JP2009050953A - Power tool - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To prevent driving of a DC motor when a trigger switch is turned off, in a power tool having the DC motor as a drive source. <P>SOLUTION: A power supply switch 16 turned on/off in conjunction with the trigger switch 10 is provided on a power source supply passage to gate circuits 21-23 corresponding to high-side switches (switching elements Q1-Q3) out of gate circuits 21-26 for turning on/off switching elements Q1-Q6 constituting a bridge circuit 12 for driving the DC motor 20. As a result, when the trigger switch 10 is in the off state, driving of the DC motor 20 due to malfunction of a control circuit 14 can be prevented. When the trigger switch 10 is turned off, the control circuit 14 turns low-side switches (switching elements Q4-Q6) on via the gate circuits 24-26 to make the DC motor 20 generate braking torque. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to an electric tool including a DC motor as a power source.

  Conventionally, in this type of electric tool, as a driving circuit for a DC motor, switching elements (a high-side switch and a low-side switch) provided between each terminal of the DC motor and a positive electrode and a negative electrode of a DC power source (battery) A bridge circuit is provided.

  When the user operates the trigger switch, a control circuit including a microcomputer or the like turns on / off each switching element in the bridge circuit, thereby causing a current to flow from the battery to the DC motor and rotating the DC motor ( For example, see Patent Documents 1 and 2).

  Also, in this type of electric tool, normally, only a bridge circuit is provided on the energization path from the battery to the DC motor, and a power switch for manually conducting / interrupting the energization path is provided. Absent.

  This is because, in a power tool, since a large current flows through a DC motor and vibration is large, in order to provide a power switch having a mechanical contact in the energization path of the DC motor, a current that can be energized in the power switch This is because it is necessary to use a power switch having a large earthquake resistance.

In other words, since the power switch having a mechanical contact hinders the miniaturization / cost reduction of the electric tool, the electric power tool is usually not provided with a power switch in the energization path to the DC motor, Switching between energization / non-energization of the DC motor is performed only by controlling the bridge circuit by the control circuit.
No. 2003-266334 No. 2003-200363

  By the way, in the above-mentioned conventional electric tool, the direct current motor starts to rotate unexpectedly when the trigger switch is turned off due to a malfunction of the control circuit, or the direct current motor continues to rotate even when the trigger switch is turned off. Sometimes.

  If the DC motor is rotating when the trigger switch is turned off as described above, if the power switch is provided on the energization path to the DC motor, the DC motor can be rotated by turning off the power switch. Can be stopped.

  However, as described above, with a general electric tool that is not provided with a power switch, the rotation of the DC motor cannot be stopped by operating the power switch. There was a problem of having to remove the battery from the tool.

  The present invention has been made in view of these problems, and an object of the present invention is to prevent a DC motor from being driven when a trigger switch is turned off in an electric tool including a DC motor as a power source.

Means for Solving the Problems and Effects of the Invention

  In the electric power tool according to claim 1, which is made to achieve the above object, when the trigger switch is turned on, the control circuit is provided on the energization path to the DC motor via the gate circuit. The DC motor is rotated by turning on / off the switching element.

  The power supply path to the gate circuit is provided with a power supply switch for conducting / cutting off the path. The power supply switch is turned on / off in conjunction with the trigger switch by the gate power supply switching means.

For this reason, according to the electric tool of the present invention, when the trigger switch is turned off, the power supply path to the gate circuit is interrupted, and the operation of the gate circuit is stopped.
Therefore, according to the power tool of the present invention, even when the control circuit malfunctions when the trigger switch is turned off and a control signal for turning on the switching element is output from the control circuit to the gate circuit, the gate is generated by the control signal. The circuit does not turn on the switching element.

Therefore, according to the electric tool of the present invention, when the trigger switch is turned off, the energization path to the DC motor can be cut off and the rotation of the DC motor can be stopped reliably.
The power supply switch is provided not on the energization path to the DC motor but on the power supply path to the gate circuit.

  For this reason, a drive current necessary for each gate circuit to turn on / off the switching element flows through the power supply switch, and a motor current does not flow like the power switch described above. As the switch, a switch having a smaller current that can be energized than the power switch described above can be used.

In addition, a switch having a mechanical contact such as a relay can be used as the power supply switch, but an electronic switch made of an FET or the like can also be used.
If the power supply switch is composed of an electronic switch, the power supply path to each gate circuit can be turned on / off without being affected by vibration, and the reliability of the electric tool can be improved. it can.

  By the way, in the present invention, the gate power supply switching means may be provided with a power supply switch on a power supply path common to all the gate circuits, and the path may be connected / cut off in conjunction with the trigger switch. For example, when the switching element provided on the energization path of the DC motor is composed of a high side switch and a low side switch (in other words, the drive circuit of the DC motor is composed of the bridge circuit described above. In this case, the gate power supply switching means may be configured as described in claim 2.

  That is, in the electric power tool according to claim 2, the power supply switch is provided on a power supply path to a gate circuit that turns on / off one of the high-side switch and the low-side switch among the plurality of switching elements. ing.

  For this reason, according to the power tool of the second aspect, when the trigger switch is turned off, only the high-side switch or the low-side switch among the switching elements constituting the bridge circuit is turned off by the operation of the gate power supply switching means. Although it is fixed to the state, it is possible to prevent the drive current from being supplied from the DC power source to the DC motor in this way, so that the DC motor can be prevented from being driven when the trigger switch is turned off.

  When the power supply switch is provided on the power supply path to the gate circuit for turning on / off the high side switch in the electric tool according to claim 2, the control circuit is configured as described in claim 3. On the contrary, when the power supply switch is provided on the power supply path to the gate circuit for turning on / off the low side switch, the control circuit may be configured as described in claim 4.

  That is, in the electric tool according to claim 3, when the trigger switch is switched to the off state, the control circuit turns on all the low side switches via the gate circuit that turns on / off the low side switch.

  For this reason, according to the electric tool of the third aspect, when the trigger switch is switched from the on state to the off state and all the high-side switches are in the off state, the occurrence of the occurrence in the motor winding due to the rotation of the DC motor. The braking torque is generated in the DC motor by the electric power, and the DC motor can be quickly stopped by the braking torque.

  On the other hand, in the electric tool according to claim 4, when the trigger switch is switched to the off state, the control circuit turns on all the high-side switches via the gate circuit that turns on / off the high-side switch.

  For this reason, according to the electric tool of the fourth aspect, when the trigger switch is switched from the on state to the off state and all the low side switches are turned off, the electromotive force generated in the motor winding by the rotation of the DC motor. Thus, a braking torque is generated in the DC motor, and the DC motor can be quickly stopped by the braking torque.

Embodiments of the present invention will be described below with reference to the drawings.
FIG. 1 is a perspective view illustrating an appearance of a rechargeable impact driver 1 according to an embodiment to which the present invention is applied.

  The rechargeable impact driver 1 of the present embodiment is formed by assembling left and right half housings 2 and 3, and a main body housing 5 having a handle portion 4 extending downward, and a lower end of the handle portion 4 of the main body housing 5. The battery pack 6 is detachably attached to the battery pack 6.

  Further, the rear side of the main body housing 5 (left side in FIG. 1) is a motor storage portion 7 that stores a DC motor 20 (see FIG. 2) that is a power source of the rechargeable impact driver 1. Further, a speed reduction mechanism and a striking mechanism are accommodated in front of the vehicle. A chuck sleeve 8 for projecting a tool bit (not shown) is provided at the tip of the main housing 5 so as to be attached to the tip of the striking mechanism.

  Here, the striking mechanism includes, for example, a spindle that is rotated via a speed reduction mechanism, a hammer that rotates together with the spindle and that can move in the axial direction, and an anvil in which a tool bit is attached to the front end of the hammer. And operates as follows.

  That is, in the striking mechanism, when the spindle rotates with the rotation of the DC motor 20, the anvil rotates through the hammer to rotate the tool bit, and then the screw tightening by the tool bit proceeds and the load on the anvil increases. The hammer moves backward against the urging force of the coil spring and disengages from the anvil. Then, the hammer moves forward with the urging force of the coil spring while revolving with the spindle and re-engages with the anvil. Add a blow and tighten.

Since this striking mechanism is conventionally known (see, for example, Japanese Patent Application Laid-Open No. 2006-218605), detailed description thereof is omitted here.
Next, the handle part 4 of the main body housing 5 is provided with a trigger switch 10 that can be operated while the user holds the handle part 4. In the handle portion 4, there is housed a drive device that operates by receiving power supply from the battery pack 6 and rotates the DC motor 20 when the trigger switch 10 is turned on.

FIG. 2 is an electric circuit diagram showing the configuration of the driving device.
As shown in FIG. 2, the DC motor 20 of the present embodiment is a three-phase brushless motor, and serves as a drive circuit between terminals of each phase of the DC motor 20 and the positive side of the DC power supply (that is, the battery pack 6). Switching elements Q1 to Q3 provided as high-side switches, and three switching elements Q4 to Q6 similarly provided as low-side switches between the terminals of the respective phases of the DC motor 20 and the negative electrode side of the battery pack 6. A bridge circuit 12 is provided.

  Further, the switching elements Q1 to Q6 constituting the bridge circuit 12 are constituted by n-channel FETs. Each switching element Q1 to Q6 receives power supply from the battery pack 6 and receives each switching element Q1. Gate circuits 21 to 26 are connected to turn on the switching elements Q1 to Q6 by applying a driving voltage equal to or higher than the threshold value between the gate and source of .about.Q6.

  The gate circuits 21 to 26 are for individually turning on / off the switching elements Q1 to Q6 in the bridge circuit 12, and their operations are controlled by a control circuit 14 comprising a microcomputer.

  That is, when the trigger switch 10 is in the ON state, the control circuit 14 switches each switching in the bridge circuit 12 via the gate circuits 21 to 26 based on the detection signal from the rotational position sensor 18 provided in the DC motor 20. The elements Q1 to Q6 are turned on / off to control the current flowing through the phase windings of the DC motor 20 and rotate the DC motor 20. The gate circuits 21 to 26 include switching elements Q1 to Q1. A control signal for driving Q6 is input.

  Further, since the control circuit 14 needs to detect the on / off state of the trigger switch 10 when driving the DC motor 20, one end of the trigger switch 10 is connected to the power source of the control circuit 14 via the pull-up resistor R1. Connected to the line (constant voltage: Vcc), the other end is grounded to the ground line, and the control circuit 14 has an anode of a diode D1 whose cathode is connected to a connection point between the trigger switch 10 and the pull-up resistor R1. Is connected.

  That is, with this configuration, when the trigger switch 10 is in the on state, the connection point of the diode D1 in the control circuit 14 is grounded to the ground line via the diode D1, and the diode on the control circuit 14 side The on / off state of the trigger switch 10 can be detected from the potential at the connection point of D1.

  Further, when the trigger switch 10 is switched from the on state to the off state, the control circuit 14 thereafter switches only the low-side switches (switching elements Q4 to Q6) in the bridge circuit 12 through the gate circuits 24 to 26 for a certain period of time. Configured to turn on.

  This is because when the trigger switch 10 is switched to the OFF state and the energization to the DC motor 20 is stopped, even if the DC motor 20 is rotating, a braking torque is generated by the electromotive force generated by the rotation, and the DC motor 20 is rotated. This is for quickly stopping the rotation of the motor 20.

  Next, the gate circuits 24 to 26 that drive the low-side switches (switching elements Q4 to Q6) in the bridge circuit 12 are directly connected to the positive side of the battery pack 6 through a power supply path common to the gate circuits. The gate circuits 21 to 23 that drive the high-side switches (switching elements Q1 to Q3) in the bridge circuit 12 are connected to the positive side of the battery pack 6 via the power supply switch 16 common to each gate circuit. It is connected.

  The power supply switch 16 is composed of a p-channel FET, and its gate is connected to the anode of a diode D2 whose cathode is connected to the connection point between the trigger switch 10 and the pull-up resistor R1. Yes.

  Therefore, the power supply switch 16 is turned on when the trigger switch 10 is turned on, and supplies power from the battery pack 6 to the gate circuits 21 to 23 on the high side switch side. When is in the off state, the power supply switch 16 is turned off, and the power supply to the gate circuits 21 to 23 is cut off.

  Therefore, according to the driving device for the DC motor 20 of the present embodiment, if the trigger switch 10 is in the OFF state, the control circuit 14 causes the high-side switch (switching element Q1) from the control circuit 14 to the gate circuits 21 to 23 due to malfunction. Even when a control signal for turning on Q3) is output, the high-side switches (switching elements Q1 to Q3) are not turned on.

  Therefore, according to the rechargeable impact driver 1 of the present embodiment, it is possible to reliably prevent the DC motor 20 from being driven by a malfunction of the control circuit 14 when the user is not operating the trigger switch 10. Thus, the reliability of the rechargeable impact driver 1 can be improved.

  In the present embodiment, the power supply switch 16 is provided on the power supply path to the gate circuits 21 to 23 that drive the high-side switches (switching elements Q1 to Q3), and the low-side switch (switching elements Q4 to Q4). Since the power supply path to the gate circuits 24 to 26 that drive Q6) is always connected regardless of the on / off state of the trigger switch 10, the control circuit 14 determines that the trigger switch 10 is in the off state. At this time, the low-side switches (switching elements Q4 to Q6) are turned on, and the DC motor 20 can be quickly stopped.

  In the present embodiment, the diode D2 that turns on / off the power supply switch 16 in conjunction with the on / off state of the trigger switch 10 corresponds to the gate power supply switching means of the present invention.

As mentioned above, although one Embodiment of this invention was described, this invention is not limited to the said embodiment, A various aspect can be taken in the range which does not deviate from the summary of this invention.
For example, in the above-described embodiment, the power supply switch 16 has been described as being provided on the power supply path to the gate circuits 21 to 23 that drive the high-side switches (switching elements Q1 to Q3). May be provided on the power supply path to all the gate circuits 21 to 26 or, as shown in FIG. 3, to the gate circuits 24 to 26 for driving the low-side switches (switching elements Q4 to Q6). It may be provided on the power supply path.

  As shown in FIG. 3, when the power supply switch 16 is provided on the power supply path to the gate circuits 24-26, the gate circuits 21-23 for driving the high-side switches (switching elements Q1-Q3). The power supply path to is always connected regardless of the on / off state of the trigger switch 10.

  Therefore, in this case, when the trigger switch 10 is switched from the on state to the off state, the control circuit 14 thereafter switches the high side switch (switching elements Q1 to Q1) in the bridge circuit 12 through the gate circuits 21 to 23 for a certain period of time. It may be configured to turn on only Q3).

  That is, in this way, when the trigger switch 10 is switched to the OFF state and the energization to the DC motor 20 is stopped, even if the DC motor 20 is rotating, the braking torque is generated by the electromotive force generated by the rotation. The rotation of the direct-current motor 20 can be quickly stopped by being generated.

  In the above embodiment, the switching elements Q1 to Q6 in the bridge circuit 12 are all configured by n-channel FETs. For example, the high-side switch (switching elements Q1 to Q3) has a p-channel. FETs may be used, or bipolar transistors may be used for the switching elements Q1 to Q6.

  Next, in the above embodiment, the case where the present invention is applied to a rechargeable impact driver has been described. However, the present invention can be applied in the same manner as the above embodiment as long as the power tool includes a DC motor as a power source. Thus, the same effect can be obtained.

  For example, in the above embodiment, the DC motor is described as a three-phase brushless motor. However, the present invention is not limited to an electric tool including a brushless DC motor, and an H-bridge circuit as illustrated in FIG. Even the electric tool including the brushed DC motor 30 driven at 32 can be applied in the same manner as in the above embodiment, and the same effect can be obtained.

  In other words, in the drive device shown in FIG. 4, the H bridge circuit 32 includes two switching elements Q1, 2 provided as high-side switches between the terminals of the DC motor 30 and the positive side of the DC power supply (battery pack 6). Q2 is also composed of two switching elements Q3 and Q4 provided as low-side switches between the terminals of the DC motor 30 and the negative side of the battery pack 6.

  Then, when the trigger switch 10 is turned on, the control circuit 34 individually turns on / off the switching elements Q1 to Q4 in the H bridge circuit 32 via the gate circuits 21 to 24, thereby supplying the DC motor 30 with the switching circuit Q1. The energization direction (in other words, the rotation direction of the motor) and the energization current (in other words, the rotation speed) are controlled.

  Further, on the power supply path to the gate circuits 21 and 22 that drive the high-side switches (switching elements Q1 and Q2), as in the above embodiment, the power supply is turned on / off in conjunction with the trigger switch 10. A switch 16 is provided.

  For this reason, when the trigger switch 10 is turned off, the power supply path to the gate circuits 21 and 22 is cut off, and the control circuit 34 malfunctions to switch the high-side switches (switching elements Q1 and Q2 from the control circuit 34 to the gate circuits 21 and 22). Even if a control signal for turning on) is output, the high-side switches (switching elements Q1, Q2) are not turned on.

  As described above, even when the electric tool includes the brushed DC motor 30 driven by the H-bridge circuit 32, by applying the present invention, when the user does not operate the trigger switch 10, It is possible to reliably prevent the DC motor 20 from being driven by a malfunction of the control circuit 34 and improve the reliability of the electric tool.

  As the power supply switch 16 which is the main part of the present invention, an electronic switch other than a p-channel FET may be used, or a switch having a mechanical contact such as a relay may be used. May be.

It is explanatory drawing showing the structure of the rechargeable impact driver of embodiment. It is an electric circuit diagram showing the structure of the drive device of the DC motor of the embodiment. FIG. 6 is an electric circuit diagram illustrating a modification of the drive device illustrated in FIG. 2. It is an electric circuit diagram showing the structural example of the drive device of the direct-current motor with a brush.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 1 ... Rechargeable impact driver 2, 3 ... Half housing, 4 ... Handle part, 5 ... Main body housing, 6 ... Battery pack, 7 ... Motor storage part, 8 ... Chuck sleeve, 10 ... Trigger switch, 12 ... Bridge circuit , Q1 to Q3: switching element (high side switch), Q4 to Q6: switching element (low side switch), 14 ... control circuit, 16 ... power supply switch, D1, D2 ... diode, R1 ... pull-up resistor, 18 ... rotation Position sensor, 20 ... DC motor (3-phase brushless motor), 21-26 ... Gate circuit, 30 ... DC motor (with brush), 32 ... H bridge circuit, 34 ... Control circuit.

Claims (4)

A tool bit for performing a predetermined machining operation on the workpiece;
A DC motor for driving the tool bit;
A plurality of switching elements provided on an energization path from a DC power source to the DC motor;
A plurality of gate circuits for turning on / off each of the switching elements;
A control circuit that drives and controls each of the switching elements via the plurality of gate circuits and rotates the DC motor when a trigger switch operated by a user is turned on;
A power supply switch for conducting / interrupting the power supply path to each gate circuit;
Gate power supply switching means for turning on / off the power supply switch in conjunction with the trigger switch;
An electric tool comprising: The plurality of switching elements are:
It is provided for each terminal of the DC motor, and consists of a high-side switch and a low-side switch that connect the terminal to the positive side and the negative side of the DC power source,
The power supply switch is
2. The power tool according to claim 1, wherein the power tool is provided in a power supply path to a gate circuit that turns on / off one of a high-side switch and a low-side switch among the plurality of switching elements. The power supply switch is provided in a power supply path to a gate circuit for turning on / off the high-side switch,
The power tool according to claim 2, wherein when the trigger switch is switched to an off state, the control circuit turns on all the low side switches via a gate circuit that turns on and off the low side switch. . The power supply switch is provided in a power supply path to a gate circuit for turning on / off the low-side switch,
3. The control circuit according to claim 2, wherein when the trigger switch is switched to an off state, the control circuit turns on all the high side switches through a gate circuit that turns on and off the high side switch. Electric tool.

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