terminal 171a and an input terminal 171b connected to the cord are provided in the connection port 171. The battery 101 is a battery that can be used in an electric tool (electric working machine 104). The battery 101 can be directly connected to a DC power tool or the like. The battery 101 is provided with a not-shown protrusion, and a positive electrode terminal (+), a negative electrode terminal (−), and the like are arranged on the protrusion. The housing 1a is provided with a recess corresponding to the protrusion. Each terminal is connected when a projection part and a recessed part fit.

  Next, the power supply control process performed by the control unit 126 will be described with reference to FIG. This process is started when the battery 101 is connected to the power supply circuit 103. When the battery 101 is connected to the power supply circuit 103, the switch 106B is ON in the initial state, so that a voltage is applied by the battery 101 to a constant voltage power source (regulator 108, etc.). A constant voltage Vcc is applied to the control unit 126. In this way, supply of power to the control unit 126 is started, and the control unit 126 starts an operation (power supply control process). Note that the current flowing from the battery 101 flows through the diode 160, but does not flow through the step-down circuit 153 due to the diode 161 and the diode 162. This prevents backflow of current. The power supply control process ends when the supply of power to the control unit 126 is stopped, for example, when the battery 101 is not connected and when the commercial power supply 150 is not connected.

  The control unit 126 determines whether there is AC connection, that is, whether the commercial power supply 150 is connected to the power supply circuit 103 (input terminals 171a and 171b) (step S101). For example, when the power supply control process is started, the control unit 126 controls the control circuit 154, and when the commercial power supply 150 is connected to the connection unit and a voltage is input to the step-down circuit 153, the input voltage is stepped down and output. Let For example, when the second divided signal is input from the second detection unit (resistor 165 and resistor 166) (when a signal having a voltage higher than a predetermined value is input), the control unit 126 is connected to the second connection unit. The commercial power supply 150 is connected to the terminal. In this case, the control unit 126 determines that there is AC connection (step S101; YES). When there is no input of the second divided voltage signal, the control unit 126 determines that there is no AC connection because the commercial power supply 150 is not connected to the second connection unit (step S101; NO).

  When determining that there is no AC connection (step S101; NO), the control unit 126 starts control of the boosting unit (step S102). After this processing, the control unit 126 continues to control the boosting unit, and boosting is performed until processing in step S110 described later is performed.

  The control unit 126 alternately supplies a High signal and a Low signal to the FET 115 of the boosting unit, switches the FET 115 on and off, and controls the boosting unit. Thereby, the booster boosts the input voltage (the output voltage of the battery 101). Here, it is assumed that the ON duty ratio for ON / OFF, that is, the duty ratio of the High signal for the High signal and the Low signal is set in advance as a set value. The control unit 126 switches ON / OFF with the set value that has been set.

  The control unit 126 determines whether the voltage indicated by the input boosted voltage divided signal supplied from between the resistors 117 and 118 is greater than a preset first threshold value. As a result, it is determined whether the boosted voltage is larger than a preset target value (step S103). Here, the target value is a voltage value (for example, a value corresponding to the drive voltage of the conductive work machine 104) desired to be obtained by the boosting unit. The first threshold value is also a value corresponding to this target value.

  When the voltage indicated by the boosted voltage divided signal is equal to or lower than the first threshold, that is, when the value of the boosted voltage is equal to or lower than the target value (step S103; NO), the control unit 126 determines that the boosted boosted voltage value is the target. Since it is lower than the value, the ON duty ratio is increased so as to increase the voltage value of the boosted voltage (step S104). That is, the control unit 126 increases the set value set as the duty ratio of the High signal. As a result, the control unit 126 switches between the high signal and the low signal with the new set value, so that the voltage value of the boosted voltage increases. It should be noted that the increment of the set value is set in advance.

  When the voltage indicated by the boosted voltage divided signal is greater than the first threshold, that is, when the value of the boosted voltage is greater than the target value (step S103; NO), the control unit 126 determines that the boosted boosted voltage value is the target. Since it is higher than the value, the ON duty ratio is lowered so as to lower the voltage value of the boosted voltage (step S105). That is, the control unit 126 decreases the set value set as the duty ratio of the High signal. As a result, the control unit 126 switches between the High signal and the Low signal with the new set value, and thus the voltage value of the boosted voltage decreases. It should be noted that the amount of decrease in the set value is set in advance.

  Next, the control part 126 starts control of the alternating current conversion part 160 (step S106). After this process, the control unit 126 continues to control the AC conversion unit 160 until a process of step S110 described later is performed. For this reason, the process of step S106 after the 2nd time is skipped.

  The control unit 126 controls the AC conversion unit 160 by controlling the gate driver 127. The gate driver 127 is controlled by the control unit 126, and by inputting the High signal or the Low signal for each of the first set and the second set, the FET of each set is turned ON / OFF, and the AC conversion unit 160 is turned ON / OFF. Power AC conversion (boost voltage AC conversion) is performed.

  Next, the control unit 126 determines whether the voltage indicated by the first divided voltage signal supplied from the resistor 111 and the resistor 112 is lower than a preset second threshold value. It is determined whether the output voltage of the battery 101 is lower than a preset overdischarge voltage value (step S107). When the output voltage is lower than the overdischarge voltage (the voltage indicated by the first divided voltage signal is lower than the second threshold value), the battery 101 is overdischarged and the output voltage is low. . The second threshold value is a value calculated based on the voltage value of the overdischarge voltage.

  When the voltage indicated by the first divided signal is not lower than the second threshold, that is, when the output voltage is not lower than the preset overdischarge voltage value (step S107; NO), the control unit 126. Determines whether the control signal (High signal) output when the battery 101 is overdischarged or overcurrent is supplied from the first input terminal (LD) (step S108).

  When the control unit 126 determines in step S107 that the voltage indicated by the first divided signal is lower than the second threshold, that is, the output voltage is lower than the voltage value of the preset overdischarge voltage. If it is determined that the voltage is low (step S107; NO), or if it is determined that the control signal is input (step S108; YES), the battery 101 is in an overdischarge or overcurrent state. And the AC converter are stopped (step S109), and the power supply control process is terminated. For example, the control unit 126 stops the supply of the High signal. At this time, a current may be supplied to the coil 106A so that the switch 106B is turned OFF, and the supply of power from the battery 101 to the booster unit or the like may be stopped.

  When it is determined that the control signal is not input (step S108; NO), the control unit 126 returns to the process of step S103 because the battery 101 is not overdischarged or overcurrent.

  By the operation as described above (steps S103 to S108), the control unit 126 boosts the output voltage of the battery 101 to the target voltage value by the power supply unit, performs AC conversion, and converts the AC converted voltage. Applied to the electric working machine 104. In this way, the control unit 126 converts the power from the battery 101 into predetermined AC power by the power supply unit, and supplies it to the electric working machine 104.

  On the other hand, when it is determined that there is AC connection (step S101; YES), the control unit 126 starts charging control (step S111). For example, the control unit 126 supplies (energizes) current to the coil 106A and turns off the switch 106B. With this OFF, power from the battery 101 is no longer supplied to the boosting unit and the like. The voltage output from the step-down circuit 153 is input to the battery 101, power is supplied to the battery 101, and charging is performed. Further, based on the second divided signal, the control unit 126 adjusts the voltage of the second divided signal to a predetermined voltage (the output voltage of the step-down circuit 153 is a predetermined voltage (charge of the battery 101). The control circuit 154 is controlled so that the voltage reduction circuit 153 is controlled. The control unit 126 controls the width by which the step-down circuit 153 decreases the input voltage by controlling the step-down circuit 153 so that the output voltage of the step-down circuit 153 becomes a predetermined voltage. Thus, proper charging is performed. Thereafter, the control unit 126 continues this charge control.

  When the switch 106B is turned off, the constant voltage power supply (regulator 108) is not supplied with power from the battery 101, but the power supplied from the step-down circuit 153 is supplied to the constant voltage power supply. For this reason, the constant voltage power supply continues to operate. The current flowing from the step-down circuit 153 by the power supply flows to the constant voltage power source via the diode 162. At this time, the diode 160 prevents the current from flowing to the booster side.

  Next, the control unit 126 determines whether to end the charging (step S112). For example, when the control unit 126 is supplied with a control signal (High signal) output from the battery 101 via the first input terminal (LD) when an overcharge or the like occurs, It is determined that the charging is finished (step S112; YES). This is because the battery 101 is fully charged in this case. For example, the control unit 126 measures the resistance value of the temperature detection element 101b via the second input terminal (TH) or the like, and when the resistance value exceeds a predetermined value (that is, a plurality of unit cells 101a). If the temperature exceeds the predetermined temperature), it is determined that the charging is finished (step S112; YES). In this case, the temperature of the battery 101 is too high.

  When the control signal is not supplied or the resistance value does not exceed the predetermined value, the control unit 126 determines that charging is not finished (step S112; NO), and performs the process of step S112 again. In this way, the charging of the battery 101 is continued until the control unit 126 determines that the charging is finished.

  When it is determined that charging is to be ended (step S112; YES), the control unit 126 stops the operation of the step-down circuit 153 via the control circuit 154 and ends charging (step S113).

  Through the processing as described above, the control circuit 126 turns off the switch 106B during the charging, controls the charging unit, converts the AC power of the commercial power supply 150 to DC, steps down, and finishes charging the battery 101. Until it is determined.

  Next, the control unit 126 determines whether or not the battery 101 is connected (step S114). That is, it is determined here whether or not the battery 101 that has been charged is removed. This determination is made based on whether the first divided voltage signal is supplied. When the first voltage division signal is supplied to the control unit 126 (when a signal having a voltage higher than a predetermined value is input), the control unit 126 determines that the battery 101 is connected (step S114). YES), the process of step S114 is performed again. Thereby, the control unit 126 stands by until the battery 101 is removed.

  When the first partial pressure signal is not supplied to the control unit 126, the control unit 126 determines that the battery 101 is not connected (step S114; NO), and determines whether the battery 101 is connected (step S114). S115). That is, here, it is determined whether another battery 101 different from the battery 101 that has been charged is connected to the power supply circuit 103. This determination is the same as in step S114.

  When the control unit 126 determines that the battery 101 is not connected (step S115; NO), the control unit 126 performs the process of step S115 again. In this way, the control unit 126 stands by until the battery 101 is replaced.

  When it is determined that the battery 101 is connected (step S115; YES), the control unit 126 performs the process of step S116 because the battery has been replaced, and returns to the process of step S101. In the process of step S116, the control unit 126 controls the control circuit 154, operates the step-down circuit 153 again, and performs the process of step S101. At this time, the control unit 126 stops energization of the coil 106A and turns on the switch 106B. As a result, the control unit 126 can perform power supply control processing again for a new battery. Note that even if the commercial power supply 150 is disconnected from the power supply circuit 103 by turning on the switch 106B, the constant voltage power supply can continue to operate by the power from the battery 101.

  As described above, in the present embodiment, with the above-described configuration, the power supply circuit 103 is connected to the electric work machine 104, and the connected electric work machine converts the DC power from the battery 101 connected to the first connection unit into AC power. And a charging unit that charges the battery 101 connected to the first connection unit based on AC power supplied from the commercial power source 150 connected to the second connection unit. In the present embodiment, with the above configuration, the power supply circuit 103 is configured such that the charging unit charges the battery 101 when the AC power supply 150 is connected to the second connection unit, and the commercial power supply The power supply unit is configured to supply AC power to the electric work machine 104 when 150 is not connected to the second connection unit. With such a configuration, switching between charging and supply of electric power to the electric working machine 104 is easily performed, and thus the power supply circuit 103 is highly convenient for the user.

  Moreover, in this embodiment, since the 1st connection part is connected with the battery 101 so that attachment or detachment is possible (connection and non-connection are possible) by the said structure, since charge etc. can be carried out about other batteries 101 etc., it is user The convenience is even higher.

  In the present embodiment, with the above configuration, the second connection portion is detachably connected to the AC power supply 150 (can be connected or disconnected), and the power supply circuit 103 is connected to the first connection portion and the battery 101. When the connection is detected by the first detection unit and the connection between the second connection unit and the AC power supply 150 is detected by the second detection unit, the charging unit is operated to charge the battery 101 by the charging unit. The power supply unit when the connection between the first connection unit and the battery 101 is detected by the first detection unit and the connection between the second connection unit and the commercial power supply 150 is not detected by the second detection unit. And a control unit that causes the power supply unit to supply the electric power from the battery to the electric working machine 104. As a result, switching between charging and supply of electric power to the electric work machine 104 is performed automatically and easily, and such a power supply circuit is highly convenient for the user.

  In the present embodiment, with the above configuration, the power supply circuit 103 includes a switching unit (here, the switch 106B and the coil 106A) that switches between supply and non-supply of power from the battery 101 to the electric work machine 104. When it is detected that the commercial power source 105 is connected to the second connection unit, the switching unit makes power not supplied to the power supply unit and causes the charging unit to charge the battery 101. Thereby, the supply of electric power to the electric working machine 104 being charged is stopped with high accuracy.

  In the present embodiment, with the above configuration, the switching unit is disposed between the first connection unit and the power supply unit. Thereby, the supply of electric power to the electric working machine 104 being charged is stopped with high accuracy.

  In the present embodiment, with the above configuration, when the commercial power supply 150 is not connected to the second connection unit, the control unit 126 operates with the power from the battery 101 connected to the first connection unit, and the second connection When the commercial power supply 150 is connected to the unit, it operates with the power from the commercial power supply 150. Thereby, even if charging and supply of electric power to the electric work machine 104 are switched, the control unit 126 can operate safely.

  In the power supply device 1 according to the present embodiment, since AC power can be supplied to the electric working machine 104 using the battery 101, the electric working machine 104 for AC power can be used even in a place where there is no commercial power supply 150 (plug outlet). Can be used, and the battery 101 can be charged where there is a commercial power source 150. Thereby, the power supply device 1 is convenient for the user.

DESCRIPTION OF SYMBOLS 1 Power supply device 101 Battery 103 Power supply circuit 104 Electric working machine 108 Regulator 126 Control part 127 Gate driver 153 Step-down circuit 154 Control circuit 160 AC conversion part

Claims (7)

First connection means connected to the battery;
An electric power supply means connected to an AC electric work machine, and to the connected electric work machine, DC power from the battery connected to the first connection means is converted into AC electric power and supplied;
A second connection means connected to the AC power source;
Charging means for charging the battery connected to the first connection means based on AC power supplied from an AC power source connected to the second connection means;
With
The charging means is configured to charge the battery when the AC power source is connected to the second connection means; and
When the AC power supply is not connected to the second connection means, the power supply means is configured to supply the AC power to the electric working machine,
A power supply circuit characterized by that. The first connection means and the battery can be connected and disconnected.
The power supply circuit according to claim 1. The first connection means and the battery can be connected and disconnected.
The second connection means and the AC power source can be connected and disconnected.
The power supply circuit is
When the connection between the first connection means and the battery is detected, and the connection between the second connection means and the AC power supply is detected, the charging means is operated, and the charging means is connected to the battery. Let's charge
When the connection between the first connection means and the battery is detected and the connection between the second connection means and the AC power supply is not detected, the power supply means is operated to operate the power supply means. Further comprising control means for causing the electric work machine to be supplied with electric power from the battery.
The power supply circuit according to claim 1. It further comprises switching means for switching between supply and non-supply of power from the battery to the electric working machine,
When the control means detects that the AC power source is connected to the second connection means, the switching means makes the power non-supplied and causes the charging means to charge the battery.
The power supply circuit according to claim 3. The switching means is disposed between the first connection means and the power supply means.
The power supply circuit according to claim 4. The control means operates with power from the battery connected to the first connection means when the AC power supply is not connected to the second connection means, and the AC power supply is connected to the second connection means. When connected, it operates with power from the AC power source,
The power supply circuit according to claim 3.   A power supply device comprising the power supply circuit according to claim 1.

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