FIELD OF THE INVENTION
The present invention relates to power tools, and more particularly to rotary hammers.
BACKGROUND OF THE INVENTION
Power tools such as, for instance, rotary hammers, are generally operable in at least two modes, combined hammer and drilling mode and hammer only mode. In combined hammer and drilling mode, the rotary hammer imparts rotation and axials impacts to a drill bit while performing a drilling or breaking operation on a work surface. In hammer only mode, the rotary hammer only imparts axial impacts to the drill bit. While in hammer only mode, a user may desire a lock-on of a trigger to continuously activate a motor to impart axial impacts without the need to manually depress the trigger.
SUMMARY OF THE INVENTION
The invention provides, in one aspect, a rotary hammer operable in a plurality of modes in which reciprocating of a tool bit along a drive axis and/or rotation of the tool bit about the drive axis occurs. The rotary hammer includes a motor, a spindle, an impact mechanism, a trigger, a mode switch, a motor direction switch, and a control unit. The motor is rotatable in a first rotational direction and an opposite, second rotational direction. The spindle is selectively coupled to the motor to receive torque therefrom, causing the spindle and the attached tool bit to rotate in either the first rotational direction or the second rotational direction. The impact mechanism is selectively coupled to the motor to receive torque therefrom and impart axial impacts upon the tool bit. The trigger is movable between an off position, in which the motor is not energized, and an on position in which the motor is energized. The mode switch is configured to select a mode of operation between a first operating mode and a second operating mode. The motor direction switch is configured to select a direction of operation of the motor between the first rotational direction and the second rotational direction. The control unit is configured to override an output of the motor direction switch by determining that the mode switch corresponds with the second operating mode, determining that the motor direction switch corresponds with the first rotational direction, and by driving the motor in the second rotational direction upon activation of the trigger to the on position.
The invention provides, in another aspect, a method of operating a rotary hammer. The method includes actuating a mode switch to select a mode of operation for the rotary hammer between a first operating mode and a second operating mode and actuating a motor direction switch to select a direction of motor operation between a first rotational direction and a second rotational direction. The method further includes determining that the mode switch is in a state corresponding with the second operating mode and determining that the motor direction switch is in a state corresponding with the first rotational direction. The method includes overriding an output of the motor direction switch by driving the motor in the second rotational direction.
The invention provides, in another aspect, a rotary hammer operable in a plurality of modes in which reciprocation of a tool bit along a drive axis and/or rotation of the tool bit about the drive axis occurs. The rotary hammer includes a motor, a spindle, an impact mechanism, a trigger, a latch, a lock status switch, and a control unit. The motor is rotatable in a first rotational direction and an opposite, second rotational direction. The spindle is selectively coupled to the motor to receive torque therefrom, causing the spindle and the attached tool bit to rotate in either the first rotational direction or the second rotational direction. The impact mechanism is selectively coupled to the motor to receive toque therefrom and impart axial impacts upon the tool bit. The trigger is movable between an off position, in which the motor is not energized, a fully-on position, in which the motor is energized at full speed, and an intermediate position in which the motor is energized at an intermediate speed less than full speed. The latch is configured to hold the trigger in one of the intermediate position or the fully-on position. The lock status switch is configured to detect the latch holding the trigger in one of the intermediate position or the fully-on position. The control unit is configured to maintain operation of the motor at full speed in response to the lock status switch detecting the latch holding the trigger in either the intermediate position or the fully-on position.
The invention provides, in another aspect, a method of operating a rotary hammer. The method includes actuating a latch to hold a trigger in one of an intermediate position in which a motor is energized and a fully-on position in which the motor is energized at full speed. The method further includes detecting, with a lock status switch in an activated state, that the latch is holding the trigger in one of the intermediate position or the fully-on position. The method further includes maintaining operation of the motor at full speed in response to the lock status switch in the activated state.
Other aspects of the invention will become apparent by consideration of the detailed description and accompanying drawings.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1 is a cross-sectional view of a rotary hammer.
FIG. 2A is a top view of the rotary hammer of FIG. 1 illustrating a mode selector dial.
FIG. 2B is a perspective view of the mode selector dial of FIG. 2A.
FIG. 2C is a perspective view the rotary hammer of FIG. 1 in a combined hammer and drilling mode.
FIG. 2D is a perspective view of the rotary hammer of FIG. 1 in a hammer only mode.
FIG. 2E is a perspective view of the rotary hammer of FIG. 1 in a chisel adjustment mode.
FIG. 3 is a top view of the rotary hammer of FIG. 1, with portions removed, illustrating a chisel lock-on mechanism.
FIG. 4A is a cross-sectional view of the rotary hammer of FIG. 1 illustrating the chisel lock-on mechanism in a disengaged position.
FIG. 4B is a cross-sectional view of the rotary hammer of FIG. 1 illustrating the chisel lock-on mechanism in an engaged position.
FIG. 5A is a flow chart illustrating direction and mode selection of the rotary hammer of FIG. 1.
FIG. 5B is a flow chart illustrating speed selection of the rotary hammer of FIG. 1.
Before any embodiments of the invention are explained in detail, it is to be understood that the invention is not limited in its application to the details of construction and the arrangement of components set forth in the following description or illustrated in the following drawings. The invention is capable of other embodiments and of being practiced or of being carried out in various ways.
DETAILED DESCRIPTION
FIG. 1 illustrates a reciprocating percussive power tool, such as a rotary hammer 10, according to an embodiment of the invention. The rotary hammer 10 includes a housing 14, a motor 18 disposed within the housing 14, and a rotatable spindle 22 coupled to the motor 18 for receiving torque from the motor 18. In the illustrated embodiment, the rotary hammer 10 includes a quick-release mechanism 24 coupled for co-rotation with the spindle 22 to facilitate quick removal and replacement of a tool bit 25. The tool bit 25 includes a groove 25a in which a detent member 26 of the quick-release mechanism 24 is received to constrain axial movement of the tool bit 25 to the length of the groove 25a. The rotary hammer 10 defines a tool bit axis 27, which in the illustrated embodiment is coaxial with a rotational axis 28 of the spindle 22.
In the illustrated embodiment, the motor 18 is configured as a brushless direct current (BLDC) motor that receives power from an on-board power source 29 (e.g., a battery). The battery may include any of a number of different nominal voltages (e.g., 12V, 18V, etc.), and may be configured having any of a number of different chemistries (e.g., lithium-ion, nickel-cadmium, etc.). In some embodiments, the battery is a battery pack removably coupled to the housing 14. In other embodiments, the motor 18 may be powered by a remote power source (e.g., a household electrical outlet) through a power cord (not shown). The motor 18 is selectively activated by depressing an actuating member, such as a trigger 30, which in turn actuates an electrical switch 33. The switch 33 is electrically connected to the motor 18 via an electronic control unit 200 (i.e., PCBA 200; including, for example, a microprocessor and/or one or more circuits) for controlling operation of the motor 18.
The rotary hammer 10 further includes an impact mechanism 32 having a reciprocating piston 34 disposed within the spindle 22, a striker 38 that is selectively reciprocable within the spindle 22 in response to reciprocation of the piston 34, and an anvil 42 that is impacted by the striker 38 when the striker 38 reciprocates toward the tool bit 25. Torque from the motor 18 is transferred to the spindle 22 by a transmission 46. In the illustrated embodiment of the rotary hammer 10, the transmission 46 includes an input gear 50 engaged with a pinion 54 on an output shaft 58 of the motor 18, an intermediate pinion 62 coupled for co-rotation with the input gear 50 and an output gear 66 coupled for co-rotation with the spindle 22 and engaged with the intermediate pinion 62. The output gear 66 is secured to the spindle 22 using a spline-fit or a key and keyway arrangement, for example, that facilitates axial movement of the spindle 22 relative to the output gear 66 yet prevents relative rotation between the spindle 22 and the output gear 66. A clutch mechanism 70 is incorporated with the input gear 50 to limit the amount of torque that may be transferred from the motor 18 to the spindle 22.
With continued reference to FIG. 1, the impact mechanism 32 is driven by a crank gear 78 that is rotatably supported within the housing 14 on a stationary shaft 82, which defines a central axis 86 that is offset from a rotational axis 90 of the output shaft 58 and pinion 54. As shown in FIG. 1, the respective axes 86, 90 of the stationary shaft 82 and output shaft 58 are parallel. Likewise, respective axes 90, 98 of the output shaft 58 and the intermediate pinion 62 are also parallel. The impact mechanism 32 also includes a crank shaft 102 rotatably supported on the stationary shaft 82 and having an eccentric pin 110. The impact mechanism 32 further includes a connecting rod 116 interconnecting the piston 34 and the eccentric pin 110.
As shown in FIG. 2A, the rotary hammer 10 includes a mode selection dial 130 which is movable (e.g., rotatable) by an operator to switch between various positions corresponding with various operating modes of the rotary hammer 10. In a “combined hammer and drilling” mode (e.g., Position 1), the motor 18 is drivably coupled to the piston 34 for reciprocating the piston 34 while the spindle rotates (i.e., the rotary hammer 10 is configured to axially and rotationally move the tool bit 25). In a “hammer only” mode (i.e., “chisel” mode, e.g., Position 3), the motor 18 is drivingly coupled to the piston 34 for reciprocation while the spindle 22 is not rotated by the motor 18 (i.e., the rotary hammer 10 is configured to axially move the tool bit 25). In a “drill only” mode, the motor 18 is drivingly coupled to the spindle 22 for rotation, while the piston 34 is not driven by the motor 18 (i.e., the rotary hammer 10 is configured to rotationally move the tool bit 25). The “drill only” mode is not provided in the illustrated rotary hammer 10 but, in other embodiments, may be included in any combination with the other operating modes described herein. In a “chisel adjustment mode” (i.e., “hammer adjustment mode”, e.g., Positions 2, 4), the spindle 22 is unlocked from the motor 18 and permitted to freely rotate within the housing 14 such that a user may adjust the orientation of the spindle 22, and thus the tool bit 25, to a desired orientation.
FIG. 2A illustrates that the mode selection dial 130 is movable between four discrete positions (positions 1-4) each corresponding to one of the aforementioned operating modes of the rotary hammer 10. However, more or fewer positions of the mode selection dial 130 (and corresponding operating modes of the rotary hammer 10) are possible. In the illustrated embodiment, the positions 1-4 which correlate to the modes of operation are spaced apart from one another approximately 90 degrees. Other spacings of the positions 1-4 are possible. Similarly, each of the positions 1-4 may correspond with and indicate any one of the aforementioned operating modes of the rotary hammer 10 (e.g., the combined hammer and drilling mode may correlate to any one of the positions 1-4). The mode selection dial 130 is configured to be moved by a user of the rotary hammer 10.
With reference to the illustrated embodiment of FIGS. 2A and 2B, position 1 in which the mode selection dial 130 faces a rear of the rotary hammer 10 correlates with the “combined hammer and drilling” mode (i.e., “chisel” mode). Position 3 in which the mode selection dial 130 faces a front of the rotary hammer 10 correlates with the “hammer only” mode. Positions 2 and 4, where the mode selection dial 130 faces lateral sides of the rotary hammer 10 each correlate with the “chisel adjustment mode” (i.e., “hammer adjustment mode”). As noted above, other arrangements of the positions 1-4 are possible.
As illustrated in FIGS. 2B-2D, the mode selection dial 130 is one component of a mode selection assembly 300. The mode selection assembly 300 includes each of the below described elements having reference numerals in the “300” series. The mode selection dial 130 is coupled to a cam 304. The cam 304 interfaces with a selector fork 308. More specifically, the cam 304 interfaces with a cam feature 312 of the selector fork 308. Opposite the cam feature 312, the selector fork 308 further includes a collar engagement plate 316 which interfaces with a selector collar 320. More specifically, the collar engagement plate 316 is positioned between axial ends of an annular recess 324 of the selector collar 320. The selector collar 320 is coupled for co-rotation with the spindle 22. The selector collar 320 further includes a front end 328 and a rear end 332 each including a plurality of axially extending ribs 336. The mode selection assembly 300 further includes a locking plate 340 that surrounds the spindle 22 and is configured to couple the selector collar 320 with the transmission 46. The locking plate 340 includes at least one recess 344 configured to interface with at least one rib 336 at the rear end 332 of the selector collar 320. The mode selection assembly 300 further includes a spindle gear 348 which is rotatable with respect to the spindle 22. When in Position 1 (FIG. 2C described below), the spindle gear 348 is configured to receive torque from the motor 18, and to transfer the torque from the motor 18 (e.g., through a gear train [pinion gear] meshed with the spindle gear 348) to the spindle 22 through the selector collar 320. The spindle gear 348 includes at least one recess 352 configured to interface with at least one rib 336 at the front end 328 of the selector collar 320. In some examples, the mode selection assembly 300 may further include one or more biasing members to bias the mode selection dial 130 and/or the mode selection assembly 300 to, after selection of a Position 1-4, retain the selected Position 1-4.
FIG. 2C illustrates the mode selection dial 130 and the mode selection assembly 300 in Position 1 which corresponds with the “combined hammer and drilling” mode, which is a “normal” operating condition of the rotary hammer 10. As illustrated in FIG. 2C, the mode selection dial 130 faces rearwardly in parallel with the tool bit axis 27, and the cam 304 is positioned rearward of the feature 312 of the selector fork 308. Due to the aforementioned interconnections of the mode selection assembly 300, the selector fork 308 is located at an advanced position along the tool bit axis 27, and the collar engagement plate 316 carries the selector collar 320 such that the ribs 336 at the front end 328 of the selector collar 320 are received within the recess(es) 352 of the spindle gear 348. In Position 1, the selector collar 320 is configured to transfer torque from the motor 18 to the spindle 22 through the spindle gear 348. As a result, in Position 1, the mode selection assembly 300 configures the rotary hammer 10 for imparting reciprocating axial impacts as well as rotation about the tool bit axis 27 upon the tool bit 25.
FIG. 2D illustrates the mode selection dial 130 and the mode selection assembly 300 in Position 3 which corresponds with the “hammer only” mode. As illustrated in FIG. 2D, the mode selection dial 130 faces forwardly in parallel with the tool bit axis 27, and the cam 304 is positioned rearward of the feature 312 of the selector fork 308. Due to the aforementioned interconnections of the mode selection assembly 300, the selector fork 308 is located at a retreated position along the tool bit axis 27, and the collar engagement plate 316 carries the selector collar 320 such that the ribs 336 at the rear end 332 of the selector collar 320 interact with the recess(es) 131k of the locking plate 340. In Position 3, due to the interaction between the ribs 336 and the recess 344, the spindle 22 is rotatably locked to the locking plate 340 to inhibit (e.g., prevent) rotation of the spindle 22. As a result, in Position 3, the mode selection assembly 300 configures the rotary hammer 10 for imparting reciprocating axial impacts along the tool bit axis 27 upon the tool bit 25.
FIG. 2E illustrates the mode selection dial 130 and the mode selection assembly 300 in Position 4 which corresponds with the “chisel adjustment mode” (i.e., “hammer adjustment mode”). FIG. 2E also is generally representative of the position and interaction of the components of the mode selection assembly 300, but with the mode selection dial 130 in Position 2, rotated 180 degrees relative to Position 4. As illustrated in FIG. 2E, the mode selection dial 130 faces laterally in a direction substantially perpendicular to the tool bit axis 27, and the cam 304 is positioned in substantial lateral alignment with the feature 312 of the selector fork 308. Due to the aforementioned interconnections of the mode selection assembly 300, the selector fork 308 carries the selector collar 320 such that the selector collar 320 is located at an intermediate position along the tool bit axis 27 between the spindle gear 348 and the locking plate 340. In this intermediate position (e.g., corresponding with Positions 2 and 4 of the mode selection dial 130), the ribs 336 of the selector collar 320 are disengaged from both the spindle gear 348 and the locking plate 340, and the spindle 22 is free to rotate with respect to the tool bit axis 27. As a result, in Positions 2 and 4, the mode selection assembly 300 configures the rotary hammer 10 to permit a user to manually rotate the spindle 22 about the tool bit axis 27 and disengages the motor 18 from imparting rotational force to the tool bit 25. In Positions 2 and 4, upon activation of the motor 18, the motor 18 drives the impact mechanism 32 for imparting axial force to the tool bit 25. During use in the “chisel adjustment mode”, the tool bit 25 reciprocates in the axial direction, and may be rotated from torque applied to the tool bit 25 by either a user or the surface being chiseled.
In operation, an operator selects combined hammer and drilling mode by rotating the mode selection dial 130 to Position 1 (FIG. 2B). In doing so, the mode selection assembly 300 advances the selector fork 308 and thus the selector collar 320 to configure the rotary hammer 10 for imparting reciprocating axial impacts as well as rotation about the tool bit axis 27 upon the tool bit 25. The operator then presses the tool bit 25 against the workpiece and depresses the trigger 30 to activate the motor 18. The trigger 30 is movable between a fully-on position, in which the motor 18 is energized at full speed, an intermediate position in which the motor 18 is energized at an intermediate speed less than full speed, and an off position in which the motor 18 is not energized. Rotation of the pinion 54 of the output shaft 58 causes the input gear 50 to rotate. Rotation of the input gear 50 causes the intermediate pinion 62 to rotate, which drives the output gear 66 on the spindle 22, causing the spindle 22 and the tool bit 25 to rotate.
Rotation of the pinion 54 also causes the crank gear 78 to rotate about the stationary shaft 82. Thus, the crank shaft 102 receives torque from the crank gear 78, causing the crank shaft 102 and the eccentric pin 110 to rotate about the central axis 86. Rotation of the eccentric pin 110 causes the piston 34 to reciprocate within the spindle 22 via the connecting rod 116, which causes the striker 38 to impart axial blows to the anvil 42, which in turn causes reciprocation of the tool bit 25 against a workpiece. Specifically, a variable pressure air pocket (or an air spring) is developed between the piston 34 and the striker 38 when the piston 34 reciprocates within the spindle 22, whereby expansion and contraction of the air pocket induces reciprocation of the striker 38. The impact between the striker 38 and the anvil 42 is then transferred to the tool bit 25, causing it to reciprocate for performing work on the workpiece.
While operating in combined hammer and drilling mode, hammer only mode, or chisel mode the trigger 30 may operate manually by depressing and releasing the trigger 30 to activate the switch 33 and thus the motor 18. However, in hammer only mode, the trigger 30 may be locked in a depressed position to continuously run the rotary hammer 10. In some embodiments, the trigger 30 may be biased away from the depressed position. As shown in FIG. 3, a chisel lock-on mechanism 134 may be used to manually lock the trigger 30 in the depressed position in which the switch 33 is activated and the motor 18 is continuously energized.
With reference to FIGS. 3, 4A, and 4B, the chisel lock-on mechanism 134 includes the mode selection dial 130, a linkage 138 with an interference part 140, a shuttle 142, a latch 144, the trigger 30, and a microswitch 145 (i.e., a lock status switch) that is in communication with the control unit 200. The linkage 138 is supported on a top side of a gear housing 150 and includes a central opening 154 that receives the mode selection dial 130. As the mode selection dial 130 is rotated, a cam (not shown) engages the inside surface of the central opening 154 to move the linkage 138 in a direction perpendicular to the tool bit axis 27. The shuttle 142 is supported by the housing 14 and extends from the housing 14 to be accessible by a user. A user may move the shuttle 142 in a direction parallel to the tool bit axis 27 between a manual position and a lock-on position. In the illustrated embodiment, the shuttle 142 moves (e.g., translates) between the manual position and the lock-on position in a direction rightward, as viewed from FIG. 3.
The latch 144 includes a first end 170 that is pivotably coupled to the housing 14 and a second end 174 opposite the first end 170. The second end 174 of the latch 144 includes a hook portion 178 and a ramp portion 182. The ramp portion 182 is supported within an opening 186 of a projection 190 of the shuttle 142. A biasing member 194 (e.g., a compression spring) biases the latch 144 in a clockwise direction from the frame of reference of FIGS. 4A and 4B, and the projection 190 limits the extent to which the latch 144 can pivot in the clockwise direction. The biasing member 194 biases the hook portion 178 into engagement with the recess 166 of the trigger 30. In other words, the biasing member 194 biases the latch 144 into engagement with the trigger 30.
When the mode selection dial 130 is in either combined hammer and drilling mode or the chisel adjustment mode, the interference part 140 of the linkage 138 is in the travel path of the shuttle 142. As such, in these modes, the shuttle 142 is prevented or blocked from moving to the lock-on position. When the mode selection dial 130 is in hammer only mode, the linkage 138 is laterally shifted to misalign the interference part 140 of the linkage 138 from the travel path of the shuttle 142. As such, in the hammer only mode, the shuttle 142 is capable of moving to the lock-on position.
As such, when in the hammer only mode, the shuttle 142 is allowed to move between the manual (i.e., disengaged) position shown in FIG. 4A and the lock-on (i.e., engaged) position shown in FIG. 4B. As the shuttle 142 moves from the manual position to the lock-on position, the projection 190 slides downward along the ramp portion 182 of the latch 144, permitting the spring 194 to rebound and pivot the latch 144 toward the trigger 30. In particular, the hook portion 178 of the latch 144 is pivoted towards a recess 166 in the trigger 30 to lock the trigger 30 in the depressed (i.e., lock-on, engaged) position (FIG. 4B). Once the hook portion 178 engages the recess 166, the trigger 30 is locked in the depressed position, which maintains activation of the switch 33 and continuously runs the motor 18. To release the trigger 30 from the depressed position, a user may move the shuttle 142 from the lock-on position to the manual position (FIG. 4A). As the shuttle 142 moves from the lock-on position to the manual position, the projection 190 slides upward along the hook portion 178 of the latch 144 to pivot the hook portion 178 out of engagement with the recess 166, allowing the trigger 30 to return from the depressed position.
With reference to FIGS. 4A and 5B, in the illustrated embodiment, when the shuttle 142 is in the manual position, the trigger 30 is a variable speed trigger. In other words, the amount the trigger 30 is depressed correlates to the speed the motor 18 rotates the tool bit 25. However, when the microswitch 145 is activated (i.e., toggled to an activated state), if the trigger 30 is depressed, the control unit 200 disables the variable speed capability of the trigger 30 and runs the motor 18 at full speed. As such, when the shuttle 142 is moved to the locked-on position, a flexible member 198 (e.g., a leaf spring 198) on the shuttle 142 engages and activates the microswitch 145. Meanwhile, the latch 144 engages the recess 166 on the trigger 30 to lock the trigger 30 in the depressed state and activate the switch 33 to continuously run the motor 18 at full speed. Once the shuttle 142 is moved back to the manual position, the microswitch 145 is deactivated (i.e., toggled to a deactivated state) allowing the user to once again vary the speed the motor 18 by depressing the trigger 30 a variable amount. FIG. 5B illustrates a flowchart of the ability of the control unit 200 to determine that the microswitch 145 is active, and the subsequent operation of the motor 18 at full speed.
FIG. 5A illustrates a flowchart of an electrical driving direction override function of the rotary hammer 10 when in the combined hammer and drilling mode. In some embodiments, in addition to actuating the linkage 138, the mode selection dial 130 also actuates a mode switch 542 which, in turn, provides an input signal to the control unit 200 corresponding to the particular mode in which the mode selection dial 130 is set. Such a mode switch 542 may be configured as, for example, a Hall-effect sensor (not shown) that detects the magnetic field emanated by a magnet located on the mode selection dial 130. Further, the rotary hammer 10 may include a forward-reverse shuttle 139 that is manually operable by the user to determine the rotational direction of the motor 18, and thus the spindle 22 and attached tool bit 25. The forward-reverse shuttle is coupled to a direction switch 546 (in FIG. 5A, “switch” is shortened to “sw”) which is configured to provide an input signal to the control unit 200 corresponding to the particular direction in which the shuttle is set (e.g., forward or reverse). In the embodiment illustrated in FIG. 1, the direction switch 546 is separated from the trigger 30. However, in other embodiments, the forward-reverse shuttle 139 may be coupled to the trigger 30, with the trigger 30 being a combined actuation/forward-reverse switch including the direction switch 546. In either construction, the forward-reverse shuttle 139 and the direction switch 546 are operable independently from the mechanical mode selection dial 130. The direction switch 546 may be configured as, for example, a Hall-effect sensor (not shown) that detects the magnetic field emanated by a magnet located on the forward-reverse shuttle 139.
In some embodiments of the rotary hammer 10, it may be desirable to only permit the motor 18 to rotate in only a single direction when the mode selection dial 130 is set to the combined hammer and drilling mode, regardless of the setting of the forward-reverse shuttle and direction switch 546. Based on the input from the mode switch 542 and the direction switch 546, the control unit 200 determines in which direction to rotate the motor 18 depending on which mode is selected, based on a lookup table 200a (FIG. 5A). The lookup table 200a includes four rows which each represent a single permutation of the output of the mode switch 542 and the direction switch 546. Other permutations of the output of the mode switch 542 and the direction switch 546 are possible (e.g., with regard to the combined hammer and drilling mode and the chisel adjustment mode).
As illustrated in the first row of the lookup table 200a (FIG. 5A), the control unit 200 is operable in a state (i.e., a first state) corresponding with the “combined hammer and drilling” mode (indicated by “drill” in FIG. 5A) in which the rotary hammer 10 actuates the tool bit 25 with rotary drilling in correspondence with direction A of the motor 18 and with axial impacts via hammering. In this state, the mode selection dial 130 is in a position corresponding with the “combined hammer and drilling” mode (e.g., Position 1, FIG. 2B), and the mode switch 542 determines the rotary hammer 10 is in the “combined hammer and drilling” mode. The direction switch 546 sends a signal to the control unit 200 indicative of a position of the forward-reverse shuttle 139 corresponding with the direction A. No override is enacted in this state. Upon activation of the trigger 30 in this state, the control unit 200 will rotate the motor 18 in direction A in accord with the signal from the direction switch 546. The motor 18 drives the transmission 46 to activate the impact mechanism 32, and the motor 18 transfers force (e.g., torque) to the spindle 22 to rotate the tool bit 25 in correspondence with direction A.
As illustrated in the second row of the lookup table 200a (FIG. 5A), the control unit 200 is operable in a state (i.e., a second state) in which the control unit 200 determines a state of the mode switch 542 and the direction switch 546, and the control unit 200 overrides the prescribed direction of the direction switch 546. When the mode selection dial 130 is in a position corresponding with the “chisel” mode (i.e., indicated by “chisel” in FIG. 5A), (e.g., Position 3, FIG. 2B), the mode switch 542 determines the rotary hammer 10 is in the “chisel” or hammer only mode, and the direction switch 546 sends a signal to the control unit 200 indicative of a position of the forward-reverse shuttle 139 corresponding with direction A. However, based on the signal from the mode switch 542 corresponding with the “chisel” mode (e.g., a signal indicative of Position 3), and determination that the direction switch 546 corresponds with the first direction A, the control unit 200 will override the signal from the direction switch 546, and the control unit 200 will rotate the motor 18 in the second direction B (e.g., counterclockwise). The control unit 200 then activates the motor 18 to transmit torque through the transmission 46 to activate the impact mechanism 32 (e.g., for axial movement of the tool bit 25). Upon activation of the trigger 30 in this state, the motor 18 is rotated in the second direction B to drive the transmission 46 and activate the impact mechanism 32, thus providing axial impacts to the tool bit 25.
Other similar control signal-based electrical overrides relating to driving the motor 18 in a direction opposite a prescribed direction (e.g., relating to different permutations of the mode switch 542 and the direction switch 546) are possible.
As illustrated in the third row of the lookup table 200a (FIG. 5A), the control unit 200 is operable in another state (i.e., a third state) corresponding with the “combined hammer and drilling mode” in which the rotary hammer 10 actuates the tool bit 25 with axial impacts via hammering. In this state, the mode selection dial 130 is in a position corresponding with the “combined hammer and drilling” mode (e.g., Position 1, FIG. 2B), and the mode switch 542 determines the rotary hammer 10 is in the “combined hammer and drilling” mode. The direction switch 546 sends a signal to the control unit 200 indicative of a position of the forward-reverse shuttle 139 corresponding with the direction B. No override is enacted in this state. Upon activation of the trigger 30 in this state, the control unit 200 will rotate the motor 18 in direction B in accord with the signal from the direction switch 546. The motor 18 drives the transmission 46 to activate the impact mechanism 32, and the motor 18 transfers force (e.g., torque) to the spindle 22 to rotate the tool bit 25 in correspondence with direction B.
As illustrated in the fourth row of the lookup table 200a (FIG. 5A), the control unit 200 is operable in another state (i.e., a fourth state) corresponding with the hammer only or “chisel” mode in which the rotary hammer 10 actuates the tool bit 25 with axial impacts via hammering. In this state, the mode selection dial 130 is in a position corresponding with the “chisel” mode (e.g., Position 3, FIG. 2B), and the mode switch 542 determines the rotary hammer 10 is in the “chisel” mode. The direction switch 546 sends a signal to the control unit 200 indicative of a position of the forward-reverse shuttle 139 corresponding with direction B. No override is enacted in this state. Upon activation of the trigger 30 in this state, the control unit 200 will rotate the motor 18 in direction B in accord with the signal from the direction switch 546. The motor 18 is rotated in the section direction B to drive the transmission 46 and activate the impact mechanism 32, thus providing axial impacts to the tool bit 25.
In some embodiments, when the mode selection dial 130 is in a position corresponding with a “drill only” mode (which is not provided in the illustrated rotary hammer 10), the mode switch 542 may determine the rotary hammer 10 is in the drill only mode, and the forward-reverse shuttle and the direction switch 546 determine a user's desired direction of rotation of the motor 18 in either a first direction A (e.g., clockwise, a first rotational direction) or a second direction B (e.g., counter-clockwise, a second rotational direction). The control unit 200 then activates the motor 18 to transmit torque to only the transmission 46 to rotate the spindle 22 in the user's desired direction (e.g., either the first rotational direction A or the second rotational direction B) without providing axial impact force.
FIG. 1 illustrates the control unit 200 in the form of a printed circuit board assembly (PCBA) 200 configured to control operation of the motor 18. As illustrated in FIG. 1, in the illustrated embodiment, the rotational axis 90 passes through the PCBA 200, with the PCBA 200 positioned on an opposite side of the motor 18 in comparison with the mode selection dial 130. In the illustrated embodiment, the PCBA 200 is positioned adjacent a bottom of the housing 14, and the mode selection dial 130 is positioned adjacent a top of the housing 14. However, other positions of the PCBA 200 are possible. For example, in the illustrated embodiment, the PCBA 200 is oriented generally perpendicular to the rotational axis 90. However, in other embodiments, the PCBA 200 may be oriented at any angle (e.g., 15, 30, 45, 60, 105, 120, 135, 150, 175, etc., degrees) relative to the rotational axis 90, the angle being inclined in any direction about the rotational axis 90.
As shown in FIG. 1, the motor housing 14 includes one or more exhaust openings 15 (shown schematically by dashed lines) in at least one side surface thereof (e.g., a left side, closest to the viewer as viewing FIG. 1, and a right side, furthest from the viewer as viewing FIG. 1). The exhaust opening 15 is positioned between the motor 18 and the mode selection dial 130 such that an airflow is exhausted laterally from the motor housing 14. In other embodiments, the exhaust opening 15 may be otherwise positioned downstream of the motor 18. The motor housing 14 further includes a plurality of inlet openings 16 positioned at the bottom of the housing 14 with air entering the motor housing 14 along a direction parallel to the rotational axis 90. In this arrangement, the PCBA 200 is positioned upstream of the motor 18 between the motor 18 and the inlet openings 16. In other embodiments, the inlet openings 16 may be otherwise positioned upstream of the motor 18, and optionally upstream of both the motor 18 and the PCBA 200. For example, the inlet openings 16 may be positioned adjacent the bottom of the housing 14, but intake air in a direction perpendicular to the rotational axis 90 and in a lateral direction into and/or out of the page as viewed in FIG. 1.
With continued reference to FIG. 1, the motor 18 is coupled to an impeller 19, which generates an airflow through the housing 14 in response to rotation of the motor 18 and impeller 19. In the illustrated embodiment, the impeller 19 is positioned downstream of the motor 18 between the motor 18 and the exhaust opening 15. During operation of the rotary hammer 10, the motor 18 and the PCBA 200 generate heat. The airflow is induced through the inlet openings 16, around the PCBA 200, and then through and/or around the motor 18, thereby transferring heat from the PCBA 200 and the motor 18 to the airflow. The heated airflow is then exhausted from the housing 14 via the exhaust openings 15. The PCBA 200 may include a printed circuit board within a potting boat. At least one heat generating electronic component (e.g., a microprocessor, field effect transistor or FET, etc.) is mounted to the printed circuit board. The potting boat can include a heat sink fin. Heat generated by the electronic component(s) can be conducted to the heat sink fin for convective dissipation by the airflow generated by the impeller 19.
Although the invention has been described in detail with reference to certain preferred embodiments, variations and modifications exist within the scope and spirit of one or more independent aspects of the invention as described.
Various features of the invention are set forth in the following claims.
Patent Application
20240238959
