POWER TOOL

Description

TECHNICAL FIELD

[0001] The invention relates generally to power tools and, more particularly, to a power tool that includes a gear shifting means.

BACKGROUND ART

[0002] When performing work, such as tightening of a screw or drilling, using a power tool which is capable of switching a reduction ratio in response to a workload's volume, at first, a user starts performing the work at a low reduction ratio, that is, a low-torque high-speed rotation, and then increases the reduction ratio, and changes toward a high-torque low-speed rotation side, in order to perform effectively the work. However, with respect to the power tool that requires shifting gear by the user's hand for switching the reduction ratio, the user needs to set to the low reduction ratio at the start of the work, and to switch toward the high reduction ratio side in middle of the work. Therefore, such a power tool increases the burden on the user.

[0003] For this reason, in the following document JP 2009-78349 A, a power tool has been proposed which detects change in a load torque directly or indirectly and shifts gear automatically in response to the change.

[0004] However, with respect to the conventional power tool that performs automatic gear shift, the low reduction ratio is fixed at the start of the work, and in addition, the low reduction ratio is fixed also when a motor is rotated in a reverse rotation direction.

[0005] Therefore, not in the case where the power tool tightens the screw by a normal rotation of the motor but in the case where the power tool loosens the screw by a reverse rotation of the motor, because the low reduction ratio is fixed, the work is started by the low-torque high-speed rotation in spite of needing the high-torque at the start of the work. As a result, the power tool increases the burden on the motor and the like. If the user starts loosening the screw after setting to the high reduction ratio by the user's hand, the burden on the motor and the like can be reduced. However, under such hand operation, the user cannot take advantage of the automatic gear shift.

[0006] Document WO 2010/134431 A1 discloses an electric tool incorporating an automatic transmission, which is automatically shifted according to an external torque acting on the spindle, wherein the transmission is automatically reset as soon as the external torque on the spindle becomes low.

[0007] Document US 2009/277658 A1 discloses a variable speed tool including a switch, a gearbox housing, a motor, an outputting shaft, a multistage transmitting gear train and a gearshift ring which are mated with the motor and the outputting shaft, the gearshift ring having inner teeth, a gearshift fork mated with the gearshift ring, a tension spring arranged between the gearbox housing and the gearshift fork and a torque sensing ring provided with a sliding groove in which the gearshift fork is movably disposed.

SUMMARY OF THE INVENTION

PROBLEMS TO BE RESOLVED BY THE INVENTION

[0008] It is an object of the invention to provide a power tool, which can shift gear automatically, and further can start at reduction ratios respectively suitable for both of works performed by a normal rotation and a reverse rotation of a motor.

MEANS OF SOLVING THE PROBLEMS

[0009] A power tool of the present invention comprises: a motor serving as a rotational power source, the motor being rotatable in a normal rotation direction and a reverse rotation direction; an output unit driven by the motor to be rotated; and a transmission located between the motor and the output unit, the transmission switching a reduction ratio, and wherein the power tool further comprises a control means that makes the transmission perform switching operation of the reduction ratio in response to a workload, the control means changing an initial reduction ratio in the transmission when work is started, in response to a rotation direction of the motor, the initial reduction ratio being set as the reduction ratio in an initial setting.

[0010] In the power tool, preferably, the initial reduction ratio when the rotation direction of the motor is the reverse rotation direction is set higher than the initial reduction ratio when the rotation direction of the motor is the normal rotation direction. Or, preferably, the initial reduction ratio when the rotation direction of the motor is the reverse rotation direction is set lower than the initial reduction ratio when the rotation direction of the motor is the normal rotation direction. Or, preferably, the initial reduction ratio when the rotation direction of the motor is the normal rotation direction is set at a non-low reduction ratio side, and the initial reduction ratio when the rotation direction of the motor is the reverse rotation direction is also set at the non-low reduction ratio side. The power tool can suitably use the above-mentioned configurations.

[0011] The power tool may further comprise a work-start gear shift setting means that changes the initial reduction ratio in the transmission through user operation when the work is started.

[0012] In the power tool, the transmission may be capable of switching the reduction ratio in three speed stages or more.

[0013] In the power tool, the power tool may further comprise an indicating means that indicates the initial reduction ratio to a user.

EFFECT OF THE INVENTION

[0014] The power tool of the present invention can start at reduction ratios respectively suitable for both of works performed by a normal rotation and a reverse rotation of the motor. Therefore, the burden on the power tool can be reduced, and the work efficiency can be improved, and the user can work with comfort.

BRIEF DESCRIPTION OF THE DRAWINGS

[0015] 

Fig. 1 is a flow chart showing operation of one example of a power tool according to an embodiment of the present invention.

Fig. 2 is a block diagram showing one example of the power tool according to the embodiment of the present invention.

Figs. 3(a) and 3(b) are illustration diagrams of torque changes with respect to tightening (loosening) of a screw, and Fig. 3(a) is an illustration diagram in the case where a motor is rotated in a normal rotation direction, and Fig. 3(b) is an illustration diagram in the case where the motor is rotated in a reverse rotation direction.

Fig. 4 is a flow chart showing operation of another example of the power tool according to the embodiment of the present invention.

Figs. 5(a) and 5(b) are illustration diagrams of torque changes with respect to tightening (loosening) of a reverse-threaded screw, and Fig. 5(a) is an illustration diagram in the case where the motor is rotated in the normal rotation direction, and Fig. 5(b) is an illustration diagram in the case where the motor is rotated in the reverse rotation direction.

Fig. 6 is a flow chart showing operation of yet another example of the power tool according to the embodiment of the present invention.

Figs. 7(a) and 7(b) are illustration diagrams of torque changes about works respectively.

Fig. 8 is a block diagram showing another example of the power tool according to the embodiment of the present invention.

Fig. 9 is a flow chart showing operation of said another example of the power tool according to the embodiment of the present invention.

Fig. 10 is a flow chart showing operation of yet another example of the power tool according to the embodiment of the present invention.

Fig. 11 is an illustration diagram of torque change about work of drilling.

Fig. 12 is a block diagram showing another example of the power tool according to the embodiment of the present invention.

Fig. 13 is a plain view showing said another example of the power tool according to the embodiment of the present invention.

BEST MODE FOR CARRYING OUT THE INVENTION

[0016] The present invention will be explained below in detail based on examples shown in Figures. A power tool shown in Fig. 2 is an electric drill driver. The power tool includes: a motor 10 that serves as a power source and is rotatable in a normal rotation direction and a reverse rotation direction; an output unit 12; and a transmission 11 that has a gear shifting function to switch a reduction ratio. Then, the rotational output of the motor 10 is outputted to the output unit 12 through the transmission 11. The reference number 18 shown in Fig. 18 represents a battery pack.

[0017] The transmission 11 is capable of switching the reduction ratio through an electromagnetic member such as a solenoid. The switching operation of the reduction ratio is performed under control of a control circuit 13.

[0018] The control circuit 13 controls rotation of the motor 10 in response to the operation of a trigger switch 14. The control circuit 13 drives the motor 10 through a motor drive circuit 15, and is connected to: a rotation number detection means 16 that detects the rotation number N of the motor 10; and a current detection means 17 that detects a motor drive current I. When the switching operation of the reduction ratio is performed automatically in response to the workload, the control circuit 13 directs the transmission 11 to switch the reduction ratio in the transmission 11 in response to a detection output of a drive status detection means that is constituted by the rotation number detection means 16 and the current detection means 17.

[0019] Here, in the case where an output load is small when the motor 10 is started, the motor drive current I increases, and also the rate of increase in the motor rotation number N increases. In the case where the output load is large, the motor drive current I similarly increases, but the rate of increase in the motor rotation number N decreases or reduces to zero.

[0020] Therefore, with respect to the control circuit 13 that is constituted by one-chip microcomputer or the like in this power tool, the reduction ratio is set at a low side (the reduction ratio 1 in Fig. 1) in an initial setting. Then, when two conditions: "the motor drive current I >= I1 (A)"; and "the rate of increase in the motor rotation number N <= α1" are fulfilled, the reduction ratio is automatically changed to a high side (the reduction ratio 2 in Fig. 1).

[0021] Accordingly, in the case where the output load is small at the time of start and the workload gradually increases with progression of the work, the motor drive current I gradually increases and the motor rotation number N decreases. Then, upon fulfillment of the two conditions: "the motor drive current I >= I1 (A)"; and "the rate of increase in the motor rotation number N <= α1", the control circuit 13 makes the transmission 11 change automatically the reduction ratio to the high side. In the decrease in the motor rotation number N, the rate of increase in the motor rotation number N may become a negative value.

[0022] The automatic gear shift is performed under the above-mentioned conditions. Therefore, even if there is an inrush current generated when the motor 10 is started or an inrush current generated when the user repeatedly performs operation for turning on the trigger switch 14 under non-load state of output in order to return to the brink of the off-state, incorrect switching for the automatic gear shift can be prevented by setting a value of the above-mentioned α1 as a determinable rate in increase.

[0023] In the case where the workload decreases with progression of the work, the reduction ratio is changed toward a direction to be reduced. When the workload decreases, the motor drive current I decreases and the motor rotation number N increases. Therefore, when two conditions: "the motor drive current I <= I3 (A)"; and "the motor rotation number N >= N3" are fulfilled, the reduction ratio is automatically changed to a low reduction ratio (that is, the high-speed side).

[0024] Here, the power tool, such as an electric drill driver, is often used for tightening a screw by rotating the motor 10 in a normal rotation direction. In this case, the workload is small at the start of the work and increases with progression of tightening of the screw. For this reason, preferably, when the above-mentioned automatic gear shift is performed, the reduction ratio is set at the low reduction ratio (a low-torque high-speed rotation) in the initial state as explained above. Preferably, when the workload increases, automatically the reduction ratio is changed to a high reduction ratio (a high-torque low-speed rotation), and when the work is completed and the trigger switch 14 is turned off, the reduction ratio is returned to the low reduction ratio that has been set in the initial state.

[0025] Here, when considering the case where the work is performed by rotating the motor 10 in a reverse rotation direction, there is the work for loosening of the screw that has been tightened, as the major example. In this case, as shown in Fig. 3(b), the workload is large at the early period of the work. At this time, if the low reduction ratio is similarly set in the initial setting, a large load is added to the motor 10 at the start of the work, and further, the actual work for loosening of the screw starts after the reduction ratio is switched to the high reduction ratio. As a result, loss of time may be generated. Also, motor lock may be generated at the start of the work. When not assembling work but disassembling work is performed, most works are performed by rotating the motor in the reverse rotation direction. For this reason, if the initial reduction ratio is set in the case of the reverse rotation direction in the same manner as the case of the normal rotation direction, such a power tool runs into many problems.

[0026] Accordingly, in the power tool, the initial reduction ratio is set at the low reduction ratio when the motor is rotated in the normal rotation direction, and is set at the high reduction ratio when the motor is rotated in the reverse rotation direction, in response to a rotation direction that has been set by a rotation direction switching means 19 that switches the rotation direction of the motor 10. It is preferred that switching of the reduction ratio for this is performed at a timing of when the rotation direction switching means 19 switches the rotation direction of the motor 10.

[0027] Because the initial reduction ratio is switched in response to the rotation direction of the motor 10, as described above, the control circuit 13 in the power tool controls the transmission 11 to start operation in the state of the low reduction ratio when the motor 10 is rotated in the normal rotation direction, and then automatically to switch the reduction ratio to the high reduction ratio with the increase in the workload, and then to return to the low reduction ratio when the work is completed and the trigger switch 14 is turned off.

[0028] When the rotation direction switching means 19 sets the rotation direction of the motor 10 to the reverse rotation direction, the transmission 11 is switched to the state of the high reduction ratio at this time. Therefore, the user can start work in the state of the high-torque low-speed rotation upon turning on the trigger switch 14. Then, the workload gradually decreases, and then if the above-mentioned conditions are fulfilled, the reduction ratio in the transmission 11 is automatically changed to the low reduction ratio side. Then, when the work is completed and the trigger switch 14 is turned off, the reduction ratio in the transmission 11 is automatically returned to the high reduction ratio side.

[0029] The power tool has the advantage that there is no need to separately perform switching operation of the reduction ratio in the transmission 11 not only upon tightening of the screw but also upon loosening of the screw, and further the reduction ratio at the start of each work is set so as to become suitable for the work. Therefore, the user can use the power tool with good usability.

[0030] Here, as a type of the screw, there is a so-called reverse-threaded screw. Tightening of this reverse-threaded screw is performed by rotating the motor 10 in the reverse rotation direction. Loosening of the reverse-threaded screw is performed by rotating the motor 10 in the normal rotation direction. Therefore, in the case where the reverse-threaded screw is used as the work's object, the reverse of setting in the above-mentioned example may be performed. Specifically, the initial reduction ratio may be set to the high reduction ratio when the motor is rotated in the normal rotation direction, and may be set to the low reduction ratio when the motor is rotated in the reverse rotation direction, in response to the rotation direction that has been set by the rotation direction switching means 19. Fig. 4 shows a flow chart in this case. Fig. 5(a) shows torque change when the reverse-threaded screw is loosened by rotating the motor in the normal rotation direction. Fig. 5(b) shows torque change when the reverse-threaded screw is tightened by rotating the motor in the reverse rotation direction.

[0031] In this case, because the reduction ratio is set to the high reduction ratio when the motor 10 is rotated in the normal rotation direction, the user can start work in the state of the high-torque low-speed rotation upon turning on the trigger switch 14. Then, the workload gradually decreases, and then if the predetermined conditions are fulfilled, the reduction ratio is automatically changed to the low reduction ratio side. When the work is completed and the trigger switch 14 is turned off, the reduction ratio in the transmission 11 is automatically returned to the high reduction ratio side.

[0032] When the rotation direction switching means 19 sets the rotation direction of the motor 10 to the reverse rotation direction, the transmission 11 is switched to the state of the low reduction ratio at this time. Therefore, the user can start work in the state of the low reduction ratio upon turning on the trigger switch 14. When the workload increases, the reduction ratio in the transmission 11 is automatically changed to the high reduction ratio. Then, when the work is completed and the trigger switch 14 is turned off, the reduction ratio is returned to the low reduction ratio.

[0033] For this reason, in the case of this example, the power tool can be also used for tightening or the like of the reverse-threaded screw that is the exact opposite of tightening of the normal screw.

[0034] In addition, there is a case where the tightening torque change is different, depending on the type of the work's object, with respect to the work performed by rotating the motor in the normal rotation direction. When a screw with a small diameter is tightened, the torque is changed as shown in Fig. 7(a), and it can be expected that the work is effectively performed by starting at the low-torque high-speed rotation in the low reduction ratio side. On the other hand, when a screw with a large diameter (e.g., a coach screw) is tightened, the torque is changed as shown in Fig. 7(b), and it can be expected that the motor lock is generated soon after the start of the work when the work is started in the low reduction ratio side.

[0035] In this case where high tightening torque is needed soon after the start of the work, the user can effectively perform the work by starting at the high reduction ratio, and the burden on the power tool, caused by the motor lock or the like, can be reduced. Then, when the tightened screw is loosened, high torque is needed at the start of loosening. As a result, also in this case, the high-torque low-speed rotation in the high reduction ratio is suitable for the start of the work. Therefore, in the case where high torque is needed at the start of the work with respect to both of the normal and reverse rotations, as shown in Fig. 6, it is preferred that the high reduction ratio is set in the initial state.

[0036] When it is considered that desirable initial reduction ratio is different depending on the type of the work's object, preferably, the power tool has the configuration that the initial reduction ratio can be set through the user operation. Fig. 8 shows the power tool that further includes a work-start gear shift setting means 20 in which the initial reduction ratio is set through the user operation. The control circuit 13 stores a reduction ratio that has been set by the work-start gear shift setting means 20, and then controls the transmission 11 so as to use the stored reduction ratio as the initial reduction ratio. Fig. 9 shows a flow chart with respect to the power tool.

[0037] In the case where the power tool is adopted to include for example a push switch as the work-start gear shift setting means 20, the initial reduction ratio that is used at the start of the work under the normal rotation state is switched by operating the push switch when the power tool is in the halting state and the rotation direction has been set to the normal rotation direction by the rotation direction switching means 19. The initial reduction ratio that is used at the start of the work under the reverse rotation state is switched by operating the push switch when the power tool is in the halting state and the rotation direction has been set to the reverse rotation direction. Further, the power tool has the configuration that the initial reduction ratio is switched sequentially by repeating the ON operation of the push switch. Of course, the work-start gear shift setting means 20 is not limited to the push switch. As described above, the power tool has the configuration that the initial reduction ratio is changed in response to the rotation direction that has been set by the rotation direction switching means 19, and therefore, the power tool can perform the setting operations for the initial reduction ratio when the motor is rotated in the normal rotation direction and the initial reduction ratio when the motor is rotated in the reverse rotation direction, while being reduced in the number of components. Further, the power tool can provide the user good usability.

[0038] There is a case where the user performs the same work continuously. In this case, the user can perform the same work continuously in the state, by setting the initial reduction ratio only once in response to the contents of the work. Therefore, the work efficiency can be improved, and the efficiency in the use of one power tool can be also improved.

[0039] The power tool of the present invention may have the configuration that the transmission 11 is capable of switching the reduction ratio in three speed stages. Fig. 10 shows a flow chart in this case.

[0040] In the state where the reduction ratio is set in the lowest stage, the reduction ratio is switched to the middle reduction ratio that is one stage higher than the lowest reduction ratio, upon fulfillment of two conditions: "the motor drive current I >= I1 (A)"; and "the rate of increase in the motor rotation number N <= α1". In this state, further, when two conditions: "the motor drive current I >= I2 (A)"; and "the rate of increase in the motor rotation number N <= α2" are fulfilled, the reduction ratio is automatically changed to a higher side.

[0041] On the other hand, in the state where the reduction ratio is set in the highest stage, the reduction ratio is switched to the middle reduction ratio, upon fulfillment of two conditions: "the motor drive current I <= I4 (A)"; and "the motor rotation number N >= N4". In this state, when two conditions: "the motor drive current I <= I3 (A)"; and "the motor rotation number N >= N3" are fulfilled, the automatic gear shift to a high-speed side is performed.

[0042] As described above, in the case where the transmission 11 is capable of switching the reduction ratio in three speed stages, preferably, the initial reduction ratio is switched to the middle reduction ratio (a middle-torque middle-speed rotation), in both cases of the normal rotation direction and the reverse rotation direction. Here, in the case of drilling a hole in wood, the user may need to make holes with various diameters, such as ϕ 10mm to ϕ 30mm. Fig. 11 shows the torque characteristic with respect to drilling the hole in wood. As shown in Fig. 11, the torque increases at the start of the drilling and then decreases gradually and then becomes stable. Finally, when the drill penetrates through wood, the torque reduces to zero. For this reason, when the work is started at the low reduction ratio, the reduction ratio is changed to the middle reduction ratio side soon after the start of the drilling, and then the work is completed while the middle reduction ratio is maintained. If the work needs high torque, the middle reduction ratio is further changed to the high reduction ratio and the work is then completed. That is, in the case of drilling a hole in wood, there is little need to perform the work at the low reduction ratio. Therefore, by starting at the middle reduction ratio, the work can be effectively performed without unnecessary gear shift and the burden on the user can be reduced.

[0043] When it is also considered that the power tool is applied to the above-mentioned tightening or the like of the screw, it is preferred that the power tool includes the work-start gear shift setting means 20 that is capable of changing the initial reduction ratio through user operation.

[0044] Figs. 12 and 13 show the power tool that further includes an indicating means 21 indicating the above-mentioned initial reduction ratio that has been initially set to a user. Preferably, this indicating means 21 is provided with three light emitting diodes located at the upper side of the power tool for example. The respective three light emitting diodes correspond to the low reduction ratio (H), the middle reduction ratio (M), and the high reduction ratio (L). In this case, the indicating means 21 turns on a light emitting diode corresponding to the initial reduction ratio at the start of the work in the rotation direction that has been set by the rotation direction switching means 19. In this way, the indicating means 21 notifies the user of the initial reduction ratio in the present rotation direction of the motor.

[0045] In addition, the indicating means 21 may be provided with a total of six light emitting diodes, three of which are used for the normal rotation direction, and the remaining three are used for reverse rotation direction. Because the user can easily recognize whether it is a predetermined initial reduction ratio, or an initial reduction ratio that has been set by the user, the power tool can prevent failure of the work caused by performing the work at the wrong initial reduction ratio.

[0046] As explained above, the power tool of the present invention includes the motor 10, the transmission 11 and the output unit 12, as shown in Fig. 2. The motor 10 is defined as a rotational power source. The motor 10 is configured to be rotatable in regard to normal and reverse rotations. More specifically, the motor 10 is configured to be rotatable in regard to the normal and reverse rotations, thereby being rotated in the normal rotation direction and in the reverse rotation direction. The output unit 12 is configured to be driven by the motor 10 to be rotated.

[0047] The power tool further includes the control means. The control means is configured to make the transmission 11 perform the switching operation of the reduction ratio in response to the workload. The control means changes the initial reduction ratio in the transmission 11 when work is started, in response to a rotation direction of the motor 10. The initial reduction ratio is set as the reduction ratio in an initial setting.

[0048] The control means is the control circuit 13 as shown in Fig. 2 for example.

[0049] As shown in the flow chart of Fig. 1, the initial reduction ratio when the rotation direction of the motor 10 is the reverse rotation direction is set higher than the initial reduction ratio when the rotation direction of the motor 10 is the normal rotation direction.

[0050] When explained from other aspect, the control means sets the reduction ratio, so that the initial reduction ratio when the rotation direction of the motor 10 is the reverse rotation direction is set higher than the initial reduction ratio when the rotation direction of the motor 10 is the normal rotation direction.

[0051] When further explained from other aspect, the rotation direction switching means 19 is configured to switch the rotation direction of the motor 10. This makes the motor 10 rotate in the normal rotation direction or in the reverse rotation direction, in response to the rotation direction of the motor 10 that has been set by the rotation direction switching means 19. When the rotation direction switching means 19 sets the rotation direction of the motor 10 so that the motor 10 is rotated in the normal rotation direction, the control means is configured to rotate the motor 10 at a first reduction ratio. When the rotation direction switching means 19 sets the rotation direction of the motor 10 so that the motor 10 is rotated in the reverse rotation direction, the control means is configured to rotate the motor 10 at a second reduction ratio. In this case, the second reduction ratio is higher than the first reduction ratio.

[0052] The rotation direction switching means 19 may be a switch or a lever provided with the power tool for example, but is not limited to those. That is, as long as the rotation direction switching means 19 is a component that is capable of switching the rotation direction of the motor 10, anything can be adopted.

[0053] Also, there is a case where the power tool is used for a reverse-threaded screw.

[0054] Therefore, as shown in the flow chart of Fig. 4, the initial reduction ratio when the rotation direction of the motor 10 is the reverse rotation direction may be set lower than the initial reduction ratio when the rotation direction of the motor 10 is the normal rotation direction.

[0055] When explained from other aspect, the control means sets the reduction ratio, so that the initial reduction ratio when the rotation direction of the motor 10 is the reverse rotation direction is set lower than the initial reduction ratio when the rotation direction of the motor 10 is the normal rotation direction.

[0056] When further explained from other aspect, the rotation direction switching means 19 is configured to switch the rotation direction of the motor 10. This makes the motor 10 rotate in the normal rotation direction or in the reverse rotation direction, in response to the rotation direction of the motor 10 that has been set by the rotation direction switching means 19. When the rotation direction switching means 19 sets the rotation direction of the motor 10 so that the motor 10 is rotated in the reverse rotation direction, the control means is configured to rotate the motor 10 at the first reduction ratio. When the rotation direction switching means 19 sets the rotation direction of the motor 10 so that the motor 10 is rotated in the normal rotation direction, the control means is configured to rotate the motor 10 at the second reduction ratio. In this case, the second reduction ratio is higher than the first reduction ratio.

[0057] The initial reduction ratio when the rotation direction of the motor 10 is the normal rotation direction may be set at a non-low reduction ratio side and also the initial reduction ratio when the rotation direction of the motor 10 is the reverse rotation direction may be also set at the non-low reduction ratio side.

[0058] As shown in Fig. 8, the power tool further includes the work-start gear shift setting means 20 that changes the initial reduction ratio in the transmission 11 through user operation when the work is started.

[0059] As shown in Fig. 10, the transmission 11 is capable of switching the reduction ratio in three speed stages or more.

[0060] As shown in Fig. 13, the power tool further includes the indicating means that indicates the initial reduction ratio to a user.

[0061] Further, as shown in Fig. 2, the power tool includes the rotation direction switching means 19. The rotation direction switching means 19 is configured to switch the rotation direction of the motor 10. This makes the motor 10 rotate in the normal rotation direction or in the reverse rotation direction, in response to the rotation direction of the motor 10 set by the rotation direction switching means 19. When the rotation direction switching means 19 sets the rotation direction of the motor 10 so that the motor 10 is rotated in the normal rotation direction, the transmission 11 is configured to set the reduction ratio to be lower than a predetermined reduction ratio. When the rotation direction switching means 19 sets the rotation direction of the motor 10 so that the motor 10 is rotated in the reverse rotation direction, the transmission 11 is configured to set the reduction ratio to be higher than a predetermined reduction ratio.

[0062] Further, as shown in Fig. 2, the power tool includes the motor rotation number detection means 16 and the motor current detection means 17. The motor rotation number detection means 16 is configured to detect the rotation number of the motor 10. The control means is configured to detect whether or not the information obtained from the rotation number of the motor 10 fulfills a first rotation condition. Then, the motor current detection means 17 is configured to detect a drive current in the motor 10. The control means is configured to detect whether or not a current value of the drive current in the motor 10 fulfills a first current state. When the rotation direction switching means 19 sets the rotation direction of the motor 10 so that the motor 10 is rotated in the normal rotation direction, the control means is configured to control the transmission 11 to set the reduction ratio to be lower than a predetermined reduction ratio. When the control means detects: that the rotation information detected by the motor rotation number detection means 16 fulfills the first rotation condition; and that the current value of the drive current in the motor 10 detected by the motor current detection means 17 fulfills the first current state, and further the rotation direction switching means 19 makes the motor 10 rotate in the normal rotation direction, the control means is configured to control the transmission 11 to set the reduction ratio to be higher than a predetermined reduction ratio.

[0063] As one example, the rotation information represents the rate of increase in the rotation number of the motor 10. The control means is configured to detect whether or not the first rotation condition is fulfilled: the rate of increase in the rotation number of the motor 10 is less than or equal to a predetermined rate of increase. The control means is configured to detect whether or not the first current state is fulfilled: the current value of the drive current in the motor 10 is more than or equal to a first current value.

[0064] As one example, the rotation information is the rotation number of the motor 10, but is not limited to that. That is, the rotation information may be the rate of increase in the rotation number of the motor 10. Or, the rotation information may be information that corresponds to the rotation number of the motor 10. Or, the rotation information may be information that corresponds to the rate of increase in the rotation number of the motor 10.

[0065] The control means further includes the motor rotation number detection means 16 and the motor current detection means 17. The motor rotation number detection means 16 is configured to detect the rotation number of the motor 10. The control means is configured to detect whether or not the rotation information obtained from the rotation number of the motor 10 fulfills a second rotation condition. The motor current detection means 17 is configured to detect the current value of the drive current in the motor 10. The control means is configured to detect whether or not a current value of the drive current in the motor 10 fulfills a second current state. When the rotation direction switching means 19 sets the rotation direction of the motor 10 so that the motor 10 is rotated in the reverse rotation direction, the transmission 11 is configured to set the reduction ratio to be higher than a predetermined reduction ratio. When the control means detects: that the rotation information detected by the motor rotation number detection means 16 fulfills the second rotation condition; and that the current value of the drive current in the motor 10 detected by the motor current detection means 17 fulfills the second current state, and further the rotation direction switching means 19 makes the motor 10 rotate in the reverse rotation direction, the transmission 11 is configured to set the reduction ratio to be lower than a predetermined reduction ratio.

[0066] As one example, the rotation information represents the rotation number of the motor 10. The control means is configured to detect whether or not the second rotation condition is fulfilled: the rotation number of the motor 10 is more than or equal to a predetermined rotation number. The control means is configured to detect whether or not the second current state is fulfilled: the current value of the drive current in the motor 10 is less than or equal to a second current value.

[0067] The power tool further includes the work-start gear shift setting means 20. The work-start gear shift setting means 20 is configured to change the reduction ratio when operation of the motor 10 is started.

[0068] The work-start gear shift setting means 20 is configured to have a first setting state or a second setting state selectively. When the work-start gear shift setting means 20 has the first setting state and the rotation direction switching means 19 sets the rotation direction of the motor 10 so that the motor 10 is rotated in the normal rotation direction, the transmission 11 is configured to set the reduction ratio to be lower than a predetermined reduction ratio. When the work-start gear shift setting means 20 has the second setting state and the rotation direction switching means 19 sets the rotation direction of the motor 10 so that the motor 10 is rotated in the normal rotation direction, the transmission 11 is configured to set the reduction ratio to be higher than a predetermined reduction ratio.

[0069] As explained above, the power tool may be used for removing a screw, and may be used with respect to a reverse-threaded screw.

[0070] In those cases, the work-start gear shift setting means 20 is configured to have a first setting state or a second setting state selectively. When the work-start gear shift setting means 20 has the first setting state and the rotation direction switching means 19 sets the rotation direction of the motor 10 so that the motor 10 is rotated in the reverse rotation direction, the transmission 11 is configured to set the reduction ratio to be higher than a predetermined reduction ratio. When the work-start gear shift setting means 20 has the second setting state and the rotation direction switching means 19 sets the rotation direction of the motor 10 so that the motor 10 is rotated in the reverse rotation direction, the transmission 11 is configured to set the reduction ratio to be lower than a predetermined reduction ratio.

[0071] In the above-mentioned explanations, the rotation direction of the motor 10 when the motor 10 is rotated in the normal rotation direction is a direction opposite to the rotation direction of the motor 10 when the motor 10 is rotated in the reverse rotation direction. Accordingly, in the case where the rotation direction of the motor 10 is defined as the rotation direction to the right when the motor 10 is rotated in the normal rotation direction, the rotation direction of the motor 10 is defined as the rotation direction to the left when the motor 10 is rotated in the reverse rotation direction. In the case where the rotation direction of the motor 10 is defined as the rotation direction to the left when the motor 10 is rotated in the normal rotation direction, the rotation direction of the motor 10 is defined as the rotation direction to the right when the motor 10 is rotated in the reverse rotation direction.

EXPLANATION OF REFERENCE NUMERALS

[0072] 

10

Motor

11

Transmission

12

Output unit

13

Control unit

14

Trigger switch

15

Motor drive circuit

16

Motor rotation number detection means

17

Motor current detection means

18

Battery pack

19

Rotation direction switching means

20

Work-start gear shift setting means

21

Indicating means

Claims

1. A power tool, comprising:

a motor (10) serving as a rotational power source, the motor (10) being rotatable in a normal rotation direction and a reverse rotation direction;

an output unit (12) driven by the motor (10) to be rotated; and

a transmission (11) located between the motor and the output unit (12), the transmission (11) switching a reduction ratio,

wherein the power tool further comprises a control means (13) configured to make the transmission (11) perform switching operation of the reduction ratio in response to a workload, characterized in that

the control means (13) is configured to change an initial reduction ratio in the transmission (11) when work is started, in response to a rotation direction of the motor (10), the initial reduction ratio being set as the reduction ratio in an initial setting.

2. The power tool according to claim 1,
wherein the initial reduction ratio when the rotation direction of the motor (10) is the reverse rotation direction is set higher than the initial reduction ratio when the rotation direction of the motor (10) is the normal rotation direction.

3. The power tool according to claim 1,
wherein the initial reduction ratio when the rotation direction of the motor (10) is the reverse rotation direction is set lower than the initial reduction ratio when the rotation direction of the motor (10) is the normal rotation direction.

4. The power tool according to claim 1,
wherein the initial reduction ratio when the rotation direction of the motor (10) is the normal rotation direction is set at a non-low reduction ratio side, the initial reduction ratio when the rotation direction of the motor (10) is the reverse rotation direction being also set at the non-low reduction ratio side.

5. The power tool according to any one of claims 1 to 4, further comprises a work-start gear shift setting means (20) configured to change the initial reduction ratio in the transmission (11) through user operation when the work is started.

6. The power tool according to any one of claims 1 to 5,
wherein the transmission (11) is capable of switching the reduction ratio in three speed stages or more.

7. The power tool according to any one of claims 1 to 6, further comprises an indicating means (21) configured to indicate the initial reduction ratio to a user.

Ansprüche

1. Elektrowerkzeug, aufweisend:

einen Motor (10), der als eine Rotationsenergiequelle dient, wobei der Motor (10) in einer normalen Drehrichtung und in einer Rückwärtsdrehrichtung drehend antreibbar ist;

eine Ausgabeeinheit (12), die durch den Motor (10) angetrieben wird, um gedreht zu werden; und

ein Getriebe (11), das zwischen dem Motor und der Ausgabeeinheit (12) angeordnet ist, wobei das Getriebe (11) ein Untersetzungsverhältnis schaltet,

wobei das Elektrowerkzeug ferner ein Steuerungsmittel (13) aufweist, das dazu eingerichtet ist, das Getriebe (11) dazu zu veranlassen, in Reaktion auf eine Arbeitslast einen Schaltvorgang des Untersetzungsverhältnisses durchzuführen, dadurch gekennzeichnet, dass

das Steuerungsmittel (13) dafür ausgelegt ist, ein anfängliches Untersetzungsverhältnis in dem Getriebe (11) bei Beginn der Arbeit in Reaktion auf eine Drehrichtung des Motors (10) zu wechseln, wobei das anfängliche Untersetzungsverhältnis als das Untersetzungsverhältnis in einer Anfangseinstellung eingestellt wird.

2. Elektrowerkzeug nach Anspruch 1,
wobei das anfängliche Untersetzungsverhältnis, wenn die Drehrichtung des Motors (10) die Rückwärtsdrehrichtung ist, höher als das anfängliche Untersetzungsverhältnis eingestellt wird, wenn die Drehrichtung des Motors (10) die normale Drehrichtung ist.

3. Elektrowerkzeug nach Anspruch 1,
wobei das anfängliche Untersetzungsverhältnis, wenn die Drehrichtung des Motors (10) die Rückwärtsdrehrichtung ist, niedriger eingestellt wird als das anfängliche Untersetzungsverhältnis, wenn die Drehrichtung des Motors (10) die normale Drehrichtung ist.

4. Elektrowerkzeug nach Anspruch 1,
wobei das anfängliche Untersetzungsverhältnis, wenn die Drehrichtung des Motors (10) die normale Drehrichtung ist, auf eine nicht niedrige Seite des Untersetzungsverhältnisses eingestellt wird, wobei das anfängliche Untersetzungsverhältnis, wenn die Drehrichtung des Motors (10) die Rückwärtsdrehrichtung ist, ebenfalls auf die nicht niedrige Seite des Untersetzungsverhältnisses eingestellt wird.

5. Elektrowerkzeug nach einem beliebigen der Ansprüche 1 bis 4, das ferner ein Arbeitsbeginnschalthebeleinstellmittel (20) aufweist, das dazu eingerichtet ist, das anfängliche Untersetzungsverhältnis in dem Getriebe (11) bei Beginn der Arbeit durch eine Benutzerhandlung zu ändern.

6. Elektrowerkzeug nach einem beliebigen der Ansprüche 1 bis 5,
wobei das Getriebe (11) in der Lage ist, das Untersetzungsverhältnis in drei oder mehr Geschwindigkeitsstufen zu schalten.

7. Elektrowerkzeug nach einem beliebigen der Ansprüche 1 bis 6, das ferner ein Anzeigemittel (21) aufweist, das dafür ausgelegt ist, das anfängliche Untersetzungsverhältnis für einen Benutzer anzuzeigen.

Revendications

1. Outil électrique, comportant :

un moteur (10) servant de source d'énergie de rotation, le moteur (10) étant rotatif dans un sens de rotation normal et dans un sens de rotation inverse ;

une unité de sortie (12) entraînée en rotation par le moteur (10) ; et

une transmission (11) située entre le moteur et l'unité de sortie (12), la transmission (11) commutant un rapport de réduction ;

dans lequel l'outil électrique comporte en outre un moyen de commande (13) configuré de manière à amener la transmission (11) à mettre en oeuvre une opération de commutation du rapport de réduction en réponse à une charge de travail, caractérisé en ce que

le moyen de commande (13) est configuré de manière à modifier un rapport de réduction initial dans la transmission (11) lorsque le travail est commencé, en réponse à un sens de rotation du moteur (10), le rapport de réduction initial étant réglé en tant que rapport de réduction dans un réglage initial.

2. Outil électrique selon la revendication 1,
dans lequel le rapport de réduction initial lorsque le sens de rotation du moteur (10) est le sens de rotation inverse est réglé de manière à être supérieur au rapport de réduction initial lorsque le sens de rotation du moteur (10) est le sens de rotation normal.

3. Outil électrique selon la revendication 1,
dans lequel le rapport de réduction initial lorsque le sens de rotation du moteur (10) est le sens de rotation inverse est réglé de manière à être inférieur au rapport de réduction initial lorsque le sens de rotation du moteur (10) est le sens de rotation normal.

4. Outil électrique selon la revendication 1,
dans lequel le rapport de réduction initial lorsque le sens de rotation du moteur (10) est le sens de rotation normal est réglé sur un côté de rapport de réduction non faible, le rapport de réduction initial lorsque le sens de rotation du moteur (10) est le sens de rotation inverse étant également réglé sur le côté de rapport de réduction non faible.

5. Outil électrique selon l'une quelconque des revendications 1 à 4, comportant en outre un moyen de réglage de changement de rapport de démarrage de travail (20) configuré de manière à modifier le rapport de réduction initial dans la transmission (11) par le biais d'une opération de l'utilisateur au démarrage du travail.

6. Outil électrique selon l'une quelconque des revendications 1 à 5,
dans lequel la transmission (11) est en mesure de commuter le rapport de réduction en trois stades de vitesse ou plus.

7. Outil électrique selon l'une quelconque des revendications 1 à 6, comportant en outre un moyen d'indication (21) configuré de manière à indiquer le rapport de réduction initial à un utilisateur.

Drawing