JP2019166627A - Power tool - Google Patents

Abstract

To provide a power tool that can reduce power consumption on a motor.SOLUTION: A power tool includes: a motor M1 for driving the tool; a measurement unit 11 for measuring load on the motor M1; and a control unit 122 that reduces output power of the motor M1 or stops the motor M1 when the load measured by the measurement unit 11 decreases so as to satisfy a predetermined condition.SELECTED DRAWING: Figure 3

Description

  The present disclosure relates to a power tool, and more particularly to a power tool that drives a tool with a motor.

  A power tool described in Patent Document 1 is illustrated as a conventional example. The electric tool described in Patent Literature 1 includes a motor, a trigger switch, a control unit, and a chuck. The control unit controls the number of rotations of the motor based on the pulling amount of the trigger switch. A tip tool such as a hole saw can be attached to and detached from the chuck. When the trigger switch is pulled, the control unit drives the motor. As a result, the tip tool rotates to enable operations such as drilling.

JP 2017-030112 A

  However, in the electric power tool described in Patent Document 1, as long as the trigger switch is retracted, the motor (electric motor) continues to be driven even after the operation such as drilling is completed. For this reason, the electric power for driving a motor may be wasted.

  An object of this indication is to provide the electric tool which can reduce the electric power consumption of an electric motor.

  In order to solve the above problem, an electric tool according to an aspect of the present disclosure includes an electric motor, a measurement unit, and a control unit. The electric motor drives a tool. The measurement unit measures the magnitude of a load applied to the electric motor. The control unit reduces the output of the electric motor or stops the electric motor when the magnitude of the load measured by the measurement unit is reduced to satisfy a predetermined condition.

  In the electric tool according to one aspect of the present disclosure, the power consumption of the electric motor can be reduced.

FIG. 1 is a perspective view of an electric power tool according to an embodiment. FIG. 2 is a perspective view of a main part of the above-described electric tool, in which the movable blade is rotated from the position shown in FIG. FIG. 3 is a circuit diagram of the above electric tool. FIG. 4 is a graph showing the time change of the voltage measured in the electric tool. FIG. 5 is a flowchart showing an operation example of the above-described electric tool.

  Hereinafter, the electric tool which concerns on embodiment is demonstrated using drawing. However, the embodiments described below are only some of the various embodiments of the present disclosure. The following embodiment can be variously modified according to the design or the like as long as the object of the present disclosure can be achieved.

(Outline of electric tool)
As shown in FIGS. 1 and 2, the electric power tool 1 of the present embodiment includes a tool body 2 and a cutter unit 6 (tool). A cutter unit 6 is attached to the tool body 2. A battery pack 13 is detachably attached to the tool body 2. The battery pack 13 is not included in the configuration of the electric power tool 1. The tool body 2 includes a housing 4, an electric motor M1 (see FIG. 3), and an operation unit 22 (trigger). The cutter unit 6 includes a fixed blade 61 and a movable blade 62. When the operation unit 22 is operated, a current is supplied from the battery pack 13 to the electric motor M1, and the electric motor M1 rotates. When the rotational force of the electric motor M1 is transmitted to the cutter unit 6, the movable blade 62 of the cutter unit 6 is driven, and the electric wire 100 (cutting target) disposed between the fixed blade 61 and the movable blade 62 is cut. The

(Circuit configuration of electric tool)
As shown in FIG. 3, the tool body 2 (see FIG. 1) of the electric power tool 1 includes an electric motor M <b> 1, a measurement unit 11, and a control unit 122. The tool body 2 further includes a trigger switch SW1, a diode D1, a switching element SW2, a drive circuit 14, and an amplifier circuit 15. The electric motor M1, the measurement unit 11, the control unit 122, the trigger switch SW1, the diode D1, the switching element SW2, the drive circuit 14, and the amplification circuit 15 are accommodated in the housing 4 (see FIG. 1) of the tool body 2.

  The battery pack 13 has a plurality of secondary batteries 131. The plurality of secondary batteries 131 are connected in series. The battery pack 13 supplies current from the plurality of secondary batteries 131 to the electric motor M1. The electric motor M <b> 1 is driven by receiving a current supplied from the battery pack 13.

  The trigger switch SW1 is turned on and off when the operation unit 22 (see FIG. 1) is operated. The trigger switch SW1 is, for example, a mechanical switch. The switching element SW2 is, for example, an FET (Field Effect Transistor). The measurement unit 11 includes a resistor 110 and a measurement function unit 121. A series circuit of a trigger switch SW1, an electric motor M1, a switching element SW2, and a resistor 110 is electrically connected between the positive electrode 132 and the negative electrode 133 of the series circuit of the plurality of secondary batteries 131. . A diode D1 is connected in parallel to the electric motor M1. The cathode side of the diode D1 is electrically connected to the positive electrode 132 of the series circuit of the plurality of secondary batteries 131 via the trigger switch SW1.

  The electric power tool 1 includes a control device 12 including a measurement function unit 121 and a control unit 122. That is, the measurement function unit 121 serves as both the configuration of the control device 12 and the configuration of the measurement unit 11. The control device 12 is configured by, for example, a computer (microcomputer) having a processor and a memory. The function as the control device 12 in the present disclosure is realized by the processor executing the program recorded in the memory of the computer. The battery pack 13 supplies power from the plurality of secondary batteries 131 to the control device 12 and the like via a power supply circuit.

  The control unit 122 controls the drive circuit 14. The drive circuit 14 turns on and off the switching element SW2 by controlling the gate voltage of the switching element SW2 in accordance with the control of the control unit 122. Thereby, the control unit 122 switches between a state in which current is supplied from the battery pack 13 to the electric motor M1 and a state in which no current is supplied, and when the current is supplied from the battery pack 13 to the electric motor M1, Control the size.

  Moreover, the control part 122 performs feedback control of the rotation speed of the electric motor M1.

  The measurement unit 11 measures the magnitude of the current supplied from the battery pack 13 to the electric motor M1. More specifically, the current supplied from the battery pack 13 to the electric motor M <b> 1 is converted into a voltage V <b> 1 across the resistor 110. The amplifier circuit 15 is connected to one end of the resistor 110. The amplifier circuit 15 includes, for example, an operational amplifier. The amplifier circuit 15 amplifies the voltage V1 and outputs the amplified voltage V2 to the control device 12. For example, the measurement function unit 121 of the control device 12 converts the voltage V2 from analog to digital and measures the magnitude of the voltage V2. The larger the load applied to the electric motor M1, the larger the current supplied from the battery pack 13 to the electric motor M1. Further, the larger the current supplied from the battery pack 13 to the electric motor M1, the larger the voltage V2.

  When the voltage V2 measured by the measurement function unit 121 is reduced to satisfy a predetermined condition, the control unit 122 stops the electric motor M1. More specifically, when the voltage V <b> 2 is reduced so as to satisfy a predetermined condition, the control unit 122 outputs a stop signal to the drive circuit 14. When the stop signal is input, the drive circuit 14 turns off the switching element SW2. Thus, the control part 122 interrupts | blocks supply of the electric current from the battery pack 13 to the electric motor M1, and stops the electric motor M1.

  The predetermined condition is that the second threshold Th2 (predetermined threshold: see FIG. 4) after the voltage V2 becomes equal to or higher than the first threshold Th1 (prescribed threshold: see FIG. 4) during the operation of the electric motor M1. ) The condition is as follows. The controller 122 detects whether or not a predetermined condition is satisfied by comparing the voltage V2 with the first threshold Th1 and the second threshold Th2. The first threshold Th1 is larger than the second threshold Th2.

(Power tool operation)
Hereinafter, an operation example of the electric power tool 1 will be described with reference to FIG.

  When the operator operates the operation unit 22 (see FIG. 1) (step S1), the trigger switch SW1 is turned on. At this time, the control unit 122 turns on the switching element SW <b> 2 via the drive circuit 14. Then, current is supplied from the battery pack 13 to the electric motor M1. Therefore, a voltage V1 is generated across the resistor 110 (step S2). The amplifier circuit 15 amplifies the voltage V1 and outputs the amplified voltage V2 to the control device 12 (step S3).

  The control unit 122 compares the voltage V2 with the first threshold Th1 (step S4). When the voltage V2 is smaller than the first threshold Th1, the control unit 122 continues to compare the voltage V2 with the first threshold Th1. When the voltage V2 is equal to or higher than the first threshold Th1, the control unit 122 compares the voltage V2 with the second threshold Th2 (step S5).

  When the voltage V2 is larger than the second threshold Th2, the control unit 122 continues to compare the voltage V2 with the second threshold Th2. When the voltage V2 is equal to or lower than the second threshold Th2, the control unit 122 outputs a stop signal to the drive circuit 14 (step S6). In response to this, the drive circuit 14 turns off the switching element SW2 (step S7). Therefore, the electric motor M1 stops (step S8).

  That is, the control unit 122 satisfies the predetermined condition that the voltage V2 becomes a value equal to or higher than the first threshold Th1 and then becomes a value equal to or lower than the second threshold Th2 during the operation of the electric motor M1. The electric motor M1 is stopped.

  Below, with reference to FIG. 4, an example of the relationship between the change of the voltage V2 and control of the electric motor M1 by the control part 122 is demonstrated.

  First, the operator places the electric wire 100 (see FIG. 1) between the fixed blade 61 (see FIG. 1) and the movable blade 62 (see FIG. 1). Next, when the operator operates the operation unit 22 (see FIG. 1), the electric motor M1 starts to rotate (time point t1). That is, at the time t1, the worker starts the work of cutting the electric wire 100 using the electric tool 1. Since the cutter unit 6 (see FIG. 1) is driven by the power transmitted from the electric motor M1 and attempts to cut the electric wire 100 by applying force to the electric wire 100, the cutter unit 6 is not in contact with the electric wire 100. However, the load applied to the electric motor M1 is increased. Therefore, the current supplied from the battery pack 13 to the electric motor M1 becomes larger than when the cutter unit 6 is not in contact with the electric wire 100. Specifically, after time t1, the current supplied from the battery pack 13 to the electric motor M1 increases as time passes. The voltage V2 increases as the current supplied from the battery pack 13 to the electric motor M1 increases. At time t2, the voltage V2 becomes a value equal to or higher than the first threshold Th1.

  At time t3, the cutter unit 6 completes the cutting of the electric wire 100. Specifically, the cutter unit 6 cuts the electric wire 100 and divides it into two. Then, since the force applied to the electric wire 100 from the cutter part 6 reduces, the magnitude | size of the load concerning the electric motor M1 reduces. Therefore, the current supplied from the battery pack 13 to the electric motor M1 is reduced. The voltage V2 decreases as the current supplied from the battery pack 13 to the electric motor M1 decreases. For example, after the time point t3, when the cutter unit 6 is separated from the electric wire 100, the electric motor M1 rotates idly, so that the electric motor M1 becomes unloaded.

  At time t4, the voltage V2 becomes equal to or lower than the second threshold Th2. That is, a predetermined condition that the voltage V2 becomes a value equal to or lower than the first threshold Th1 after the voltage V2 becomes equal to or lower than the second threshold Th2 during the operation of the electric motor M1 is satisfied at the time point t4. Then, the control part 122 stops the electric motor M1. More specifically, the control unit 122 turns off the switching element SW2 via the drive circuit 14 to cut off the supply of current from the battery pack 13 to the electric motor M1, and stops the electric motor M1. Therefore, the voltage V2 becomes 0 at the time point t5. When the operator stops the operation on the operation unit 22, the trigger switch SW1 is turned off.

  After the time point t4, the control unit 122 does not control the drive circuit 14 until the operation unit 22 (see FIG. 1) is operated again and the trigger switch SW1 is turned on. Keep it off. Therefore, the electric motor M1 continues to stop. When the operation unit 22 is operated and the trigger switch SW1 is turned on, the control unit 122 turns on the switching element SW2 via the drive circuit 14, so that current is again supplied from the battery pack 13 to the electric motor M1, The electric motor M1 starts to rotate.

  As described above, when the voltage V2 is reduced to satisfy the predetermined condition, the control unit 122 stops the electric motor M1. Therefore, compared with the case where the control part 122 does not perform such operation | movement, the power consumption of the motor M1 can be reduced.

(Power tool structure)
Next, the structure of the electric power tool 1 will be described in more detail with reference to FIGS.

  The electric tool 1 includes a tool body 2 and a cutter unit 6 (tool). The tool body 2 includes a housing 4, an electric motor M <b> 1 (see FIG. 3), and an operation unit 22.

  The housing 4 includes a cylindrical part 41, a grip part 42, and a mounting part 43. The grip part 42 protrudes from the side surface 410 of the cylindrical part 41. The operation unit 22 is attached to the grip unit 42. A cutter portion 6 is attached to one end of the cylindrical portion 41 in the axial direction. In more detail, the cutter part 6 is attached to the cylindrical part 41 so that attachment or detachment is possible.

  The mounting portion 43 is connected to the tip of the grip portion 42 on the side opposite to the cylindrical portion 41 side. The battery pack 13 is detachably attached to the attachment portion 43.

  When the operator performs an operation of pulling in the operation unit 22, the electric motor M1 (see FIG. 3) rotates. When the operator stops the operation of pulling the operation unit 22, the electric motor M1 is stopped.

  The tool body 2 further includes a transmission mechanism. The transmission mechanism includes a plurality of gears. The rotational force of the electric motor M1 is transmitted to the cutter unit 6 by the transmission mechanism.

  In addition to the fixed blade 61 and the movable blade 62, the cutter unit 6 further includes a handle 63, a storage portion 64, an attachment portion 65, and a gear. The gear is accommodated in the accommodating portion 64. The gear rotates by the rotational force transmitted from the electric motor M1 (see FIG. 3) via the transmission mechanism. The accommodating portion 64 has an opening 640. The opening 640 is provided on the side of the accommodating portion 64 opposite to the tool body 2 side.

  Each of the fixed blade 61 and the movable blade 62 is formed in an arc shape. The fixed blade 61 is connected to the accommodating portion 64. More specifically, the fixed blade 61 is formed integrally with the housing portion 64. The movable blade 62 is rotatably attached to the fixed blade 61. The handle 63 is attached to the movable blade 62. The operator can grip the handle 63 and rotate the movable blade 62 relative to the fixed blade 61.

  The movable blade 62 has a plurality of teeth 621. The plurality of teeth 621 are provided on the outer edge of the movable blade 62. When an operator cuts the electric wire 100 using the electric tool 1, a part of the movable blade 62 is passed through the opening 640 of the housing portion 64. Then, the plurality of teeth 621 of the movable blade 62 come into contact with the gear accommodated in the accommodating portion 64. The plurality of teeth 621 of the movable blade 62 mesh with the plurality of teeth of the gear housed in the housing portion 64.

  The attachment portion 65 is connected to the accommodation portion 64. The attachment portion 65 is formed with a screw hole through which the screw 67 is passed. The attachment portion 65 is detachably attached to the tool body 2 by screwing using a screw 67.

(Working with electric tools)
Below, an example of the procedure which an operator cuts the electric wire 100 using the electric tool 1 is demonstrated.

  First, the operator grasps the handle 63 and rotates the movable blade 62 to place the plurality of teeth 621 of the movable blade 62 away from the gear accommodated in the accommodating portion 64 as shown in FIG.

  Next, the operator arranges the electric wire 100 on the inner edge side of the fixed blade 61. Furthermore, the operator holds the handle 63 and rotates the movable blade 62 so that the plurality of teeth 621 of the movable blade 62 are in contact with the gear accommodated in the accommodating portion 64. Thereby, as shown in FIG. 1, the electric wire 100 is disposed between the fixed blade 61 and the movable blade 62.

  Next, the operator performs an operation of pulling the operation unit 22. Thereby, the electric motor M1 rotates. The rotational force of the electric motor M1 is transmitted to the gear accommodated in the accommodating portion 64 via the transmission mechanism, and the gear rotates. Accordingly, the movable blade 62 rotates while the plurality of teeth 621 of the movable blade 62 mesh with the plurality of teeth of the gear. When the movable blade 62 rotates, the electric wire 100 is cut by receiving a shearing stress from the fixed blade 61 and the movable blade 62.

  As described above, when the voltage V2 is reduced to satisfy the predetermined condition during the operation of the electric motor M1, the control unit 122 stops the electric motor M1. Since the voltage V2 increases as the load applied to the electric motor M1 increases, the voltage V2 may decrease when the force applied to the electric wire 100 from the cutter unit 6 driven by the electric motor M1 is reduced. Therefore, the operator can know that the force applied to the electric wire 100 from the cutter part 6 has decreased when the electric motor M1 stops.

  More specifically, when the cutter unit 6 completes the cutting of the electric wire 100, the voltage V2 decreases. Therefore, the operator can know that the cutter unit 6 has completed the cutting of the electric wire 100 when the electric motor M1 is stopped.

(Modification of the embodiment)
Next, modifications of the embodiment will be listed. The following modifications may be implemented in combination as appropriate.

  When the voltage V2 becomes a value equal to or higher than the first threshold value Th1 during the operation of the electric motor M1, the control unit 122 satisfies the predetermined condition that the voltage V2 becomes a value equal to or lower than the second threshold value Th2. The output of the electric motor M1 may be reduced instead of stopping the motor. More specifically, the control unit 122 reduces the current supplied from the battery pack 13 to the electric motor M1 by turning on and off the switching element SW2 via the drive circuit 14, thereby reducing the output of the electric motor M1. May be. Alternatively, the control unit 122 may reduce at least one of the current supplied from the battery pack 13 to the electric motor M1 and the rotational speed of the electric motor M1 in order to reduce the output of the electric motor M1.

  Moreover, the electric tool 1 is not limited to the electric tool for cutting an electric wire. For example, the electric power tool 1 may be an electric drill, a driver, a wrench, a nibra, or a grinder. Alternatively, the electric power tool 1 may be an electric power tool for cutting an object to be cut other than an electric wire (for example, a metal material such as a screw or wood). Alternatively, the electric tool 1 may be an electric tool in which a hole saw is attached to the tool body 2 and a hole is made in a ceiling material or the like with the hole saw.

  The cutter unit 6 (tool) may or may not be included in the configuration of the electric power tool 1.

  Further, the battery pack 13 may or may not be included in the configuration of the electric power tool 1.

  Further, the electric motor M1 is not limited to receiving a current from the battery pack 13, and may receive a current from an external power source such as a commercial power source.

  The magnitude of the current supplied to the electric motor M1 is a physical quantity corresponding to the magnitude of the load applied to the electric motor M1, and the measurement unit 11 of the embodiment uses a voltage based on the magnitude of the electric current supplied to the electric motor M1. V2 is measured. On the other hand, the measurement unit 11 may be configured to measure the magnitude of the current supplied to the electric motor M1. Alternatively, the measurement unit 11 may be configured to measure at least one of the torque and the rotation speed of the electric motor M1, which is a physical quantity corresponding to the magnitude of the load applied to the electric motor M1.

  Further, the predetermined condition may be a condition that a state where the voltage V2 is equal to or lower than the first threshold Th1 continues for a predetermined time after the voltage V2 becomes equal to or higher than the first threshold Th1.

  Further, the predetermined condition may be a condition that the magnitude of the load applied to the electric motor M1 (or the physical quantity corresponding to the magnitude of the load applied to the electric motor M1) is reduced by a predetermined amount or more. Alternatively, the predetermined condition may be a condition that a magnitude of a load applied to the electric motor M1 (or a physical quantity corresponding to a magnitude of the load applied to the electric motor M1) is reduced by a predetermined amount or more during a predetermined time. Alternatively, the predetermined condition may be a condition that the voltage V2 becomes a value equal to or lower than the second threshold Th2 until a predetermined time elapses after the voltage V2 becomes equal to or higher than the first threshold Th1.

  In addition, the measurement function unit 121 and the control unit 122 may be integrated in one housing, or the measurement function unit 121 and the control unit 122 may be provided in a plurality of housings.

(Summary)
As described above, the electric power tool 1 according to the first aspect includes the electric motor M1, the measurement unit 11, and the control unit 122. The electric motor M1 drives a tool (cutter part 6). The measurement part 11 measures the magnitude | size of the load concerning the electric motor M1. If the magnitude | size of the load measured by the measurement part 11 reduces so that predetermined conditions may be satisfy | filled, the control part 122 will reduce the output of the electric motor M1 or will stop the electric motor M1.

  According to said structure, if the magnitude | size of the load concerning the electric motor M1 reduces so that predetermined conditions may be satisfy | filled, the control part 122 will reduce the output of the electric motor M1 or will stop the electric motor M1. Therefore, compared with the case where the control part 122 does not perform such operation | movement, the power consumption of the motor M1 can be reduced.

  Moreover, in the electric tool 1 which concerns on a 2nd aspect, in the 1st aspect, the tool (cutter part 6) is driven by the electric motor M1, and can cut | disconnect cutting object (electric wire 100). The predetermined condition is a condition that is satisfied when the tool completes the cutting of the cutting target.

  According to said structure, when the tool (cutter part 6) completes the cutting | disconnection of the cutting object (electric wire 100), the control part 122 reduces the output of the electric motor M1, or stops the electric motor M1, thereby the electric motor M1. Power consumption can be reduced.

  Moreover, in the electric tool 1 which concerns on a 3rd aspect, in the 1st or 2nd aspect, the measurement part 11 measures the magnitude | size of the electric current supplied to the electric motor M1. The predetermined condition is that the current value (voltage V2) measured by the measurement unit 11 during operation of the electric motor M1 is changed from a value larger than a predetermined threshold value (second threshold value Th2) to a value equal to or lower than the predetermined threshold value. This is a condition.

  According to said structure, the control part 122 reduces the output of the electric motor M1 according to the magnitude | size of the electric current supplied to the electric motor M1, or stops the electric motor M1. When a load is connected to the electric motor M1, the magnitude of the load applied to the electric motor M1 changes according to the current supplied to the electric motor M1, so the control unit 122 responds to the magnitude of the load applied to the electric motor M1. The output of the electric motor M1 can be reduced or the electric motor M1 can be stopped.

  In the electric tool 1 according to the fourth aspect, in the third aspect, the predetermined condition is that the current value (voltage V2) measured by the measuring unit 11 during the operation of the electric motor M1 is a predetermined threshold value ( The condition is that after the value becomes equal to or greater than the first threshold Th1), the value becomes equal to or less than the predetermined threshold (second threshold Th2). The prescribed threshold is larger than the predetermined threshold.

  While the magnitude of the current supplied to the electric motor M1 increases from a predetermined threshold (second threshold Th2) to a predetermined threshold (first threshold Th1), the current fluctuates due to noise or the like and is below the predetermined threshold. May be. In this case, according to said structure, it can suppress that the control part 122 reduces the output of the electric motor M1 or stops the electric motor M1.

  The configuration other than the first aspect is not an essential configuration for the electric power tool 1 and can be omitted as appropriate.

DESCRIPTION OF SYMBOLS 1 Electric tool 11 Measuring part 122 Control part 6 Cutter part (tool)
100 electric wire (to be cut)
M1 electric motor Th1 1st threshold value (regulated threshold value)
Th2 Second threshold (predetermined threshold)

Claims (4)

An electric motor for driving the tool;
A measuring unit for measuring the load applied to the electric motor;
And a controller that reduces the output of the electric motor or stops the electric motor when the load measured by the measuring unit is reduced to satisfy a predetermined condition. The tool is driven by the electric motor and is capable of cutting an object to be cut.
The power tool according to claim 1, wherein the predetermined condition is a condition that is satisfied when the tool completes the cutting of the cutting target. The measurement unit measures the magnitude of the current supplied to the electric motor,
The predetermined condition is a condition that during operation of the electric motor, a current value measured by the measurement unit is a value that is larger than a predetermined threshold value and not more than the predetermined threshold value. The electric tool according to claim 1 or 2. The predetermined condition is that the current value measured by the measuring unit during operation of the electric motor becomes a value equal to or greater than a predetermined threshold value that is greater than the predetermined threshold value, and then a value equal to or less than the predetermined threshold value. The power tool according to claim 3, wherein

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