JP3783573B2 - DC power supply with charging function - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a DC power supply device with a charging function that supplies a DC voltage via a cable having an adapter that can be attached to and detached from a cordless tool such as a cordless electric tool that uses a detachable battery pack as a power source and charges the battery pack. Is. Hereinafter, for convenience of explanation, the cordless tool will be described as being a cordless power tool (hereinafter simply referred to as a power tool).
[0002]
[Prior art]
The power tool has the advantage of being able to work in any place without any power cable restrictions, but if the battery pack capacity drops, the battery pack can be recharged or another charged battery pack. There was a problem that had to be replaced. Therefore, if the work place is close to the AC power supply installation location and there is little movement during work, use a DC power supply device that converts AC to DC, and if the work place is far from the AC power supply installation place and there is much movement during work A battery pack was used, and a battery pack and a DC power source were used in combination as the power source of the electric tool according to the work situation.
[0003]
However, there is a problem that efficient work cannot be performed unless a charger and a DC power supply are brought into the work place. In order to solve this problem, in Japanese Patent Laid-Open No. 2000-184614, when the operation of the electric tool is detected, the DC power is supplied without charging when the electric tool is operating, and the operation of the electric tool is stopped. We proposed a DC power supply with a charging function to charge the battery pack.
[0004]
[Problems to be solved by the invention]
In Japanese Patent Laid-Open No. 2000-184614, when the power switch of the electric tool is turned on while the battery pack is being charged, the microcomputer outputs a signal to turn off the DC-DC converter that is the power supply and temporarily turns off the DC-DC converter. When the power switch of the power tool is turned on during charging of the battery pack, the switch for switching between charging or power supply is switched from the charging side to the power tool driving side, and then the DC-DC converter is turned on again. The electric tool cannot be driven instantaneously, giving the user a sense of incongruity. This is because the DC-DC converter is turned off and then turned on again, and switching between charging and power supply is performed by one switch.
[0005]
The object of the present invention is to eliminate the drawbacks of the prior art described above, and when the power switch of the power tool is turned on during charging of the battery pack, the charging is instantaneously stopped and switched to power supply to the power tool, It is to provide a DC power supply device with a charging function that does not give a sense of incongruity to a user.
[0006]
[Means for Solving the Problems]
The object is to provide a trigger detection means for outputting a charging non-permission signal and a permission signal for permitting power supply to the power tool at the moment when the power switch of the power tool is detected, and to enable power supply to be supplied to the power tool. A power supply output switch circuit, a power supply output switching means having a charge output switch circuit that enables charging of the battery pack, a charge current control circuit that controls a charge current to the battery pack, and a supply voltage to the power tool are controlled. And a power supply output control means having a drive voltage control circuit that performs the switching from charging to power supply instantaneously based on the output of the trigger detection means when the power switch is turned on during charging. .
[0007]
DETAILED DESCRIPTION OF THE INVENTION
FIG. 1 is a perspective view showing an embodiment of a DC power supply device with a charging function according to the present invention. 1 is an AC cord set, 2 is a DC power supply main body with a charging function (hereinafter simply referred to as a power supply main body), 3 is an adapter set, an adapter plug connected to the electric tool 4 at one end, and a DC power supply main body 2 at the other end And an output cable connected to the. The upper part of the adapter plug has the same shape as the insertion part of the battery pack 5 and can be attached to and detached from the electric tool 4 in the same manner as the battery pack 5.
[0008]
FIG. 2 is a block diagram showing an embodiment of a DC power supply device with a charging function. The AC cord set 1 is connected to an AC 100V commercial AC power source. Reference numeral 2 denotes a power supply device body, and the adapter set 3 includes output voltage setting means 3a for outputting a voltage corresponding to each rated voltage to a plurality of power tools 4. The electric power tool 4 includes a DC motor 4a and a power switch 4b connected in series. When the power switch 4b is turned on, DC power is supplied from the power supply device body 2 via the adapter set 3. A battery pack 5 that can be attached to the electric tool 4 includes a rechargeable storage battery 5a and a temperature element 5b (for example, a thermistor) that is attached in the vicinity of or in contact with the storage battery 5a.
[0009]
The switching power supply 10 includes a first rectifying / smoothing circuit 11, a high-frequency transformer 12, a second rectifying / smoothing circuit 13, a switching element 14, a switching control circuit 15 and the like. The switching control circuit 15 changes the drive pulse width of the switching element 14. The output voltage and output current of the second rectifying / smoothing circuit 13 are adjusted.
[0010]
The power output control means 20 controls the drive voltage of the electric tool 4 when the power switch 4b is turned on, and controls the charging current when the battery pack 5 can be charged when the power switch 4b is turned off. And a voltage / current setting circuit 22 for setting values of the driving voltage and the charging current. When the power tool 4 is driven, the switching control circuit 15 is fed back based on the signal from the voltage detection circuit 42 to control the switching duty of the switching element 14, and at the same time, the adapter assembly is set based on the signal from the output current detection circuit 41. 3 has a function of correcting a voltage drop in the cable 3. Further, when the battery pack 5 can be charged when the power switch 4b is turned off, feedback is given to the switching control circuit 15 based on a signal from the output current detection circuit 41, and the switching duty of the switching element 14 is controlled. 5 is controlled based on the output of the battery state detecting means 50.
[0011]
The power output switching means 30 includes a power output switch circuit 31 that can supply power output to the power tool 4 when the power switch 4b is turned on, and a charge output switch that enables charging of the battery pack 5 when the power tool 4 is not used. The circuit 32 is configured.
[0012]
The power output detection means 40 includes an output current detection circuit 41 for detecting a current supplied to the electric tool 4 when the power switch 4b is turned on or a charging current supplied to the battery pack 5 when the power switch 4b is turned off. A voltage detection circuit 42 that detects the output voltage of the circuit 13, a trigger detection circuit that detects that the power switch 4 b is turned on and outputs a charging non-permission signal and a signal that permits power supply to the power tool 4 at that moment. 43, an output voltage setting detection circuit 44 for detecting the set voltage of the output voltage setting means 3a of the adapter set 3 and the like.
[0013]
The battery state detection means 50 includes a battery voltage detection circuit 51 that detects the battery voltage of the storage battery 5a, and a battery temperature detection circuit 52 that detects the battery temperature in accordance with the characteristics of the temperature element 5b in the battery pack 5.
[0014]
The microcomputer 60 constituting the control means of the present invention sets the drive voltage of the electric tool 4 and the battery pack 5 when the electric tool 4 is not used based on the output of the power output detection means 40 and the output of the battery state detection means 50. When the electric power tool 4 is not used, that is, whether or not charging is possible is determined based on the power switch 4b being turned off and the output of the battery state detecting means 50, and the battery pack 5 can be charged. Has a function of outputting a charge permission signal to the charge output switch circuit 32 via the trigger detection circuit 43.
[0015]
For example, the display circuit 70 constituted by an LED or the like displays, based on the output of the microcomputer 60, an indication as to whether or not the electric power tool 4 is in use or usable, or that the battery pack 5 is being charged. The auxiliary power supply circuit 80 supplies the reference voltage Vcc to the power supply and power supply output control means 20, the power supply output detection means 40, the battery state detection means 50, etc. of the microcomputer 60 and the like.
[0016]
Next, when the power switch 4b is turned on while the battery pack 5 is being charged, the operation for instantaneously stopping the charging and switching the power supply to the power tool 4 will be described with reference to FIG.
[0017]
The voltage / current control circuit 21 includes a drive voltage control circuit 21a for controlling the drive voltage of the electric tool 4, charging current control means 21b for controlling a charging current supplied to the storage battery 5a, and a predetermined drive voltage and charge for the switching control circuit 15. It is composed of a photocoupler 21c, diodes 21d and 21e, digital transistors 21f and 21g, which are transmission means for applying feedback to control the current, an inverter 21h that inverts a signal from the charge output switch circuit 32, and the like.
[0018]
The charge output switch circuit 32 turns on and off the charging current supplied to the storage battery 5a, the digital transistor 32b that drives the relay 32a, the trigger detection circuit 43, and the AND circuit 32c that permits charging by the logical sum of the output signals of the microcomputer 60. , And an inverter 32d for inverting the output signal of the trigger detection circuit 43.
[0019]
The output current detection circuit 41 includes a shunt resistor 41 a and a current detection circuit 41 b that amplifies the output of the shunt resistor 41 a and inputs the current value to the microcomputer 60.
[0020]
The trigger detection circuit 43 includes a comparator 43a, resistors 43b to 43k, a diode 43l, a digital transistor 43m, and the like. The trigger detection circuit 43 is configured such that the output of the comparator 43a becomes a logical value 1 when the power switch 4b is turned on. Specifically, when the power tool 4 is not used, that is, when the power switch 4b is OFF, the voltage obtained by dividing the output voltage Vout of the second rectifying and smoothing circuit 13 by the resistors 43b and 43c is applied to the inverting input terminal of the comparator 43a. The voltage obtained by dividing the output voltage Vout of the second rectifying / smoothing circuit 13 by the resistors 43j and 43k is further applied to the non-inverting input terminal of the comparator 43a by the resistors 43d and 43e. At this time, the resistors 43b The resistance values of .about.43e are set so that the output of the comparator 43a becomes a logical value of zero. When the power switch 4b is on, the DC resistance of the DC motor 4a is very small (about several ohms) compared to the resistor 43j, so the voltage applied to the non-inverting input terminal of the comparator 43a is The output voltage Vout is divided by the resistors 43d and 43e, and the output of the comparator 43a becomes a logical value 1, thereby determining that the power switch 4b is turned on. The voltage dividing ratio of the resistors 43d and 43e is set to be larger than the voltage dividing ratio of the resistors 43b and 43c. As a result, the comparator 43a outputs a logical value 1. When the output of the comparator 43a becomes the logical value 1, that is, when the power switch 4b is turned on, the output of the comparator 43a is fed back to the non-inverting input terminal via the diode 43l and the resistor 43h, and the output of the comparator 43a is the logical value. The power output switch circuit 31 composed of an FET is always turned on and the driving of the power tool 4 is maintained.
[0021]
When the power tool 4 is changed from being used to being unused, and then the storage battery 5a is switched to charging, the microcomputer 60 detects that the power tool 4 is not used from the output of the current detection circuit 41b, and the trigger transistor 43 has a digital transistor 43m. This is performed by outputting a signal of logical value 1 applied to the base of the comparator 43a and releasing the latch operation of the comparator 43a. When the latch operation is released, the output of the comparator 43a becomes a logical value 0, the power output switch circuit 31 is turned off, and the power supply to the power tool 4 is prohibited. On the other hand, a signal of logical value 1 is applied to one input terminal of the AND circuit 32c of the charging output switch circuit 32 via the inverter 32d, and a charging permission signal of logical value 1 is sent from the microcomputer 60 to the other input terminal of the AND circuit 32c. When applied to the input terminal, the AND circuit 32c generates an output of logical value 1, so that the relay 32a is turned on via the digital transistor 32b, and the charging current is supplied to the storage battery 5a.
[0022]
When this charging is permitted, a signal having a logical value 1 of the AND circuit 32c is supplied to the drive voltage control circuit 21a that controls the drive voltage of the electric tool 4 by turning on the digital transistor 21g via the inverter 21h of the voltage / current control circuit 21. Make inoperable. At the same time, the digital transistor 21f of the voltage / current control circuit 21 is turned off, and the charge current control means 21b can be operated to control the charge current.
[0023]
Contrary to the above, when the power switch 4b of the power tool 4 is turned on during charging, the output of the comparator 43a becomes a logical value 1 as described above, and one input terminal of the AND circuit 32c of the charge output switch circuit 32 Since a signal having a logical value of 0 is applied to the AND circuit 32c, the output of the AND circuit 32c becomes a logical value of 0 even if a charge permission signal having a logical value of 1 is generated from the microcomputer 60, the digital transistor 32b is turned off, and the relay 32a Is also turned off, and the supply of the charging current to the storage battery 5a is cut off.
[0024]
In addition, when the power switch 4b of the electric tool 4 is turned on during this charging, the logical value 0 signal of the AND circuit 32c turns off the digital transistor 21g via the inverter 21h of the voltage / current control circuit 21, thereby The drive voltage control circuit 21a for controlling the drive voltage of the tool 4 is enabled, while the digital transistor 21f of the voltage / current control circuit 21 is turned off to disable the charge current control means 21b.
[0025]
According to the above-described embodiment, when the power switch 4b of the electric tool 4 is turned on even when the battery pack 5 is being charged, the user can instantaneously supply DC power to the electric tool 4, so that the user can The power tool can be used without a sense of incongruity, and the usability of the power tool can be improved.
[0026]
【The invention's effect】
As described above, according to the present invention, in the power supply device with a charging function that can supply the DC power to the electric tool without charging the battery pack when the electric tool is operated and can charge the battery pack when the electric tool is not used. If the power switch of the power tool is turned on while the battery pack is being charged, the charging is stopped instantaneously and the power supply is switched to the power tool, thus providing a DC power supply with a charging function that does not give the user a sense of incongruity can do.
[Brief description of the drawings]
FIG. 1 is a perspective view showing an embodiment of a DC power supply device with a charging function according to the present invention.
FIG. 2 is a block circuit diagram showing an embodiment of a DC power supply device with a charging function according to the present invention.
FIG. 3 is a block circuit diagram showing an example of the switch operation detecting means of the present invention shown in FIG. 2;
[Explanation of symbols]
2 is a DC power supply main body, 3 is an adapter set, 4 is an electric tool, 5 is a battery pack, 10 is a switching power supply, 20 is a power output control means, 30 is a power output switching means, 40 is a power output detection means, and 43 is A trigger detection circuit, 50 is a battery state detection means, and 60 is a microcomputer.

Claims (5)

A cordless tool that has a power switch and is driven by using a detachable battery pack as a power source, and a DC that has a battery pack insertion slot into which a battery pack to be charged is inserted after the input AC is converted into a direct current and output. A battery pack comprising: a power supply main body; and an adapter that can be attached to and detached from the cordless tool through an insertion portion having the same shape as the tool insertion portion of the battery pack, and that is supplied with the output of the DC power supply main body to be a power source for the cordless tool Or a DC power supply device with a charging function that selectively performs DC power supply to the cordless tool via an adapter,
Power supply output control means for controlling the output of the DC power supply main body in response to power supply to the cordless tool and charging to the battery pack; and power supply output switching means for switching power supply to the cordless tool or charging to the battery pack. A DC power supply device with a charging function, comprising: a trigger detection means for outputting a charging non-permission signal and a signal for permitting power supply to the cordless tool at the moment when the power switch on of the cordless tool is detected. 2. The charging function according to claim 1, wherein the power output switching means comprises a power output switch circuit that enables power supply to be supplied to the cordless tool and a charge output switch circuit that enables charging of the battery pack. DC power supply with 3. The charging function according to claim 2, wherein the trigger detection means outputs a signal for turning on the power output switch circuit and a signal for turning off the charge output switch circuit when the power switch of the cordless tool is turned on. DC power supply with The power supply output control means includes a voltage / current control circuit for controlling the output voltage and output current of the DC power supply main body, and the voltage / current control circuit includes a charging current control circuit for controlling the charging current to the battery pack, and a cordless A drive voltage control circuit that controls the supply voltage to the tool, and based on the output of the charge output switch circuit, the charge current control circuit is switched to the drive voltage control circuit when using the cordless tool, and the charge current control circuit is switched when using the cordless tool. The DC power supply device with a charging function according to claim 2 or 3. A cordless tool that has a power switch and is driven by using a detachable battery pack as a power source, and a DC that has a battery pack insertion slot into which a battery pack to be charged is inserted after the input AC is converted into a direct current and output. A battery pack comprising: a power supply main body; and an adapter that can be attached to and detached from the cordless tool through an insertion portion having the same shape as the tool insertion portion of the battery pack, and that is supplied with the output of the DC power supply main body to be a power source for the cordless tool Or a DC power supply device with a charging function that selectively performs DC power supply to the cordless tool via an adapter,
Power supply output control means for controlling the output of the DC power supply unit in response to power supply to the cordless tool or charging to the battery pack, and power supply output switching means for switching power supply to the cordless tool or charging to the battery pack, respectively Battery state detection means for detecting the state of the battery pack, trigger detection means for detecting the power switch on of the cordless tool, output current detection means for detecting the output current of the DC power supply main body, output current detection means, A DC power supply with a charging function, comprising: control means for switching to charging the battery pack when the cordless tool is not used, based on the output of the battery state detecting means.

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