JP2014110654A - Charger for electric tool - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a charger for electric tool including a fuel cell, that can also supply power even to an electrical apparatus other than a battery pack for electric tool.SOLUTION: A charger 2 includes a battery pack charging control circuit 22 that charges a battery pack for electric tool by receiving power supply from a fuel cell 14, and a USB output control circuit 24 for supplying power to a USB apparatus by receiving power supply from the fuel cell 14. When the battery pack for electric tool is connected with a battery pack charging terminal 10, or a USB apparatus is connected with a USB output terminal 12, a control unit 30 supplies fuel to the fuel cell 14 via a fuel adjustment unit 18, so as to generate DC power therefrom.

Description

  The present invention relates to a charging device for an electric tool that includes a fuel cell and charges an electric tool battery pack by an output from the fuel cell.

2. Description of the Related Art Conventionally, a charging device that includes a fuel cell is known as a charging device that charges a battery pack for an electric tool (for example, see Patent Document 1).
When the power tool battery pack to be charged is connected, the charging device drives the fuel cell to output DC power and charges the power tool battery pack with the output.

WO2011 / 162357A1

Therefore, according to the conventional charging device, the battery pack for the electric tool can be charged even when an external power source such as a commercial power source does not exist in the vicinity.
However, since the conventional charging device is a dedicated charging device for the power tool battery pack, there is a problem in that power cannot be supplied to electric devices other than the power tool battery pack, and the usability is poor.

  The present invention has been made in view of these problems, and an object of the present invention is to enable power supply to an electric device other than a battery pack for an electric tool in a charging device for an electric tool provided with a fuel cell. And

According to a first aspect of the present invention, there is provided a power tool charging apparatus including a fuel cell, a driving power source for driving the fuel cell, and a control unit for driving the fuel cell.
In addition, as a DC output unit that receives power supply from the fuel cell and outputs DC power, the first DC output unit that charges the power tool battery pack, and outputs DC power to an electric load different from the power tool battery pack A second DC output unit.

  Therefore, according to the power tool charging device of the present invention, not only can the battery pack for the power tool be charged, but also DC power can be supplied to an electric load different from the battery pack for the power tool. The usability of the battery charger can be improved.

Next, in the charging device for electric tools of Claim 2, a 2nd DC output part is provided with the connection terminal for connecting an electric load.
For this reason, according to the charging device for electric tools of Claim 2, even if an electric load is an external electric load which is not built in the charging device for electric tools, DC power is supplied through a connection terminal. It is possible to expand the application of the power tool charging device.

  In addition, since the charging device for electric tools of this invention is for charging the battery pack for electric tools, as described in Claim 3, a 2nd DC output part is a 1st DC output part. It is desirable that the output power is smaller than that.

  That is, in this way, when the DC power is output from the second DC output unit to the electric load simultaneously with the charging of the battery pack for the electric tool from the first DC output unit, the battery pack for the electric tool is supplied. It is possible to prevent the charging power of the battery from being reduced and the charging time from becoming longer.

  Further, when the connection terminal is provided in the second DC output unit, it is preferable to provide a USB (Universal Serial Bus) terminal or a cigar socket as at least one of the connection terminals.

  In this way, DC power can be supplied to a USB device that operates by receiving power supply from the USB terminal or an electrical device that operates by receiving power supply from the cigar socket.

  Next, according to a fifth aspect of the present invention, there is provided a power tool charging apparatus including a secondary battery that is charged with an output from a fuel cell as a driving power source. The secondary battery supplies power to the first DC output unit, the second DC output unit, and the control means.

  For this reason, according to the charging device for electric tools of Claim 5, after direct-current power output from a fuel cell is once accumulate | stored in a secondary battery, it supplies to a 1st DC output part and a 2nd DC output part. be able to.

Therefore, it is possible to more stably supply power from the first DC output unit or the second DC output unit to the power tool battery pack or other electric load.
Further, since it is possible to supply power to the control means with DC power stored in the secondary battery, it is necessary to separately provide a power source for supplying power necessary for the control means to drive the fuel cell. Therefore, the apparatus configuration can be simplified.

  The power tool charging apparatus according to claim 5, wherein the control unit is configured to charge the DC power from the second DC output unit to the electric load when charging the battery pack for the electric tool by the first DC output unit. When outputting, the fuel cell is driven.

  In addition, when the control unit outputs the DC power from the second DC output unit to the electric load when charging from the first DC output unit to the power tool battery pack is stopped, the secondary battery The remaining capacity is detected, and if the detected remaining capacity is less than a predetermined threshold value, the fuel cell is driven, and if the remaining capacity is equal to or greater than the threshold value, the driving of the fuel cell is stopped.

  For this reason, according to the charging device for electric tools of Claim 5, both the electric power supply from the 1st DC output part to the battery pack for electric tools and the electric power supply from the 2nd DC output part to the electric load are stopped. When the fuel cell is running, the drive of the fuel cell is stopped.

  Further, even when power is supplied from the second DC output unit to the electric load, the driving of the fuel cell is stopped when the power supply can be performed only with the power stored in the secondary battery.

  Therefore, according to the charging device for an electric tool according to claim 5, the fuel cell can be driven only when the electric power from the fuel cell is necessary, and the driving efficiency of the fuel cell is improved. It is possible to reduce the amount of fuel consumed by the fuel cell.

According to a sixth aspect of the present invention, there is provided a charging device for an electric tool comprising an informing means for informing at least one of a remaining amount of fuel in the fuel cell and a remaining capacity of the secondary battery.
For this reason, according to the charging device for electric tools of Claim 6, a user detects the fall of the fuel of a fuel cell, or the fall of the remaining capacity of a secondary battery by the alerting | reporting from an alerting | reporting means. Measures such as fuel replenishment and secondary battery charging can be implemented.

  That is, when there is no fuel in the fuel cell or when the secondary battery is completely discharged, power supply from the first DC output unit or the second DC output unit to the power tool battery pack or other electric load is performed. Although it becomes impossible to implement, according to the charging device for a power tool described in claim 6, it is possible to prevent such a problem from occurring due to the notification from the notification means.

  In addition, in the charging device for electric tools provided with the secondary battery, as described in claim 7, it is preferable that the charging to the secondary battery can be performed not only from the fuel cell but also from an external power source. .

In addition, as described in claim 8, the charging of the secondary battery may be performed from a battery pack for an electric tool connected to the first DC output unit instead of the fuel cell. .
In other words, in this way, even when the secondary battery is completely discharged and the control means cannot drive the fuel cell to charge the secondary battery, the external power source or the power tool battery The secondary battery can be charged by supplying power from the pack, and the power tool charging device can be returned to the normal state.

  Further, according to the charging device for an electric tool of the present invention, the power supply path to the second DC output unit is connected to the first DC output unit in place of the path from the fuel cell. Alternatively, the path may be switched from the power tool battery pack.

It is a block diagram showing the structure of the charging device of 1st Embodiment. It is a block diagram showing the structure of the charging device of 2nd Embodiment. It is a flowchart showing the battery pack charge process performed in the control part of 2nd Embodiment. It is a flowchart showing the USB apparatus output process and output stop process which are performed in the control part of 2nd Embodiment. It is a block diagram showing the structure of the charging device of 3rd Embodiment. It is a block diagram showing the structure of the charging device of 4th Embodiment. It is a flowchart showing the battery pack charge process performed in the control part of 4th Embodiment. It is a block diagram showing the structure of the charging device of 5th Embodiment. It is a flowchart showing the USB apparatus output process performed in the control part of 5th Embodiment.

Embodiments of the present invention will be described below with reference to the drawings.
[First Embodiment]
As shown in FIG. 1, a power tool charging device (hereinafter simply referred to as a charging device) 1 according to the present embodiment connects a battery pack charging terminal 10 for connecting a power tool battery pack to a USB device. USB output terminal 12.

  The charging device 1 also adjusts the amount of fuel supplied from the fuel tank 16 to the fuel cell 14, the fuel cell 14 that generates DC power by oxidizing the fuel and the oxidant, and the fuel tank 16. A fuel adjusting unit 18 is provided.

  In this embodiment, the fuel cell 14 does not supply the reformed fuel (hydrogen), but directly supplies the liquid fuel (methanol) stored in the fuel tank 16 (direct methanol fuel cell ( DMFC) is adopted.

  Further, the output path of the DC power from the fuel cell 14 is branched into two systems, and one output path is connected to the battery pack charging terminal 10 via the battery pack charging control circuit 22 and the other output path. Are connected to the USB output terminal 12 via the USB output control circuit 24.

The battery pack charge control circuit 22 is for supplying power from the fuel cell 14 and charging the battery pack for the electric tool connected to the battery pack charge terminal 10.
The battery pack charge control circuit 22 performs charging of the power tool battery pack in accordance with the charge request from the control unit 30.

  Further, the USB output control circuit 24 receives power supply from the fuel cell 14, generates a power supply voltage (DC 5 V) for driving the USB device, and the generated power supply voltage is connected to the USB output terminal 12. It is for output to.

  The USB output control circuit 24 operates in accordance with the output request from the control unit 30. When the output request from the control unit 30 is stopped, generation of the power supply voltage for driving the USB device and the USB device having the power supply voltage are generated. Stops output to.

In addition, the charging device 1 of the present embodiment is provided with a drive battery 32 for supplying a power supply voltage for operation to the fuel adjustment unit 18 and the control unit 30.
Since the battery pack charge control circuit 22 is for charging the battery pack for the electric tool, the battery pack charge control circuit 22 is configured to be able to output power of 50 W or more necessary for the charge. Since power is supplied to the USB device, the output power is set to 10 W or less.

Next, the control part 30 is comprised with the microcomputer centering on CPU, ROM, RAM, etc.
And the control part 30 detects the connection state of the battery pack to the battery pack charge terminal 10 based on the signal input into the battery pack charge terminal 10 from the control terminal of a battery pack.

Further, the control unit 30 detects the connection state of the USB device to the USB output terminal 12 based on a signal input from the communication terminal of the USB device to the USB output terminal 12.
When the battery pack is connected to the battery pack charging terminal 10, the control unit 30 outputs a charge request to the battery pack charge control circuit 22 to start charging the battery pack for the electric tool.

  After that, when the charging to the power tool battery pack is completed or the power tool battery pack is removed from the battery pack charging terminal 10, the control unit 30 issues a request for charging to the battery pack charging control circuit 22. The output is stopped, and charging of the battery pack for the electric power tool is stopped.

  Further, when a USB device is connected to the USB output terminal 12, the control unit 30 outputs an output request to the USB output control circuit 24 to start supplying power to the USB device, and then from the USB output terminal 12. When the USB device is disconnected, the output request to the USB output control circuit 24 is stopped, and the power supply to the USB device is stopped.

  Further, when the battery pack is connected to the battery pack charging terminal 10 or the USB device is connected to the USB output terminal 12, the control unit 30 determines whether or not the fuel cell 14 is operating, If the battery 14 is not operating, driving of the fuel cell 14 is started via the fuel adjustment unit 18.

The fuel cell 14 is driven by causing the fuel adjustment unit 18 to supply the fuel in the fuel tank 16 to the fuel cell 14.
Thereafter, when both the charging request and output request output to the battery pack charging control circuit 22 and the USB output control circuit 24 are stopped, the control unit 30 stops the fuel supply to the fuel cell by the fuel adjusting unit 18. Then, the driving of the fuel cell 14 is stopped.

  As described above, the charging device 1 according to the present embodiment supplies a power supply voltage to the USB device separately from the battery pack charging control circuit 22 and the battery pack charging terminal 10 for charging the power tool battery pack. A USB output control circuit 24 and a USB output terminal 12 are provided.

  When charging the battery pack for the electric tool and supplying power to the USB device, the control unit 30 drives the fuel cell 14 via the fuel adjustment unit 18 to generate DC power for charging or generating a power supply voltage. Generate.

  Therefore, according to the charging device 1 of the present embodiment, not only can the battery pack for the electric power tool connected to the battery pack charging terminal 10 be charged, but also power can be supplied to the USB device connected to the USB output terminal 12. It is possible to improve the usability of the charging device 1.

In the present embodiment, the driving battery 32 corresponds to the driving power source of the present invention, the battery pack charging control circuit 22 and the battery pack charging terminal 10 correspond to the first DC output unit of the present invention, and the USB. The output control circuit 24 and the USB output terminal 12 correspond to the second DC output unit of the present invention, and the control unit 30 corresponds to the control means of the present invention.
[Second Embodiment]
Next, the charging device 2 of 2nd Embodiment is demonstrated.

  As shown in FIG. 2, the charging device 2 of the present embodiment is provided with a secondary battery 34, a secondary battery charge control circuit 36, and a display unit 40 with respect to the charging device 1 of the first embodiment. Instead of the driving battery 32, a power supply circuit 38 is provided.

  The charging device 2 of the present embodiment is the same as the charging device 1 of the first embodiment except that the configuration of these units and the operation of the control unit 30 are different from those of the first embodiment. Now, only differences from the first embodiment will be described, and description of the same parts as those of the first embodiment will be omitted.

The secondary battery 34 and the secondary battery charge control circuit 36 are provided in the output path of DC power from the fuel cell 14 to the battery pack charge control circuit 22 and the USB output control circuit 24.
Then, the secondary battery charge control circuit 36 receives power supply from the fuel cell 14 to charge the secondary battery 34, and the secondary battery 34 is converted to the DC power charged via the secondary battery charge control circuit 36. Thus, power is supplied to the battery pack charge control circuit 22 and the USB output control circuit 24.

  That is, the secondary battery 34 functions as a buffer for temporarily storing the output from the fuel cell 14, and stably supplies DC power to the battery pack charge control circuit 22 and the USB output control circuit 24. Used.

The secondary battery 34 is configured by a chargeable / dischargeable chemical battery, a capacitor, or the like.
The power supply circuit 38 operates by receiving power supply from the secondary battery 34 and generates a power supply voltage for operating the fuel adjusting unit 18 and the control unit 30.

  That is, since the charging device 2 of the first embodiment does not have the secondary battery 34 that is charged by the output from the fuel cell 14, it is necessary to provide the drive battery 32 as a power source for the fuel adjustment unit 18 and the control unit 30. It was.

  On the other hand, in the present embodiment, since the secondary battery 34 is provided, the secondary battery 34 is used as a power source for the fuel adjustment unit 18 and the control unit 30 without providing the drive battery 32. The fuel adjustment unit 18 and the control unit 30 can be operated.

  The display unit 40 displays the remaining capacity that represents the amount of power charged in the secondary battery 34 and the remaining fuel amount that represents the amount of fuel in the fuel tank 16 in accordance with a display command from the control unit 30. Is.

  The remaining capacity of the secondary battery 34 represents the ratio of the remaining power amount when the amount of power stored when the secondary battery 34 is fully charged is 100%. The remaining fuel amount can be stored in the fuel tank 16. This represents the ratio of fuel when the amount of fuel is 100%.

  Accordingly, the user detects the remaining capacity and the remaining fuel amount of the secondary battery 34 by checking the display content of the display unit 40, and drives the fuel cell 14 when the remaining capacity of the secondary battery 34 is small. Thus, when the secondary battery 34 is charged and the remaining amount of fuel is low, the fuel can be supplied to the fuel tank 16.

  That is, the user cannot discharge the secondary battery 34 due to such an operation to charge the power tool battery pack and supply power to the USB device, or the fuel in the fuel tank 16 runs out. It can be prevented that the battery 14 cannot be driven.

  Next, as in the first embodiment, the control unit 30 determines the battery pack charge control circuit 22 and the USB output control circuit 24 based on the connection state of the battery pack and the USB device to the battery pack charge terminal 10 and the USB output terminal 12. In addition, the fuel adjusting unit 18 is controlled, and the secondary battery charging control circuit 36 is also controlled.

Hereinafter, the control operation of the control unit 30 in the present embodiment will be described with reference to the flowcharts shown in FIGS. 3 and 4.
The battery pack charging process shown in FIG. 3 is a process that is repeatedly executed as one of the main routines in the control unit 30. When the process is started, the battery pack charging is first performed in S100 (S represents a step). It is determined whether or not a battery pack is connected to the terminal 10.

  If the battery pack is not connected, the battery pack charging process is terminated. If the battery pack is connected, the process proceeds to S110, and the battery pack charge control circuit 22 is switched to the power tool battery pack. The charge request is output.

As a result, charging of the battery pack for the electric tool by the battery pack charge control circuit 22 is started.
Next, in S120, a request for charging the secondary battery 34 is output to the secondary battery charge control circuit 36, and in the subsequent S130, fuel supply to the fuel cell 14 by the fuel adjustment unit 18 is started. Then, the fuel cell 14 is operated.

  That is, for example, 50 W or more of electric power is required for charging the battery pack for the electric tool, and the amount of electric power for charging the electric tool battery pack is insufficient with the secondary battery 34 alone. And the secondary battery charge control circuit 36 charges the secondary battery 34.

  As a result, the secondary battery 34 is charged by the output from the fuel cell 14 via the secondary battery charge control circuit 36 and is connected to the battery pack charge terminal 10 via the battery pack charge control circuit 22. It will be discharged to the pack side.

  Next, in S140, it is determined whether or not the battery pack is disconnected from the battery pack charging terminal 10 (in other words, whether or not the battery pack has been removed). If the battery pack has not been removed, S150 is determined. Then, it is determined whether or not the power tool battery pack is fully charged.

  If it is determined in S150 that the power tool battery pack is not fully charged, the process proceeds to S140, and it is determined in S150 that the power tool battery pack is fully charged, or If it is determined in S140 that the battery pack has been removed, the process proceeds to S160.

In S160, the charging of the power tool battery pack is stopped by stopping the output of the charging request to the battery pack charging control circuit 22.
Next, in S <b> 170, the USB output control circuit 24 determines whether power is being supplied to the USB device connected to the USB output terminal 12.

If the USB output control circuit 24 supplies power to the USB device, the battery pack charging process is terminated as it is.
On the other hand, if the USB output control circuit 24 is not supplying power to the USB device, the process proceeds to S180, and the charging request to the secondary battery charging control circuit 36 is stopped to charge the secondary battery 34. Stop.

  In the subsequent S190, the fuel adjustment unit 18 stops the fuel supply to the fuel cell 14 to stop the operation of the fuel cell 14, and then the battery pack charging process is terminated.

  Next, the USB device output process shown in FIG. 4 is started when a USB device is connected to the USB output terminal 12 (when connection is detected), and the USB device output stop process shown in FIG. This process is started when the connection of the USB device to the output terminal 12 is released (when release is detected).

  As shown in FIG. 4, when the USB device output process is started, first, in S200, the USB output control circuit 24 outputs a power supply voltage output request to the USB device to the USB output terminal 12. Power supply to the connected USB device is started.

  In subsequent S210, the battery pack charge control circuit 22 determines whether or not the battery pack for the electric tool is being charged. If the battery pack is being charged, the USB device output process is terminated as it is, and the battery pack is being charged. If not, the process proceeds to S220.

In S220, the remaining capacity of the secondary battery 34 is detected, and it is determined whether or not the remaining capacity is less than a threshold value C1 (for example, 30%) with respect to the amount of power when fully charged.
That is, the power consumption of the USB device is extremely small compared to the power required for charging the battery pack for the power tool. If the remaining capacity of the secondary battery 34 is equal to or greater than the threshold value C1, it is stored in the secondary battery 34. The amount of power supply to the USB device can be performed only with the remaining power.

  Therefore, in S220, it is necessary to charge the secondary battery 34 by operating the fuel cell 14 when power is supplied to the USB device by determining whether the remaining capacity of the secondary battery 34 is less than the threshold value C1. Judging whether there is.

  For this reason, if it is determined in S220 that the remaining capacity of the secondary battery 34 is less than the threshold value C1, the process proceeds to S230, and if not, the process of S220 is performed again to perform the secondary process. A decrease in the remaining capacity of the battery 34 is monitored.

The remaining capacity of the secondary battery 34 is calculated based on the voltage of the secondary battery 34 or the integrated value of charge / discharge current to the secondary battery 34.
In S230, a request for charging the secondary battery 34 is output to the secondary battery charge control circuit 36, and in S240, fuel supply to the fuel cell 14 is started by the fuel adjusting unit 18 to thereby start the fuel cell. 14 is operated.

  As described above, when charging of the secondary battery 34 is started by the processing of S230 and S240, the process proceeds to S250, and it is determined whether or not the secondary battery 34 is fully charged by the charging. This determination is made based on the voltage or charging current of the secondary battery 34.

The determination process of S250 is repeatedly executed until the secondary battery 34 is fully charged. When the secondary battery 34 is fully charged, the process proceeds to S260.
In S260, the battery pack charge control circuit 22 determines whether or not the battery pack for the electric tool is being charged. If the battery pack is being charged, the USB device output process is terminated as it is, and the battery pack must be charging. If so, the process proceeds to S270.

In S270, the charging of the secondary battery 34 is stopped by stopping the output of the charging request to the secondary battery charging control circuit 36.
In subsequent S280, the fuel adjustment unit 18 stops the fuel supply to the fuel cell 14 to stop the operation of the fuel cell 14, and then the USB device output process is terminated.

  Accordingly, when charging of the battery pack is stopped, when the USB device is connected to the USB output terminal 12 and power supply to the USB device is started, if the remaining capacity of the secondary battery 34 becomes less than the threshold value C1, The fuel cell 14 is driven and charged until the secondary battery 34 is fully charged.

  On the other hand, when the USB device output stop process is started, in S290, the output of the output request to the USB output control circuit 24 is stopped to stop the power supply to the USB device, and then the USB device output is stopped. The process ends.

  As described above, according to the charging device 2 of the present embodiment, the secondary battery 34 that is charged by the output from the fuel cell 14 is provided, and the battery pack charge control circuit 22 and the USB output control circuit 24 include DC power is supplied from the secondary battery 34.

  Therefore, as in the first embodiment, the power to the battery pack and the USB device is compared with the case where direct power is directly supplied from the fuel cell 14 to the battery pack charge control circuit 22 and the USB output control circuit 24. Supply can be performed stably.

  Further, in the charging device 2 of the present embodiment, when the power supply to the USB device is started when charging to the power tool battery pack is stopped, the remaining capacity of the secondary battery 34 is equal to or greater than the threshold value C1. The driving of the fuel cell 14 and the charging of the secondary battery 34 are not performed.

  Further, when the remaining capacity of the secondary battery 34 is less than the threshold value C1 and the driving of the fuel cell 14 and the charging of the secondary battery 34 are started, thereafter, until the fuel cell 14 is fully charged, The driving of the fuel cell 14 and the charging of the secondary battery 34 are continued.

For this reason, according to the charging device 2 of this embodiment, the fuel cell 14 can be driven efficiently and the fuel consumption by the fuel cell 14 can be suppressed.
In the present embodiment, the display unit 40 corresponds to the notification unit of the present invention.

  However, in the present embodiment, it is assumed that the remaining capacity of the secondary battery 34 and the remaining amount of fuel in the fuel tank 16 are displayed on the display unit 40 to notify the user of these parameters. However, for example, one of these, such as the remaining amount of fuel, may be displayed.

Further, the notification (notification) to the user is not limited to the display on the display unit 40. For example, the notification may be made by voice according to a request from the user, and the remaining amount of the secondary battery 34 may remain. You may make it notify by generating a warning sound at the time of the fall of a capacity | capacitance or a fuel remaining amount. Moreover, you may make it alert | report combining these.
[Third Embodiment]
Next, the charging device 3 of 3rd Embodiment is demonstrated.

  As shown in FIG. 5, the charging device 3 of the present embodiment has an AC / AC that converts an AC voltage supplied from an external AC power source (for example, a commercial power source) 42 to a DC voltage to the charging device 2 of the second embodiment. A DC converter 44 is provided.

The output of the AC / DC converter 44 is connected in parallel to the output of the fuel cell 14.
Further, the control unit 30 stops the operation of the fuel cell 14 when the AC / DC converter 44 is supplied with power from the external AC power source 42, and the AC / DC converter 44 replaces the fuel cell 14 with DC power. To recharge the secondary battery 34.

  For this reason, according to the charging device 3 of the present embodiment, if there is an AC power source 42 around the charging device 3, it is used to charge the battery pack for the power tool, supply power to the USB device, and The secondary battery 34 can be charged, and the driving of the fuel cell 14 (and hence the consumption of fuel) can be suppressed.

The AC / DC converter 44 may be built in the charging device 3 or may be configured as a separate body from the charging device 3 as a so-called AC adapter.
[Fourth Embodiment]
Next, the charging device 4 of 4th Embodiment is demonstrated.

  As shown in FIG. 6, the charging device 4 of the present embodiment charges the secondary battery 34 by receiving power from the battery pack side connected to the battery pack charging terminal 10 to the charging device 2 of the second embodiment. The secondary battery charging control circuit 26 is provided.

  The secondary battery charge control circuit 26 is connected in parallel with the battery pack charge control circuit 22, and power is supplied from both the secondary battery 34 and the battery pack for the electric tool connected to the battery pack charge terminal 10. Can be supplied.

The secondary battery charging control circuit 26 supplies power to the power supply circuit 38 with the supplied power.
For this reason, even if the secondary battery 34 is completely discharged and the remaining capacity becomes zero, the battery pack is connected to the battery pack charging terminal 10 and can receive power supply from the battery pack for the electric tool. If possible, the power supply circuit 38 can supply power to the control unit 30 and operate the control unit 30.

And the control part 30 performs a battery pack charge process in the procedure shown in FIG.
That is, in this embodiment, when the control unit 30 receives power supply from the power circuit 38 and starts the battery pack charging process, and determines in S100 that the battery pack is connected to the battery pack charging terminal 10, In S102, it is determined whether or not the remaining capacity of secondary battery 34 is less than lower limit value C2 (for example, 0%).

  If it is determined in S102 that the remaining capacity of the secondary battery 34 is less than the lower limit C2, the fuel adjustment unit 18 cannot be driven by the output from the secondary battery 34, and the process proceeds to S104. Then, a charge request is output to the secondary battery charge control circuit 26.

As a result, the secondary battery charge control circuit 26 starts to charge the secondary battery 34 upon receiving power supply from the power tool battery pack.
In addition, when charging to the secondary battery 34 is started in this way, the process proceeds to S106, and the remaining capacity of the secondary battery 34 is set to the set value C3 (however, C3 is C1 ≧ C3 ≧ C2). (For example, 10%) or more is determined to wait for the remaining capacity of the secondary battery 34 to reach the set value C3.

  When it is determined in S106 that the remaining capacity of the secondary battery 34 has reached the set value C3, the process proceeds to S108, and the output of the charge request to the secondary battery charge control circuit 26 is stopped. Then, the charging from the battery pack to the secondary battery 34 is stopped, and thereafter, the processing after S110 is executed as in the first embodiment.

In S102, when it is determined that the remaining capacity of the secondary battery 34 is equal to or greater than the lower limit C2, the process proceeds to S110, and the processes after S110 are executed as in the first embodiment.
Thus, according to the charging device 4 of the present embodiment, even if the secondary battery 34 is completely discharged and the remaining capacity becomes zero, the secondary battery is supplied with power from the battery pack for the electric tool. 34 can be charged with electric power necessary to start the fuel cell 14.

And since the control part 30 operate | moves similarly to 2nd Embodiment after the charge, it can acquire the effect similar to 2nd Embodiment.
[Fifth Embodiment]
Next, the charging device 5 of 5th Embodiment is demonstrated.

  As shown in FIG. 8, the charging device 5 of this embodiment is similar to the charging device 2 of the second embodiment in that a power path 50 that receives power supply from the power tool battery pack, two switches SW <b> 1 and SW <b> 2 are used. And a USB power mode setting unit 46 operated by a person.

  The power supply path 50 has an output terminal (a pair of positive and negative) of DC power (charging power) to the battery pack for the electric tool at the battery pack charging terminal 10 and an input terminal (a pair of positive and negative) of the DC power in the USB output control circuit 24. By connecting, the USB device connected to the USB output terminal 12 can be supplied with power from the power tool battery pack.

  Of the two switches, one switch SW2 is provided on the positive-side (or negative-side) path that constitutes the power supply path 50, and is for conducting and blocking the path.

  The other switch SW1 is provided on the positive side (or negative side) of the pair of positive and negative paths from the secondary battery 34 to the USB output control circuit 24, and is used for conducting and blocking the path. Is.

Each of these switches SW1 and SW2 is constituted by a semiconductor switch or a relay switch.
Next, the USB power mode setting unit 46 supplies power from the secondary battery 34 in the charging device 5 to the USB device connected to the USB output terminal 12 or power from the battery pack for the electric tool. This is for the user to manually set whether to supply.

  Then, when the control unit 30 detects that the USB device is connected to the USB output terminal 12 and executes the USB device output process, the control unit 30 executes the first implementation according to the power mode set by the USB power mode setting unit 46. Whether to execute the same processing as that of the mode is switched.

  That is, in the USB device output process executed by the control unit 30 of the present embodiment, as shown in FIG. 9, first, in S310, the USB power supply mode is changed to a mode in which power is supplied from the power tool battery pack. Determine whether it is set.

  If the USB power supply mode is set to supply power from the battery pack, the process proceeds to S330, the switch SW1 is turned off and the switch SW2 is turned on. An output request is output to the control circuit 24, and the USB device output process is terminated.

  As a result, when the USB power supply mode is set to a mode in which power is supplied from the battery pack, the USB output control circuit 24 receives power supply from the power tool battery pack and supplies a voltage to the USB device. (Power supply voltage) is generated, and power is supplied from the battery pack for the electric tool to the USB device.

  On the other hand, if it is determined in S310 that the USB power supply mode is not set to a mode in which power is supplied from the battery pack (in other words, a mode in which power is supplied from the secondary battery), the process proceeds to S320. Then, the switch SW1 is turned on and the switch SW2 is turned off.

Thereafter, similarly to the USB device output process of the second embodiment shown in FIG. 4, in S200, an output request is output to the USB output control circuit 24, and the processes after S210 are executed.
As described above, according to the charging device 5 of the present embodiment, a power source for supplying power to the USB device is electrically connected from the secondary battery 34 in the charging device 5 to the battery pack charging terminal 10. It can be switched to a battery pack for tools.
[Modification]
As mentioned above, although embodiment of this invention was described, this invention is not limited to the said embodiment, In the range which does not deviate from the summary of this invention, a various aspect can be taken.

  For example, in the fifth embodiment, the charging device 5 that can supply power to the USB device from the battery pack for the electric tool by setting the operation mode by the user has been described. The power supply may be performed from the power tool battery pack by a switch operation by the user.

  In each of the above embodiments, the charging device is described as having the USB output terminal 12 for supplying power to the USB device as an output terminal different from the battery pack charging terminal 10. Alternatively, or in addition to the USB output terminal 12, another output terminal such as a cigar socket may be provided.

  In this case as well, as in the case of the USB output control circuit 24 that controls the output from the USB output terminal 12, if each output control circuit is provided for another output terminal such as a cigar socket, the above-described embodiments The same effect as the form can be obtained.

  In each of the above embodiments, the charging device that supplies power to a USB device that is an external electrical load has been described. However, for example, the charging device that supplies power to an electrical load built in the charging device can also be applied to the present invention. Can be applied.

  In this case, it is only necessary to connect the electrical load directly to the output control circuit such as the USB output control circuit 24. Therefore, there is no need to provide a connection terminal for connecting the electrical load such as the USB output terminal 12, and the device configuration Can be easy.

  1, 2, 3, 4, 5 ... charging device, 10 ... battery pack charging terminal, 12 ... USB output terminal, 14 ... fuel cell, 16 ... fuel tank, 18 ... fuel regulator, 22 ... battery pack charging control circuit, 24 ... USB output control circuit, 26 ... secondary battery charge control circuit, 30 ... control unit, 32 ... drive battery, 34 ... secondary battery, 36 ... secondary battery charge control circuit, 38 ... power supply circuit, 40 ... display unit , 42 ... AC power supply, 44 ... AC / DC converter, 46 ... USB power supply mode setting unit, 50 ... Power supply path, SW1, SW2 ... switch.

Claims (9)

A fuel cell;
A driving power source for driving the fuel cell;
A first DC output unit that receives power from the fuel cell and charges the battery pack for the electric tool;
A second DC output unit that receives power supply from the fuel cell and outputs DC power to an electric load different from the battery pack for the electric tool;
Control means for driving the fuel cell;
A charging device for an electric tool, comprising:   The charging device for an electric tool according to claim 1, wherein the second DC output unit includes a connection terminal for connecting the electric load.   The power tool charging device according to claim 1, wherein the second DC output unit has a smaller output power than the first DC output unit.   4. The electric tool charging according to claim 2, wherein the second DC output unit includes at least one of a USB terminal and a cigar socket as the connection terminal. 5. apparatus. As the driving power source,
A secondary battery that is charged with an output from the fuel cell and supplies power to the first DC output unit, the second DC output unit, and the control unit;
The control means includes
Driving the fuel cell at the time of charging the battery pack for the electric tool by the first DC output unit, or at the time of outputting DC power from the second DC output unit to the electric load,
In addition, when charging from the first DC output unit to the power tool battery pack is stopped, when the DC power is output from the second DC output unit to the electric load, Detecting a remaining capacity, driving the fuel cell if the remaining capacity is less than a predetermined threshold, and stopping driving the fuel cell if the remaining capacity is equal to or greater than the threshold. The charging device for electric tools according to any one of claims 1 to 4.   The charging device for an electric tool according to claim 5, further comprising a notification unit that notifies at least one of a remaining amount of fuel in the fuel cell and a remaining capacity of the secondary battery.   The charging device for the electric tool according to claim 5 or 6, wherein charging to the secondary battery can be performed from an external power source instead of the fuel cell.   The charging to the secondary battery can be performed from the battery pack for the electric tool connected to the first DC output unit instead of the fuel cell. The charging device for electric tools of any one of these.   The power supply path to the second DC output unit can be switched to a path from the battery pack for the electric tool connected to the first DC output unit, instead of the path from the fuel cell. The charging device for an electric tool according to any one of claims 1 to 8.

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