JP5874018B2 - Control circuit and electrical equipment for construction - Google Patents

Description

  The present invention relates to a control circuit used in a construction electrical device and a construction electrical device including the control circuit.

  2. Description of the Related Art Conventionally, construction electrical devices that perform overdischarge prevention control even when a battery pack having a different voltage is selectively attached are known. For example, the electrical equipment for construction disclosed in Patent Document 1 identifies a power supply connection unit that can selectively connect a plurality of types of battery packs having different rated output voltages and a type (rated output voltage) of the connected battery packs. Means.

International Publication WO2011 / 118475

  By the way, in the control circuit used in the construction electrical device as described above, for example, when used in a construction electrical device that uses only one type of rated output voltage (single voltage) battery pack, the power supply to this device is turned on. At each start of use, such as when or when a switch is operated, identification is performed each time. For this reason, the time for starting use is required for the time of the identification.

  Therefore, it is conceivable to use another control circuit in which the battery pack identification function is omitted for electrical equipment for construction that uses only one type of rated output voltage battery pack, but the control circuit can be shared. Can not.

  The present invention has been made in order to solve the above-mentioned problems, and its purpose is to provide a plurality of types of battery packs having different rated output voltages and electrical equipment for construction using only one type of rated output voltage battery pack. Control circuit and construction electrical equipment that can reduce the time of starting use in construction electrical equipment that uses only one type of rated output voltage battery pack while sharing circuits with available construction electrical equipment Is to provide.

In order to solve the above problems, a control circuit according to the present invention is a control circuit that receives power supply from a battery pack attached to a construction electrical device and operates a drive unit built in the construction electrical device. , in a single voltage control mode of the operation contents of the different voltage control mode of the rated output voltage of different kinds of battery pack for construction for electrical equipment available for construction for an electric apparatus for a battery pack of a single voltage A storage unit for storing the operation content , a setting unit for setting whether the construction electrical device can use a plurality of types of battery packs having different rated output voltages, or a construction electrical device for a single voltage battery pack, and a control unit that operates in the control mode to suit the construction for electrical equipment set by the setting unit, wherein different voltage control mode, determine a plurality of kinds of voltages of the battery packs having different rated output voltage Has the function of, the single voltage control mode, characterized in that it is to have no set function to determine the voltage of the battery pack of single voltage.

In Also the above configuration, the setting unit is a resistor for identification attached to the construction for electrical equipment, obtains the voltage across the resistor, by the obtained voltage across values, plural kinds of different rated output voltage It is preferable to set whether the battery pack is a construction electrical device that can be used or a single-voltage battery pack construction electrical device.

In the above configuration, the setting unit is preferably a dip switch.
Moreover, the electrical equipment for construction according to the present invention includes the control circuit having any one of the above-described configurations.

  According to the present invention, a circuit is shared between a construction electrical device using only one type of rated output voltage battery pack and a construction electrical device capable of using a plurality of types of battery packs having different rated output voltages. It is possible to provide a control circuit and a construction electrical device that can reduce the start-up time at the start of use in a construction electrical device that uses only one type of rated output voltage battery pack.

It is a schematic block diagram for demonstrating schematic structure of the electric tool in embodiment. It is a flowchart for demonstrating at the time of starting of an electric tool. It is explanatory drawing for demonstrating the difference in operation | movement of the electric tool using the control circuit of embodiment, and the electric tool using the conventional control circuit.

Hereinafter, an embodiment in which the electrical equipment for construction of the present invention is embodied in an electric tool will be described with reference to the drawings.
As shown in FIG. 1, the power tool 10 of the present embodiment includes a power tool main body 11 having a built-in motor M and a detachable battery pack 12.

  As shown in FIG. 1, the electric tool body 11 includes a motor M as a drive unit, a control circuit 21 that performs communication with the battery pack 12 and various drive controls of the electric tool body 11, and the control circuit 21 and the electric tool body 11. And a drive control unit 22 for controlling the drive (rotation speed) of the motor M.

  As shown in FIG. 1, the control circuit 21 includes a microcomputer 31, a storage unit 32, and a setting unit 33. The control circuit 21 controls the motor M via the drive control unit 22 by operating a trigger switch TS provided on the electric tool body 11 so as to be exposed to the outside so that the user can operate it.

  As shown in FIG. 1, the microcomputer 31 includes a plurality of ports through which various signals are input / output, and a storage unit 32 in which two control modes are stored in advance is connected to one port P1. The microcomputer 31 is connected to the setting port 33 for switching the two control modes to the one port P2. The setting unit 33 includes either a pull-up resistor 33a or a pull-down resistor 33b connected to the port P2 of the microcomputer 31. That is, the setting unit 33 inputs a high-level electrical signal or a low-level electrical signal to the port P2 of the microcomputer 31. The microcomputer 31 switches between two control modes, which will be described later, based on the difference in the electrical signals described above. In FIG. 1, the pull-up resistor 33a of the resistors 33a and 33b is connected, but actually, either one of the resistors 33a and 33b is connected to function as the setting unit 33.

  As shown in FIG. 1, the drive control unit 22 connected to the control circuit 21 controls the rotation speed of the motor M. The drive controller 22 controls the rotation of the motor M by turning on and off a switching element (not shown) in accordance with a signal output from the control circuit 21 and performing PWM control.

  Here, the rated output voltage is determined for the battery pack 12 that can be used in the electric power tool main body 11 configured as described above. The battery pack 12 shown in FIG. 1 is a lithium ion battery, and the voltage value per cell C is approximately 3.6 V. The rated output voltage is determined by the number of cells C. For example, one battery pack 12a in the battery pack 12 shown in FIG. 1 is configured such that four cells C are connected in series and the rated output voltage is 14.4V. Further, one battery pack 12b in the battery pack 12 shown in FIG. 1 is configured such that five cells C are connected in series and the rated output voltage is 18V.

  Each battery pack 12a, 12b includes an information storage unit 41 as shown in FIG. The information storage unit 41 outputs information on the rated output voltage of the battery packs 12a and 12b to the power tool body 11 and a charger (not shown). For this reason, it is possible to identify whether or not the battery packs 12a and 12b correspond to each other by the control circuit 21 of the electric tool main body 11.

Next, an effect | action (example of operation | movement) of the electric tool 10 provided with the control circuit 21 of this embodiment is demonstrated.
Here, the power tool body 11 can selectively use only one of the battery packs 12a and 12b, that is, a case where the rated output voltage is one type and a plurality of types of battery packs 12a and 12b having different rated output voltages. There are some cases. This is manufactured as one of the power tool main bodies 11 at the shipping stage of the power tool 10 (power tool main body 11).

[When the power tool body 11 is operated in the different voltage control mode]
When the trigger switch TS provided in the power tool body 11 is operated, the power tool 10 receives a signal for starting the operation of the control circuit 21 (step S10). Next, the microcomputer 31 of the control circuit 21 performs various initial processes associated with the activation of the power tool body 11 (step S11). Thereafter, when the setting unit 33 connected to its own port P2 is the pull-up resistor 33a, the microcomputer 31 is connected because a low-level electrical signal is input to the port P2 (step S12: YES). Whether the battery pack 12 is the battery pack 12a or 12b is identified (step S13). Thereafter, the microcomputer 31 starts the operation process of the electric power tool body 11, that is, the drive of the motor M (step S14).

[When operating the power tool body 11 in the single voltage control mode]
When the trigger switch TS provided in the power tool body 11 is operated, the power tool 10 receives a signal for starting the operation of the control circuit 21 (step S10). Next, the microcomputer 31 of the control circuit 21 performs various initial processes associated with the activation of the power tool body 11 (step S11). Thereafter, when the setting unit 33 connected to the port P2 of the microcomputer 31 is the pull-down resistor 33b, a low-level electrical signal is input to the port P2 (step S12: NO). The process S13 is omitted, and the operation process of the electric power tool body 11, that is, the drive of the motor M is started (step S14). That is, in the single voltage control mode, the battery identification process is omitted compared to the different voltage control mode and stored in the storage unit 32.

  As described above, the control circuit 21 provided in the electric power tool main body 11 of the present embodiment has an electric input to the port P2 depending on whether the setting unit 33 connected to the microcomputer 31 is the pull-up resistor 33a or the pull-down resistor 33b. Signal is changed. Then, whether to operate the power tool main body 11 in the single voltage control mode or to operate the power tool main body 11 in the different voltage control mode is set by this electrical signal.

  Here, for example, in the conventional power tool, the start-up process (step S11), the battery identification process (step S13), and the main body operation process (step S14) shown in FIGS. 2 and 3 are performed, and step S12 is performed. It is assumed that the process is not performed. In this case, the processing time t0 for performing the startup process, the battery identification process, and the main body operation process is approximately 200 milliseconds.

On the other hand, in the power tool 10 including the control circuit 21 of the present embodiment, the control mode setting process is added because the time Δt1 of the control mode setting process (step S12) is approximately 1 to 2 milliseconds. Even so, it is difficult for the user to feel the difference. Therefore, even if the pull-up resistor 33a is connected to the port P2 of the microcomputer 31 and the microcomputer 31 operates in the different voltage control mode, the processing time is only Δt1 as compared with the conventional power tool as shown in FIG. Does not increase (t2 = t0 + Δt1). If the pull-down resistor 33b is connected to the port P2 of the microcomputer 31 and the rated output voltage corresponds only to one type of battery pack 12a (12b), the microcomputer 31 operates in the single voltage control mode. As shown, the battery identification process is omitted. That is, in the single voltage control mode, the processing time t1 can be made shorter than the different voltage control mode by the battery identification processing time Δt2. Since the battery identification processing time Δt2 is longer than the setting time Δt1 in the control mode setting processing (step S 12 ) (Δt2> Δt1), the processing time t1 in the single voltage control mode is the processing of the conventional power tool. It can be made shorter than time t0.

Next, characteristic effects of the present embodiment will be described.
(1) The control circuit 21 includes a different voltage control mode for the electric tool 10 that can use the battery packs 12a and 12b having different voltages, and a single voltage control mode for the electric tool 10 for a single voltage battery pack. Is provided. In addition, the control circuit 21 includes a setting unit 33 that sets the electric tool 10 that can use the battery packs 12a and 12b with different voltages or the electric tool 10 for the battery pack 12a (12b) with a single voltage. Further, the control circuit 21 includes a microcomputer 31 as a control unit that is operated in a control mode in accordance with the electric tool 10 as a construction electric device set by the setting unit 33. By adopting such a configuration, for example, in the single voltage control mode, it is possible to omit the identification processing of the battery packs 12a and 12b which is essential in the different voltage control mode. Further, since the processing time of this identification process is longer than the control mode setting process time for confirming the control mode setting, the processing time at the start of use in the single voltage control mode can be reduced. In addition, since the configuration of the setting unit 33 is only the pull-up resistor 33a or the pull-down resistor 33b between the single voltage control mode and the different voltage control mode, the control circuit 21 can be shared. it can.

  (2) Since the different voltage control mode set in the storage unit 32 is set to have a function of determining the voltage of the battery pack in addition to the single voltage control mode, the battery pack in the single voltage control mode The function of discriminating the voltage (battery identification process) can be omitted.

  (3) The setting unit 33 is identification resistors 33a and 33b attached to the electric power tool 10. The voltage at both ends of the resistors 33a and 33b is acquired, and the electric tool main body 11 for battery packs 12a and 12b having different voltages can be used, or the electric tool main body 11 for a single voltage battery pack depending on the acquired voltage value at both ends. Is set in the microcomputer 31. With such a simple configuration, the control mode of the electric power tool main body 11 can be set.

(4) Since the setting unit 33 is configured to connect only one of the resistors 33a and 33b, an increase in the number of resistors, that is, the number of components can be suppressed.
In addition, you may change embodiment of this invention as follows.

  In the above embodiment, either the resistor 33a or the resistor 33b is connected to input a high level signal or a low level signal to a certain port P2 of the microcomputer 31. However, the present invention is not limited to this. . For example, a resistor 33a and a resistor 33b are connected in advance to the port P2 of the microcomputer 31, and one resistor and the microcomputer 31 are disconnected, so that the other resistor is connected to the microcomputer 31 and a high level signal is connected. Or a low level signal may be input.

Further, the setting unit 33 may be configured by providing a DIP switch and inputting a high level signal or a low level signal to the microcomputer 31.
In the above embodiment, the electric tool is used as the construction electric device, but the electric tool includes a drill driver, an impact driver, an impact wrench, a hammer drill, a vibration drill, a jigsaw, a sealing gun, a circular saw, and the like.

  -In the above-mentioned embodiment, although the electric tool was employ | adopted as an electrical equipment for construction, it is not restricted to this. For example, construction lights and construction vacuum cleaners (cleaners and blowers) are included.

  DESCRIPTION OF SYMBOLS 10 ... Electric tool as construction electrical equipment, 12, 12a, 12b ... Battery pack, 21 ... Control circuit, 32 ... Memory | storage part, 33 ... Setting part, 33a, 33b ... Resistance which comprises a setting part.

Claims (4)

A control circuit for operating a drive unit built in the electrical equipment for construction by receiving power supply from a battery pack attached to the electrical equipment for construction,
And operation contents of different voltage control mode of the rated output voltage different for plural kinds of battery pack for an electric apparatus which can work available, operating in a single voltage control mode for the construction for electrical equipment for battery pack single voltage A storage unit for storing contents ;
A setting unit for setting whether the construction electrical equipment can use a plurality of types of battery packs having different rated output voltages or the construction electrical equipment for a single voltage battery pack;
A control unit that operates in a control mode according to the electrical equipment for construction set in the setting unit;
Equipped with a,
The different voltage control mode has a function of discriminating voltages of a plurality of types of battery packs having different rated output voltages, and the single voltage control mode has no function of discriminating a voltage of a single voltage battery pack. A control circuit characterized by being set . The control circuit according to claim 1 ,
The setting unit is an identification resistor attached to the construction electrical device,
Obtain the voltage at both ends of the resistor, and depending on the obtained voltage value at both ends, whether it is a construction electrical device that can use multiple types of battery packs with different rated output voltages, or a construction electrical device for a single voltage battery pack A control circuit characterized by setting. The control circuit according to claim 1 ,
The control circuit, wherein the setting unit is a dip switch. Electrical equipment for construction comprising the control circuit according to any one of claims 1 to 3 .