This application is the U.S. National Phase under 35 U.S.C. § 371 of International Application No. PCT/JP2016/050498, filed on Jan. 8, 2016, which in turn claims the benefit of Japanese Application No. 2015-014473, filed on Jan. 28, 2015, the disclosures of which are incorporated by reference herein.
The present invention relates to an impact tool that applies a rotational force or an impact force to a tool bit to drill a hole in an object or crush an object with the tool bit.
An impact tool that applies a rotational force or an impact force to a tool bit such as a drill bit to drill a hole in a concrete wall, a concrete floor or the like or crush it with the drill bit has been known, and such an impact tool is generally referred to as a “hammer drill”.
Most of conventional hammer drills have at least two operating modes. A conventional hammer drill has, for example, a hammer mode in which only an impact force is transmitted to a drill bit, and a hammer drill mode in which both of an impact force and a rotational force are transmitted to the drill bit. In the conventional hammer drill having a plurality of operating modes, when a trigger lever is operated by an operator, required power is transmitted to the drill bit in accordance with a selected operating mode.
Here, the hammer mode is mainly selected for crushing work, and the hammer drill mode is mainly selected for drilling work. In general, the crushing work does not reed to be delicate, but is continuously performed over a long time as compared with the drilling work.
Patent Document 1: Japanese Patent No. 4281273
When the hammer mode is selected in the work using the impact tool, it is preferable that the work can be continued even when an operator releases a trigger lever, namely, a motor is maintained in an operating state even when the trigger lever is not pulled. On the other hand, when the hammer drill mode is selected, the motor is preferably switched between the operating state and a stop state in accordance with the operation of the trigger lever in order to adjust a size and depth of a hole.
Accordingly, it has been desired to provide a hammer drill having a function of maintaining the motor in the operating state even if the trigger lever is not operated when the hammer mode is selected. Such a function is referred to as an ON-lock function as needed in the present specification.
An object of the present invention is to achieve the ON-lock function with a simple mechanism and to make it possible to switch between activation and deactivation of the ON-lock function with few operation processes.
In an aspect of the present invention, an impact tool has at least two operating codes including a first operating mode in which an impact force is transmitted to a tool bit whereas a rotational force is not transmitted to the tool bit. The impact tool includes: a motor as a power source; a first, operation part and a second operation part operated by an operator; a mode detection part detecting whether a selected operating mode is the first operating mode or not; and a control part controlling the motor based on an operation of the first operation part and the second operation part. When the second operation part is operated while the first operating mode is selected, the control part performs ON-lock control to maintain the motor in an operating state even when the first operation part is not operated.
In another aspect of the present invention, an impact tool has a first operating mode in which an impact force is transmitted to a tool bit whereas a rotational force is not transmitted to the tool bit and a second operating mode in which at least the rotational force is transmitted to the tool bit. The impact tool includes: a motor as a power source; a first operation part and a second operation part operated by an operator; and a control part controlling ON/OFF of the motor based on an operation of the first operation part and the second operation part. When the first operating mode is selected, the control part controls ON/OFF of the motor based on the operation of the first operation part and the operation of the second operation part, and performs ON-lock control to maintain the motor in an ON state by the operation of the second operation part. In addition, when the second operating mode is selected, the control part controls ON/OFF of the motor based on the operation of the first operation part.
In another aspect of the present invention, the control part stops the motor when the first operation part is operated while the ON-lock control is performed.
In another aspect of the present invention, the control part stops the motor when the first operation part is operated while the ON-lock control is performed, and then the operation of the first operation part is released.
In another aspect of the present invention, when the first operation part is operated while the ON-lock control is performed, the control part stops performing the ON-lock control and controls the motor based on the operation of the first operation part.
In another aspect of the present invention, the second operation part is a tactile switch outputting a signal to the control part for each operation.
In another aspect of the present invention, the impact tool further includes a lighting part, and the control part lights the lighting part while the ON-lock control is performed.
According to the present invention, it is possible to realize the impact tool that achieves the ON-lock function with the simple mechanism and makes it possible, to switch between activation and deactivation of the ON-lock function with few operation processes.
Hereinafter, a first embodiment of an impact tool according to the present invention will be described. The impact tool according to the present embodiment is a hammer drill capable of attaching and detaching a drill bit as an example of a tool bit. Although applications of the hammer drill according to the present embodiment are not particularly limited, the hammer drill is suitable for the work for drilling a hole in an object such as a concrete wall or a stone material or for crushing the object. In addition, the hammer drill according to the present embodiment has a first operating mode in which an impact force is transmitted to the drill bit whereas a rotational force is not transmitted thereto, and a second operating mode in which at least the rotational force is transmitted to the drill bit. Further, in the second operating mode in this embodiment, the impact force is transmitted to the drill bit in addition to the rotational force. Accordingly, in the following description, the first operating mode is referred to as a “hammer mode”, and the second operating mode is referred to as a “hammer drill mode”.
As shown in
Inside the cylinder housing 2, a cylinder 10 in a cylindrical shape and a retainer sleeve 11 are housed. The cylinder 10 and the retainer sleeve 11 are concentric, and a part of the retainer sleeve 11 protrudes from a tip of the cylinder housing 2. The cylinder 10 and the retainer sleeve 11 are engaged so as to be relatively unrotatable, and the cylinder 10 and the retainer sleeve 11 integrally rotate about a center axis as a rotation axis when a rotational force is transmitted to the cylinder 10. In addition, a part of the drill bit (not shown) is inserted into the retainer sleeve 11. The drill bit inserted into the retainer sleeve 11 is engaged with the retainer sleeve 11 so as toy be unmovable in a rotational direction and movable within a predetermined range in an axial direction. Consequently, when the cylinder 10 and the retainer sleeve 11 rotate, a rotational force is transmitted to the drill bit, and the drill bit is rotated. Further, when an impact force is transmitted to the drill bit, the drill bit is reciprocally moved within a predetermined range in the axial direction. Movement of the cylinder 10, the retainer sleeve 11, and the drill bit will be described in detail later.
Inside the cylinder 10, a piston 20 and an impact element 21 are housed in a reciprocally movable manner. In addition, an intermediate element 22 is housed in a reciprocally movable manner so as to be laid across the cylinder 10 and the retainer sleeve 11. The piston 20, the impact element 21, and the intermediate element 22 are aligned in this order from a rear side to a front side of the cylinder 10. Further, an air chamber 23 is provided between the piston 20 and the impact element 21 inside the cylinder 10.
A motor 30 as a power source is housed in the motor housing 4. The motor 30 is an inner rotor brushless motor, and has a stator 31 in a cylindrical shape, a rotor 32 disposed inside the stator 31, and an output shaft 33 disposed inside the rotor 32. The output shaft 33 is fixed to the rotor 32, and vertically extends to pass through the rotor 32. A center axis of the output shaft 33 is orthogonal to a center axis of the cylinder 10 and the retainer sleeve 11.
An upper part of the output shaft 33 protruding from the rotor 32 passes through a partition between the motor housing 4 and the intermediate housing 3, to enter inside the intermediate housing 3. A pinion gear 34 is provided at an upper end of the output shaft 33 protruding inside the intermediate housing 3. Inside the intermediate housing 3, a first driving shaft 40 is rotatably disposed near the output shaft 33, and a second driving shaft 50 is rotatably disposed near the first driving shaft 40. The output shaft 33, the first driving shaft 40, and the second driving shaft 50 are in parallel with each other.
A first gear 41 that is meshed with the pinion gear 34 is provided at a lower part of the first driving shaft 40, an eccentric pin 42 is provided at an upper part of the first driving shaft 40, and this eccentric pin 42 is coupled to the piston 20 via a connecting rod 43.
A second gear 51 that is meshed with the first gear 41 is provided at a lower part of the second driving shaft 50, a bevel gear 52 is provided at an upper part of the second driving shaft 50, and this bevel gear 52 is meshed with a ring gear 53 disposed around the cylinder. The ring gear 53 is mounted on an outer circumferential surface of the cylinder 10 via a sliding bearing (metal), and freely rotates with respect to the cylinder 10.
A sleeve 54 is provided on the outer circumferential surface of the cylinder 10 in addition to the ring gear 53. The sleeve 54 integrally rotates with the cylinder 10, and individually slides reciprocally in an axial direction of the cylinder 10. A spring always applies a force to the sleeve 54 in a direction approaching to the ring gear 53.
A mode-switching dial 60 is provided on a top surface of the intermediate housing 3. The hammer mode and the hammer drill mode are switched by a rotational operation of the mode-switching dial 60. In other words, a power transmission path in which only an impact force is transmitted to the drill bit and a power transmission path in which an impact force and a rotational force are transmitted to the drill bit are selectively formed by the rotational operation of the mode-switching dial 60. The power transmission path will be described in detail later.
When the mode-switching dial 60 shown in
On the other hand, when the mode-switching dial 60 shown in
As shown in
Next, the power transmission path in the hammer drill 1 will be described. When the brushiess motor 30 shown in
When the first driving shaft 40 rotates, the eccentric pin 42 provided at the upper end of the first driving shaft 40 is rotated about a center axis of the first driving shaft 40 as a rotation axis. Namely, the eccentric pin 42 revolves around the center axis of the first driving shaft 40. Consequently, the piston 20 coupled to the eccentric pin 42 via the connecting rod 43 is reciprocally moved in the cylinder 10. When the piston 20 moves in a direction separating from the impact element 21, namely, when, the piston 20 moves backward, pressure in the air chamber 23 is decreased, and the impact element 21 moves backward. On the other hand, when, the piston 20 moves in a direction approaching to the impact element 21, namely, when the piston 20 moves forward, the pressure in the air chamber 23 is increased, and the impact element 21 moves forward. When the impact element 21 moves forward, the impact element 21 impacts the intermediate element 22, and the intermediate element impacts the drill bit (not shown). The impact force is intermittently transmitted to the drill bit in this manner.
When the second driving shaft 50 rotates, the bevel gear 52 provided at an upper end of the second driving shaft 50 is rotated, and the ring gear 53 meshed with the bevel gear 52 is rotated. At this time, when the hammer mode is selected by the rotational operation of the mode-switching dial 60, namely, when engagement of the ring gear 53 and the sleeve 54 is released as shown in.
On the other hand, when the hammer drill mode is selected by the rotational operation of the mode-switching dial 60, namely, when the ring gear 53 and the sleeve 54 are engaged as shown in
Next, various circuits provided in the hammer drill according to the present embodiment and a circuit configuration or the like of the brushless motor 30 will be described with reference to
As shown in
The switching circuit 102 shown in
The switching circuit 102 is a 3-phase full-bridge inverter circuit, and has two switching elements Tr1 and Tr2 connected in parallel, two switching elements Tr3 and Tr4 connected in parallel, and two switching elements Tr5 and Tr6 connected in parallel. Each of the switching elements is an IGBT (Insulated Gate Bipolar Transistor). The switching elements Tr1 and Tr2 are connected to the coil U1 to control current supplied to the coil U1. The switching elements Tr3 and Tr4 are connected to the coil V1 to control current supplied to the coil V1. The switching elements Tr5 and Tr6 are connected to the coil W1 to control current supplied to the coil W1.
The switching elements Tr1, Tr3, and Tr5 are connected to positive-electrode-side output terminal of the power factor improvement circuit 104, and the switching elements Tr2, Tr4, and Tr6 are connected to a negative-electrode-side output terminal of the power factor improvement circuit 104. Namely, the switching elements Tr1, Tr3, and Try are on a high side, and the switching elements Tr2, Tr4, and Tr6 are on a low side.
In this embodiment, the coils U1, V1, and W1 are star-connected. However, a connection method of the coils U1, V1, and W1 is riot limited to the star connection, and it may be, for example, a delta connection.
The motor control unit 105 shown in
An ON signal and an OFF signal which are output from the main switch 71 by the operation of the trigger lever 70 shown in
An ON-lock signal output from the ON-lock button 80 shown in
Referring back to
(First Control Flow) Next, one example of control of the brushless motor 30 (ON/OFF control) which is performed by the controller 106 shown in
When a power cable is connected to a power source, control by the controller 106 is started. The controller 106 firstly determines whether the selected operating mode is the hammer mode or not (S1). When the operating mode is not the hammer mode (S1: No), the controller 106 determines whether the main switch 71 is turned on or not (S2). Namely, the controller 106 determines whether the trigger lever 70 (
As described above, when the selected operating mode is the hammer drill mode, the motor 30 is started up by the operation of the trigger lever 70 shown in
On the other hand, when the selected operating mode is the hammer mode (S1: Yes), the controller 106 determines the presence or absence of the reception of the ON-lock signal (S5). Namely, the controller 106 determines whether the ON-lock button 80 (
Next, the controller 106 determines whether the main switch 71 is turned on or not (S8). Namely, the controller 106 determines whether the trigger lever 70 (
However, when it is determined that the mode detection signal is not received and the mode is switched (S10: Yes) while the ON-lock control is performed (during the repetition of the steps S8 to S10), the controller 106 extinguishes the LED contained in the ON-lock button 80 (S11), and performs the active-stop control (S12). Namely, when the operating mode is switched while the ON-lock control is performed, the motor 30 is stopped by the active-stop control including the braking process.
Moreover, when the main switch 71 is turned on (S8: Yes) or the ON-lock signal is received (S9: Yes) while the ON-lock control is performed (during the repetition of the steps S8 to S10), the controller 106 extinguishes the LED contained in the ON-lock button 80 (S13), and performs a natural-stop control. To be specific, the controller 106 turns off the motor 30 (S14). More specifically, the controller 106 turns off the switching elements Tr1, Tr2, Tr3, Tr4, Tr5, and Tr6, and cuts off the power supply to the coils V1, U1 and W1 provided in the stator 31. Namely, when the trigger lever 70 (
As described above, when the hammer mode is selected, the motor 30 can be started up and the ON-lock control can be performed by one operation of the ON-lock button 80. In other words, the ON-lock control can be performed only when the hammer mode is selected. In addition, lighting of the LED contained in the ON-lock button 80 (
When the ON-lock signal is not received in the step S5 (S5: No), the controller 106 determines whether the main switch 71 is turned on or not (S15). Namely, the controller 106 determines whether the trigger lever 70 (
As described above, when the hammer mode is selected, the motor 30 can be started up also by the operation of the trigger lever 70 shown in
(Second Control Flow) Next, another example of control of the brushless motor 30 (ON OFF control) which is performed by the controller 106 shown in
When a power cable is connected to a power source, control by the controller 106 is started. The controller 106 firstly determines whether the selected operating mode is the hammer mode or not (S1). When the operating mode is not the hammer mode (S1: No), the controller 106 sets a lock flag to “0” (S2), and determines whether the main switch 71 is turned on or not (S3). Namely, the controller 106 determines whether the trigger lever 70 (
As described above, when the selected operating mode is the hammer drill mode, the motor 30 is started up by the operation of the trigger lever 70 shown in
On the other hand, when the selected operating mode is the hammer mode (S1: Yes), the controller 106 determines whether the lock flag is “1” or not (S6). When the lock flag is not “1” (S6: No), the controller 106 determines the presence or absence of the reception of the ON-lock signal (S7). Namely, the controller 106 determines whether the ON-lock button 80 (
In the step S11, the controller 106 determines the presence or absence of the reception of the ON-lock signal (S11). When the controller 106 does not receive the ON-lock signal (S11: No), the controller 106 determines whether the main switch 71 is turned on or not (S12). When the main switch 71 is not turned on (S12: No), the controller 106 returns to the step S1. Thereafter, the controller 106 repeats the steps S1, S6, S11 and S12 to maintain the motor 30 in the operating state. In other words, the controller 106 performs the ON-lock control to maintain the motor 30 in the operating state even when the trigger lever 70 (
As described above, when the hammer mode is selected, the motor 30 can be started up and the ON-lock control can be performed by one operation of the ON-lock button 80. In other words, the ON-lock control can be performed only when the hammer mode is selected. In addition, lighting of the LED contained in the ON-lock button 80 (
However, when the ON-lock signal is received (S11: Yes) or the main switch 71 is turned on (S12: Yes) while the ON-lock control is performed (during the repetition of the steps S1, S6, S11, and S12), the controller 106 shifts to step S13. Namely, if the trigger lever 70 (
After shifting to the step S13, the controller 106 changes the lock flag to “0” (S13), and extinguishes the LED contained in the ON-lock button. 80 (S14).
Then, the controller 106 shifts to step S15 through the steps S1, S6, and S7. In the step S15, the controller 106 determines whether the main switch 71 is turned on or not (S15). Namely, the controller 106 determines whether the trigger lever 70 (
As described above, if the trigger lever 70 is operated and the main switch 71 is turned on while the ON-lock control is performed (S12: Yes), the operating state of the motor 30 is maintained until the operation of the trigger lever 70 is released and the main switch 71 is turned off.
Further, if the ON-lock button 80 is operated again and the ON-lock signal is received while the ON-lock control is performed (S11: Yes), the controller 106 shifts to the step S15 through the steps S1, S6, and S7, and further shifts to step S17 to perform the natural-stop control of the motor 30. Namely, if the ON-lock button 80 is operated again while the ON-lock control is performed, the natural-stop control of the motor 30 is performed. Note that, in order to prevent erroneous determination in the steps S7 and S11, the controller 106 determines only the rise of the signal when the ON-lock button 80 is operated, as the reception.
The present invention is not limited to the above-described embodiment, and various modifications and alterations can be made within the scope of the present invention. For example, the present invention is applicable also to an impact tool in which a rotational movement of a motor is converted into a reciprocating motion of a piston through a reciprocating-type conversion mechanism. In addition, the first operating mode in the present invention includes an operating mode in which only an impact force is transmitted to a tool bit, and the second operating mode includes an operating mode in which a rotational force is transmitted to the tool bit. Although the hammer drill according to the above-described embodiment is the impact tool having operating modes such as the hammer mode and the hammer drill mode, the impact tool of the present invention includes an impact tool having operating modes such as a hammer mode and a drill mode and an impact tool having three operating modes such as a hammer mode, a drill mode, and a hammer drill mode.
Note that the natural-stop control including no braking process actively stops the rotation of the motor is one example of the stop control with a smaller braking force than that of the active-stop control. In other words, the natural-stop control and the active-stop control are one example of two stop controls with different braking forces.
The present invention includes an embodiment in which an active-stop control having a relatively small braking force and an active-stop control having a relatively large braking force are selectively performed in accordance with a predetermined condition, and further includes an embodiment in which a controller controls ON/OFF of switching elements to control the number of closed circuits of coils and the formation time of the closed circuit, thereby changing a braking force in accordance with an operating mode. Furthermore, the present invention includes not only an embodiment in which the braking force in the active-stop control is constant, but also an embodiment in which the braking force varies.
1 hammer drill
2 cylinder housing
3 intermediate housing
4 motor housing
5 handle
10 cylinder
20 piston
30 brushless motor (motor)
60 mode-switching dial
62 sensor
70 trigger lever
71 main switch
80 ON-lock button
Number | Date | Country | Kind |
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JP2015-014473 | Jan 2015 | JP | national |
Filing Document | Filing Date | Country | Kind |
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PCT/JP2016/050498 | 1/8/2016 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2016/121458 | 8/4/2016 | WO | A |
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