Power tool having multiple operating modes

专利摘要:
A handheld power tool is configured to receive an input indicative of a clutch setting for an electronic clutch from the tool operator, where the clutch setting is selectable from a drill mode, an automated drive mode and one or more user-defined drive modes. Each of the user-defined drive modes specifies a different value of torque at which to interrupt transmission of torque to the output spindle. In an automated drive mode, the controller interrupt torque to the output spindle in an automated manner when a fastener being driven reaches a desired stopping position. In a selected one of the user-defined drive modes, the controller sets a value of a maximum current threshold in accordance with the selected one of the user-defined drive modes and interrupts torque to the output spindle when current measures exceeding the maximum current threshold. Ff0 264 30a 26 30b 24-- 20 -32 33b
公开号:AU2013206011A1
申请号:U2013206011
申请日:2013-05-24
公开日:2014-01-09
发明作者:Shaun Lovelass；Marco A. Mattucci；Jason Mcroberts；David Miller；Christopher J. Murray；Wong Kun Ng；Steven J. Phillips；Jonathan Priestly；Fugen Qin；Oleksiy Sergyeyenko；Christopher W. Shook；Kevin Stones
申请人:Black and Decker Inc；
IPC主号:B25B23-157

专利说明:
Australian Patents Act 1990 - Regulation 3.2 ORIGINAL COMPLETE SPECIFICATION STANDARD PATENT Invention Title Power tool having multiple operating modes The following statement is a full description of this invention, including the best method of performing it known to me/us: 5102 Attorney Docket No. 0275-001 595/UiS CROSS-REFERENCE TO RELATED APPLICATIONS [0001] This application claims the benefit of U.S. Provisional Application No. 61/657,269, filed on June 8, 2012. The entire disclosure of the above application is incorporated herein by reference. FIELD [0002] The present disclosure relates to portable hand held power tools including drills and drill drivers. BACKGROUND [00031 It is known to provide a power tool with switches, knobs, and other controls. For example, a power drill or driver typically includes a trigger that the user actuates to cause rotation of a tool held in a chuck. Power drills or drivers also typically include a forward/reverse selector switch located near the trigger that the user actuates to change a rotation direction of the too. Some power drills or drivers also include a clutch control (e.g., a dial) that is used to change a clutch torque setting such that the amount of resistance necessary to stop rotation of the chuck can be set or changed by the user. [0004] Conventional power tool controls suffer from certain disadvantages. For example, conventional controls can be awkward to manipulate while holding the power tool. The user is often required to hold the tool with a first hand and set or change operating controls with a second hand, a1 Attorney Docket No, 0275-00159B/US and controls may take up substantial space or be awkwardly located, thereby making setting or changing control operations difficult. Moreover, these power tools may have a manual only or an automatic only operated clutch, thereby limiting operational control of the clutch and tool. [00051 This section provides background information related to the present disclosure which is not necessarily prior art. SUMMARY [0006] This section provides a general summary of the disclosure, and is not a comprehensive disclosure of its full scope or all of its features. [0007] In one aspect of this disclosure, a method is provide for operating a power tool having an electric motor drivably connected to an output spindle. The tool is configured to receive an input indicative of a clutch setting for an electronic clutch form the tool operator, where the cutch setting is selectable from a drill mode and a drive mode. In a drill mode, torque applied to the output spindle is ignored; whereas, in the drive mode, the torque applied to the output spindle is monitored and interrupted in an automated mariner by a controller when a fastener being driven reaches a desired stopping position. [00081 in other aspects of this disclosure, the clutch setting is selectable from a drill mode, an automated drive mode and one or more user defined drive modes, where each of the user-defined drive modes specifies a different value of torque at which to interrupt transmission of torque to the output spindle. In an automated drive mode, the controller interrupt torque to the output 2 Attorney Docket No. 0275-001 59B/US spindle in an automated manner when a fastener being driven reaches a desired stopping position. In a selected one of the user-defined drive modes, the controller sets a value of a maximum current threshold in accordance with the selected one of the user-defined drive modes and interrupts torque to the output spindle when current measures exceeding the maximum current threshold. [0009] An improved technique for detecting when a fastener has reaches a desired stopping position is also presented. The improved techniques generally includes: sampling periodically current delivered to the electric motor; storing a sequence of current measures most recently sampled; and determining a slope for the sequence of current measures by way of linear regression. Transmission of torque to the output spindle can be interrupted based in part on the slope of the current measures. [00101 Further areas of applicability will become apparent from the description provided herein. The description and specific examples in its summary are intended for purposes of illustration only and are not intended to limit the scope of the present disclosure. DRAWINGS [00111 The drawings described herein are for ibustrative purposes only of selected embodiments and not all possible implementations, and are not intended to limit the scope of the present disclosure. [0012] FIG. 1 is a front left perspective view of a dri/driver of the present disclosure; 3 iL7 Attorney Docket No. 0275-001598/US [0013] FIG. 2 is a partial cross sectional front left perspective view taken at section 2 of FIG. 1; [0014] FIG. 3 is a front left perspective view of a rotary potentiometer and switch assembly of the present disclosure; [0015] FIG. 4 is a top left perspective view of the rotary potentiometer and switch assembly of FIG. 3; [00161 FIG. 5 is a top plan view of the rotary potentiometer and switch assembly of FIG. 3; [0017] FIG. 6 is a left side elevational view of the rotary potentiometer and switch assembly of FIG. 3; (0018] FIG. 7 is a flow diagram defining a forward/reverse clutch operation using a rotary potentiometer/switch assembly of the present disclosure; [0019] FIG. 8 is a left rear elevational perspective view of the drill/driver of FIG. 1; (0020] FIG. 9A is a flow diagram defining a battery state of charge operation of the present disclosure; [0021] FIG. 9B is a table providing exemplary battery voltages at various capacity levels associated with the flow diagram of FIG. 9A; [0022] FIG. 10 is a current vs. time graph depicting a change in current rate during operation in a drive mode; [0023] FIG. 1 1A is a front left perspective view of the drill/driver of FIG. 1; 4 Attorney Docket No. 0275-001596/US (0024] FIG. 118 is a top view of the drill/driver depicting an alternative display interface for selecting between a drill mode and a drive mode; [0025] FIG. 11 C is an exploded view of the alternative display interface module; [0026] FIGS. 12A and 128 are first and second portions of a flow diagram of the operating steps differentiating the drill mode from the drive mode, including use of algorithms; [0027] FIG. 13 is a left side elevational view of the drill/driver of FIG. 1 during installation of a fastener through two components; [0028] FIG. 14 is a top left perspective view of the drill/driver of FIG. 1; [0029] FIG. 15 is a partial cross sectional left side elevational view of the drill/driver of FIG, 13; [0030] FIG. 16 is a flow diagram of a timed operation mode of the drill driver of FIG. 1; [0031] FIG. 17 is a voltage versus time graph identifying a current flow during timed operation mode; [00321 FIG. 18 is a left side perspective view of the drill/driver of FIG. 1 during remote operation with a user interface device; [0033] FIG. 19 is a flow diagram of an initialization operation of the drill driver of FIG. 1 for selection of an operating mode; [00341 FIG. 20 is a diagram of the electronic control system for the drill driver of FiG. 1; 5 Attorney Docket No. 0275-001 59/US [00351 FIG. 21 is a flow diagram of drill driver operation in a motor control mode; [0036] FIG. 22A is a flow diagram of LED illumination corresponding to selected clutch torque settings; [0037] FIG. 22B is a table of selected input level, torque level and corresponding LED display data corresponding to the clutch torque flow diagram FIG. 22A; [0038] FIG, 23 is a flow diagram for LED illumination indicated during each of a forward and a reverse clutch operation; [00391 FIG. 24 is a flowchart illustrating an improved technique for setting a fastener in a workpiece; [0040] FIGS. 25 and 26 are diagrams depicting an exemplary embodiment for controlling operation of the drill driver to set a fastener; [0041] FIG. 27 is a diagram depicting another exemplary embodiment for controller operation of the drill driver to set a fastener; [0042] FIG. 28 is a perspective view of a drill driver having an alternative display. [0043] Corresponding reference numerals indicate corresponding parts throughout the several views of the drawings. 6 Attorney Docket No. 0275-00159B/US DETAILED DESCRIPTION [0044] Referring to FIG. 1, a portable hand-held power tool which in one form is a drill driver 10 includes a body 12 having a handle 14 shaped to be grasped in a single hand of a user, a rechargeable battery pack 16 that is releasably connected to a battery mounting portion 18 of body 12, and a chuck 20 having two or more clutch jaws 22 which are axially rotated with respect to a rotational axis 24. A clutch sleeve 26 is also rotatable with respect to rotational axis 24 that is used to manually open or close clutch jaws 22. White the following description is provided with reference to a drill driver, it is readily understood that some of the features set forth below are applicable to other types of power tools. [0045] A manually depressible and return biased trigger 28 is provided to initiate and control operation of drill driver 10, Trigger 28 is operated by manually depressing in a trigger engagement directiDn "A" and returns in a trigger release direction "B" upon release. Trigger 28 is provided in a motor housing 30 that according to several aspects is divisible into individual halves, including a motor housing first half 30a and a motor housing second half 30b which can be made for example of molded polymeric material. Positioned adjacent to trigger 28 is a rotary potentiometer/switch assembly 32. A portion 33b of rotary potentiometer/switch assembly 32 extends freely outwardly from body second half 30b on a second or left hand side of body 12. A similar portion 33a (shown in reference to FIG. 5) extends freely outwardly from body first half 30a on a first or right hand side of body 12. Rotary potentiometer/switch assembly 32 provides several functions which will be described in reference to 7 Attorney Docket No. 0275-001 598/US subsequent figures. A display port 80 is also provided with body 12 which will be described in greater detail in reference to FIG. 8. [0046] Referring to FIG. 2 and again to FIG. 1, with the motor housing second half 30b removed for clarity, drill driver 10 further includes a DC motor 34 and a motor transmission 35, the motor 34 operable using DC current from battery pack 16 and controlled by trigger 28. Motor 34 and motor transmission 35 are mounted in motor housing 30 and are drivably connected via an output spindle (not shown) to chuck 20 for rotation of chuck 20. It is readily understood that broader aspects of this disclosure are applicable to corded tool as well as battery powered tools. [0047] Rotary potentiometer/switch assembly 32 includes a rotary member 36 in the shape of a circular disk wherein portion 33b extending outward from body 12 is a portion of rotary member 36 extending freely outwardly with respect to body 12 on the left hand side of body 12. The outwardly extending portions 33a, 33b of rotary member 36 allow manual rotation and a side-to-side displacement of rotary member 36 by the user of drill driver 10 from either the right hand side or left hand side of body 12. Rotary member 36 is positioned in a housing space 38 of motor housing 30 providing clearance for both axial rotation of rotary member 36, and side-to-side displacement of rotary member 36 in either a left hand or a right hand displacement such that rotary potentiometer/switch assembly 32 performs at least dual functions as will be described in reference to FIGS. 3-6, According to further aspects, rotary member 36 can be replaced by a sliding member, a rocking member, or other types in input components. 8 aF Attorney Docket No. 0275-001598/US [0048] A printed circuit board (PCB) 40 is positioned in handle 14. PCB 40 defines an electronic control circuit and includes multiple components including a microcontroller 42 such as a microchip, having a central processing unit (CPU) or the like for performing multiple functions of drill driver 10, at least one electrically erasable programmable read-only memory (EEPROM) function providing storage of data or selected inputs from the user of drill driver 10, and at least one memory device function for storing both temporarily and permanently saved data such as data lookup tables, torque values and the like for use by drill driver 10. According to other aspects (not shown), microcontroller 42 can be replaced by separate components including a microprocessor, at least one EEPROM, and at least one memory device. [0049] Rotary member 36 is rotatable with respect to a rotary member axis of rotation 43. Rotation of rotary member 36 can be in either a first rotational direction "C" or a second rotational direction "D" which is opposite to first rotational direction "C". It is noted that the rotary member axis of rotation 43 can displace when rotary member 36 is moved in the side-to-side displacement described above and which will be described in greater detail in reference to FIG. 5. [0050] Referring to FIG. 3 and again to FIG. 2, the rotary potentiometer/switch assembly 32 has rotary member 36 rotatably connected to an assembly platform 44 such as a circuit board which is housed within body 12. A connector 46 is fixed to assembly platform 44 providing for electrical communication between assembly platform 44 and printed circuit board 40, 9 Attorney Docket No. 0275-001 598/US thereby including assembly platform 44 with the electronic control circuit defined by PCB 40. Assembly platform 44 includes an assembly platform first end 48 having a first axle 50 extending from a first side of first end 48 and a second axle 52 oppositely directed with respect to assembly platform first end 48. First and second axles 50, 52 are coaxially aligned defining an axle axis of rotation 54. The first and second axles 50, 52 allow the assembly platform 44 as a unit to rotate with respect to axle axis of rotation 54. The assembly platform 44 further includes an assembly platform second end 56 having a mount member 58. Mount member 58 provides attachment and support for each of a first biasing member 60 and an oppositely directed second biasing member 62. [00511 Referring to FIG. 4 and again to FIGS, 2 and 3, the first biasing member 60, which according to several aspects can be a compressible spring, contacts and is supported against a mount member first face 64 of mount member 58. First biasing member 60 is shown in its normally extended, non biased condition. From this position, first biasing member 60 is compressible in a first compression direction "E". The second biasing member 62 is similar to first biasing member 60 and therefore provides a substantially mirror image configuration of a compressible spring which contacts and is supported against a mount member second face 66 of mount member 58. From its normally non biased position shown in FIG. 4, second biasing member 62 is elastically compressible in a second compression direction "F" whch is oppositely oriented with respect to first compression direction "E". During axial rotation of assembly platform 44 with respect to axle axis of rotation 54, either the first or the second 10 Attorney Docket No. 0275-001598/US biasing member 60, 62 is elastically depressed against one of the motor housing first or second halves 30a, 30b. The biasing force generated by compression of either first or second biasing member 60, 62 acts to return the assembly platform 44 to a neutral position when the manual force applied to rotate assembly platform 44 is released, [0052] Referring to FIG. 5 and again to FIGS. 2-4, as previously noted assembly platform 44 is rotatable with respect to axle axis of rotation 54 using first axle 50 and second axle 52 (not visible in this view). With the assembly platform 44 positioned in a neutral position, rotary member 36 is axially rotatable with respect to rotary member axis of rotation 43 to either increase or decrease an operating torque created as a torque limit command or signal by the rotational position of rotary member 36 and applied to chuck 20. Rotary member 36 can be rotated in each of a first rotational direction "G", which is clockwise as viewed with respect to FIG. 5, or in a second rotational direction "H", which is opposite with respect to first rotational direction "G" and is therefore counterclockwise as viewed in FIG. 5. Axial rotation of rotary member 36 can be used, for example, to predetermine a torque setting of chuck 20 between a minimum and a maximum predetermined torque value as the torque limit command, For example, rotation of rotary member 36 in the first rotationa direction "G" can be used to increase the torque setting or torque lmit command, and rotation of rotary member 36 in the opposite second rotationa directon "H" can be used to reduce the torque setting or torque limit command. Rotary member 36 can therefore act as a rotary potentiometer generating commands or 11 Attorney Docket No. 0275-001598/US signals transferred via connector 46 to PCB 40. The first and second portions 33a, 33b of rotary member 36 that extend outwardly from first and second halves 30a, 30b (shown in phantom) of body 12 are shown. [0053] With continuing reference to FIG. 5, assembly platform 44 further includes mirror image switches which are actuated when assembly platform 44 is manually rotated with respect to axle axis of rotation 54. For example, when the operator applies a force to rotary member 36 in a first force acting direction "J", rotation of assembly platform 44 with respect to axle axis of rotation 54 acts to elastically compress first biasing member 60 in the first compression direction "E" until a first displacement member 68 of a first directional switch 70 is depressed/closed. When the operator applies a force to rotary member 36 from a second force acting direction "K", the assembly platform 44 rotates with respect to axle axis of rotation 54 such that second biasing member 62 is elastically compressed in the second compression direction "F" until a second displacement member 72 of a second directional switch 74 is depressed/closed. When the force applied in either the first or second force acting directions "J", "K" is removed, the biasing force of either of the first or second biasing members 60, 62 causes the assembly platform 44 to return to ts original or neutral position, opening either the first or the second directional switch 70, 74. Circuits closed by operation of either the first or the second directional switch 70, 74 generate signals or commands used to dotermine a rotational direction of chuck 20, for example by setting either a forward (clockwise) rotation or a reverse (counter clockwise) directional rotation. The 12
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Attorney Docket No. 0275-001598/US "dual mode" of operation provided by rotary potentiometer/switch assembly 32 in one aspect is first to control clutch torque and second to control the chuck rotation direction. The "dual mode" of operation can also include multiple variations of torque application, directional control, timed operation, clutch speed settings, motor current control, operation from data saved in memory from previous operations, and others as further defined herein. 10054] The electronic control provided by microcontroller 42 and the electronic control circuit of PCB 40 determines multiple operations of drill driver 10. As previously noted, when first directional switch 70 is closed, chuck 20 will operate in a forward or clockwise operating rotational direction. In addition, by subsequent rotation of rotary member 36 following the actuation of first directional switch 70, additional modes of operation of drill driver 10 can be selected, including selecting a speed setting of motor 34, selecting an automatic torque cutout setting, selecting a speed control response, selecting a fastening seating algorithm, and additional modes which will be described later herein. If second directional switch 74 is closed, chuck 20 will be rotated in a reverse or counter-clockwise direction of rotation and subsequent rotation of rotary member 36 can have similar control mode selection features for operation of drill driver 10 in the reverse direction. In addition, the electronic control provided by operation of rotary member 36 and first and second directional swItches 70, 74 can also be used to customize the operation of rotary member 36 through a series of operations of rotary member 36 and trigger 28 to sult either a left or right handed user of drill driver 10. 13 Attorney Docket No. 0275-00159B/US [00551 For example, once the user has set a left or right hand mode of operation, subsequent rotation of rotary member 36 can always result in a forward mode being selected such that the operation of drill driver 10 for either a right or left handed operator becomes intuitive for the operator. An advantage of placing rotary member 36 adjacent to handle 14, where the control of rotary member 36 is achieved for example by the thumb of the operator, provides for one-handed operation of drill driver 10, allowing control of multiple modes of operation in a one-handed operation. The same one-handed operation is also permitted by the rotational displacement provided by first and second axles 50, 52 of assembly platform 44 such that physical side-to-side rotational displacement of assembly platform 44 about the axle axis of rotation 54 provides additional functions for the accessible positions of rotary member 36. [00561 Referring to FIG. 6 and again to FIGS. 2-5, the various components of assembly platform 44 can be fixed. For example, first and second axles 50, 52 and mount member 58 can be fixed using adhesives or integraly connected to assembly platform 44 during a molding process, creating assembly platform 44. First and second directional switches 70, 74 (only second directional switch 74 is clearly visible in this view) are also fixed to assembly platform 44. A mount member 75 fixed to assembly platform 44 allows for axial rotation of rotary member 36. According to several aspects, a planar surface 76 is defined by assembly platform 44 such that the components mounted to assembly platform 44 are retained in the same relative positions during axial rotation of rotary member 36 and also during axial rotation of assembly platform 1 14 Attorney Docket No. 0275-001598/US 44. A plurality of grip slots 7B can also be provided with rotary member 36 to assist in the axial rotation of rotary member 36. Grip slots 78 can also be positioned about the perimeter of rotary member 36 at locations corresponding to individual rotary positions that visually indicate to the operator the degree of rotation required to achieve a next torque setting of drill driver 10. {0057] Referring to FIG. 7, operation of the rotary potentiometer/switch assembly 32 is depicted in a flow diagram, In an initializing step 82, variables and hardware that may be in an off or standby mode are initialized. In a next trigger timing step 83, a time period following initiation of trigger pull is measured to determine if trigger 28 has been depressed for a minimum or required time period, If following the trigger timing step 83 it is determined that the minimum required time of trigger pull has not been met, this step repeats itself until the required minimum time period has been met. If following the trigger timing step 83 the required minimum time of depression of trigger 28 has been met, a latching step 84 is performed wherein the power supply to the motor is latched, thereby providing electrical power to the electrical components of drill driver 10. Following latching step 84, a read EEPROM step 85 is performed wherein data saved in the EEPROM of microcontroller 42 is accessed to initialize mode selection and to illuminate appropriate ones of tne first through sixth LEDs 102-112. Following read EEPROM step 85, a shutdown check step 86 is performed wherein it is determined whether any of a power off timeout has occurred, an under-voltage cutoff has occurred, or a high temperature cutoff has occurred. If none of the conditions are present as 15 Attorney Docket No. 0275-001598/US determined in shutdown check step 86, a trigger position determination step 87 is performed wherein a trigger position ADC (analog-digital converter) is read to determine if it is greater than a predetermined start limit, If so, drill driver 10 is positioned in motor control mode in a motor controlling step 88. If the trigger position ADC reading is not greater than the predetermined start limits, a forward wheel determining step 89 is performed to determine if rotary member 36 has been rotated in a forward rotational direction. If so, in a check forward mode step 90, a determination is made if drill driver 10 is already positioned in a forward operating mode. If not, drill driver 10 is returned to a previous forward mode in a return step 91. If drill driver 10 is already in the forward operating mode, a next mode is selected in a select next mode step 92. Following either return step 91 or select next mode step 92, a setting step 93 is performed wherein the LEDs, an H-bridge forming a portion of PCB 40, and a maximum PWM (pulse width modulation) value are set. Following setting step 93, or f the forward wheel determining step 89 indicates that rotary member 36 has not been rotated in a forward rotating direction, a reverse wheel determining step 94 is performed. It is initially determined if drill driver 10 is in a forward operating mode in a check forward mode step 95, and if the forward made is indicated the current forward operating mode is stored in a store made step 96. Flowing either check forward mode step 95 or store made step 96, a setting step 97 is performed which is similar to setting step 93 with the exception that the reverse mode is sot in addition to setting the LEDs, the "H" bridge direction, and the maximum PWM. Returning to the shutdown check step 86, if any of the power off timeout, under 16 Attorney Docket No. 0275-001 595/US voltage cutoff, or high temperature cutoff indicators is present, a save to EEPROM step 98 is performed wherein values presently set for operation of drill driver 10 are saved to EEPROM of microcontroller 42. Following save to EEPROM step 98, an unlatch step 99 is performed wherein the power suppy is unlatched. [0058} Referring to FIG. 8, display port 80 can be provided on an upper surface of motor housing 30 and extend across both first and second halves 30a, 30b of motor housing 30. Display port 80 includes multiple color light emitting diodes (LEDs) that are capable of displaying three colors, as two pure or primary colors plus a third color which is a mix of the two primary colors. Each LED color can therefore provide visual indication of multiple different operating modes of drill driver 10. The multiple LEDs include a first, second, third, fourth, fifth, and sixth LED 102, 104, 106, 108, 110, 112, all positioned on an LED display screen 100. For example, the LEDs of display port 80 can represent functions including a live torque reading, the status of battery 16, a direction of rotation of chuck 20, and a changing (increasing or decreasing) torque signal as rotary member 36 is rotated. [0059] In one example, first through sixth LEDs 102-112 can be used to indicate the status of battery 16 as follows. If battery 16 is fully charged and therefore at maximum voltage potential, all of LEDs 102-112 will be illuminated. If battery 16 is at its lowest voltage potential, only first LED 102 wiH be illuminated. Successive ones of the LEDs, such as first, second and third LEDs 102, 104, 106, will be illuminated when battery 16 is at a capacity greater 17
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Attorney Docket No. 0275-00159B/US than the minimum but less than the maximum. The color used for illumination of the LEDs, for example during the battery status display check, can be different from the color used for other mode checks. For example, the battery state of charge indication can illuminate the LEDs using a green color while torque indication can use a blue color. [0060] Referring to FIGS. 9A, 9B and again to FIG. 8, the battery state of charge display of display port 80 is depicted on a battery state of charge flow diagram 113 with corresponding voltages provided in a table 142 of FIG. 98, In an initial LED de-energizing step 114, all of the LEDs 102-112 are turned off. In a next reading step 116, a stack voltage of battery 16 is read. In a first voltage determination step 118, if the battery voltage is above a predetermined value, for example 20.2 volts, all of the LEDs 102-112 are turned on in a LED energzing step 120. If, following the first voltage determination step 118, the voltage of battery 16 is less than 20.2 volts but greater than 19.7 volts, in a five LED energizing step 124 LEDs 102-110 are turned on. Following the second voltage determination step 122, if the voltage of battery 16 is less than 19.7 volts but greater than 19.2 volts, LEDs 102-108 are turned on in a four LED energizing step 128. Following the third voltage determination step 126, if the voltage of battery 16 is less than 19.2 volts but greater than 18.7 volts as determined in a fourth voltage determination step 130, LEDs 102-106 are turned on in a three LED energizing step 132. Similarly, following fourth voltage determination step 130, if a voltage of battery 16 is less than 18.7 volts but greater than 18.2 volts, in a fifth voltage determination step 134 LEDs 102-104 are turned on in a two LED 18 Attorney Docket No. 0275-001598/US energizing step 136. Finally, in a sixth voltage determination step 138, if the voltage of battery 16 is less than 18.2 volts but greater than 17.7 volts, only first LED 102 is turned on in a one LED energizing step 140. [00611 The battery status check can be performed by the operator of drill driver 10 any time operation of drill driver 10 is initiated, and wHI repeat the steps noted above depending upon the voltage of the battery cells forming battery 16. For the exemplary steps defined in battery state of charge flow diagram 113, the voltage lookup table 142 of FIG. 9B, which can be saved for example in the memory device/function provided with microcontroller 42 shown and described in reference to FIG. 2, can be accessed for determining the number of LEDs which will be illuminated based on multiple ranges of battery voltages that are measured. It is noted the values identified in voltage lookup table 142 can vary depending upon the voltage and number of cells provided by battery 16. [0062] Additional modes of operation for drill driver 10 can be displayed on display port 80 as follows. For example, either forward or reverse direction of operation for chuck 20 can be indicated as follows. When the forward operating mode is selected, first, fifth, and sixth LEDs 102, 110, 112 will be illuminated. When a reverse or counterclockwise rotation of chuck 20 is selected, fourth, fifth, and sixth LEDs 108, 110, 112 will be illuminated. The color selected for indication of rotational direction can vary from the color selected for the battery status check. For example, the color indicated by the LEDs during indication of the rotational direction can be blue or a combination color of 19 Attorney Docket No. 0275-001598/US blue/green. Similar to the indication provided for the battery status check, a live torque reading selected during rotation of rotary member 36 will illuminate either one or multiple successive ones of the LEDs depending upon the torque level selected. For example, at a minimum torque level only first LED 102 will be illuminated. At a maximum torque level all six of the LEDs 102-112 will be illuminated. Individual ones of the LEDs will successively illuminate as rotary member 36 is axially rotated between the minimum and tne maximum torque command settings. Oppositely, the number of LEDs illuminated will reduce successively as rotary member 36 is oppositely rotated, indicating a change in torque setting from the maximum toward the minimum torque command setting. When there are more settings than the number of LEDs available, combination colored LEDs can be illuminated such as blue/green. The LEDs of display port 80 will also perform additional functions related to operation of chuck 20, which will be described in greater detail with reference to clutch operating modes to be further described herein. [0063] In another aspect of this disclosure, the drill driver 10 is configured to operate in -different modes. For example, the drill driver 10 may provide an input component (e.g., rotary member 36) that enables the tool operator to select a clutch setting for an electronic clutch, In one embodiment, the operator selects between a drill mode and a drive mode, In a drill mode, the amount of torque applied to the output spindle is ignored and transmission of torque is not interrupted by the controller 42 during tool operation; whereas, in a drive mode, torque applied to the output spindle is monitored by the controller 42 20 Attorney Docket No. 0275-001598/US during tool operation. The controller 42 may in turn interrupt transmission of torque to the output spindle under certain tool conditions. For example, the controller may determine when a fastener being driven by the tool reaches a desired stopping position (e.g. flush with the workpiece) and terminate operation of the tool in response thereto without user intervention. It is readily understood that the selected clutch setting can be implemented by the controller 42 with or without the use of a mechanical clutch, That is, in some embodiments, the drill driver 10 does not include a mechanical clutch. [00641 Referring to FIG. 11A, drill driver 10 can include individual switches for operator selection between either a drill mode or a drive mode. A drill selector switch 170 is depressed when drill operating mode is desired. Conversely, a drive selector switch 172 is depressed when drive operating mode is desired. The drll and drive operating modes are both operable with drill driver 10 regardless of the rotating direction of chuck 20. For example, operation in both the drill mode and drive mode are possible in a clockwise or forward rotational direction 174 and also in a counter clockwise or reverse rotational direction 176 of chuck 20. It is further noted that the selected one of either drill selector switch 170 or drive selector switch 172 may illuminate upon depression by the user. This provides further visual indication of the mode seLected by tho user. [0065] Drill selector switch 170 and drive selector switch 172 may be actuated in different sequences to activate other tool operating modes. For example, the drive selector switch 172 may be pushed and held for a fixed period 21
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Attorney Docket No. 0275-001598/US of time (e.g., 0.15 sec) to activate a high torque drive mode; whereas, pushing the driver selector switch 172 twice in the fixed period of time may activate a low torque drive mode. To indicate the different drive modes, the driver selector switch 172 may be lit steady when in the high torque drive mode and banking when in the low torque drive mode. These two sequences are merely illustrative and other combinations of sequences are envisioned to activate these or other tool operating modes. [0066] Figure 11 B depicts an alternative display interface 1100 for selecting between a drill mode and a drive mode. In this embodiment, the buttons for selecting the operating mode are integrated into the top surface of the drill driver housing. A drill icon 1102 is used to represent the drill mode; whereas, a screw icon 1104 is used to represent the drive mode although other types of indicia may be used to represent either of these two operating modes. Once selected by the tool operator, the mode is activated (i.e., a signal is sent from the button to the controller) and an LED behind the button is lit to indicate which operating mode has been selected. The LED lights the icon which remains lit until the operating mode is changed, the tool becomes inactive or is otherwise powered down. The display interface may also include LEDs 1106 for indicating the state of charge of the battery in a similar manner as described above. [00671 An exemplary construct for the display interface is further illustrated in Figure 11C. The display interface module is comprised of a plastic carrier 1112, a flexible circuit board 1113, and a translucent rubber pad 1114. 22 Attorney Docket No. 0275-001598/US The carrier 1112 serves to hold the assembly together and attaches to the top of the housing. The circuit board 1113 supports the switches and LEDs and is sandwiched between the rubber pad 1114 and the carrier 1112. The rubber pad is painted black and laser etched to form the icon shapes thereon, [0068] Referring to FIGS. 12A and 12B and again to FIG. 11, a drill/drive mode flow diagram 177 defines steps taken by the control circuit of drill driver 10 distinguishing between a drill mode 180 and a drive mode 182. In an initial check mode step 178, the status of drill selector switch 170 and/or drive selector switch 172 is checked to determine which input is received by the user. If the check mode step 178 indicates that drill mode 180 is selected, a trigger actuation first function 184 is initiated when trigger 28 is depressed. Following trigger actuation first function 184, a motor start step 186 is performed, thereby initiating operation of motor 34. During operation of the motor 34, an over current check step is performed to determine if motor 34 is operating above a predetermined maximum current setting. If the over-current indication is present from motor over-current check 188, an over current flag 190 is initiated followed by a stop motor step 192 where electrical power to motor 34 is isolated. A drill drive mode return step 194 is then performed wherein continued operation of motor 34 is permitted after the user releases trigger 28. Returning to the motor over-current check 188, if an over-current condition is not sensed during the motor over-current check 188, continued operation of motor 34 is permitted. [0069] With continuing reference to drill/drive mode flow diagram 177, when driver selector switch 172 is depressed by the user and drive mode 23 Attorney Docket No. 0275-001598/US 182 is entered, a check is performed to determine if an auto seating flag 196 is indicated. If the auto seating flag 196 is not present, the following step determines if a timed operating system flag 198 is present. If the timed operating system flag 198 is present, in a next duty cycle setting step 200 a timed operating duty cycle is set. Following step 200, motor 34 is turned on for a predetermined time period such as 200 ms (milliseconds) in a timed operating step 202. Following timed operating step 202, in a seating/timed operating flag indication step 204, the control system identifies if both an auto seating flag and a timed operating flag are indicated. If both the auto seating flag and timed operating flag indication step 204 are indicated, operation of motor 34 is stopped in a stop motor running step 206. [00701 Returning to timed operating system flag 198, if the flag is not present, a trigger activation second function 208 is performed which initiates operation of motor 34 in a tirned turn on motor start 210. Following this and similar to motor over-current check 188, a motor over-current check 212 is performed. If an over-current condition is not indicated, a first routine 214 algorithm is actuated followed by a selection "on" check 216. If the selection "on" check 216 is negative, a second torque routine 218 algorithm is run, following which if a positive indication is present, returns to the seating/timed operating flag indication; and if negative, returns to the return step 194. If the selection "on" check performed at step 216 is positive, a third routine 220 algorithm is run which if positive thereafter returns to seating/timed operating flag indication step 204 and, if negative, returns to return step 194. 24 Attorney Docket No, 0275-001 598/US [0071] in some embodiments, the drive mode may divided into an automated drive mode and one or more user-defined drive modes, where each of the user-defined drive modes specify a different value of torque at which to interrupt transmission of torque to the output spindle. In the automated drive mode, the controller monitors the current being delivered to the motor and interrupts torque to the output spindle in response to the rate of change of current measures. Various techniques for monitoring and interrupting torque in an automated manner are known in the art, including techniques to setting a fastener in a workpiece, and fall within the broader aspects of the disclosure. An improved technique for detecting when a fastener reaches a desired stopping position is further described below. In such embodiments, it is readily understood that the input component may be configured for selection amongst a drill mode, an automated drive mode and one or more user-defined drive modes. [0072] Referring to FIG. 10 and again to FIGS. 1 and 2, a current versus time graph 144 defines a typical motor current draw during operation to install a fastener using drill driver 10. Initially, an inrush current 146 briefly peaks prior to the current draw continuing at a low rate of change (LROC) current 148. LROC current 148 corresponds to a body of a fastener such as a screw penetrating a material such as wood at a constant speed. At the timo when a head of the fastener contacts and begins to enter the wood, the current draw changes to a high rate of change (HROC) current 150 for a brief period of time until a current plateau 152 is reached, defining when the fastener head is fully 25 Attorney Docket No, 0275-001598/US embedded into the wood. As is known, the level of current draw is proportional to the torque created by motor 34. [00731 In a selected one of the user-defined drive modes, the controller sets a value of a maximum current threshold in accordance wth the selected one of the user-defined drive modes and interrupts torque to the output spindle in response to the current measures exceeding the maximum current threshold. For example, the user selects one of the user-defined drives modes as the desired clutch setting using, for example rotary member 36. Current levels 154 designated as "a", "b", "c", "d", "e", '" correlate to the plurality of predefined torque levels designated as "1", "2", "3", "4", "5", "6", respectively. During tool operation, the controller 42 will act to terminate rotation of the chuck when the current monitored by the controller 42 exceeds the current leve associated with the selected user-defined drive mode (i.e., torque setting). The advantage of providing both types of drive modes (i.e., control techniques) within drill driver 10 includes the use of current level increments 154 which, based on prior operator experience, may indicate an acceptable predetermined torque setting for operation of chuck 20 in a specific material. Where the user may not be familiar with the amount of fastener headset in a particular material and/or with respect to a particular sized fastener, the automatic analysis system can be selected, providing for acceptable setting of the fastener which may occur in between individual ones of the current level increments 154. [0074] Figure 24 illustrates an improved technique for controlling operation of the drill driver when driving a fastener. Briefly, the current delivered 26 Attorney Docket No. 0275-001598/US to the electric motor is sampled periodically at 502 by the controller of the drili driver. The current measures most recently sampled by the controller are stored at 504 in a memory of the drill driver. From the most recently sampled current measures, a slope for the current measures is determined at 506 by way of linear regression. Linear regression is used because it has a better frequency response making it more immune to noise as compared to conventional computation methods. When a fastener being driven by the drill driver reaches a desired stopping position, torque transmitted to the output shaft is interrupted at 508 by the controller. The desired stopping position is determined based in part on the slope of the current measures as will be further described below. [0075] Figures 25 and 26 further illustrating an automated technique for setting a fastener in a workpiece. Current delivered to the electric motor is sampled periodically by the controller of the drill driver. In an example embodiment, the controller can ignore current samples captured during an inrush current period (e.g., 180 ms after trigger pull). Whenever there is a change in the trigger position (i.e., change in PWM duty cycle), the controller will stop sampling the current until the inrush current period has lapsed. In some embodiments, the automated technique is implemented by the controller regardless of the position of the trigger switch. In other embodiments, the automated technique is only implemented by the controller when the trigger position exceeds a predefined position threshold (e.g., 90%). Below this position threshold, the tool operates at lower speeds, thereby enabling the tool operator to set the fastener to the desired position without the need for the automated technique. 27 Attorney Docket No. 0275-001598/US {00761 Current measures may be digitally filtered before computing the current change rate. In an example embodiment, current is sampled in 15 milliseconds intervals. During each interval, the controller will acquire ten current measures as indicated at 560 and compute an average from the ten measures although more or less measures may be acquired during each interval. The average for a given interval may be considered one current sample and stored in an array of current samples indicated at 562 in Figure 26, where the array of current samples stores a fixed number (e.g., four) of the most recently computed values. The controller will then compute an average from the current samples in the array of current samples. The average for the values in the array of current samples is in turn stored in a second array as indicated at 564 in Figure 26, where the second array also stores a fixed number (e.g., five) of the most recently computed averages. These averaged current measures can then be used to determine the rate of current change. Other techniques for digitally filtering the current measures are also contemplated by this disclosure. [0077] With continued reference to Figure 25, the slope of the current is determined at 524 from the digitally filtered current measures. In an example embodiment, a linear regression analysis is used to compute the slope. n a scatter plot, the best fit line of the scatter data is defined by the equation y = a + bx, where the slope of the best fit Jine can be defined as b where n is the number of data points. The intercept will be ignored in this disclosure. For illustration purposes, assume data scatter plot with current values for y of [506,670,700,820,890] corresponding to sample values of [1, 2, 3, 4, 5], such that 28 Attorney Docket No. 0275-001598/LS n=5. Using linear regression, the slope b of the best fit line is equal to 91.8. While a simple linear regression technique has been explained, other linear regression techniques are also contemplated by this disclosure. [0078 Slope of the current measures may be used as the primary indicator for when the fastener has been set at a proper depth in the workpiece. Particularly, by using the slope of the current, the tool is able to determine when the tool is in the HROC (of current) area shown in the graph of Fig. 10. In the example embodiment, a slope counter is maintained by the controller. The current slope is compared at 524 to a minimum slope threshold. For example, the minimum slope threshold may be set to a value of 40. This value may be set such that slope values exceeding the minimum slope threshold are indicative of the HROC 150 range shown in Fig. 10. The slope threshold value may be derived empirically for different tools and may be adjusted according to the sampling time, motor attributes and other system parameters. In embodiments where the automated technique is implemented by the controller only when the trigger position exceeds a predefined position threshold, minor variations in trigger position (e.g., 10% from a baseline position) can be ignored once the current slope exceeds the minimum slope threshold and unt| such time as tre fastener has been set and the torque to the output spindle is interrupted. [0079] The slope counter is adjusted in accordance with the comparison of the current slope to the minimum slope threshold. The slope counter is incremented by one when the computed siope exceeds the minimum slope threshold as indicated at 536. Conversely, the slope counter is 29 Attorney Docket No. 0275-001598/US decremented by one when the computed slope is less than or equals tne minimum slope threshold as indicated at 532. When the slope is less than or equal to the minimum slope threshold, the value of the current siope is also set to zero as indicated at 528. In the event the slope counter is equal to zero, the slope counter is not decremented further and the slope counter remains at zero as indicated at 534. Following each adjustment, the value of the slope counter is stored in an array of slope counts as indicated at 566 in Figure 26, where the array of slope counts stores a fixed number (e.g,, five) of the most recent slope count values. [0080] Next, the slope counts are evaluated at 546 in relation to a fastener criteria. The fastener criteria at step 546 includes both a setting criteria, which is indicative of a desired stopping position for the fastener being driven by the tool, and a default criteria. The setting criteria and default criteria may be used together, as shown in 546 of Fig. 25, or only one of the criteria may be used. The setting criteria will be described first. In the setting criteria a fastener is assumed to have reached a desired stopping position when the slope counts increase over a series of values stored in the array of slope counts, where the series of values may be less than or equal to the total number of values stored in the entire array. In this example, each slope count value in the array is compared to an adjacent slope count value starting with the oldest value. The setting criteria is met when each value in the array is less than the adjacent value as compared from oldest value to the most recent value. For example, if the array is designed to hold five slope count values (SC1 through S05), the setting 30 Attorney Docket No. 0275-001598/US criteria may be met when the consecutive count values are each increasing i.e., SC1<SC2<SC3<SC4<SC5. In other words, the setting criteria is satisfied when the controller detects five successive computer slope values greater than the predetermined minimum slope threshold. [0081] As noted above, the setting criteria may not use the entire array of values. For example, the array may be designed to hold five slope count values, but the setting criteria may be set such that an increase of counts over a series of four values (e.g. SC2<SC3<SC4<SC5) is sufficient. Other variations regarding the particular number of counts required are also contemplated. [0082] The fastening criteria evaluated at step 546 may also include a default criteria. In some instances, the setting criteria described above with respect to Figs. 25 and 26 may fail to trigger due to, for example, an anomaly reading or variations in a workpiece which result in the controller failing to detect the occurrence of the above-described setting criteria. In that case, there may be an additional criteria serving as a default criteria. In the default criteria, a fastener is assumed to have reached, or passed, a desired stopping position when the slope count peaks within a series of values stored in the array. In other words, if after detecting successive slope values that exceed the minimum slope threshold, the controller now detects successive slope values less than the minimum slope threshold, it is apparent the above-described setting criteria wIl not be met. [0083] As with the setting criteria, the series of values may be less than or equal to the number of values stored in the entire array. In this example, siope 31 Attorney Docket No. 0275-001598/US count values in the array are again compared to each other. The default criteria is met when the slope count values in the array increase from the oldest value to an intermediate peak value and then decrease from the intermediate peak value to the most recent value. For example, the default criteria may be met if SC1<SC2<SC3>SC4>SC5. Of course, other particular default critera may be used. For example, the default criteria may require more successive increases or more successive declines than that provided in the example above (e.g., SC1 <SC2<SC3<SC4>SC5>SC6>SC7; or SC1 <SC2>SC3>SC4; etc.). In this embodiment shown in Fig. 25, the setting criteria and default criteria are used together. However, in an alternative embodiment, each may be used alone. Other types of setting and default criteria are also contemplated by this disclosure. [0084] Torque transmitted to the output spindle is interrupted at 548 when the slope counts meet the setting criteria or default criteria; otherwise, tool operation continues as indicated at 550. Torque may be interrupted in one or more different ways including but not limited to interrupting power to the motor, reducing power to the motor, actively braking the motor or actuating a mechanical clutch interposed between the motor and the output spindle. In one example embodiment, the torque is interrupted by braking the motor, thereby setting the fastener at the desired position. To simulate the electronic clutching function, the user may be subsequently provided with haptic feedback. By driving the motor back and forth quickly between clockwise and counter clockwise, the motor can be used to generate a vibration of the housing which is 32 Attorney Docket No. 0275-001598/US perceptible to the tool operator. The magnitude of a vibration is dictated by a ratio of on time to off time; whereas, the frequency of a vibration is dictated by the time span between vibrations. The duty cycle of the signal deflvered to the motor is set (e.g., 10%) so that the signal does not cause the chuck to rotate. Operation of the tool is terminated after providing haptic feedback for a short period of time. It is to be understood that only the relevant steps of the technique are discussed in relation to Figure 25, but that other software-implemented instructions may be needed to implement the technique within the overall operation of the tool. [0085] Figure 27 illustrates an additional technique for controling operation of the drill driver when driving a fastener, Current delivered to the electric motor can be sampled and filtered at 582 by the controller in the same manner as described above in relation to Figure 25. Likewise, the slope of the current samples can be determined at 584 in the manner described above. [0086] In this technique, motor speed is used as a secondary check on whether to interrupt transmission of torque to the output spindle but only when the current slope exceeds a minimum slope threshold. Accordingly, the current slope is compared at 586 to a minimum slope threshold (e.g., with a value of 40). The secondary check proceeds at 588 when the current slope exceeds the minimum slope threshold: otherwise, processing continues with subsequent current sample as indicated at 582. [0087] To perform the secondary check, motor speed is captured at 588. In one example embodiment, motor speed may be captured by a Hall effect 33 Attorney Docket No. 0275-001 598/US sensor disposed adjacent to or integrated with the electric motor. Output from the sensor is provided to the controller. Other types of speed sensors are also contemplated by this disclosure. [0088] In the example embodiment, the controller maintains a variable or flag (i.e., RefRPM-Capture) to track when the current slope exceeds the minimum slope threshold. The flag is initally set to false and thereafter remains false while the present slope is less than the minimum siope threshold. At the first occurrence of the current slope exceeding the minimum slope threshold, the flag is faise and the controller will set a reference motor speed equal to the present motor speed at 592. The reference motor speed is used to evaluate the magnitude of decrease in motor speed. In addition, the flag is set to true at 593 and will remain set to true until the current slope is less than the minimum slope threshold. For subsequent and consecutive occurrences of the current slope exceeding the minimum slope threshold, the flag remains set to true and reference speed is not reset. In this way, the flag (when set to true) indicates that preceding slope values have exceeded the minimum slope threshold. [0089] Next, the present speed is compared at 594 to the reference speed. When the motor is slowing down (i.e., the reference speed exceeds the present speed), a further determination is made as to the size of the decrease. More specifically, a difference is computed at 595 between the reference speed and the present motor speed, A difference threshod is also set at 596 to be a predefined percentage (e.g., 5%) of the reference speed. The predefined percentage can be derived empirically and may vary for different tool types. The 34 Attorney Docket No. 0275-001598/US difference is then compared at 597 to the difference threshold. Processing of subsequent current sample continues until the difference between the reference speed and the present speed exceeds the difference threshold as indicated at 597. Once the difference between the reference speed and the present speed exceeds the difference threshold (and while the motor speed is decreasing), transmission of torque to the output spindle is interrupted at 598. It is to be understood that only the relevant steps of the technique are discussed in relation to Figure 25, but that other software-implemented instructions may be needed to implement the technique within the overall operation of the tool. Furthermore, the secondary check described above in relation to FIG. 27 is intended to work cooperatively (e.g., in parallel with) the technique described in FIGS 25 and 26. It is also envisioned that this technique may be implemented independent from the technique described in FIGS 25 and 26 as a method for automatically setting a fastener in a workpiece. [0090] Referring to FiG. 13 and again to FIGS. 1-6, when the user places the drill driver 10 in a clutch mode by manual rotation or operation of the rotary member 36 of rotary potentiometer/switch assembly 32, and positions a tool such as a setting tool 222 in clutch jaws 22 of chuck 20, a first fastener 224 can be driven into first and second components 226, 227 to join the first and second components 226, 227. Subsequent operation of trigger 28 permits installation of first fastener 224 to a desired depth or degree of head seating for a fastener head 228 in relation to a component surface 230 of first component 226. Because different screws have different characteristics, the drill driver 10 may 35 Attorney Docket No. 0275-001598/US enable the user to rough tune the fastener setting algorithm. For example, the current change rate threshold for a shorter screw may be lower than for a longer screw. To accommodate such differences, the drill driver 10 may provide two or more different user-actuated buttons that allow the user to tune the fastener setting algorithm. Continuing with the example above, one button may be provided to a shorter screw and one button may be provided for a longer screw. The current change rate threshold may be adjusted depending upon which button is actuated by the tool operator before an installation operation. It is readily understood that other parameters of the fastener setting algorithm or the tool (e.g., motor speed) may be adjusted in accordance with button actuation. Moreover, more or less buttons may be provided to accommodate different fastener characteristics or installation conditions. [0091] After completing installation of first fastener 224 such that fastener head 228 contacts component surface 230, it is often desirable to install a second or more fasteners to couple the first and second components 226, 227. Referring to FIG. 14 and again to FIGS. 12 and 13, drill driver 10 can further include a control feature zone 232 positioned, for example, at an upper facing surface of motor housing 30. Control feature zone 232 can include a plus (+) button 234 and a minus (-) button 236, as well as a memory store button 238. After completing installation of first fastener 224, the user can press the memory store button 238 to record an amperage draw that was required to seat first fastener 224. 36 Attorney Docket No. 0275-001598/US [0092] Referring to FIG. 15 and again to FIGS. 1-2 and 12-14, to install a second or subsequent fastener 224', the user again presses the memory store button 238 and actuates trigger 28 to begin installation of second fastener 224'. The electronic control circuit of PCB 40 senses when the current draw that equals the current draw stored in the memory feature of microcontroller 42 is again reached during the installation of fastener 224' and provides feedback to the user that fastener 224' has seated in a similar manner as first fastener 224. As previously noted, the current draw for installation of each of the fasteners 224, 224' can be equated to a torque force required to drive the fastener. After the control circuit identifies that fastener 224, 224' is nearly seated based on the torque level sensed, the control circuit can vary the feedback to allow the user better control in stopping installation of fastener 224' at the appropriate time and/or depth. [0093] The feedback provided to the user can be manipulated as follows. First, the output of motor 34 can be stopped. Second, the speed of motor 34 can be reduced. For example, the speed of rotor 34 can be reduced from approximately 600 rpm to approximately 200 rpm. This reduction in operating speed provides the user with visible feedback on the rate at which the fastener is being installed and provides additional time for the user to respond to how far fastener 224' is being set into the first and second components 226, 227. Third, operation of motor 34 can be ratcheted, for example by pulsing motor 34 on and off to provide dscreet, small rotations of the fastener 224'. This acts to slow down the average rotation speed of chuck 20, providing the user more 37 Attorney Docket No. 0275-001598/US control in setting the depth of penetration of fastener 224'. This could also function as an indication to the user that fastener installation is nearly complete and that the drill driver 10 has changed operating mode. In addition, ratcheting of motor 34 also provides a sensation to the user similar to a mechanical clutch operation. Fourth, the varied output of motor 34 from the above second and third operations can continue indefinitely or could continue for a fixed period of time and then stop. For example, the varied output of motor 34 can continue until the user releases trigger 28. [0094] With continuing reference to FIG. 14, in addition to the memory storage feature provided by memory store button 238, the user can use either the plus button 234 or the minus button 236 to fine tune a current draw limit in response to slight variations in either the fastener and/or the first or second component 226, 227. For example, if the user identifies that the amperage draw saved using memory store button 238 after installation of the first fastener 224 does not seat the fastener head 228 of second fastener 224' to an acceptable degree, the user can press the plus button 234 to incrementally increase a cutout level of current load provided to motor 34. Similarly, but to an opposite extent, the minus button 236 can be depressed to incrementally decrease the cutout level of current load. The features provided by plus button 234, minus button 236, and memory store button 238 are available in either drill or drive mode. These features allow the user to fine tune the operation of drill driver 10 over a wide variety of materials, such as wood, plywood, particle board, plastics, metal, and the like, for which universal limits cannot be established. 38 Attorney Docket No. 0275-O 598/US [0095] Referring again to FIGS. 12 and 14 as well as to FIGS. 1 and 2, in the event that operation of motor 34 stops before fastener head 228 is completely engaged or parallel with respect to component surface 230, a timed operation mode is available to complete the installation of fastener 224 which provides an automatic period of operating time for motor 34, thereby eliminating the need for the user to estimate the time or degree of rotation of chuck 20 to achieve full setting of fastener 224. When operation of motor 34 ceases and the user releases trigger 28, if the user visually recognizes that additional displacement of fastener 224 is required, and if the user subsequently depresses trigger 28 within a predetermined time period after the motor 34 has ceased operation, a timed operation mode is automatically engaged. The predetermined time period for initiation of the timed operation mode can be varied, but can be set, for example, at a period of time of approximately one second. Therefore, if the user recognizes that additional driving force is required to seat fastener 224' and again depresses trigger 28 within approximately one second of the stop of motor 34, motor 34 is again energized to rotate chuck 20 for a period of time approximating 200 ms of chuck 20 rotation. If the first operation in timed operation mode is not sufficient to fully seat fastener 224, and the user releases trigger 28 and again depresses trigger 28 within approximately one second, a second or subsequent timed operation mode operation of approximately 200 ms will occur. The number of timed operation mode operations is not limited; therefore, the user can continue in this mode provided that trigger 28 is depressed within the minimum time period required. The timed operation mode 39
I
Attorney Docket No. 0275-001598/US will time-out if the user does not again depress trigger 28 within the predetermined time period, such as the exemplary one second time perod described above. Following the time-out of the timed operation mode operation, the drill driver 10 will return to norma or the previous operating mode based on the parameters previously set by the user. [00961 Referring to FIG. 16 and again to FIGS. 12, 14, and 1-2, a timed operation mode flowchart identifies the various steps of operation of the electronic control circuit of drll driver 10 providing for timed operation mode control. Initially, with drill driver 10 in drive mode, when the user releases trigger 28 the control circuit searches for a timed operation flag 242. If the timed operation flag 242 is present, indicating that the user has re-depressed trigger 28 within a predetermined time period (for example 1 second), a timed operation duty cycle set step 244 is performed which subsequently directs, via a motor turn on step 246, motor 34 to energize for a predetermined time period (for example 200 ms) of chuck 20 rotation. As motor 34 operates in the timed operation mode, following indication by a counter that timed operation has been completed, in a stop motor step 248 motor 34 is de-energized. After motor 34 is de-energized, an increase switch hold counter step 250 initiates, which will alJow further operation in the timed operation mode if trigger 28 is again depressed within the predetermined time period. In a switch check step 252, a check is performed to identify if an analog digital converter (ADC) switch controlled by trigger 28 is still closed while an additional increase switch hold counter stop 250 is performed. if the switch check step 252 indicates that the trigger 28 has been released, a first 40 Attorney Docket No. 0275-001596/US comparison step 254 is performed wherein a switch hold counter is compared to a normal hold counter to determine if the switch hold counter is Jess than the normal hold counter. If the switch hold counter in first comparison step 254 is not less than the normal hold counter, a subsequent second comparison step 256 is performed wherein it is determined if the switch hold counter is greater than the normal hold counter. If, as a result of the second comparison step, the switch hold counter is not determined to be greater than the normal hold counter, the timed operation mode is ended. Returning to the timed operation flag 242 initially quered at the start of the timed operation mode, if timed operation flag 242 is not present, the timed operation mode cannot be initiated. [0097] Returning to the first comparison step 254, if the switch hold counter is less than the normal hold counter, a decrease counter step 258 is performed wherein the timed operation time delay counter is decreased. Returning to the second comparison step 256, if the switch hold counter is greater than the normal hold counter, an increase counter step 260 is performed wherein the timed operation time delay counter is increased. Following either the decrease counter step 258 or the increase counter step 260, the timed operation mode is timed-out. [0098] Referring to FIG. 17 and again to FIG. 16, a voltage versus time graph 262 identifies the current draw at various voltages over time provided for operation of motor 34 in the timed operation mode. [0099] If drill driver 10 is preset to operate in an automatic operating mode, the timed operation mode can be automatically induced when the 41 Attorney Docket No. 0275-001598/US electronic control system identifies that motor 34 has stopped rotation, for example due to either the maximum current or torque setting being reached, while the user continues to depress trigger 28. After the determination that motor 34 has stopped for a predetermined period of time while trigger 28 is still depressed, the timed operation mode automatically begins and will rotate motor 34 and chuck 20 for approximately 200 ms. The predetermined time period for automatic initiation of the timed operation mode can also be for example one second, or set to any other desired time period. [00100] If drill driver 10 is set to operate in the manual mode and the rotary potentiometer/switch assembly 32 is used to predetermine or preset an operating torque via a torque command for chuck 20, motor 34 will stop when the predetermined torque setting is reached. If the user releases trigger 28 at this time, and then re-depresses trigger 28 within a predetermined period of time, a last saved high current level required to fully seat a fastener, saved for example in the EEPROM or memory device/function of microcontroller 42, will be automatically reapplied, thereby further rotating chuck 20 until the high current level last saved in memory is achieved. This permits a combination of a manual and an automatic operation of drill driver 10 such that the predetermined or preset torque limits manually entered by the user can be supplemented automatically by a current level saved in the memory corresponding to a fully set fastener position. [00101] Referring to FIG. 18 and again to FIGS. 1 and 2, information stored in any of the various memory devices/functions of drill driver 10 can be 42 Attorney Docket No, 0275-001598/US supplemented by additional information from one or more offsite locations, to increase the number of operations performed by drill driver 10, or to change tool performance for particular tasks. For example, where electronic clutch settings for multiple different fasteners are available for multiple different material combinations, the user can download additional data for these clutch settings which will automatically be saved for use for operation of drill driver 10. To receive new data, a receiver 264 provided in drill driver 10 is connected to a programmable controller 266. According to one aspect, an application library 268 that is remote from drill driver 10 contains data to transfer to drBI driver 10. Data stored at application library 268 can be transferred upon query by the user via a wireless signal path 270 to a user interface device 272. Predetermined password or authorization codes can be sent to the user to authorize entry into application library 268. User interface device 272 can be one of multiple devices, including computers or portable cell phones such as a smartphone. The data received wirelessly by the user interface device 272 and temporarily stored therein can be subsequently transferred by the user via a wireless signal path 274 to drill driver 10. The data received via the wireless signal path 274 from user interface device 272 is received at receiver 264 and stored by programmable controller 266 or other memory devices/functions of drUl driver 10. This operation increases or supplements the database of data saved by drill driver 10 such that new information that may become available during the lifetime of drill driver 10 can be used. 43 Attorney Docket No, 0275-001598/US [00102] Referring to FIG. 19, an initialization flow diagram 276 identifies the various steps taken by the electronic control system of drill driver 10 upon initial startup of the unit. In an initialization step 278, variables and hardware required during startup of the unit are initialized. In a following read EEPROM step 280, the data saved in the EEPROM of microcontroller 42 is read to determine the last mode of operation and thereby used to initialize the mode selection for initial operation of drill driver 10. In a check status step 282, it is determined whether any of a power off timeout has occurred, whether an under voltage cutoff has occurred, whether a high temperature cutoff has occurred, or if an over-current flag is indicated. If none of the conditions identified by check status step 282 are present, a subsequent read trigger step 284 is performed wherein the analog-digital converter (ADC) for trigger 28 is read to determine if the ADC signal is greater than a predetermined start limit. If the start limit is not exceeded, as determined in read trigger step 284, a stop motor running operation 286 is performed. If the limits read for the trigger ADC signal in read trigger step 284 are greater than the predetermined start limits, a select mode step 288 operates to return to the check status step 282. [00103] Following the stop motor running operation 286, a first check button step 290 is performed wherein it is determined if a forward operational selection button or switch is actuated. If the first check button step 290 is positive, a set forward mode step 292 is performed. If the first check button step 290 is negative, a second check button step 294 is performed, wherein it is determined if a reverse operational selection button or switch has been actuated. 44 Attorney Docket No 0275-00159B/US If the second check button step 294 is positive, a set reverse mode step 296 is performed. If the second check button step 294 is negative, a third check button step 298 is performed wherein a determination is made if the drive mode button or drve mode selector is actuated. If the third check button step 298 is positive, a set drive mode step 300 is performed. If the third check button stop 298 is negative, a fourth check button step 302 is performed wherein it is determined if the drill mode button or drill mode selector is actuated. If the result of the fourth check button step 302 is positive, a set drill mode step 304 is performed. If the fourth check button step 302 is negative, a clear flag step 306 is performed wherein an auto seating flag is set to zero. [00104] Returning to the check status step 282, if any of the items checked are indicated, a stop motor step 308 is performed to stop operation of motor 34. Following the stop motor step 308, a saved step 310 is performed wherein last data received, such as a maximum operating torque or operating current, is saved to the EEPROM of microcontroller 42. Following saved step 310, a power off step 312 is performed turning off operating power to drill driver 10 and enter sleep mode step 314 is performed following the power off step 312 to save electrical battery energy of drill driver 10. [001051 Referring to FIG. 20 and again to FIGS. 1-2 and 12, a diagram 316 of the electronic control circuit of the present disclosure is provided. The battery 16 voltage is normally isolated when a trigger switch 318 is open. When trigger switch 318 is closed, for example by depressing trigger 28, a DC/DC 10 volt supply 320 is energized by battery 16, The DC/DC 10-volt supply 320 is a 45 Attorney Docket No. 0275-001598/US 1 0-volt DC regulator that supplies power to the LED display screen 100 and to an "H" bridge driver which will be further described herein. Also connected to DC/DC 10-volt supply 320 is a 3-volt supply 322. Three-volt supply 322 provides 3-volt power for operation of electronics logic. The LED display screen IOU, as previously described herein, provides multiple LEDs including first through sixth LEDs 102-112. A mode select module 324 receives input from operation of either drill selector switch 170 or driver selector switch 172. The LED display screen 100, 3-volt supply 322, mode select module 324, and rotary potentiometer/switch assembly 32 are each connected to a microcontroller 42. Microcontroller 42 controls all peripheral features and interfaces, sets the direction of operation and the pulse-width module setting for "H" bridge control and further processes all analog input signals for drill driver 10. An "H" bridge driver 328 is also connected to microcontroller 42. "H" bridge driver 328 is a motor controller for a four MOSFET (metal-oxide-silicon field-effect transistor) bridge and controls forward, reverse, and breaking functions of motor 34. An "H" bridge 330 is a group of four MOSFETs connected in an "H" configuration that drive motor 34 in both forward and reverse directions. A current amplifier 332 senses the current draw across a shunt resistor and amplifies the current signal for the microcontroller 42. [00106] Referring to FIG. 21, a motor control mode flow diagram 334 identifies the various operational steps performed during motor control mode operation. A read trigger position step 336 is initially performed to identify an on" or "off" position of trigger 28. Following the read trigger position step 336, a 46 Attorney Docket No. 0275-001595/US trigger release check 338 is performed to identify when trigger 28 is released following depression. If trigger 28 has been released, a stop motor step 340 is performed, stopping operation of motor 34. A subsequent return step 342 is performed to return to the motor control mode. If the trigger 28 has not been released, as determined by trigger release step 338, a setting step 344 is performed wherein the pulse-width modulation is set and an FET (field effect transistor) drive is enabled. Following the setting step 344, a check step 346 is performed to determine if a battery under-voltage trip has occurred. f a battery under-voltage trip has occurred, the stop motor step 340 is performed. If no battery under-voltage trip has occurred during check step 346, a subsequent battery over-temperature check 348 is performed to determine if an over temperature condition of battery pack 16 has occurred. If a.battery over temperature condition has occurred, the stop motor step 340 is performed. If there is no indication of a battery over-temperature condition, a monitoring step 350 is performed wherein the motor back EMF (electromagnetic field) and load current are monitored during the time period of operation in motor control mode. [00107] Referring to FIG. 22A and again to FIGS. 1-6 and 8, as the user rotates rotary member 36 to adjust or set a clutch torque setting, individual ones of the first through sixth LEDs 102-112 may be illuminated. This provides visual indication to the user of the relative increase or decrease in torque setting. initially, upon rotation in any direction of rotary member 36, in a step 352 all of the green or blue LEDs that are currently illuminated are turned off. Following this, a read torque select input step 354 is performed wherein the electrical signal 47 Attorney Docket No. 0275-001598/US generated by rotation of rotary member 36 is read which corresponds to a selected torque input. [00108] According to several aspects, axial rotation of rotary member 36 provides twelve individual torque settings. In a first torque select step 356, a determination is made if the selected torque input corresponds to torque setting 12. If step 356 is affirmative, in a setting torque step 358, a torque level of 20 amps is set. At this time, in a step 360, green LED represented by sixth LED 112 is illuminated. If the result of step 356 is negative, in a following step 362, a determination is made if the selected torque input corresponds to torque setting 11. If affirmative, in a step 364, a torque of 18.5 amp level is set. At this same time, the color of sixth LED 112 is changed from green to blue in a step 366. If the response from step 362 is negative in a step 368, a determination is made if the selected torque input corresponds to torque setting 10. If the answer is affirmative, in a step 370, a torque level of 17 amps is set. At this time, the fifth LED 110 is illuminated using a green color in a step 372. If the response to step 368 is negative, in a step 374, a determination is made if the selected torque input corresponds to torque setting 9. If the response is affirmative, in a step 376, a torque of 15.5 amp level is set. At this time, fifth LED 110 is changed from green to blue in a step 378. If the response from step 374 is negative, in a step 380, a determination is made if the selected torque input corresponds to torque setting 8. If affirmative, in a step 382, a torque level of 14 amps is set. At this time, the fourth LED 108 is illuminated using a green color in a step 384. f the response from step 380 is negative, in a step 386, a determination is made if the 48 Attorney Docket No. 0275-001598/US selected torque input corresponds to torque setting 7. If affirmative, in a step 388, a torque of 12.5 amp level is set. At this time, the fourth LED 108 is changed from green to a blue color in a step 390. If the response to step 386 is negative, in a step 392, a determination is made if the selected torque input corresponds to torque setting 6. If affirmative, in a step 394, a torque of 11 amp level is set. At this time, the third LED 106 is illuminated using a green color in a step 396. If the response from step 392 is negative, in a step 398, a determination is made if the selected torque input corresponds to torque setting 5. If affirmative, in a step 400, a torque of 9.5 amp level is set. At this time, the third LED 106 is changed from a green to a blue color in a step 402. If the response to step 398 is negative, in a step 404, a determination is made if the selected torque input corresponds to torque setting 4. If affirmative, in a step 406, a torque of 8 amp level is set. At this time, the second LED 104 is illuminated using a green color in a step 408. If the response to step 404 is negative, in a step 410, a determination is made if the selected torque input corresponds to torque setting 3. If affirmative, in a step 412, a torque of 6.5 amp level is set. At this time, the second LED 104 is changed from a green to a blue color in a step 414. If the response to step 410 is negative, in a step 416, a determination is made if the selected torque input corresponds to torque setting 2. If affirmative, in a step 418, a torque of 5 amp level is set. At this time, the first LED 102 is illuminated using a green color in a step 420. If the response to step 416 is negative, in a step 422, a determination is made if the selected torque input corresponds to torque setting 1. If affirmative, in a step 424, a torque of 3.5 49
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Attorney Docket No. 0275-001598/US amp level is set. At this time, the first LED 102 is changed in color from green to blue in a step 426. It is noted that the sequencing identified in clutch torque flow diagram 351 corresponds to a decreasing torque value manually set by the user. The sequence is reversed if the user is selecting torque values that increase in value. [00109] Referring to FIG. 22B, a lookup table 428 provides saved values corresponding to the selected torque input level. A torque level in amps corresponding to the torque input level is also provided, as well as the corresponding color and illuminated LED for the LED display. [00110] Referring to FIG. 23 and again to FIGS. 1-6 and 8, when the user manually displaces the rotary potentiometer/switch assembly 32 by pushing in either a right-to-left or left-to-right direction against rotary member 36, a drill driver 10 clutch rotation direction is selected or changed. As previously noted, opposite displacements of rotary potentiometer/switch assembly 32 provide either a forward or a reverse clutch rotational direction. A forward/reverse LED display flow diagram 430 identifies the corresponding LED display that is presented upon selecting either the forward direction in a forward step 434 or the reverse direction in a reverse step 436. These steps follow an initial inquiry in a forward/reverse step 432 initiated by motion of the rotary member 36. If the forward rotational direction is selected, following forward step 434 and in sequential order, each of the first through sixth LEDs 102-112 are illuminated. Initially, in a step 438, the first LED 102 is illuminated using a blue color. Following a 60 millisecond delay step 440, first LED 102 is turned off and second 50 Attorney Docket No, 0275-001596/US LED 104 is turned on in a blue color in a stop 442. Following a 60 millisecond delay step 444, second LED 104 is turned off and third LED 106 is turned on in a blue color in a step 446. Following another delay of 60 ms in a step 448, third LED 106 is turned off and fourth LED 108 is turned on in a blue coior in a step 450. Following a delay of 60 ms in a step 452, fourth LED 108 is turned off and fifth LED 110 is turned on in a blue color in a step 454, Following an additional 60 ms delay step 456, the fifth LED 110 is turned off and the sixth LED 112 is turned on in a blue color in a step 458. Following a final delay of 60 ms in a step 460, the sixth LED 112 is turned off in a step 462. Based on the sequence of operation of first through sixth LEDs 102-112 in the forward operating mode, the LEDs will appear to rapidly illuminate in a clockwise direction. [00111] An opposite operation starting with illumination of sixth LED 112 and continuing to first LED 102 occurs if the reverse step 436 is actuated. Following reverse step 436, sixth LED 112 is illuminated in a blue color in a step 464. Following a delay of 60 ms in a step 466, the sixth LED 112 is turned off and the fifth LED 110 is turned on in a blue color in a step 468. Following a delay of 60 ms in a step 470, the fifth LED 110 is turned off and the fourth LED 108 is turned on in a blue color in a step 472. Following a delay of 60 ms in a step 474, the fourth LED 108 is turned off and the third LED 106 is turned on in a blue coior in a step 476. Following an additional delay of 60 ms in a step 478, the third LED 106 is turned off and the second LED 104 is turned on in a blue color in a step 480. Following a delay of 60 ms in a step 482, the second LED 104 is turned off and the first LED 102 is tried on in a blue color in a step 484. Finally, following 51 Attorney Docket No. 0275-001598/US a delay of 60 ms in a step 486, the frst LED 102 is turned off in a step 488. Based on the sequence of operation of sixth through first LEDs 112-102 in the reverse operating mode, the LEDs will appear to rapidly illuminate in a counter clockwise direction. [00112] One of the drawback of the LED-based display described above is that the clutch setting is not quantified for the tool operator. An alternative display 600 for a drill driver 10 having an electronic clutch is shown in Figure 28. In this alternative embodiment, a number corresponding to the clutch setting is displayed on the display 600. For example, the numeric value may range from one to six as described above in relation to Figure 10. In one embodiment, the display 600 may be implemented using a simple dot matrix display although other types of displays are also contemplated by this disclosure. The clutch setting can be set, for example, using the rotary member 36. Other types on mechanisms fall for selecting a clutch setting also within the broader aspects of this feature. In some embodiments, a light sensor 602 may also be integrated into the housing of the drill driver 10. The signal from the light sensor is received by the controller and can be used to adjust the brightness of the display, thereby improving the visibility of the display in different light conditions. [00113] For drill drivers having multi-speed transmissions, the maximum clutch torque setting for the mechanical clutch is dictated by the maximum torque that can be achieved in a high speed (low torque) setting. Setting the maximum torque setting for the clutch in this manner prevents the tool from stalling regardless of the speed and clutch settings but creates a difference in the 52
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Attorney Docket No. 0275-001598/US maximum torque setting between low speed and high speed modes, in an electronic clutch, different ranges of clutch settings can be assigned to each of the different speed settings. For example, in a high speed (low torque) setting, the clutch settings may range between eight settings (i.e., 1-8); whereas, in the low speed (high torque) setting, the clutch setting may range between twelve settings (i.e,, 1-12), where for clutch setting correlates to a different user selectable predefined maximum torque level as noted above. To support this arrangement, the clutch settings are display by the controller on the display 600 using different scales. When the tool is in the low speed setting, all twelve clutch settings can be selected by the user and thus may be displayed on the display. When the tool is in the high speed setting, only the first eight settings (i.e., 1-8) are selected by the user and thus may be display on the display. In some embodiments, the clutch setting mechanism (e.g., rotary member 36) enables the user to pick from the full range of settings (e.g., 12 different settings)r In the case the tool is in the high speed setting, values for the first eight setting are displayed as well as the value for the eight setting being displayed for the four additional setting available on the clutch setting mechanism. That is, values for the twelve selectable setting of the rotary member are displayed as 1, 2, 3, 4, 5, 6, 7, 8, 8, 8, 8, 8, respectively. While reference is made to a drill driver with two speed transmission, it is readily understood that this concept may be extended to three or more speed transmissions as well. [00114] Example embodiments are provided so that this disclosure will be thorough, and will fully convey the scope to those who are sled in the art. 53 Attorney Docket No. 0275-001598/US Numerous specific details are set forth such as examples of specific components, devices, and methods, to provide a thorough understanding of embodiments of the present disclosure. It will be apparent to those skilled in the art that specific details need not be employed, that example embodiments may be embodied in many different forms and that neither should be construed to limit the scope of the disclosure. In some example embodiments, well-known processes, well-known device structures, and well-known technologies are not described in detail. [00115] The terminology used herein is for the purpose of describing particular example embodiments only and is not intended to be limiting. As used herein, the singular forms "a," "an," and "the" may be intended to include the plural forms as well, unless the context clearly indicates otherwise. The terms "comprises," "comprising," "Including," and "having," are inclusive and therefore specify the presence of stated features, integers, steps, operations, elements, and/or components, but do not preclude the presence or addition of one or more other features, integers, steps, operations, elements, components, and/or groups thereof. The method steps, processes, and operations described herein are not to be construed as necessarily requiring their performance in the particular order discussed or illustrated, unless specifically identified as an order of performance. It is also to be understood that additional or alternative steps may be employed. [00116] The foregoing description of the embodiments has been provided for purposes of illustration and description. It is not intended to be exhaustive or to limit the disclosure. Individual elements or features of a 54- Attorney Docket No. 0275-001598/US particular embodiment are generally not limited to that particular embodiment, but, where applicable, are interchangeable and can be used in a selected embodiment, even if not specifically shown or described. The same may also be varied in many ways. Such variations are not to be regarded as a departure from the disclosure, and all such modifications are intended to be included within the scope of the disclosure. Throughout this specification and the claims which follow, unless the context requires otherwise, the word composee", and variations such as "comprises" and "comprising", will be understood to imply the inclusion of a stated integer or step or group of integers or steps but not the exclusion of any other integer or step or group of integers or steps. The reference in this specification to any prior publication (or information derived from t), or to any matter which is known, is not, and should not be taken as an acknowledgment or admisson or any form of suggestion that that prior publication (or information derived from it) or known matter forms part of the common general knowledge in the field of endeavour to which this specification relates.

权利要求:
Claims (20)
[1] 1. A method of controlling operation of a power tool having an electric motor drivably connected to an output spindle to impart rotary motion thereto, comprising: receiving, by a controller residing in the power tool, an input indicative of a clutch setting for an electronic clutch, the clutch setting being selectable from a drill mode and a drive mode; monitoring, by the controller, torque applied to the output spindle when the clutch setting is in a drive mode by sampling periodically current delivered to the electric motor; storing a sequence of current measures most recently sampled, the sequence of current measures being stored in a memory of the power tool; and determining a slope for the sequence of current measures by way of linear regression; interrupting, by the controller, transmission of torque to the output spindle based in part on the slope of the sequence of current measures and when the clutch setting is in a drive mode; and disregarding, by the controller, torque applied to the output spindle when the clutch setting is in drill mode. 56 Attorney Docket No, 0275-001598/US
[2] 2. The method of claim 1 further comprises detecting, by the controller, an occurrence of a trigger switch being released and subsequently depressed by the tool operator, where the trigger switch controls quantity of electric power delivered to the electric motor ard the occurrence of the trigger switch being released and subsequently depressed by the tool operator occurs within a time limit of interrupting transmission of torque; and energizing, by the controller, the electric motor for a period of time after generating haptic feedback and in response to detecting the occurrence of the trigger switch being released and subsequently depressed by the tool operator.
[3] 3. The method of claim 1 further comprises comparing, by the controller, the slope to a minimum slope threshold; incrementing, by the controller, a slope counter by one when the slope exceeds the minimum slope threshold; evaluating, by the controller, the slope counter in relation to a setting criteria, where the setting criteria is indicative of a desired stopping position for a fastener being driven by the power tool; and interrupting, by the controller, transmission of torque to the output spindle when the slope counter meets the setting criteria.
[4] 4. The method of claim 3 further comprises storing, by the controller, a sequence of values for the slope counter; and 57 Attorney Docket No. 0275-001598/LJS evaluating, by the controller, the sequence of values for the slope counter in relation to the setting criteria.
[5] 5. The method of claim 4 further comprises interrupting transmission of torque when values in the sequence of values for the slope counter are increasing from an oldest value to a most recent value.
[6] 6. The method of claim 4 further comprises interrupting transmission of torque when values in the sequence of values for the slope counter increase from an oldest value to an intermediate value and decrease from the intermediate value to a most recent value.
[7] 7. The method of claim 1 further comprises providing a visual indicator for the clutch setting during the operation of the tool.
[8] 8. The method of claim I wherein receiving an input further comprises receiving a signal from one or two buttons provided on a housing of the power tool, where one of the two buttons is associated with the drill mode and other of the two buttons is associated with the drive mode.
[9] 9. The method of claim 8 further comprises illuminating an icon integrated into one of the two buttons actuated by the tool operator, where the icon is indicative of the operating mode associated with the actuated button. 58 PK Attorney Docket No. 0275-001 598/US
[10] 10. The method of claim 1 further comprising determining, by the controller, a magnitude of current being delivered to the electric motor immediately prior to interrupting transmission of torque: storing, by the controller, the magnitude of current in a storage device in response to an input from the tool operator; interrupting transmission of torque to the output spindle during a subsequent operation of the tool when the amount of current being delivered to the electric motor is equal to or exceeds the stored magnitude of current. 59 Attorney Docket No. 0275-001 595/US
[11] 11. A portable, hand held power tool, comprising: a housing; an electric motor drivable connected to an output spindle to impart rotary motion thereto; a current sensor configured to sample current being delivered to the electric motor; an input component operable by the tool operator to set a clutch setting for tool, the clutch setting being selectable from a drib mode, an automated drive mode and one or more user-defined drive modes, where each of the user-defined drive modes specifies a different value of torque at which to interrupt transmission of torque to the output spindle; and a controller configured to receive the clutch setting from the input component and current measures from the current sensor, wherein the controller operates, when the clutch setting is an automated drive mode, to interrupt torque to the output spindle monitor rate of change of the current measures and interrupt torque to the output spindle in response to the rate of change of current measures exceeding a rate change threshold, the controller further operates, when the clutch setting is in a selected one of the user-defined drive modes, to set a value of a maximum current threshold in accordance with the selected one of the user-defined drive modes and interrupt torque to the output spindle in response to the current measures exceeding the maximum current threshold. 60 Attorney Docket No. 0275-00159B/US
[12] 12. The power tool of claim 11 wherein the controer, when the clutch setting is an automated drive mode, operates to receive current measure from the current sensor, stores a sequence of current measures most recently sampled in a memory of the power tool, and determine a slope for the sequence of current measures by way of linear regression and operates to interrupt transmission of torque based in part on the slope of the sequence of current measures.
[13] 13. The power tool of claim of claim 12 wherein the controufer further operates to compare the slope to a minimum slope threshold; adjust a slope counter in accordance with the comparison of the slope with the minimum slope threshold, evaluate the slope counter in relation to a setting criteria, and interrupt transmission of torque to the output spindle when the slope counter meets the setting criteria, where the setting criteria is indicatve of a desired stopping position for a fastener being driven by the power tool.
[14] 14. The power tool of claim 10 wherein the controller, when the clutch setting is a drill mode, ignores torque applied to the output spindle.
[15] 15. The power tool of claim 10 wherein the controller provides haptic feedback to the tool operator concurrently with interrupting transmission of torque to the output spindle. 61 Attorney Docket No. 0275-00159S/US
[16] 16. The power tool of claim 10 wherein the input component is further defined as two pushbuttons integrated into the housing, such that actuation of one pushbutton sets the clutch setting to a drill mode and actuation of the other pushbutton sets the clutch setting to a drive mode.
[17] 17. The power tool of claim 16 wherein one of the two pushbuttons actuated by the tool operator is illuminated during operation of the tool.
[18] 18. The power tool of claim 10 wherein the input component is further defined as a rotary potentiometer switch assembly including: an assembly platform rotatably mounted to the body; a rotary device rolatably mounted to the assembly palform such that manual axial rotation of the rotary device acts to create a clutch setlng; and opposed first and second directional switches mounted to the assembly platform, wherein when one of the first or second directional switches contacts the body during a manual rotation of the assembly platform, either a forward or a reverse operating direction of rotation command for the output spindle is created. 62 Attorney Docket No. 0275-001598/US
[19] 19. The power tool of claim 10 further comprising a display port located on the housing including multiple bi-color light emitting diodes (LEDs) each operating to display three colors, including two primary colors and a thrd color which is a mix of the two primary colors, each LED color providing visual indication of multiple different operating modes of the power tool.
[20] 20. The power tool of claim 10 further comprising a display port located on the housing, wherein a numeric value for the selected one of the user-defined drive modes is presented on the display port. 63 E7

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引用文献:

---

公开号 | 申请日 | 公开日 | 申请人 | 专利标题

---

US5014793A|1989-04-10|1991-05-14|Measurement Specialties, Inc.|Variable speed DC motor controller apparatus particularly adapted for control of portable-power tools|

---

JPH0628947U|1992-09-21|1994-04-15|アルプス電気株式会社|Switch device|

---

GB9320181D0|1993-09-30|1993-11-17|Black & Decker Inc|Improvements in and relating to power tools|

---

US6536536B1|1999-04-29|2003-03-25|Stephen F. Gass|Power tools|

---

DE10045985A1|2000-09-16|2002-03-28|Hilti Ag|Electric drill has fixing bar code reader sets torque automatically|

---

JP4230276B2|2003-05-19|2009-02-25|本田技研工業株式会社|Brushless DC motor control device|

---

JP2005066785A|2003-08-26|2005-03-17|Matsushita Electric Works Ltd|Power tool|

---

JP2005118910A|2003-10-14|2005-05-12|Matsushita Electric Works Ltd|Impact rotary tool|

---

JP4669663B2|2004-02-27|2011-04-13|勝行 戸津|Torque management system using an electric screwdriver having a torque detection function and an electric screwdriver having a torque detection function|

---

JP4211675B2|2004-05-12|2009-01-21|パナソニック電工株式会社|Impact rotary tool|

---

JP4400303B2|2004-05-12|2010-01-20|パナソニック電工株式会社|Impact rotary tool|

---

EP1802970B1|2004-06-17|2016-01-06|Bayer HealthCare LLC|Detecting incomplete fill of biosensors|

---

BRPI0402362A|2004-06-18|2006-01-31|Metalac Sps Ind E Com Ltda|System and method for automated execution of bolted joints|

---

US7331406B2|2004-06-21|2008-02-19|Duraspin Products Llc|Apparatus for controlling a fastener driving tool, with user-adjustable torque limiting control|

---

US7552781B2|2004-10-20|2009-06-30|Black & Decker Inc.|Power tool anti-kickback system with rotational rate sensor|

---

US7677844B2|2005-04-19|2010-03-16|Black & Decker Inc.|Electronic clutch for tool chuck with power take off and dead spindle features|

---

JP4339275B2|2005-05-12|2009-10-07|株式会社エスティック|Method and apparatus for controlling impact type screw fastening device|

---

CA2621293A1|2005-08-29|2007-03-08|Demain Technology Pty Ltd.|Power tool|

---

US7551411B2|2005-10-12|2009-06-23|Black & Decker Inc.|Control and protection methodologies for a motor control module|

---

DE102006016448A1|2006-04-07|2007-10-11|Robert Bosch Gmbh|Electric machine tool and method of operating the same|

---

CN101247100B|2007-02-16|2012-01-25|苏州宝时得电动工具有限公司|Electric tool control method and electric tool using the same|

---

JP5182562B2|2008-02-29|2013-04-17|日立工機株式会社|Electric tool|

---

EP2521832B1|2010-01-07|2020-03-25|Black & Decker, Inc.|Power screwdriver having rotary input control|

---

JP5822085B2|2010-06-30|2015-11-24|日立工機株式会社|Electric tools and power tools|US20070084897A1|2003-05-20|2007-04-19|Shelton Frederick E Iv|Articulating surgical stapling instrument incorporating a two-piece e-beam firing mechanism|

---

US9060770B2|2003-05-20|2015-06-23|Ethicon Endo-Surgery, Inc.|Robotically-driven surgical instrument with E-beam driver|

---

US8215531B2|2004-07-28|2012-07-10|Ethicon Endo-Surgery, Inc.|Surgical stapling instrument having a medical substance dispenser|

---

US8549513B2|2005-06-29|2013-10-01|Microsoft Corporation|Model-based virtual system provisioning|

---

US7669746B2|2005-08-31|2010-03-02|Ethicon Endo-Surgery, Inc.|Staple cartridges for forming staples having differing formed staple heights|

---

US11246590B2|2005-08-31|2022-02-15|Cilag Gmbh International|Staple cartridge including staple drivers having different unfired heights|

---

US7934630B2|2005-08-31|2011-05-03|Ethicon Endo-Surgery, Inc.|Staple cartridges for forming staples having differing formed staple heights|

---

US9237891B2|2005-08-31|2016-01-19|Ethicon Endo-Surgery, Inc.|Robotically-controlled surgical stapling devices that produce formed staples having different lengths|

---

US10159482B2|2005-08-31|2018-12-25|Ethicon Llc|Fastener cartridge assembly comprising a fixed anvil and different staple heights|

---

US20070106317A1|2005-11-09|2007-05-10|Shelton Frederick E Iv|Hydraulically and electrically actuated articulation joints for surgical instruments|

---

US11207064B2|2011-05-27|2021-12-28|Cilag Gmbh International|Automated end effector component reloading system for use with a robotic system|

---

US7845537B2|2006-01-31|2010-12-07|Ethicon Endo-Surgery, Inc.|Surgical instrument having recording capabilities|

---

US20120292367A1|2006-01-31|2012-11-22|Ethicon Endo-Surgery, Inc.|Robotically-controlled end effector|

---

US8186555B2|2006-01-31|2012-05-29|Ethicon Endo-Surgery, Inc.|Motor-driven surgical cutting and fastening instrument with mechanical closure system|

---

US20110295295A1|2006-01-31|2011-12-01|Ethicon Endo-Surgery, Inc.|Robotically-controlled surgical instrument having recording capabilities|

---

US7753904B2|2006-01-31|2010-07-13|Ethicon Endo-Surgery, Inc.|Endoscopic surgical instrument with a handle that can articulate with respect to the shaft|

---

US8820603B2|2006-01-31|2014-09-02|Ethicon Endo-Surgery, Inc.|Accessing data stored in a memory of a surgical instrument|

---

US11224427B2|2006-01-31|2022-01-18|Cilag Gmbh International|Surgical stapling system including a console and retraction assembly|

---

US8708213B2|2006-01-31|2014-04-29|Ethicon Endo-Surgery, Inc.|Surgical instrument having a feedback system|

---

US8992422B2|2006-03-23|2015-03-31|Ethicon Endo-Surgery, Inc.|Robotically-controlled endoscopic accessory channel|

---

US8322455B2|2006-06-27|2012-12-04|Ethicon Endo-Surgery, Inc.|Manually driven surgical cutting and fastening instrument|

---

US8348131B2|2006-09-29|2013-01-08|Ethicon Endo-Surgery, Inc.|Surgical stapling instrument with mechanical indicator to show levels of tissue compression|

---

US10568652B2|2006-09-29|2020-02-25|Ethicon Llc|Surgical staples having attached drivers of different heights and stapling instruments for deploying the same|

---

US8684253B2|2007-01-10|2014-04-01|Ethicon Endo-Surgery, Inc.|Surgical instrument with wireless communication between a control unit of a robotic system and remote sensor|

---

US8652120B2|2007-01-10|2014-02-18|Ethicon Endo-Surgery, Inc.|Surgical instrument with wireless communication between control unit and sensor transponders|

---

US8827133B2|2007-01-11|2014-09-09|Ethicon Endo-Surgery, Inc.|Surgical stapling device having supports for a flexible drive mechanism|

---

US11039836B2|2007-01-11|2021-06-22|Cilag Gmbh International|Staple cartridge for use with a surgical stapling instrument|

---

US20090005809A1|2007-03-15|2009-01-01|Hess Christopher J|Surgical staple having a slidable crown|

---

US8893946B2|2007-03-28|2014-11-25|Ethicon Endo-Surgery, Inc.|Laparoscopic tissue thickness and clamp load measuring devices|

---

US8931682B2|2007-06-04|2015-01-13|Ethicon Endo-Surgery, Inc.|Robotically-controlled shaft based rotary drive systems for surgical instruments|

---

US7753245B2|2007-06-22|2010-07-13|Ethicon Endo-Surgery, Inc.|Surgical stapling instruments|

---

RU2493788C2|2008-02-14|2013-09-27|Этикон Эндо-Серджери, Инк.|Surgical cutting and fixing instrument, which has radio-frequency electrodes|

---

US7866527B2|2008-02-14|2011-01-11|Ethicon Endo-Surgery, Inc.|Surgical stapling apparatus with interlockable firing system|

---

US8758391B2|2008-02-14|2014-06-24|Ethicon Endo-Surgery, Inc.|Interchangeable tools for surgical instruments|

---

US9179912B2|2008-02-14|2015-11-10|Ethicon Endo-Surgery, Inc.|Robotically-controlled motorized surgical cutting and fastening instrument|

---

US8636736B2|2008-02-14|2014-01-28|Ethicon Endo-Surgery, Inc.|Motorized surgical cutting and fastening instrument|

---

US7819298B2|2008-02-14|2010-10-26|Ethicon Endo-Surgery, Inc.|Surgical stapling apparatus with control features operable with one hand|

---

US8573465B2|2008-02-14|2013-11-05|Ethicon Endo-Surgery, Inc.|Robotically-controlled surgical end effector system with rotary actuated closure systems|

---

US9585657B2|2008-02-15|2017-03-07|Ethicon Endo-Surgery, Llc|Actuator for releasing a layer of material from a surgical end effector|

---

US8210411B2|2008-09-23|2012-07-03|Ethicon Endo-Surgery, Inc.|Motor-driven surgical cutting instrument|

---

US9005230B2|2008-09-23|2015-04-14|Ethicon Endo-Surgery, Inc.|Motorized surgical instrument|

---

US9386983B2|2008-09-23|2016-07-12|Ethicon Endo-Surgery, Llc|Robotically-controlled motorized surgical instrument|

---

US8608045B2|2008-10-10|2013-12-17|Ethicon Endo-Sugery, Inc.|Powered surgical cutting and stapling apparatus with manually retractable firing system|

---

US8517239B2|2009-02-05|2013-08-27|Ethicon Endo-Surgery, Inc.|Surgical stapling instrument comprising a magnetic element driver|

---

US20110024477A1|2009-02-06|2011-02-03|Hall Steven G|Driven Surgical Stapler Improvements|

---

US8444036B2|2009-02-06|2013-05-21|Ethicon Endo-Surgery, Inc.|Motor driven surgical fastener device with mechanisms for adjusting a tissue gap within the end effector|

---

US8220688B2|2009-12-24|2012-07-17|Ethicon Endo-Surgery, Inc.|Motor-driven surgical cutting instrument with electric actuator directional control assembly|

---

US10945731B2|2010-09-30|2021-03-16|Ethicon Llc|Tissue thickness compensator comprising controlled release and expansion|

---

CN104321024B|2012-03-28|2017-05-24|伊西康内外科公司|Tissue thickness compensator comprising a plurality of layers|

---

US9320523B2|2012-03-28|2016-04-26|Ethicon Endo-Surgery, Llc|Tissue thickness compensator comprising tissue ingrowth features|

---

US9629814B2|2010-09-30|2017-04-25|Ethicon Endo-Surgery, Llc|Tissue thickness compensator configured to redistribute compressive forces|

---

US9282962B2|2010-09-30|2016-03-15|Ethicon Endo-Surgery, Llc|Adhesive film laminate|

---

RU2644272C2|2012-03-28|2018-02-08|Этикон Эндо-Серджери, Инк.|Limitation node with tissue thickness compensator|

---

US9364233B2|2010-09-30|2016-06-14|Ethicon Endo-Surgery, Llc|Tissue thickness compensators for circular surgical staplers|

---

JP6026509B2|2011-04-29|2016-11-16|エシコン・エンド−サージェリィ・インコーポレイテッドＥｔｈｉｃｏｎ Ｅｎｄｏ−Ｓｕｒｇｅｒｙ，Ｉｎｃ．|Staple cartridge including staples disposed within a compressible portion of the staple cartridge itself|

---

US9295464B2|2010-09-30|2016-03-29|Ethicon Endo-Surgery, Inc.|Surgical stapler anvil comprising a plurality of forming pockets|

---

US9517063B2|2012-03-28|2016-12-13|Ethicon Endo-Surgery, Llc|Movable member for use with a tissue thickness compensator|

---

US8695866B2|2010-10-01|2014-04-15|Ethicon Endo-Surgery, Inc.|Surgical instrument having a power control circuit|

---

EP2691212B1|2011-03-31|2016-12-14|Ingersoll-Rand Company|Display assemblies having integrated display covers and light pipes and handheld power tools and methods including same|

---

US9072535B2|2011-05-27|2015-07-07|Ethicon Endo-Surgery, Inc.|Surgical stapling instruments with rotatable staple deployment arrangements|

---

JP2014525840A|2011-07-24|2014-10-02|株式会社マキタ|Power tool adapter, power tool system, and method for wirelessly communicating maintenance information thereof|

---

US9908182B2|2012-01-30|2018-03-06|Black & Decker Inc.|Remote programming of a power tool|

---

US9044230B2|2012-02-13|2015-06-02|Ethicon Endo-Surgery, Inc.|Surgical cutting and fastening instrument with apparatus for determining cartridge and firing motion status|

---

RU2639857C2|2012-03-28|2017-12-22|Этикон Эндо-Серджери, Инк.|Tissue thickness compensator containing capsule for medium with low pressure|

---

US8919456B2|2012-06-08|2014-12-30|Black & Decker Inc.|Fastener setting algorithm for drill driver|

---

US9101358B2|2012-06-15|2015-08-11|Ethicon Endo-Surgery, Inc.|Articulatable surgical instrument comprising a firing drive|

---

US20140001231A1|2012-06-28|2014-01-02|Ethicon Endo-Surgery, Inc.|Firing system lockout arrangements for surgical instruments|

---

US20140005718A1|2012-06-28|2014-01-02|Ethicon Endo-Surgery, Inc.|Multi-functional powered surgical device with external dissection features|

---

US9289256B2|2012-06-28|2016-03-22|Ethicon Endo-Surgery, Llc|Surgical end effectors having angled tissue-contacting surfaces|

---

US9408606B2|2012-06-28|2016-08-09|Ethicon Endo-Surgery, Llc|Robotically powered surgical device with manually-actuatable reversing system|

---

RU2636861C2|2012-06-28|2017-11-28|Этикон Эндо-Серджери, Инк.|Blocking of empty cassette with clips|

---

US11202631B2|2012-06-28|2021-12-21|Cilag Gmbh International|Stapling assembly comprising a firing lockout|

---

JP6032400B2|2012-08-15|2016-11-30|日立工機株式会社|Chainsaw|

---

JP6382235B2|2013-03-01|2018-08-29|エシコン・エンド−サージェリィ・インコーポレイテッドＥｔｈｉｃｏｎ Ｅｎｄｏ−Ｓｕｒｇｅｒｙ，Ｉｎｃ．|Articulatable surgical instrument with a conductive path for signal communication|

---

JP6345707B2|2013-03-01|2018-06-20|エシコン・エンド−サージェリィ・インコーポレイテッドＥｔｈｉｃｏｎ Ｅｎｄｏ−Ｓｕｒｇｅｒｙ，Ｉｎｃ．|Surgical instrument with soft stop|

---

US10882119B2|2013-03-14|2021-01-05|Black & Decker Inc.|Chuck sleeve for power tool|

---

US9629629B2|2013-03-14|2017-04-25|Ethicon Endo-Surgey, LLC|Control systems for surgical instruments|

---

US9687230B2|2013-03-14|2017-06-27|Ethicon Llc|Articulatable surgical instrument comprising a firing drive|

---

US9826976B2|2013-04-16|2017-11-28|Ethicon Llc|Motor driven surgical instruments with lockable dual drive shafts|

---

DE202014102422U1|2013-05-31|2014-08-08|Hitachi Koki Co., Ltd.|Electric power tools|

---

EP3021767B1|2013-07-19|2018-12-12|Pro-Dex Inc.|Torque-limiting screwdrivers|

---

US10011006B2|2013-08-08|2018-07-03|Black & Decker Inc.|Fastener setting algorithm for drill driver|

---

US9283054B2|2013-08-23|2016-03-15|Ethicon Endo-Surgery, Llc|Interactive displays|

---

JP6416260B2|2013-08-23|2018-10-31|エシコン エルエルシー|Firing member retractor for a powered surgical instrument|

---

US9370372B2|2013-09-04|2016-06-21|Mcginley Engineered Solutions, Llc|Drill bit penetration measurement systems and methods|

---

WO2015061370A1|2013-10-21|2015-04-30|Milwaukee Electric Tool Corporation|Adapter for power tool devices|

---

DE102013222550A1|2013-11-06|2015-05-07|Robert Bosch Gmbh|Hand tool|

---

AU2014346458B2|2013-11-08|2018-11-29|Mcginley Engineered Solutions, Llc|Surgical saw with sensing technology for determining cut through of bone and depth of the saw blade during surgery|

---

DE102013224759A1|2013-12-03|2015-06-03|Robert Bosch Gmbh|Machine tool device|

---

US9962161B2|2014-02-12|2018-05-08|Ethicon Llc|Deliverable surgical instrument|

---

JP6462004B2|2014-02-24|2019-01-30|エシコン エルエルシー|Fastening system with launcher lockout|

---

JP6484918B2|2014-02-28|2019-03-20|工機ホールディングス株式会社|Electric working machine|

---

US11259799B2|2014-03-26|2022-03-01|Cilag Gmbh International|Interface systems for use with surgical instruments|

---

US20150272557A1|2014-03-26|2015-10-01|Ethicon Endo-Surgery, Inc.|Modular surgical instrument system|

---

US9750499B2|2014-03-26|2017-09-05|Ethicon Llc|Surgical stapling instrument system|

---

US10299792B2|2014-04-16|2019-05-28|Ethicon Llc|Fastener cartridge comprising non-uniform fasteners|

---

US20150336248A1|2014-05-20|2015-11-26|Kevin Goe|Power Drill Having Torque Setting Mechanism|

---

WO2016036756A1|2014-09-05|2016-03-10|Mcginley Engineered Solutions, Llc|Instrument leading edge measurement system and method|

---

BR112017004361A2|2014-09-05|2017-12-05|Ethicon Llc|medical overcurrent modular power supply|

---

US9737301B2|2014-09-05|2017-08-22|Ethicon Llc|Monitoring device degradation based on component evaluation|

---

DE102014219393A1|2014-09-25|2016-03-31|Robert Bosch Gmbh|Operating control device|

---

MX2017003960A|2014-09-26|2017-12-04|Ethicon Llc|Surgical stapling buttresses and adjunct materials.|

---

US10206677B2|2014-09-26|2019-02-19|Ethicon Llc|Surgical staple and driver arrangements for staple cartridges|

---

US10076325B2|2014-10-13|2018-09-18|Ethicon Llc|Surgical stapling apparatus comprising a tissue stop|

---

US9924944B2|2014-10-16|2018-03-27|Ethicon Llc|Staple cartridge comprising an adjunct material|

---

JP6457778B2|2014-10-24|2019-01-23|オークマ株式会社|Numerical controller|

---

US11141153B2|2014-10-29|2021-10-12|Cilag Gmbh International|Staple cartridges comprising driver arrangements|

---

US10517594B2|2014-10-29|2019-12-31|Ethicon Llc|Cartridge assemblies for surgical staplers|

---

US20160121467A1|2014-10-31|2016-05-05|Black & Decker Inc.|Impact Driver Control System|

---

US9844376B2|2014-11-06|2017-12-19|Ethicon Llc|Staple cartridge comprising a releasable adjunct material|

---

US10736636B2|2014-12-10|2020-08-11|Ethicon Llc|Articulatable surgical instrument system|

---

JP6380933B2|2014-12-12|2018-08-29|パナソニックＩｐマネジメント株式会社|Electric tool|

---

US10085748B2|2014-12-18|2018-10-02|Ethicon Llc|Locking arrangements for detachable shaft assemblies with articulatable surgical end effectors|

---

US9987000B2|2014-12-18|2018-06-05|Ethicon Llc|Surgical instrument assembly comprising a flexible articulation system|

---

US9844374B2|2014-12-18|2017-12-19|Ethicon Llc|Surgical instrument systems comprising an articulatable end effector and means for adjusting the firing stroke of a firing member|

---

US9844375B2|2014-12-18|2017-12-19|Ethicon Llc|Drive arrangements for articulatable surgical instruments|

---

US10004501B2|2014-12-18|2018-06-26|Ethicon Llc|Surgical instruments with improved closure arrangements|

---

US10188385B2|2014-12-18|2019-01-29|Ethicon Llc|Surgical instrument system comprising lockable systems|

---

US10045779B2|2015-02-27|2018-08-14|Ethicon Llc|Surgical instrument system comprising an inspection station|

---

US10180463B2|2015-02-27|2019-01-15|Ethicon Llc|Surgical apparatus configured to assess whether a performance parameter of the surgical apparatus is within an acceptable performance band|

---

US11154301B2|2015-02-27|2021-10-26|Cilag Gmbh International|Modular stapling assembly|

---

US10441279B2|2015-03-06|2019-10-15|Ethicon Llc|Multiple level thresholds to modify operation of powered surgical instruments|

---

US9993248B2|2015-03-06|2018-06-12|Ethicon Endo-Surgery, Llc|Smart sensors with local signal processing|

---

US10245033B2|2015-03-06|2019-04-02|Ethicon Llc|Surgical instrument comprising a lockable battery housing|

---

US9901342B2|2015-03-06|2018-02-27|Ethicon Endo-Surgery, Llc|Signal and power communication system positioned on a rotatable shaft|

---

US9924961B2|2015-03-06|2018-03-27|Ethicon Endo-Surgery, Llc|Interactive feedback system for powered surgical instruments|

---

US10052044B2|2015-03-06|2018-08-21|Ethicon Llc|Time dependent evaluation of sensor data to determine stability, creep, and viscoelastic elements of measures|

---

US10687806B2|2015-03-06|2020-06-23|Ethicon Llc|Adaptive tissue compression techniques to adjust closure rates for multiple tissue types|

---

US10617412B2|2015-03-06|2020-04-14|Ethicon Llc|System for detecting the mis-insertion of a staple cartridge into a surgical stapler|

---

US9808246B2|2015-03-06|2017-11-07|Ethicon Endo-Surgery, Llc|Method of operating a powered surgical instrument|

---

US10213201B2|2015-03-31|2019-02-26|Ethicon Llc|Stapling end effector configured to compensate for an uneven gap between a first jaw and a second jaw|

---

US10603770B2|2015-05-04|2020-03-31|Milwaukee Electric Tool Corporation|Adaptive impact blow detection|

---

US10295990B2|2015-05-18|2019-05-21|Milwaukee Electric Tool Corporation|User interface for tool configuration and data capture|

---

CN107921613B|2015-06-02|2020-11-06|米沃奇电动工具公司|Multi-speed power tool with electronic clutch|

---

US11260517B2|2015-06-05|2022-03-01|Ingersoll-Rand Industrial U.S., Inc.|Power tool housings|

---

WO2016196918A1|2015-06-05|2016-12-08|Ingersoll-Rand Company|Power tool user interfaces|

---

WO2016196979A1|2015-06-05|2016-12-08|Ingersoll-Rand Company|Impact tools with ring gear alignment features|

---

CN107635725B|2015-06-05|2019-11-12|英古所连公司|Lighting system for electric tool|

---

JP2017001115A|2015-06-05|2017-01-05|株式会社マキタ|Working tool|

---

EP3302891B1|2015-06-05|2020-11-04|Ingersoll-Rand Industrial U.S., Inc.|Power tool user interfaces|

---

CN107614205B|2015-06-05|2020-06-16|英古所连工业美国公司|Power tool user interface|

---

WO2016196891A1|2015-06-05|2016-12-08|Ingersoll-Rand Company|Power tool user interfaces|

---

US10618151B2|2015-06-15|2020-04-14|Milwaukee Electric Tool Corporation|Hydraulic crimper tool|

---

US10339496B2|2015-06-15|2019-07-02|Milwaukee Electric Tool Corporation|Power tool communication system|

---

CN207096983U|2015-06-16|2018-03-13|米沃奇电动工具公司|The system and server of system including external equipment and server including electric tool and external equipment|

---

SE1550911A1|2015-06-30|2016-11-29|Atlas Copco Ind Technique Ab|Method and a power tool for error proof screw joint tightening.|

---

JP6558986B2|2015-07-13|2019-08-14|株式会社マキタ|Handheld power tool|

---

US10998805B2|2015-07-23|2021-05-04|Black & Decker Inc.|Power tool with direction sensing controller|

---

US10835249B2|2015-08-17|2020-11-17|Ethicon Llc|Implantable layers for a surgical instrument|

---

JP6888255B2|2015-09-14|2021-06-16|マックス株式会社|Electric scissors|

---

US10345797B2|2015-09-18|2019-07-09|Milwaukee Electric Tool Corporation|Power tool operation recording and playback|

---

US10105139B2|2015-09-23|2018-10-23|Ethicon Llc|Surgical stapler having downstream current-based motor control|

---

US10327769B2|2015-09-23|2019-06-25|Ethicon Llc|Surgical stapler having motor control based on a drive system component|

---

US10363036B2|2015-09-23|2019-07-30|Ethicon Llc|Surgical stapler having force-based motor control|

---

US10238386B2|2015-09-23|2019-03-26|Ethicon Llc|Surgical stapler having motor control based on an electrical parameter related to a motor current|

---

US10299878B2|2015-09-25|2019-05-28|Ethicon Llc|Implantable adjunct systems for determining adjunct skew|

---

US10433846B2|2015-09-30|2019-10-08|Ethicon Llc|Compressible adjunct with crossing spacer fibers|

---

US10327777B2|2015-09-30|2019-06-25|Ethicon Llc|Implantable layer comprising plastically deformed fibers|

---

US10980539B2|2015-09-30|2021-04-20|Ethicon Llc|Implantable adjunct comprising bonded layers|

---

WO2017075224A1|2015-10-27|2017-05-04|Mcginley Engineered Solutions, Llc|Techniques and instruments for placement of orthopedic implants relative to bone features|

---

WO2017075044A1|2015-10-27|2017-05-04|Mcginley Engineered Solutions, Llc|Unicortical path detection for a surgical depth measurement system|

---

WO2017075547A1|2015-10-30|2017-05-04|Milwaukee Electric Tool Corporation|Remote light control, configuration, and monitoring|

---

EP3165332A1|2015-11-04|2017-05-10|Robert Bosch Gmbh|Industrial manual operating device|

---

EP3370629A4|2015-11-06|2019-07-24|Mcginley Engineered Solutions LLC|Measurement system for use with surgical burr instrument|

---

DE102015222152A1|2015-11-11|2017-05-11|Robert Bosch Gmbh|Electric hand tool|

---

US10478950B2|2015-11-26|2019-11-19|Makita Corporation|Power tool|

---

EP3202537B1|2015-12-17|2019-06-05|Milwaukee Electric Tool Corporation|System and method for configuring a power tool with an impact mechanism|

---

DE102015226090A1|2015-12-18|2017-06-22|Robert Bosch Gmbh|Hand tool with a striking mechanism|

---

DE102015226087A1|2015-12-18|2017-06-22|Robert Bosch Gmbh|Hand tool with adjustable direction of rotation|

---

DE102015226374A1|2015-12-21|2017-06-22|Robert Bosch Gmbh|Method for operating a power tool|

---

DE102015226190A1|2015-12-21|2017-06-22|Robert Bosch Gmbh|System with at least one machine tool and with at least one mobile sensor device|

---

US10368865B2|2015-12-30|2019-08-06|Ethicon Llc|Mechanisms for compensating for drivetrain failure in powered surgical instruments|

---

US10292704B2|2015-12-30|2019-05-21|Ethicon Llc|Mechanisms for compensating for battery pack failure in powered surgical instruments|

---

US10265068B2|2015-12-30|2019-04-23|Ethicon Llc|Surgical instruments with separable motors and motor control circuits|

---

JP2019506303A|2016-01-05|2019-03-07|ミルウォーキー エレクトリック ツール コーポレーションＭｉｌｗａｕｋｅｅ Ｅｌｅｃｔｒｉｃ Ｔｏｏｌ Ｃｏｒｐｏｒａｔｉｏｎ|Vibration reduction system and method for power tools|

---

EP3411204B1|2016-02-03|2021-07-28|Milwaukee Electric Tool Corporation|System and methods for configuring a reciprocating saw|

---

US11213293B2|2016-02-09|2022-01-04|Cilag Gmbh International|Articulatable surgical instruments with single articulation link arrangements|

---

US10588625B2|2016-02-09|2020-03-17|Ethicon Llc|Articulatable surgical instruments with off-axis firing beam arrangements|

---

US11224426B2|2016-02-12|2022-01-18|Cilag Gmbh International|Mechanisms for compensating for drivetrain failure in powered surgical instruments|

---

US10258331B2|2016-02-12|2019-04-16|Ethicon Llc|Mechanisms for compensating for drivetrain failure in powered surgical instruments|

---

US10448948B2|2016-02-12|2019-10-22|Ethicon Llc|Mechanisms for compensating for drivetrain failure in powered surgical instruments|

---

EP3419791A4|2016-02-25|2019-11-13|Milwaukee Electric Tool Corporation|Power tool including an output position sensor|

---

ITUB20161240A1|2016-03-02|2017-09-02|Cembre Spa|Hydraulic pump for a hydrodynamic compression tool|

---

DE102016204629A1|2016-03-21|2017-09-21|Robert Bosch Gmbh|Hand tool|

---

US10376263B2|2016-04-01|2019-08-13|Ethicon Llc|Anvil modification members for surgical staplers|

---

US10617413B2|2016-04-01|2020-04-14|Ethicon Llc|Closure system arrangements for surgical cutting and stapling devices with separate and distinct firing shafts|

---

DE102016004525A1|2016-04-14|2017-10-19|Andreas Stihl Ag & Co. Kg|Method and device for detecting the switching position of an operating switch for starting up an electric motor|

---

US10357247B2|2016-04-15|2019-07-23|Ethicon Llc|Surgical instrument with multiple program responses during a firing motion|

---

US10492783B2|2016-04-15|2019-12-03|Ethicon, Llc|Surgical instrument with improved stop/start control during a firing motion|

---

US10456137B2|2016-04-15|2019-10-29|Ethicon Llc|Staple formation detection mechanisms|

---

US10426467B2|2016-04-15|2019-10-01|Ethicon Llc|Surgical instrument with detection sensors|

---

US10405859B2|2016-04-15|2019-09-10|Ethicon Llc|Surgical instrument with adjustable stop/start control during a firing motion|

---

US11179150B2|2016-04-15|2021-11-23|Cilag Gmbh International|Systems and methods for controlling a surgical stapling and cutting instrument|

---

US10335145B2|2016-04-15|2019-07-02|Ethicon Llc|Modular surgical instrument with configurable operating mode|

---

US10828028B2|2016-04-15|2020-11-10|Ethicon Llc|Surgical instrument with multiple program responses during a firing motion|

---

US10368867B2|2016-04-18|2019-08-06|Ethicon Llc|Surgical instrument comprising a lockout|

---

JP6724563B2|2016-05-30|2020-07-15|マックス株式会社|tool|

---

US10383674B2|2016-06-07|2019-08-20|Pro-Dex, Inc.|Torque-limiting screwdriver devices, systems, and methods|

---

CN105798357A|2016-06-12|2016-07-27|高峰|Novel intelligent electric drill capable of displaying drilling depth|

---

DE102016210772A1|2016-06-16|2017-12-21|Robert Bosch Gmbh|Method for a, in particular wireless, transmission of electronic data between at least two connection partners, in particular between a hand-held power tool and an external unit|

---

CN105922184A|2016-06-25|2016-09-07|中铁电气化局集团有限公司|High-speed rail electric fixed torque spanner|

---

CN107544426B|2016-06-27|2021-09-07|苏州宝时得电动工具有限公司|Control method and device of electric tool and electric tool|

---

JP6734163B2|2016-09-26|2020-08-05|株式会社マキタ|Electric tool|

---

DE112017005671T5|2016-11-10|2019-09-05|Nitto Kohki Co., Ltd.|ELECTRIC MOTOR DRIVEN TOOL AND CONTROL DEVICE AND CONTROL UNIT FOR THIS|

---

CN106426011B|2016-11-29|2018-11-16|南京九致信息科技有限公司|Can delayed startup electric tool|

---

US10177651B2|2016-12-20|2019-01-08|Mercury Magnetics, Inc.|System for controlling inrush current to eliminate inrush overcurrent to electrical equipment|

---

US20180168625A1|2016-12-21|2018-06-21|Ethicon Endo-Surgery, Llc|Surgical stapling instruments with smart staple cartridges|

---

US10517595B2|2016-12-21|2019-12-31|Ethicon Llc|Jaw actuated lock arrangements for preventing advancement of a firing member in a surgical end effector unless an unfired cartridge is installed in the end effector|

---

US10758229B2|2016-12-21|2020-09-01|Ethicon Llc|Surgical instrument comprising improved jaw control|

---

US20180168608A1|2016-12-21|2018-06-21|Ethicon Endo-Surgery, Llc|Surgical instrument system comprising an end effector lockout and a firing assembly lockout|

---

US10675026B2|2016-12-21|2020-06-09|Ethicon Llc|Methods of stapling tissue|

---

US10617414B2|2016-12-21|2020-04-14|Ethicon Llc|Closure member arrangements for surgical instruments|

---

CN110087565A|2016-12-21|2019-08-02|爱惜康有限责任公司|Surgical stapling system|

---

US10779823B2|2016-12-21|2020-09-22|Ethicon Llc|Firing member pin angle|

---

US10499914B2|2016-12-21|2019-12-10|Ethicon Llc|Staple forming pocket arrangements|

---

US10568625B2|2016-12-21|2020-02-25|Ethicon Llc|Staple cartridges and arrangements of staples and staple cavities therein|

---

US10492785B2|2016-12-21|2019-12-03|Ethicon Llc|Shaft assembly comprising a lockout|

---

US10639034B2|2016-12-21|2020-05-05|Ethicon Llc|Surgical instruments with lockout arrangements for preventing firing system actuation unless an unspent staple cartridge is present|

---

US11134942B2|2016-12-21|2021-10-05|Cilag Gmbh International|Surgical stapling instruments and staple-forming anvils|

---

US10426471B2|2016-12-21|2019-10-01|Ethicon Llc|Surgical instrument with multiple failure response modes|

---

US10588632B2|2016-12-21|2020-03-17|Ethicon Llc|Surgical end effectors and firing members thereof|

---

WO2018129100A1|2017-01-04|2018-07-12|Interlink Electronics, Inc.|Multi-modal sensing for power tool user interface|

---

EP3379019B1|2017-03-24|2019-09-04|Techtronic Outdoor Products Technology Limited|Digging apparatus|

---

US10624633B2|2017-06-20|2020-04-21|Ethicon Llc|Systems and methods for controlling motor velocity of a surgical stapling and cutting instrument|

---

US10307170B2|2017-06-20|2019-06-04|Ethicon Llc|Method for closed loop control of motor velocity of a surgical stapling and cutting instrument|

---

USD879808S1|2017-06-20|2020-03-31|Ethicon Llc|Display panel with graphical user interface|

---

US10390841B2|2017-06-20|2019-08-27|Ethicon Llc|Control of motor velocity of a surgical stapling and cutting instrument based on angle of articulation|

---

US10327767B2|2017-06-20|2019-06-25|Ethicon Llc|Control of motor velocity of a surgical stapling and cutting instrument based on angle of articulation|

---

US10779820B2|2017-06-20|2020-09-22|Ethicon Llc|Systems and methods for controlling motor speed according to user input for a surgical instrument|

---

USD879809S1|2017-06-20|2020-03-31|Ethicon Llc|Display panel with changeable graphical user interface|

---

US10881396B2|2017-06-20|2021-01-05|Ethicon Llc|Surgical instrument with variable duration trigger arrangement|

---

US10646220B2|2017-06-20|2020-05-12|Ethicon Llc|Systems and methods for controlling displacement member velocity for a surgical instrument|

---

US11090046B2|2017-06-20|2021-08-17|Cilag Gmbh International|Systems and methods for controlling displacement member motion of a surgical stapling and cutting instrument|

---

US10980537B2|2017-06-20|2021-04-20|Ethicon Llc|Closed loop feedback control of motor velocity of a surgical stapling and cutting instrument based on measured time over a specified number of shaft rotations|

---

US10368864B2|2017-06-20|2019-08-06|Ethicon Llc|Systems and methods for controlling displaying motor velocity for a surgical instrument|

---

US10881399B2|2017-06-20|2021-01-05|Ethicon Llc|Techniques for adaptive control of motor velocity of a surgical stapling and cutting instrument|

---

USD890784S1|2017-06-20|2020-07-21|Ethicon Llc|Display panel with changeable graphical user interface|

---

US10813639B2|2017-06-20|2020-10-27|Ethicon Llc|Closed loop feedback control of motor velocity of a surgical stapling and cutting instrument based on system conditions|

---

US11071554B2|2017-06-20|2021-07-27|Cilag Gmbh International|Closed loop feedback control of motor velocity of a surgical stapling and cutting instrument based on magnitude of velocity error measurements|

---

US10888321B2|2017-06-20|2021-01-12|Ethicon Llc|Systems and methods for controlling velocity of a displacement member of a surgical stapling and cutting instrument|

---

US10993716B2|2017-06-27|2021-05-04|Ethicon Llc|Surgical anvil arrangements|

---

US10856869B2|2017-06-27|2020-12-08|Ethicon Llc|Surgical anvil arrangements|

---

US10772629B2|2017-06-27|2020-09-15|Ethicon Llc|Surgical anvil arrangements|

---

US11090049B2|2017-06-27|2021-08-17|Cilag Gmbh International|Staple forming pocket arrangements|

---

US10765427B2|2017-06-28|2020-09-08|Ethicon Llc|Method for articulating a surgical instrument|

---

USD906355S1|2017-06-28|2020-12-29|Ethicon Llc|Display screen or portion thereof with a graphical user interface for a surgical instrument|

---

US11246592B2|2017-06-28|2022-02-15|Cilag Gmbh International|Surgical instrument comprising an articulation system lockable to a frame|

---

US10903685B2|2017-06-28|2021-01-26|Ethicon Llc|Surgical shaft assemblies with slip ring assemblies forming capacitive channels|

---

US20190000477A1|2017-06-28|2019-01-03|Ethicon Llc|Surgical instrument comprising a shaft including a housing arrangement|

---

USD854151S1|2017-06-28|2019-07-16|Ethicon Llc|Surgical instrument shaft|

---

US11259805B2|2017-06-28|2022-03-01|Cilag Gmbh International|Surgical instrument comprising firing member supports|

---

USD869655S1|2017-06-28|2019-12-10|Ethicon Llc|Surgical fastener cartridge|

---

US10786253B2|2017-06-28|2020-09-29|Ethicon Llc|Surgical end effectors with improved jaw aperture arrangements|

---

USD851762S1|2017-06-28|2019-06-18|Ethicon Llc|Anvil|

---

US10211586B2|2017-06-28|2019-02-19|Ethicon Llc|Surgical shaft assemblies with watertight housings|

---

US10716614B2|2017-06-28|2020-07-21|Ethicon Llc|Surgical shaft assemblies with slip ring assemblies with increased contact pressure|

---

US10398434B2|2017-06-29|2019-09-03|Ethicon Llc|Closed loop velocity control of closure member for robotic surgical instrument|

---

US10932772B2|2017-06-29|2021-03-02|Ethicon Llc|Methods for closed loop velocity control for robotic surgical instrument|

---

US10898183B2|2017-06-29|2021-01-26|Ethicon Llc|Robotic surgical instrument with closed loop feedback techniques for advancement of closure member during firing|

---

US10258418B2|2017-06-29|2019-04-16|Ethicon Llc|System for controlling articulation forces|

---

US11007022B2|2017-06-29|2021-05-18|Ethicon Llc|Closed loop velocity control techniques based on sensed tissue parameters for robotic surgical instrument|

---

US10483901B2|2017-07-10|2019-11-19|Newfrey Llc|System and method for installation and verification of fasteners|

---

EP3672501A4|2017-08-25|2021-05-19|McGinley Engineered Solutions, LLC|Sensing of surgical instrument placement relative to anatomic structures|

---

US10926368B2|2017-09-27|2021-02-23|Ingersoll-Rand Industrial U.S., Inc.|Part illumination status lights|

---

US10729501B2|2017-09-29|2020-08-04|Ethicon Llc|Systems and methods for language selection of a surgical instrument|

---

US10765429B2|2017-09-29|2020-09-08|Ethicon Llc|Systems and methods for providing alerts according to the operational state of a surgical instrument|

---

USD907647S1|2017-09-29|2021-01-12|Ethicon Llc|Display screen or portion thereof with animated graphical user interface|

---

USD907648S1|2017-09-29|2021-01-12|Ethicon Llc|Display screen or portion thereof with animated graphical user interface|

---

US10743872B2|2017-09-29|2020-08-18|Ethicon Llc|System and methods for controlling a display of a surgical instrument|

---

US10796471B2|2017-09-29|2020-10-06|Ethicon Llc|Systems and methods of displaying a knife position for a surgical instrument|

---

USD917500S1|2017-09-29|2021-04-27|Ethicon Llc|Display screen or portion thereof with graphical user interface|

---

AU2018345760A1|2017-10-02|2020-01-30|Mcginley Engineered Solutions, Llc|Surgical instrument with real time navigation assistance|

---

US11090075B2|2017-10-30|2021-08-17|Cilag Gmbh International|Articulation features for surgical end effector|

---

US11134944B2|2017-10-30|2021-10-05|Cilag Gmbh International|Surgical stapler knife motion controls|

---

US10842490B2|2017-10-31|2020-11-24|Ethicon Llc|Cartridge body design with force reduction based on firing completion|

---

US10779903B2|2017-10-31|2020-09-22|Ethicon Llc|Positive shaft rotation lock activated by jaw closure|

---

US10779826B2|2017-12-15|2020-09-22|Ethicon Llc|Methods of operating surgical end effectors|

---

US11197670B2|2017-12-15|2021-12-14|Cilag Gmbh International|Surgical end effectors with pivotal jaws configured to touch at their respective distal ends when fully closed|

---

US10743875B2|2017-12-15|2020-08-18|Ethicon Llc|Surgical end effectors with jaw stiffener arrangements configured to permit monitoring of firing member|

---

US11071543B2|2017-12-15|2021-07-27|Cilag Gmbh International|Surgical end effectors with clamping assemblies configured to increase jaw aperture ranges|

---

US10828033B2|2017-12-15|2020-11-10|Ethicon Llc|Handheld electromechanical surgical instruments with improved motor control arrangements for positioning components of an adapter coupled thereto|

---

US10966718B2|2017-12-15|2021-04-06|Ethicon Llc|Dynamic clamping assemblies with improved wear characteristics for use in connection with electromechanical surgical instruments|

---

US10687813B2|2017-12-15|2020-06-23|Ethicon Llc|Adapters with firing stroke sensing arrangements for use in connection with electromechanical surgical instruments|

---

US10869666B2|2017-12-15|2020-12-22|Ethicon Llc|Adapters with control systems for controlling multiple motors of an electromechanical surgical instrument|

---

US10743874B2|2017-12-15|2020-08-18|Ethicon Llc|Sealed adapters for use with electromechanical surgical instruments|

---

US11006955B2|2017-12-15|2021-05-18|Ethicon Llc|End effectors with positive jaw opening features for use with adapters for electromechanical surgical instruments|

---

US10779825B2|2017-12-15|2020-09-22|Ethicon Llc|Adapters with end effector position sensing and control arrangements for use in connection with electromechanical surgical instruments|

---

US11033267B2|2017-12-15|2021-06-15|Ethicon Llc|Systems and methods of controlling a clamping member firing rate of a surgical instrument|

---

US10729509B2|2017-12-19|2020-08-04|Ethicon Llc|Surgical instrument comprising closure and firing locking mechanism|

---

US11045270B2|2017-12-19|2021-06-29|Cilag Gmbh International|Robotic attachment comprising exterior drive actuator|

---

USD910847S1|2017-12-19|2021-02-16|Ethicon Llc|Surgical instrument assembly|

---

US10716565B2|2017-12-19|2020-07-21|Ethicon Llc|Surgical instruments with dual articulation drivers|

---

US11020112B2|2017-12-19|2021-06-01|Ethicon Llc|Surgical tools configured for interchangeable use with different controller interfaces|

---

US10835330B2|2017-12-19|2020-11-17|Ethicon Llc|Method for determining the position of a rotatable jaw of a surgical instrument attachment assembly|

---

US11076853B2|2017-12-21|2021-08-03|Cilag Gmbh International|Systems and methods of displaying a knife position during transection for a surgical instrument|

---

US20190192151A1|2017-12-21|2019-06-27|Ethicon Llc|Surgical instrument having a display comprising image layers|

---

US11129680B2|2017-12-21|2021-09-28|Cilag Gmbh International|Surgical instrument comprising a projector|

---

WO2019208105A1|2018-04-27|2019-10-31|工機ホールディングス株式会社|Electric tool|

---

US11083458B2|2018-08-20|2021-08-10|Cilag Gmbh International|Powered surgical instruments with clutching arrangements to convert linear drive motions to rotary drive motions|

---

US11253256B2|2018-08-20|2022-02-22|Cilag Gmbh International|Articulatable motor powered surgical instruments with dedicated articulation motor arrangements|

---

US10842492B2|2018-08-20|2020-11-24|Ethicon Llc|Powered articulatable surgical instruments with clutching and locking arrangements for linking an articulation drive system to a firing drive system|

---

USD914878S1|2018-08-20|2021-03-30|Ethicon Llc|Surgical instrument anvil|

---

US11045192B2|2018-08-20|2021-06-29|Cilag Gmbh International|Fabricating techniques for surgical stapler anvils|

---

US10912559B2|2018-08-20|2021-02-09|Ethicon Llc|Reinforced deformable anvil tip for surgical stapler anvil|

---

US11207065B2|2018-08-20|2021-12-28|Cilag Gmbh International|Method for fabricating surgical stapler anvils|

---

US10856870B2|2018-08-20|2020-12-08|Ethicon Llc|Switching arrangements for motor powered articulatable surgical instruments|

---

US11039834B2|2018-08-20|2021-06-22|Cilag Gmbh International|Surgical stapler anvils with staple directing protrusions and tissue stability features|

---

WO2020041211A1|2018-08-20|2020-02-27|Pro-Dex, Inc.|Torque-limiting devices, systems, and methods|

---

US10779821B2|2018-08-20|2020-09-22|Ethicon Llc|Surgical stapler anvils with tissue stop features configured to avoid tissue pinch|

---

JP2020032504A|2018-08-30|2020-03-05|パナソニックＩｐマネジメント株式会社|Electric power tool|

---

CN111025937A|2018-10-10|2020-04-17|苏州宝时得电动工具有限公司|Control method and device of electric tool, electric tool and computer equipment|

---

TWI733067B|2018-12-06|2021-07-11|優鋼機械股份有限公司|Setting method of electronic torque tool|

---

US11147551B2|2019-03-25|2021-10-19|Cilag Gmbh International|Firing drive arrangements for surgical systems|

---

US11147553B2|2019-03-25|2021-10-19|Cilag Gmbh International|Firing drive arrangements for surgical systems|

---

US11172929B2|2019-03-25|2021-11-16|Cilag Gmbh International|Articulation drive arrangements for surgical systems|

---

US11253254B2|2019-04-30|2022-02-22|Cilag Gmbh International|Shaft rotation actuator on a surgical instrument|

---

US11224497B2|2019-06-28|2022-01-18|Cilag Gmbh International|Surgical systems with multiple RFID tags|

---

US11051807B2|2019-06-28|2021-07-06|Cilag Gmbh International|Packaging assembly including a particulate trap|

---

US11229437B2|2019-06-28|2022-01-25|Cilag Gmbh International|Method for authenticating the compatibility of a staple cartridge with a surgical instrument|

---

US11259803B2|2019-06-28|2022-03-01|Cilag Gmbh International|Surgical stapling system having an information encryption protocol|

---

US11246678B2|2019-06-28|2022-02-15|Cilag Gmbh International|Surgical stapling system having a frangible RFID tag|

---

US11219455B2|2019-06-28|2022-01-11|Cilag Gmbh International|Surgical instrument including a lockout key|

---

US11234698B2|2019-12-19|2022-02-01|Cilag Gmbh International|Stapling system comprising a clamp lockout and a firing lockout|

法律状态:
2017-10-26| FGA| Letters patent sealed or granted (standard patent)|

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2020-12-24| MK14| Patent ceased section 143(a) (annual fees not paid) or expired|

优先权:

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申请号 | 申请日 | 专利标题

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US201261657269P| true| 2012-06-08|2012-06-08||

---

US61/657,269||2012-06-08||

---

US13/832,454|US20130327552A1|2012-06-08|2013-03-15|Power tool having multiple operating modes|

---

US13/832,454||2013-03-15||

---