JP2023120798A - electric work machine - Google Patents

Abstract

To provide an electric work machine capable of suppressing data stored therein from disappearing.SOLUTION: An electric work machine according to one embodiment in the disclosure comprises a motor, a storing part and a control part. The control part makes the storing part store data related to the work machine. According to setting operation performed by a user of the electric work machine, the control part selectively sets the control part into a permission mode in which the storing part is permitted to overwrite data on the data related to the work machine or into a prohibition mode in which the storing part is prohibited from overwriting data on the data related to the work machine. In the case that the control part is set in the permission mode, the control part drives the motor in accordance with driving operation that is performs by the user in order to drive the motor. In the case that the control part is set in the prohibition mode, the control part prohibits the motor from being driven when data amounts of the data related to the work machine stored in the storing part reach a prohibition determination value.SELECTED DRAWING: Figure 2

Description

The present disclosure relates to an electric working machine.

Patent Literature 1 discloses an electric working machine configured to store various types of history information related to the electric working machine in a nonvolatile memory mounted on a control circuit board housed in the electric working machine.

JP 2017-213615 A

When a large amount of history information is accumulated in the non-volatile memory and the storage area of the non-volatile memory runs out, by overwriting the old history information stored in the non-volatile memory with new history information, Recent history information can be retained. However, if the history information is overwritten in this manner, all history information cannot be retained.

An object of one aspect of the present disclosure is to suppress loss of data stored in an electric working machine.

An electric working machine according to one aspect of the present disclosure includes a motor, a storage section, and a control section. The storage unit stores data.
The control unit executes data storage processing, mode setting processing, drive permission processing, and drive prohibition processing.

In the data storage process, the control unit causes the storage unit to store working machine-related data that is related to the electric working machine and is set in advance as data to be stored in the storage unit.
In the mode setting process, the control unit sets the control unit to a permission mode that permits overwriting of work machine-related data in the storage unit, or a work machine-related Selectively set prohibit mode to prohibit overwriting of data.

In the drive permission process, the control unit drives the motor according to the driving operation performed by the user to drive the motor when the control unit is set to the permission mode.

In the drive prohibition process, when the control unit is set to the prohibition mode and the data amount of the working machine-related data stored in the storage unit reaches a preset prohibition determination value, Prohibit motor drive.

In such an electric working machine, when the amount of work machine-related data stored in the storage unit becomes large, the driving of the motor is prohibited, and the work machine-related data generated due to the driving of the motor is prevented. can be prevented from being newly created. Therefore, the electric working machine described above can prevent the working machine-related data already stored in the storage unit from being overwritten by the newly generated working machine-related data and disappearing.

Further, the above-described electric working machine can drive the motor according to the driving operation when the control unit is set to the permission mode. Therefore, the electric working machine described above allows the user to select to continue the work by operating the electric working machine even if the working machine-related data stored in the storage unit is overwritten.

1 is a perspective view of an electric working machine; FIG. FIG. 3 is a block diagram showing electrical configurations of an electric working machine and an external terminal; 4 is a flowchart showing mode setting processing; 4 is a flowchart showing motor control processing; 6 is a flowchart showing a fastening data saving process; FIG. 10 is a diagram showing a state change of a fastening data storage area due to writing of fastening data; 9 is a flowchart showing a conclusion data transfer process; FIG. 10 is a diagram showing a state change of a conclusion data storage area due to transfer of the conclusion data;

[Summary of embodiment]
An electric working machine in one embodiment may include a motor. Additionally/or, the electric operating machine may include a storage unit. The storage unit may be configured to store data. Additionally/or, the electric operating machine may include a control unit. The controller may be configured to perform data storage operations. In the data storage process, the control unit may cause the storage unit to store work machine-related data that is related to the electric work machine and is set in advance as data to be stored in the storage unit. Additionally/or alternatively, the controller may be configured to perform a mode setting process. In the mode setting process, the control unit sets the control unit to a permission mode for permitting overwriting of the work implement-related data in the storage unit, or to a permission mode for allowing the work implement-related data to be overwritten in the storage unit, based on a setting operation by the user of the electric work machine. You may selectively set to the prohibition mode which prohibits overwriting of . Additionally/or, the control unit may be configured to perform a drive permission process. In the drive permission process, the control unit may drive the motor in accordance with a driving operation performed by the user to drive the motor when the control unit is set to the permission mode. Additionally/or, the controller may be configured to perform a drive prohibition process. In the drive prohibition process, when the control unit is set to the prohibition mode and the data amount of the working machine-related data stored in the storage unit reaches a preset prohibition determination value, Motor driving may be prohibited.

If an electric working machine in an embodiment includes the above motor, the above control unit, and the above storage unit, such an electric working machine can store work machine-related data already stored in the storage unit. can be suppressed from being overwritten and lost by newly generated working machine-related data.

Additionally/or alternatively, the controller may be further configured to perform a data transfer process. In the data transfer process, the work machine-related data stored in the storage unit is transferred to an external terminal connected to the control unit, and then, in the storage unit, a storage area in which the transferred work machine-related data is stored. can be overwritten. Such an electric working machine can store old work machine-related data in the external terminal, and furthermore, can secure a storage area for storing new work machine-related data in the storage unit.

Additionally/or, the prohibition determination value may be set to be smaller than the amount of data that the storage unit can store work implement related data. In such an electric work machine, even when the prohibition mode is set to prohibit overwriting of the work machine-related data, it is possible to write data to a storage area in which the work machine-related data is not stored. Become.

Additionally/or alternatively, the controller may include a motor control circuit and a communication circuit, the motor control circuit and the communication circuit configured to be in data communication with each other. In such an electric working machine, the motor control circuit can be arranged at a location suitable for motor control, and the communication circuit can be arranged at a location suitable for communication.

Additionally/or alternatively, the communications circuitry may comprise a communications controller configured to perform data storage operations. Such an electric working machine can reduce the processing load of the motor control circuit.

Additionally/or, the communication control unit may comprise a microcomputer, and the storage unit may be provided outside the microcomputer. Such an electric working machine can store working machine-related data in addition to the memory provided in the microcomputer, increasing the amount of work machine-related data that can be stored in the electric working machine. can be made

Additionally/or, the control unit is connected to a wireless communication unit configured to perform wireless data communication with the external terminal and/or a wired communication unit configured to perform wired data communication with the external terminal. may be Additionally/or, the control unit may be configured to transfer work implement-related data from the wireless communication unit connected to the control unit and/or the wired communication unit connected to the control unit to the external terminal. .

In addition/or, in the mode setting process, the control unit switches the control unit to the permission mode or the prohibition mode based on the setting operation performed by the user on the external terminal connected to the control unit for data communication. can be selectively set to With such an electric working machine, it is possible to perform a setting operation while transferring the working machine-related data to the external terminal, so that convenience for the user can be improved.

In some embodiments, the above features may be combined in any combination. In some embodiments, any of the above features may be excluded.
[Specific exemplary embodiments]
Exemplary embodiments of the present disclosure are described below in conjunction with the drawings.

As shown in FIG. 1, the electric working machine 1 of this embodiment is in the form of a battery-driven angle screwdriver that rotates a fastening part (for example, a screw) to fasten it to a work object. In another embodiment, electric work machine 1 may be in the form of any corded or battery-powered electric work machine other than a battery-powered angle screwdriver. Examples of such electric working machines include electric hammers, electric hammer drills, electric drills, electric drivers, electric wrenches, electric grinders, electric circular saws, electric reciprocating saws, electric jigsaws, electric cutters, electric chainsaws, electric planes, and electric nailers. (including tackers), electric hedge trimmers, electric lawn mowers, electric lawn clippers, electric brush cutters, electric cleaners, electric blowers, electric sprayers, electric spreaders, and electric dust collectors.

The electric working machine 1 includes an elongated body 2, an angle head 3 detachably attached to a first longitudinal end of the body 2, and a battery detachably attached to a second longitudinal end of the body 2. A pack 4 is provided.

The main body 2 is formed in a hollow cylindrical shape, and sequentially from the first end in the longitudinal direction of the main body 2, there is a motor housing portion 2a for housing a motor 11, which will be described later, and a grip portion for a user to grip. 2b and a battery mounting portion 2c for mounting the battery pack 4 thereon.

The grip portion 2b of the main body 2 is thinner than the motor housing portion 2a and the battery mounting portion 2c, and is formed to have a thickness that is easy for the user to grip.
The battery mounting portion 2c of the main body 2 is formed so that the battery pack 4 is detachably mounted on the side opposite to the side to which the grip portion 2b is connected.

The angle head 3 has a tool mounting portion 3a at the end opposite to the side on which the main body 2 is attached.
The tool mounting portion 3a has an output shaft to which a tip tool (not shown) is mounted. The rotation axis of the output shaft is perpendicular to the rotation axis of the motor 11 . That is, the angle head 3 converts the rotation of the motor 11 in an axial direction different from the rotation axis of the motor 11 via a gear mechanism provided inside the angle head 3, thereby rotating the output shaft of the tool mounting portion 3a. to

On the side of the motor housing portion 2a in the grip portion 2b, there are provided a trigger 5 operated when the user drives the electric working machine 1, and a forward switch for switching the rotation direction of the motor 11 between the forward direction and the reverse direction. A reverse switch 6 is provided. The trigger 5 is formed so that the user can pull it with a finger while gripping the grip portion 2b.

The battery mounting portion 2c is provided with a communication connector 7 for connecting an external terminal such as a personal computer via a communication cable.
As shown in FIG. 2 , electric working machine 1 includes motor 11 , motor control circuit 12 , communication circuit 13 , connector 14 , rotation sensor 15 , torque sensor 16 , and trigger switch 17 .

The motor 11 is in the form of a three-phase brushless motor in this embodiment.
The motor control circuit 12 includes a motor control section 21 , a regulator 22 , a motor drive section 23 and a current detection section 24 .

The motor control unit 21 includes a microcomputer 21d including a CPU 21a, a ROM 21b, a RAM 21c, and the like in this embodiment. Various functions of the microcomputer 21d are realized by the CPU 21a executing a program stored in a non-transitional substantive recording medium. In this example, the ROM 21b corresponds to the non-transitional substantive recording medium storing the program. Also, by executing this program, a method corresponding to the program is executed. Some or all of the functions executed by the CPU 21a may be achieved by one or more electronic components such as ICs. Also, the motor controller 21 may comprise one or more microcomputers. Motor controller 21 may be in the form of a logic circuit including a plurality of electronic components. In this case, the motor controller 21 may comprise an application specific integrated circuit (ASIC) and/or an application specific standard product (ASSP) or the like. Alternatively, the motor control section 21 may have a programmable logic device capable of constructing an arbitrary logic circuit. Examples of programmable logic devices include field programmable gate arrays (FPGAs).

The regulator 22 receives power from the battery pack 4 , generates a power supply voltage (for example, 5 V) for operating the motor control section 21 , and supplies the power supply voltage to the motor control section 21 .

The motor drive unit 23 is a circuit for receiving power supply from the battery pack 4 and applying current to each phase winding of the motor 11 . In this embodiment, the motor driving section 23 is in the form of a three-phase full bridge circuit including six switching elements (not shown).

The current detection unit 24 detects the value of the current flowing through the motor 11 and outputs a current detection signal indicating the detected current value to the motor control unit 21 .
The communication circuit 13 includes a communication control section 31 , a regulator 32 , a nonvolatile memory 33 , an operation section 34 , a wireless communication section 35 , a wired communication section 36 and a notification section 37 .

The communication control unit 31 includes a microcomputer 31d including a CPU 31a, a ROM 31b, a RAM 31c, and the like in this embodiment. Various functions of the microcomputer 31d are realized by the CPU 31a executing a program stored in a non-transitional substantive recording medium. In this example, the ROM 31b corresponds to the non-transitional substantive recording medium storing the program. Also, by executing this program, a method corresponding to the program is executed. Some or all of the functions executed by the CPU 31a may be achieved by one or more electronic components such as ICs. Also, the communication control unit 31 may include one or more microcomputers. The communication control unit 31 may be in the form of a logic circuit including multiple electronic components. In this case, the communication control unit 31 may include an ASIC and/or ASSP. Alternatively, the communication control section 31 may have a programmable logic device capable of constructing an arbitrary logic circuit. Examples of programmable logic devices include FPGAs.

The regulator 32 receives power supply from the regulator 22 to generate a power supply voltage (for example, 3.3 V) for operating the communication control unit 31, Supply power voltage.

The nonvolatile memory 33 is rewritable and retains stored data even when power is not supplied.
The operation unit 34 is a switch operated by the user to switch the lock mode, which will be described later, between an ON state and an OFF state. The operation unit 34 outputs a mode-on signal when switched to the on state by the user's operation, and outputs a mode-off signal when switched to the off state by the user's operation.

The wireless communication unit 35 performs data communication with an external terminal 100, which will be described later, by short-range wireless communication (for example, wireless communication based on the Wi-Fi standard). Wi-Fi is a registered trademark. Note that the wireless communication unit 35 may perform data communication with the external terminal 100 by wireless communication based on the Bluetooth standard, wireless communication based on the NFC standard, or the like. Bluetooth is a registered trademark. NFC is an abbreviation for Near Field Communication.

The wired communication unit 36 performs data communication with the external terminal 100 via a communication cable (for example, a USB cable) connected to the communication connector 7 . USB is an abbreviation for Universal Serial Bus.

The notification unit 37 has at least one LED. The notification unit 37 notifies whether the lock mode is on or off by turning on or off at least one LED.

The connector 14 communicates with the motor control circuit 12 so that power supply voltage is supplied from the regulator 22 to the regulator 32 and data can be transmitted and received between the motor control unit 21 and the communication control unit 31. It connects with the circuit 13 .

Rotation sensor 15 detects the rotation position and rotation speed of motor 11 and outputs a rotation detection signal indicating the detection result to motor control unit 21 .
The torque sensor 16 is installed in the angle head 3 between the motor 11 and the tool mounting portion 3a. The torque sensor 16 detects the torque applied to the output shaft of the tool mounting portion 3a and outputs a torque detection signal indicating the detection result to the motor control portion 21 .

The trigger switch 17 is configured to be turned on or off according to the pulling operation of the trigger 5 and to change the resistance value according to the amount of operation of the trigger 5 .
Examples of the external terminal 100 include personal computers, smart phones, and tablets. The external terminal 100 may be a dedicated terminal for the electric working machine 1 .

The external terminal 100 includes a terminal control section 101 , a display section 102 , an operation section 103 , a wireless communication section 104 and a wired communication section 105 .
Terminal control unit 101 executes various processes based on inputs from operation unit 103 , wireless communication unit 104 and wired communication unit 105 , and controls display unit 102 , wireless communication unit 104 and wired communication unit 105 .

The display unit 102 displays various images on the display screen.
The operation unit 103 is a device for inputting a command by an external operation from the user. Operation unit 103 outputs, to terminal control unit 101, a mode-on signal indicating that a lock mode ON operation, which is set in advance to set the lock mode to an ON state, is performed on operation unit 103. . Operation unit 103 outputs a mode-off signal to terminal control unit 101 when a preset lock mode off operation for setting the lock mode to the off state is performed on operation unit 103 .

The wireless communication unit 104 performs data communication with the wireless communication unit 35 of the electric working machine 1 by short-range wireless communication.
The wired communication unit 105 performs data communication with the wired communication unit 36 of the electric working machine 1 via a communication cable.

When a mode-on signal is input from operation unit 103 , terminal control unit 101 transmits a mode-on command to communication circuit 13 of electric working machine 1 via wireless communication unit 104 and wired communication unit 105 . Further, when a mode-off signal is input from operation unit 103 , terminal control unit 101 transmits a mode-off command to communication circuit 13 of electric working machine 1 via wireless communication unit 104 and wired communication unit 105 .

When the user pulls the trigger 5 , the motor control unit 21 of the electric working machine 1 controls the current supplied from the motor driving unit 23 to the motor 11 according to the operation amount of the trigger 5 , and also controls the forward/reverse switch 6 . The direction of rotation of the motor 11 is controlled according to the switching state. Therefore, the user can perform the fastening operation by pulling the trigger 5 while fitting the tip tool attached to the tool attachment portion 3a to the fastening part.

When the torque detection value indicated by the torque detection signal reaches the set value while the motor 11 is being driven, the motor control unit 21 determines that the fastening of the fastening parts is completed, and stops driving the motor 11 .

Next, a procedure of mode setting processing executed by the communication control unit 31 of the communication circuit 13 will be described. The mode setting process is repeatedly executed while the communication control unit 31 is operating.
As shown in FIG. 3, when the mode setting process is executed, the CPU 31a of the communication control unit 31 first performs an operation to switch the lock mode from the off state to the on state (hereinafter referred to as lock mode on switching operation) in S10. determine whether it has been done. Specifically, the CPU 31a performs the lock mode ON switching operation when the state in which the operation unit 34 outputs the mode OFF signal changes to the state in which the operation unit 34 outputs the mode ON signal. I judge.

Here, if the lock mode ON switching operation has not been performed, the CPU 31a proceeds to S30. On the other hand, when the lock mode ON switching operation is performed, the CPU 31a sets the lock mode flag F_LOCK provided in the RAM 31c in S20, and proceeds to S30. Note that setting a flag indicates setting the value of the flag to 1, and clearing the flag indicates setting the value of the flag to 0.

After shifting to S30, the CPU 31a determines whether or not an operation for switching the lock mode from the ON state to the OFF state (hereinafter referred to as lock mode OFF switching operation) has been performed. Specifically, the CPU 31a performs the lock mode off switching operation when the state in which the operation unit 34 outputs the mode-on signal changes to the state in which the operation unit 34 outputs the mode-off signal. I judge.

Here, if the lock mode off switching operation has not been performed, the CPU 31a proceeds to S50. On the other hand, when the lock mode OFF switching operation is performed, the CPU 31a clears the lock mode flag F_LOCK in S40, and proceeds to S50.

After shifting to S<b>50 , the CPU 31 a determines whether or not a mode-on command has been received from the external terminal 100 . Here, when the mode-on command is not received, the CPU 31a proceeds to S70. On the other hand, when the mode-on command is received, the CPU 31a sets the lock mode flag F_LOCK in S60, and proceeds to S70.

After shifting to S<b>70 , the CPU 31 a determines whether or not a mode-off command has been received from the external terminal 100 . Here, when the mode-off command is not received, the CPU 31a ends the mode setting process. On the other hand, when the mode-off command is received, the CPU 31a clears the lock mode flag F_LOCK in S80 and ends the mode setting process.

Next, a procedure of motor control processing executed by the motor control section 21 of the motor control circuit 12 will be described. The motor control process is a process that is repeatedly executed while the motor control unit 21 is operating.
As shown in FIG. 4, when the motor control process is executed, the CPU 21a of the motor control unit 21 first determines in S110 whether or not the motor drive flag F_MTR_DRV provided in the RAM 21c is set.

Here, when the motor drive flag F_MTR_DRV is set, the CPU 21a proceeds to S160. On the other hand, when the motor drive flag F_MTR_DRV is cleared, the CPU 21a determines in S120 whether or not the trigger switch flag F_SW provided in the RAM 21c is set. The trigger switch flag F_SW is set by the CPU 21a when the trigger switch 17 is on, and is cleared by the CPU 21a when the trigger switch 17 is off.

Here, when the trigger switch flag F_SW is cleared, the CPU 21a clears the engagement completion flag F_JOB_DONE provided in the RAM 21c in S130, and proceeds to S200. The fastening completion flag F_JOB_DONE is set by the CPU 21a when the CPU 21a determines that fastening of the fastening component is completed as described above.

If the trigger switch flag F_SW is set at S120, the CPU 21a determines at S140 whether or not the motor drive permission flag F_JOB_EXE provided in the RAM 21c is set.

Here, when the motor drive permission flag F_JOB_EXE is cleared, the CPU 21a proceeds to S200. On the other hand, when the motor drive permission flag F_JOB_EXE is set, the CPU 21a sets the motor drive flag F_MTR_DRV in S150, and proceeds to S200.

After shifting to S160, the CPU 21a determines whether or not the trigger switch flag F_SW is set. Here, when the trigger switch flag F_SW is cleared, the CPU 21a proceeds to S180.

On the other hand, when the trigger switch flag F_SW is set, the CPU 21a determines in S170 whether or not the engagement completion flag F_JOB_DONE is set. Here, when the engagement completion flag F_JOB_DONE is cleared, the CPU 21a proceeds to S200. On the other hand, when the engagement completion flag F_JOB_DONE is set, the CPU 21a proceeds to S180.

After shifting to S180, the CPU 21a clears the motor drive flag F_MTR_DRV. Furthermore, in S190, the CPU 21a generates fastening data, transmits the generated fastening data to the communication circuit 13, and proceeds to S200.

The fastening data includes fastening results, fastening setting information, operation parameters, and the like. Further, the engagement result includes the engagement torque, the engagement rotation angle, the total elapsed time (that is, the time required for engagement), and the engagement determination result. The fastening setting information includes the above setting values for determining whether or not the fastening of the fastening parts has been completed. The operating parameters are, for example, the number of revolutions and the rise time of the soft start.

The tightening torque is the torque applied to the output shaft of the tool mounting portion 3a when the tightening of the fastening component is completed. The CPU 21a calculates the engagement torque based on the torque detection signal acquired when the trigger switch flag F_SW transitions from set to clear.

The fastening rotation angle is the angle by which the fastening part rotates until fastening of the fastening part is completed. The CPU 21a calculates the engagement rotation angle based on the rotation detection signal acquired from when the motor drive flag F_MTR_DRV is set until it is cleared.

The fastening determination result indicates whether or not the fastening of the fastening parts has been completed. The CPU 21a sets the fastening determination result to "OK" when the fastening completion flag F_JOB_DONE is set, and sets the fastening determination result to "NOK" when the fastening completion flag F_JOB_DONE is cleared. .

After shifting to S200, the CPU 21a determines whether or not the motor drive flag F_MTR_DRV is set. Here, when the motor drive flag F_MTR_DRV is cleared, the CPU 21a stops driving the motor 11 in S210 and ends the motor control process.

On the other hand, if the motor drive flag F_MTR_DRV is set, the CPU 21a drives the motor 11 at a rotation speed corresponding to the operation amount of the trigger 5 in S220, and ends the motor control process.

Next, the procedure of the conclusion data saving process executed by the communication control unit 31 of the communication circuit 13 will be described. The fastening data storage process is started each time fastening data is received from the motor control circuit 12 .

As shown in FIG. 5, when the conclusion data storage process is executed, the CPU 31a of the communication control unit 31 first, in S310, stores the conclusion data storage area provided in the nonvolatile memory 33 corresponding to the conclusion data storage address n. The received fastening data is saved at the address. The conclusion data storage address n is an integer of 0 or more.

Next, the CPU 31a increments (that is, adds 1 to) the fastening data storage address n in S320. Furthermore, the CPU 31a increments the unread data number m in S330. The unread data number m is an integer of 0 or more.

In S340, the CPU 31a determines whether or not the fastening data storage address n is greater than or equal to the preset maximum storage number N of fastening data. In this embodiment, the maximum number of stored fastening data N is 1056, for example.

Here, if the conclusion data storage address n is less than the maximum number N of the conclusion data that can be stored, the CPU 31a proceeds to S360. On the other hand, if the conclusion data storage address n is greater than or equal to the maximum number of stored conclusion data N, the CPU 31a sets the conclusion data storage address n to 0 in S350, and proceeds to S360.

After shifting to S360, the CPU 31a determines whether or not the lock mode flag F_LOCK is set. Here, when the lock mode flag F_LOCK is cleared, the CPU 31a terminates the fastening data saving process.

On the other hand, if the lock mode flag F_LOCK is set, the CPU 31a determines in S370 whether or not the number m of unread data is equal to or greater than the preset lock threshold value M. In this embodiment, the lock threshold M is 1000, for example.

Here, when the number of unread data items m is less than the lock threshold value M, the CPU 31a terminates the conclusion data saving process. On the other hand, if the number of unread data items m is equal to or greater than the lock threshold value M, the CPU 31a clears the motor drive permission flag F_JOB_EXE in S380, and further sets motor drive permission flag information indicating the value of the motor drive permission flag F_JOB_EXE. The data is transmitted to the motor control circuit 12, and the fastening data saving process ends. Note that when the CPU 21a of the motor control unit 21 of the motor control circuit 12 receives the motor drive permission flag information indicating that the value of the motor drive permission flag F_JOB_EXE is 0, it sets the motor drive permission flag F_JOB_EXE provided in the RAM 21c. clear.

Next, a change in the state of the conclusion data storage area by writing the conclusion data to the conclusion data storage area of the nonvolatile memory 33 will be described.
As shown in FIG. 6, the conclusion data storage area SA1 is a conclusion data storage area when the conclusion data storage address n is 0 and the unread data number m is 0. FIG. The conclusion data storage area SA2 is a conclusion data storage area when the conclusion data storage address n is 999 and the unread data number m is 999. FIG. The conclusion data storage area SA3 is a conclusion data storage area when the conclusion data storage address n is 1000 and the unread data number m is 1000. FIG.

Conclusion data storage addresses from 0 to 1055 are set in the conclusion data storage area, and the conclusion data is written in each of the conclusion data storage addresses. An unread data flag is set at each conclusion data storage address.

First, in the conclusion data storage area SA1, no conclusion data is written in any of the conclusion data storage addresses, and all unread data flags are cleared.
Thereafter, the conclusion data is sequentially written from address 0, and the conclusion data is written up to address 998 in the conclusion data storage area SA2. In the conclusion data storage area SA2, the unread data flags for addresses 0 to 998 are set, and the unread data flags for addresses 999 to 1055 are cleared.

The conclusion data storage area SA3 is in a state where the conclusion data is written up to the 999th address. In the conclusion data storage area SA3, unread data flags for addresses 0 to 999 are set, and unread data flags for addresses 1000 to 1055 are cleared.

In the state of the conclusion data storage area SA3, the number of unread data items m is 1000. Therefore, the number of unread data items m is greater than or equal to the lock threshold value M (1000 in this embodiment). As a result, driving of the motor 11 is prohibited when the lock mode is in the ON state.

Next, the procedure of the conclusion data transfer process executed by the communication control unit 31 of the communication circuit 13 will be described. The engagement data transfer process is started each time a preset transfer period elapses in a state where the electric working machine 1 is connected to the external terminal 100 so as to be capable of data communication by wire or wirelessly.

As shown in FIG. 7, when the conclusion data transfer process is executed, the CPU 31a of the communication control unit 31 first stores, in S410, the conclusion data that has not been transferred (hereinafter referred to as unread data) exists. Specifically, the CPU 31 a determines that there is unread data in the conclusion data storage area of the nonvolatile memory 33 when the unread data number m is greater than zero.

Here, if there is no unread data, the CPU 31a terminates the conclusion data transfer process. On the other hand, if there is unread data, the CPU 31a selects the earliest unread data (hereafter referred to as the oldest ) to obtain the conclusion data storage address x of the oldest unread data (hereinafter referred to as the oldest unread address x).

Next, the CPU 31a transmits the conclusion data stored at the oldest unread address x to the external terminal 100 in S430. The CPU 31a also clears the unread flag of the oldest unread address x in S440. Further, the CPU 31a decrements the unread data number m (that is, subtracts 1) in S450.

Then, the CPU 31a determines whether or not the unread data number m is equal to or greater than the lock threshold value M in S460. Here, when the unread data number m is equal to or greater than the lock threshold value M, the CPU 31a proceeds to S410. On the other hand, if the number of unread data items m is less than the lock threshold value M, the CPU 31a sets the motor drive permission flag F_JOB_EXE in S470, and furthermore, sets the motor drive permission flag F_JOB_EXE as motor drive permission flag information. The data is transmitted to the motor control circuit 12, and the process proceeds to S410. When the CPU 21a of the motor control unit 21 of the motor control circuit 12 receives the motor drive permission flag information indicating that the value of the motor drive permission flag F_JOB_EXE is 1, it sets the motor drive permission flag F_JOB_EXE provided in the RAM 21c. set.

Next, a change in the state of the conclusion data storage area due to the transfer of the conclusion data will be described.
As shown in FIG. 8, the conclusion data storage area SA11 is a conclusion data storage area when the conclusion data storage address n is 1,000 and the number of unread data m is 1,000.

In the conclusion data storage area SA11, the conclusion data are written from 0 to 999 addresses. Therefore, the oldest unread address x is 0.
When the conclusion data transfer process is started in the state of the conclusion data storage area SA11, the conclusion data at address 0 is transferred to the external terminal 100 first. As a result, the unread data flag at address 0 is cleared, and the unread data number m is decremented to 999, as shown in the conclusion data storage area SA12. Therefore, address 0 becomes a state in which fastening data can be written.

In the conclusion data storage area SA12, the conclusion data are written from 1 to 999 addresses. Therefore, the oldest unread address x is 1. Therefore, the conclusion data at address 1 is next transferred to the external terminal 100 by the conclusion data transfer process. As a result, the unread data flag at address 1 is cleared, and the unread data number m is decremented to 998, as shown in the conclusion data storage area SA13. Therefore, address 1 becomes a state in which fastening data can be written.

Such an electric working machine 1 can prevent the fastening data already stored in the nonvolatile memory 33 from being overwritten and lost by newly generated fastening data.
The electric operating machine 1 can store old fastening data in the external terminal 100, and can secure a storage area in the nonvolatile memory 33 for storing new fastening data.

In the electric working machine 1, even when the lock mode flag F_LOCK is set to prohibit overwriting of the fastening data, data can be written to a storage area in which fastening data is not stored.

In the electric working machine 1, the motor control circuit 12 can be arranged at a location suitable for motor control, and the communication circuit 13 can be arranged at a location suitable for communication.
Since the electric operating machine 1 includes the communication control unit 31, the processing load on the motor control circuit 12 can be reduced.

The electric working machine 1 can store fastening data in addition to the memory provided in the microcomputer 31d, and the amount of fastening data that can be stored in the electric working machine 1 can be increased. can.

Since the electric working machine 1 can perform setting operation while transferring the fastening data to the external terminal 100, it is possible to improve convenience for the user.
In the above-described embodiments, the motor control circuit 12 and the communication circuit 13 correspond to an example of the control section in the summary of the above embodiments, and the non-volatile memory 33 corresponds to an example of the storage section in the summary of the embodiments.

Further, S310 to S350 correspond to the data storage processing in the summary of the embodiment, S10 to S80 correspond to an example of the mode setting processing in the summary of the embodiment, and S140, S150, S200, and S220 correspond to the driving in the summary of the embodiment. This corresponds to an example of permission processing, and S140, S200, and S210 correspond to an example of drive prohibition processing in the summary of the embodiment.

Further, the fastening data corresponds to an example of work machine-related data in the summary of the embodiment, the operation on the operation units 34 and 103 corresponds to an example of the setting operation in the summary of the embodiment, and the lock mode flag F_LOCK is cleared. The state corresponds to an example of the permission mode in the overview of the embodiment, and the state in which the lock mode flag F_LOCK is set corresponds to an example of the prohibition mode in the overview of the embodiment.

Further, the operation on the trigger 5 corresponds to an example of the drive operation in the summary of the embodiment, the lock threshold value M corresponds to an example of the prohibition determination value in the summary of the embodiment, and S410 to S450 are data transfer processing in the summary of the embodiment. corresponds to an example of

An embodiment of the present disclosure has been described above, but the present disclosure is not limited to the above embodiment, and can be implemented in various modifications.
For example, in the above-described embodiment, the form in which the fastening data is stored in the nonvolatile memory 33 has been shown. However, the data to be stored in the non-volatile memory 33 may be any data related to the electric working machine 1, such as a setting change history of the electric working machine 1, information on the type of battery connected to the electric working machine 1, and so on. A history, a history of abnormalities detected in the electric working machine 1, and a maintenance history of the electric working machine 1 (for example, trigger count, number of motor drives, motor driving time) may be used.

Further, in the above-described embodiment, a configuration including a motor control circuit board on which the motor control circuit 12 is mounted and a communication circuit board on which the communication circuit 13 is mounted is shown. However, motor control circuit 12 and communication circuit 13 may be implemented on a single substrate.

In the above embodiment, the microcomputer 21d of the motor control circuit 12 and the microcomputer 31d of the communication circuit 13 execute processing. However, the processing performed by the microcomputers 21d and 31d may be performed by one microcomputer.

Further, in the above-described embodiment, once the conclusion data transfer process is started, transfer of the conclusion data is repeated until the unread data number m becomes zero. However, in a single conclusion data transfer process, only the conclusion data of one address may be transferred, and the process may end once.

A plurality of functions possessed by one component in the above embodiment may be implemented by a plurality of components, or a function possessed by one component may be implemented by a plurality of components. Also, a plurality of functions possessed by a plurality of components may be realized by a single component, or a function realized by a plurality of components may be realized by a single component. Also, part of the configuration of the above embodiment may be omitted. Also, at least part of the configuration of the above embodiment may be added or replaced with respect to the configuration of the other above embodiment.

In addition to the electric operating machine 1 described above, a system having the electric operating machine 1 as a component, a program for causing a computer to function as the electric operating machine 1, a non-transitional actual record such as a semiconductor memory in which the program is recorded The present disclosure can also be implemented in various forms such as media and control methods.

DESCRIPTION OF SYMBOLS 1... Electric working machine, 11... Motor, 12... Motor control circuit, 13... Communication circuit, 33... Non-volatile memory

Claims (8)

An electric working machine,
a motor;
a storage configured to store data;
a control unit,
data storage processing for storing, in the storage unit, working machine-related data related to the electric working machine and preset as data to be stored in the storage unit;
Based on the setting operation by the user of the electric working machine, the control unit is placed in a permission mode that permits overwriting of the working machine-related data in the storage unit, or allows overwriting of the working machine-related data in the storage unit. a mode setting process for selectively setting a prohibited mode to be prohibited;
a driving permission process for driving the motor in accordance with a driving operation performed by the user to drive the motor when the control unit is set to the permission mode;
When the control unit is set to the prohibition mode, driving of the motor is prohibited when the data amount of the work machine-related data stored in the storage unit reaches a preset prohibition judgment value. and a control unit configured to execute a drive prohibition process to perform and an electric working machine. The electric working machine according to claim 1,
The control unit further
transferring the work machine-related data stored in the storage unit to an external terminal connected to the control unit, and then storing the transferred work machine-related data in the storage unit. The electric working machine configured to execute data transfer processing to set the overwriteable. The electric working machine according to claim 1 or 2,
The electric working machine, wherein the prohibition determination value is set to be smaller than a data amount in which the storage unit can store the working machine-related data. The electric working machine according to any one of claims 1 to 3,
The control unit includes a motor control circuit and a communication circuit,
The electric working machine, wherein the motor control circuit and the communication circuit are configured to perform data communication with each other. The electric operating machine according to claim 4,
The electric operating machine, wherein the communication circuit includes a communication control unit configured to execute the data storage process. The electric working machine according to claim 5,
The communication control unit includes a microcomputer,
The storage unit is an electric working machine provided outside the microcomputer. The electric working machine according to claim 2,
The control unit is connected to a wireless communication unit configured to perform wireless data communication with the external terminal and/or a wired communication unit configured to perform wired data communication with the external terminal,
The control unit is configured to transfer the work machine-related data from the wireless communication unit connected to the control unit and/or the wired communication unit connected to the control unit to the external terminal. electric work machine. The electric working machine according to any one of claims 1 to 7,
In the mode setting process, the control unit switches the control unit to the permitted mode or the An electric work machine that is configured to be selectively set to an inhibit mode.

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