USRE43041E1 - Control module for flywheel operated hand tool - Google Patents

Abstract

A control module advantageously reduces cost and enhances reliability, design flexibility, ease of assembly, and performance of a flywheel operated hand tool. The control module includes a thin film printed circuit with non-contact speed sensing of a flywheel to more accurately set the target speed and control transfer kinetic energy thereof to a fastener, achieving a desired depth regardless of variations in component performance and battery voltage. The printed circuit also includes long service life thin film switches for responding to trigger and safety inputs. Furthermore, the control module responds to a user speed selection and to preset speed selection ranges to reconfigure the controls as appropriate to constraints of a fastener drive assembly and to user preferences.

Description

CROSS REFERENCE TO RELATED APPLICATIONS

This reissue patent application of U.S. Pat. No. 6,974,061 is related to Reexamination patent application Ser. No. 90/008,833, which is directed to U.S. Pat. No. 6,974,061. A reexamination certificate issued in Reexamination patent application Ser. No. 90/008,833 on May 11, 2010. The changes shown in this reissue patent application are relative to the changes to U.S. Pat. No. 6,974,061 as shown in the issued reexamination certificate.

This application is a divisional of U.S. Non-Provisional Patent Application Ser. No. 10/027,767, filed Dec. 20, 2001, now abandoned, entitled CONTROL MODULE FOR FLYWHEL OPERATED HAND TOOL.

This application claims the priority of Provisional Patent Applicant Ser. No. 60/258,022, filed on Dec. 22, 2000 and incorporates herein, by reference, the totality of the invention disclosure therein.

This application is related to three commonly-owned, co-pending U.S. non-provisional patent applications filed on even date herewith and respectively titled, “FLYWHEEL OPERATED TOOL” to Conrad Gravis, et al; “FLYWHEEL OPERATED NAILER” to John Burke, et al; and “RETURN MECHANISM FOR A CYCLICAL TOOL” to Kevin Harper, et al. This application further relates to the commonly-owned, co-pending U.S. non-provisional patent application to Shane Adams, et al., filed on even date herewith and titled “SPEED CONTROLLER FOR FLYWHEEL OPERATED HAND TOOL”.

FIELD OF THE INVENTION

This invention generally relates to a hand-held electromechanical fastener driving tool, and more particularly to a fastener driving tool having an inertial member for imparting kinetic energy to drive a fastener into a work piece.

BACKGROUND OF THE INVENTION

In the past, where relatively large energy impulses have been required to operate a fastener driving tool, such as an industrial nailer or stapler, it has been common practice to power such tool pneumatically. Such tools are capable of driving a 3″ or longer nail, or staple, into framing wood such as 2×4s, for example. However, pneumatic driving tools require an on-site air compressor, which is often unavailable or not desired. Also, dragging the pneumatic umbilical is often an impediment to the user.

Corded AC electrical fastener driving tools are often used instead of pneumatic power since electrical power is more often available than air compressors. In particular, much effort has been expended in the prior art in providing heavy duty, high powered, fastener driving tools employing a flywheel as a means of delivering kinetic energy sufficient to drive a heavy duty fasteners. Examples of such systems are disclosed in U.S. Pat. Nos. 4,042,036; 4,121,745; 4,204,622; 4,298,072; and 5,511,715. Use of a flywheel is an attempt to limit the large current draws to actuate a solenoid to drive a fastener. A DC motor is activated over a non-instantaneous period and then the kinetic energy thus developed in the flywheel is clutched to the driver in an “energy dump”.

While such corded electrical fastener driving tools may perform well, in many instances an AC outlet is not available. Even if an AC outlet is available, many users find dragging the electrical cord to be an impediment to use. To address these preferences, it is further known to employ a portable power source such as a battery, such as solenoid-operated fastener driving tools. These portable fastener driving tools are primarily used in light-duty applications such as in driving one inch brad nails, for example, rather than the larger 2″ to 4″ staples or nails used in framing.

One approach to an efficient portable electrically driven tool is a multiple impact tool, such as described in U.S. Pat. No. 4,625,903, wherein a linear inertial member is repeatedly raised by a cam against a compression spring and released to impact a fastener. An electrical motor and portable battery pack are operated in a more efficient manner by running the motor for a period of time rather than providing a surge of power to a device such as a solenoid. The relatively small amount of energy stored in the spring each cycle typically requires a large number of impacts to drive a staple or nail into a workpiece. During this time, the user is required to maintain an appropriate position and force on the fasten and to gauge the appropriate length of time to achieve the desired depth. However, while the multiple impact tool is efficient and effective in driving fasteners, some users prefer a single driving action comparable to pyrotechnic or compressed air systems. The multiple impact tools also can damage a wood surface due to the vibrations the tool generates while stroking.

It would be desirable to use a battery to power a flywheel operated hand tool to provide a portable fastener driver that can drive larger fasteners in a single drive. However, using a battery has been thwarted by a number of challenges. First, each specific application generally requires a fastener drive assembly and motor customized for the type of fastener. In particular, the size of flywheel, the desired rotary speed of the flywheel, and the type of electric motor to accelerate the flywheel to the desired rotary speed are generally specifically sized for the type of fastener and work piece into which the fastener is typically driven. Thus, each specific application was thought to require a custom control module, with the increased costs of design, manufacture and support.

Even assuming that various types of fasteners could then be used with a family of flywheel operated hand tools, each tool would suffer the disadvantages inherent in using battery power. The battery voltage varies as a function of the amount of charge remaining and the amount of electrical current being drawn. The rotary speed of the flywheel varies with the battery voltage, and thus the depth of drive of the fastener would unacceptably vary. The generally known controllers for corded flywheel operated hand tools are unable to accommodate these power variations.

Furthermore, even for a specific application, the desired depth of drive is affected by the type of work piece into which the fastener is driven and to user preferences. However, flywheel operated hand tools rely upon a given amount of kinetic energy imparted by the flywheel to achieve a desired depth of travel. Thus, when the work piece is more or less dense, the depth of the drive will vary. Moreover, the user may prefer in some instances to sink the fastener below the plane of the work piece or to leave the head of the fastener exposed for easy removal.

Other types of hand tools, such a pneumatic powered hand tools, generally rely on driving the fastener to a specific position in order to achieve a desired depth. For example, in U.S. Pat. Nos. 4,679,719, 5,732,870 and 5,918,788 a control module is described that advantageously determines the mode of operation for the trigger. In particular, a microprocessor provided additional capabilities by receiving two signal inputs initiated by the user and by selectively activating an electronic solenoid in response thereto. Although the increased functionality of the control module in such pneumatic tools has advantages, these control modules are not responsive to changes in operating conditions to vary the depth of drive.

Other tools employing a rotary member (e.g., drill) generally require the user to determine the proper speed of the tool. The user provides the closed loop control of the tool, monitoring the tool for binding and proper operation and depressing the trigger an appropriate amount. However, consistent operation of the tool is thus dependent upon the skill level and attentiveness of the user. Due to the speed in which a fastener must be driven into the workpiece, the user would only learn after the fact whether the rotary member (in this case a flywheel) was accelerated to an appropriate speed prior to firing.

Therefore, a significant need exists for a control module that drives medium and large fasteners into a work piece with a single driving action, yet has the increased portability of battery power. It would be further desired to have such a tool that consistently provides a depth of fastener regardless of the state of charge of the battery. It would be yet further desired to have a control module readily adapted to a family of hand tools.

BRIEF SUMMARY OF THE INVENTION

These and other problems in the prior art are addressed by a control module that is responsive to a rotary speed of a rotational member of an electrically powered hand tool and is responsive to an adjustable target speed for the rotational member. Thereby, the control module more consistently controls the hand tool, avoiding human error and the inconvenience of relying upon the user to modulate the speed of the tool.

In one aspect of the invention, a control module for a hand tool includes a speed setting that is used for presetting the control module to an operating range of the intended rotational member of the hand tool. Thus, the control module is readily adjusted to the operating environment, using the speed setting as a target for comparing a sensed speed.

In another aspect of the invention, a method of controlling a fastener-driving tool enforces a user input sequence to ensure that a fastener is driven into a workpiece. In particular, a safety signal is received from a safety switch indicating a nose assembly of the tool is against a workpiece. A safety time-out value is accessed. The duration of depression of the safety signal is timed. Then, the tool is activated to drive a fastener in response to receiving a trigger signal from a trigger switch before the timed duration of the safety signal exceeds the safety time-out value. By so enforcing this sequence, a user is less likely to inadvertently drive a fastener in instances where the trigger is inadvertently squeezed and the tool contacts a surface.

In yet another aspect of the invention, an electrically powered hand tool is provided a reliable interface to a control module through use of a thin film switch interface to user controls (e.g., safety and trigger) and through use of noncontact speed sensing.

These and other objects and advantages of the present invention shall be made apparent from the accompanying drawings and the description thereof.

BRIEF DESCRIPTION OF THE DRAWING

The accompanying drawings, which are incorporated in and constitute a part of this specification, illustrate embodiments of the invention, and, together with the general description of the invention given above, and the detailed description of the embodiments given below, serve to explain the principles of the present invention.

FIG. 1 presents a left side elevational view of a hand held nailing tool, embodying the present invention, having a portion of its left side removed to show the general positioning of a fastener drive assembly and control module.

FIG. 1A presents a generally rearward elevated view of the control module of the nailing tool ofFIG. 1

FIG. 2 presents a top view of the fastener drive assembly removed from the main body of the hand held nailing machine as illustrated inFIG. 1.

FIG. 3 presents a left side elevational view of the fastener drive assembly as removed from the nailing machine illustrated inFIG. 1.

FIG. 4 presents a bottom view, looking upward from the handle of the fastener drive assembly as removed from the nailing machine outer shell illustrated inFIG. 1 and having the electrical control module removed for clarity.

FIG. 5 presents an end elevational view of the fastener drive assembly as removed from the nailing machine illustrated inFIG. 1 and having the electrical control module removed for clarity.

FIG. 6 presents a pictorial view of the fastener drive assembly, having the electrical control module removed for clarity, showing the general arrangement the clutch drive assembly components.

FIG. 7 presents an exploded pictorial view showing the components of the fastener drive assembly illustrated inFIGS. 2 through 6.

FIG. 8 presents a sectional view taken alongline8—8 inFIG. 3.

FIG. 9 presents a sectional view taken along line9—9 inFIG. 4.

FIG. 10 presents an enlarged view of the circled section inFIG. 8.

FIG. 11 is a sectional view taken alongline11—11 inFIG. 4.

FIG. 12 is a sectional view taken alongline12—12 inFIG. 4.

FIGS. 13A through 13C present a schematical presentation of the ball/cam action between the fixed plate and the activation plate.

FIG. 14 presents a graph showing the distance x between the fixed plate and the actuation plate as a function of degrees of rotation of the actuation plate.

FIG. 15 presents an expanded pictorial view of the solenoid camming plates.

FIG. 16 presents an expanded pictorial view of the activation camming plates.

FIG. 17 is a cross-sectional view taken along line17—17 inFIG. 9.

FIG. 18 presents a block diagram of a control system for the fastener-driving tool ofFIG. 1.

FIG. 19 presents a flow diagram for a sequence of steps, or main routine, for a controller ofFIG. 18 to operate the fastener-driving tool.

FIG. 20 presents a flow diagram of a diagnostic routine, referenced by the main routine ofFIG. 19.

FIG. 21 presents an intermittent mode portion of the main routine ofFIG. 19.

FIG. 22 presents a continuous mode portion of the main routine ofFIG. 19.

FIG. 23A–23F present illustrative timing diagrams for sequencing of safety and trigger signals for a valid command, referenced in the main routine ofFIGS. 19–22.

FIG. 24A–24B present illustrative timing diagrams for motor activation and solenoid actuation in response to variations in battery charge and clutch wear, referenced in the main routine ofFIGS. 19–22.

FIG. 25 presents an illustrative control circuit for the control system ofFIG. 18.

FIG. 26 presents an indexing control circuit for the control circuit ofFIG. 25.

DETAILED DESCRIPTION OF THE INVENTION

With reference toFIG. 1, wherein like numbers refer to like components throughout the several views, a portable flywheel operated hand tool, depicted as a hand-heldnailing tool10, includes acontrol system12 that advantageously provides consistent speed control throughout a range of operating conditions. In particular, the nailingtool10 generally comprises a housing ormain body14 enclosing afastener drive assembly16 and acontrol module18, and further includes and agripping handle20. Attached to the end ofhandle20 is a removable,rechargeable battery22 for providing the necessary electrical energy to operate aDC motor24 and asolenoid26 of thefastener drive assembly16, as well as theelectrical control module18. Unlike generally known batteries that are required to handle large current influxes (e.g., Nickel Cadmium), the present invention advantageously may utilize other types of batteries (e.g., Nickel Metal Hydride (NiMH), lithium Polymers).

TheDC motor24, when accelerated by thecontrol module18, turns aflywheel28 to build kinetic energy in the form of rotational inertia. Thereafter, thecontrol module18 actuates thesolenoid26 in response to user inputs and a sensed parameter of rotational speed of theflywheel28 to impart the kinetic energy of theflywheel28 to a fastener, which is described in further detail below

A user input to thenailing tool10 are depicted as atrigger30 of thehandle20, which mechanically communicates with thecontrol module18 via atrigger linkage32. Another user input is depicted as asafety device34 of anose assembly36 that mechanically communicates with thecontrol module18 via asafety linkage38. Yet another user input is depicted as a speed adjustknob40.

Thenailing tool10 includes a fastener supplyingmagazine assembly42, which is typically attached to themain body14 and handle20, as illustrated, for supplying a strip of fasteners (not shown) to thenose assembly36. It will be appreciated that thecontrol system12 may be advantageously operated with different types ofmagazine assemblies42 to include different numbers, types and sizes of fasteners. Moreover, thecontrol system12 advantageously enhances use of indexed magazine assemblies, as will be described in more detail below.

Control Module.

With reference toFIGS. 1 and 2, thecontrol module18 of thecontrol system12 advantageously enhances reliability, design flexibility, ease of assembly, and performance of thenailing tool10. In particular, thecontrol module18 includes user speed selection capability, depicted as apotentiometer44 that is adjusted byknob40. By being responsive to the userspeed adjustment knob40 enables thenailing tool10 to adjust a target speed of theflywheel28. In addition to any preset target speed of thecontrol module18, the user may adjust theknob40 to compensate for variations in the workpiece or the desired depth of fastener insertion.

Thecontrol module18 further includes a thin film printedcircuit46 that provides an extremely reliable electrical interface to the mechanical user inputs of thesafety device34 and thetrigger30. Moreover, the printedcircuit46 is readily adapted to various three-dimensional orientations with the support of a moldedbridge48. Thus, atrigger switch50 and asafety switch52 are readily positioned to receive the respective trigger and safetymechanical linkages32,36. It will be appreciated that thin film switches50,52 provide a service life that exceed generally known trigger and safety switches and at a reduced cost.

The moldedbridge48 further supports and orients a portion of the printedcircuit46 that forms arotary speed transducer54. Twoinductive pickups56,58 of the printedcircuit46 are oriented to register to respectively to alternating north and south magnetic poles on a ring magnet (not shown inFIGS. 1 and 2) of theflywheel28, forming arotary speed sensor60. The non-contact nature of therotary speed sensor60 avoids degradation due to wear. In addition, by sensing rotary speed directly, thesensor60 provides an accurate measurement representative of the kinetic energy of theflywheel28. By contrast, if electrical current drawn by the motor was sensed instead, the resulting measurement may contain variations due to friction, motor component degradation, etc. More accurate speed sensing allows more accurate transfer of kinetic energy to the fastener and thus a more consistent result.

Before discussing thecontrol system12 in greater, the mechanical aspects of thefastener drive assembly16 are discussed in greater detail.

Fastener Drive Assembly of the Flywheel Operated Hand Tool

Thefastener drive assembly16 is described that has features of efficiently uses DC electrical power by accelerating theflywheel28 with theDC motor24. A clutching technique is advantageously used that avoids the need for a manual reset. In addition, components are described below that advantageously couple to the flywheel during acceleration to increase the inertial load prior to driving the fastener and then disengage after driving the fastener. Furthermore, resetting thefastener drive assembly16 with a vacuum return approach further conserves electrical power and avoids the generally known techniques that require a manual reset key.

FIGS. 2,3,4, and5 illustrate top, left side, bottom and rear views of thefastener drive assembly16 as positioned within themain body14 of thenailing tool10 illustrated inFIG. 1.FIGS. 2,4, and5 haveelectrical control module18 removed for clarity. As illustrated inFIG. 6, the primary operational elements offastener drive assembly16 comprise theflywheel28 for providing kinetic energy, for driving a fastener into a workpiece, energized by anelectric motor24.Flywheel28 is freewheeling upon a fixedcentral shaft62. Upon achieving the required revolutions per minute (RPM), a clutch drive assembly64 (seeFIGS. 7 and 9) causes engagement of aclutch plate66 andflywheel28 thereby transferring a portion of the kinetic energy offlywheel28 to a linearly movingfastener driver68 for driving a fastener into a workpiece. Theflywheel28 is thereafter allowed to continue spinning with any remaining kinetic energy between cycles to further conserve electrical power and to reduce cycle time.

Referring now toFIGS. 2, through9, the elements and operation of thefastener drive assembly16 will be discussed. Thefastener drive assembly16 comprisesclutch drive assembly64 andflywheel28 gear driven byelectric motor24. Although a gear drive betweenmotor24 andflywheel28 is primarily illustrated herein, it is understood that a belt drive may also be used betweenmotor24 andflywheel28 or any other suitable drive mechanism. As an alternative to having the motor axis of rotation parallel to the axis of rotation offlywheel28, as illustrated herein, it may be preferable to positionmotor24 such that its axis of rotation is perpendicular to the axis of rotation offlywheel28 andshaft62, thereby employing a bevel gear drive between the motor output shaft and the flywheel periphery.

Referring particularly toFIG. 9 and additionally toFIGS. 6 through 8, the mechanical structure offlywheel28 andclutch drive assembly64 will be operationally described.

Clutch drive assembly64 andflywheel28 are axially aligned uponcentral shaft62 as best illustrated inFIG. 9.Central shaft62 is threadingly affixed toend plate70 which in turn is rigidly attached to aframe72 by anintegral boss74 extending axially fromend plate70 and received within a slottedgroove76 such thatend plate70 andcentral shaft62 are non-rotatable. The opposite end ofcentral shaft62 is received within supportinggroove78 inframe72.

Flywheel28 is rotatingly positioned at the end ofcentral shaft62, as best illustrated inFIG. 9, upon a deepgroove ball bearing80, wherebyflywheel28 freely rotates aboutcentral shaft62 when energized bymotor24.

Flywheel28 includes aconical cavity82 for receiving therein aconical friction surface84 of conicalclutch plate66.Clutch plate66 and anactivation plate86, although they are separable members, are geared to adrum88 by interlockingprojections90 and92 respectively, wherebyclutch plate66,activation plate86 and drum88 rotate freely aboutshaft62 as a single unitary assembly.Roller hearings94a and94b, positioned on the inside diameter ofdrum88, are provided to assure the free rotational characteristic ofactivation plate86,drum88 andclutch plate66 as a unitary assembly.

Adjacent activation plate86 is a fixedplate96. Fixedplate96 andactivation plate86 are connected to one another by three equally spaced axially expandable ball ramps98a,98b,98c,98a′,98b′, and98c′ as illustrated inFIG. 16. The operation of the ball ramps98 between fixedplate96 andactivation plate86 is described in greater detail below. Fixedplate96 is fixed to frame72 such that fixedplate96 is free to move axially uponcentral shaft62, but not free to rotate aboutcentral shaft62 by ananti-rotation tang100 slidably received within an axially alignedslot102 withinframe72. SeeFIG. 17.

Fixedplate96 includes acircular projection104 receiving thereon freely rotatable thrust bearing106 positioned between fixedplate96 and aretarder plate108. A pair of nested, parallel acting, Belleville springs110 are positioned, as illustrated inFIG. 9, betweenretarder plate108 and asolenoid plate112 the function of which is described in greater detail below. Axially expandable ball ramps113, seeFIG. 15, connectend plate70 andsolenoid plate112, the function of which is also described in greater detail below.

Positioned uponcentral shaft62, betweenclutch plate66 andflywheel28, is acompression spring assembly114 comprisingwashers116 and118 having acoil spring120 therebetween the function of which is described in further detail below.

Upon start of the fastener work, or driving, cycle, thecontrol module18 causes motor24 to “spin up”flywheel28, in the counter clockwise direction as indicated by arrow A inFIG. 7, to a predetermined RPM. Uponflywheel28 achieving its desired RPM, or kinetic energy state, thecontrol module18 activatessolenoid26 which, through a flexiblewire solenoid cable122 extending from asolenoid plunger124 and affixed to the periphery ofsolenoid plate112 causessolenoid plate112 to rotate clockwise, as indicated by arrow B inFIG. 7. Assolenoid plate112 rotates clockwise,solenoid plate112 is caused to move axially away fromend plate70 by action of the corresponding ball ramps98 inend plate70 andsolenoid plate112. SeeFIG. 15. Asend plate70 andsolenoid plate112 axially separate, the remaining elements ofclutch drive assembly64 are thereby caused to move axially towardflywheel28 compressingcoil spring120 wherebyclutch surface36 preliminarily engagesflywheel cavity44. Engagement ofclutch plate66 withflywheel28 causes counter clockwise rotation ofclutch plate66,drum88 andactivation plate86, as an assembly. By action of corresponding ball ramps98, between fixedplate96 andactivation plate86, seeFIG. 16, rotation ofactivation plate86 causes axial separation ofclutch plate66 andactivation plate86. Belleville springs72 are thus compressed againstsolenoid plate112 thereby providing an opposite axial force, forcingclutch plate66 into tighter engagement withflywheel28.

Asdrum88 rotates counter clockwise,cables126a and126b wrap about peripheral grooves128 and130 indrum88 andclutch plate66 respectively, thereby drawing a vacuumreturn piston assembly132 downward, within acylinder134, in a power, or working, stroke whereby the attachedfastener driver68 is likewise driven downward, throughguide block108 andopening135 withinframe72, thereby driving a selected fastener into a targeted workpiece.

FIGS. 13A through 13C sequentially illustrate the action between fixedplate96 andactivation plate86 asplate86 rotates during the power stroke ofclutch drive assembly64. Although ball ramps98 of fixedplate96 andactivation plate86 are helical as illustrated inFIG. 16, ramps98 are illustrated as being linear inFIGS. 13A through 13C for simplicity of explanation.

FIG. 13A illustrates fixedplate96 andactivation plate86 at the beginning of the tool's work cycle. Asflywheel28drives activation plate86 counter clockwise (to the left inFIG. 13A)balls136, following the profile oframp98, cause a fast and sudden separation x, betweenactivation plate86 and fixedplate96 as illustrated inFIG. 13B. Separation x is maintained throughout the power stroke offastener driver68, as illustrated inFIG. 13B, thereby affecting the transfer of the kinetic energy, stored withinflywheel28, to adriver68 as described above. At the end of the power stroke, as illustrated inFIG. 13C,plates96 and86 suddenly close together thereby causing the rapid disengagement ofclutch plate66 fromflywheel28.

FIG. 14 presents a representative graphical plot of the separation x betweenactivation plate86 and fixedplate96 as a function of the angle of rotation ofactivation plate86. A combination driver guide andresilient stop block138 is preferably positioned at the bottom ofcylinder134 to stoppiston assembly132, withincylinder134, at the end of the power stroke.

Upon disengagement ofclutch plate66 fromflywheel28,coil spring120 urges all elements ofclutch drive assembly64 back towardend plate70. The resulting axial force and pressure now being applied tosolenoid plate112, by action ofcoil spring120 and Belleville springs74,cause solenoid plate112 to close uponend plate70. The pressure being exerted, bysolenoid plate112, uponballs140cause solenoid plate112 to rotate, counterclockwise, towards its original start position wherebysolenoid cable122, being wrapped aboutsolenoid plate112, stops the rotation ofsolenoid plate112 whensolenoid plunger124 returns to its start position as illustrated inFIG. 12. In order to decrease the tensile stress applied tosolenoid cable122 as it stops, the counterclockwise rotation ofsolenoid plate112 andretarder plate108 is provided. By action of the axial force remaining within Belleville springs72,retarder plate108 andsolenoid plate112, as an assembly, exhibit a combined mass and/or inertia greater than that ofsolenoid plate112 alone. Thus, during the short period of time during which the combinedsolenoid plate112 andretarder plate108 assembly is rotationally accelerated the rotational velocity achieved has been reduced and upon separation ofretarder plate108 fromsolenoid plate112,solenoid plate112 has a lower angular momentum resulting in a lower tensile stress being applied tosolenoid cable122 as it stops rotation ofsolenoid plate112. Onceretarder plate108 is uncoupled fromsolenoid plate112,retarder plate108 freely rotates aboutcentral shaft62 until its kinetic energy dissipates. By use ofretarder plate108 the mass and/or inertia ofsolenoid plate112 may be selectively chosen so as not to unnecessarily stresssolenoid cable122 upon stopping the rotation ofsolenoid plate112.

By constructing theclutch drive assembly64, as taught hereinabove,clutch plate66 disengages fromflywheel28 thereby allowingflywheel28 to continue spinning afterclutch drive assembly64 has reached the end of its power stroke. Thus in the event it is desired to successively drive additional fasteners, the remaining kinetic energy is available for the subsequent operation thereby economizing battery power and saving the drive assembly elements and/or theframe72 from having to absorb the impact that would otherwise occur by bringingflywheel28 to a full stop immediately after the power stroke. This feature also permits “dry firing” of the tool.

The clutch drive system as taught herein also provides for automatic compensation for clutch wear in that the expansion betweenend plate70 andsolenoid plate112 will continue untilclutch plate66 engagesflywheel28 thereby allowingsolenoid plate112 to take up the difference at the start of every power drive.

Referring now toFIG. 10. Vacuumreturn piston assembly132 comprisespiston142 slidably received withincylinder134. Spaced from the top ofpiston142 is a circumscribing groove144 having positioned therein a sealing O-ring146. Positioned toward the bottom ofpiston142 are two axial stabilizingbands148 and150.

The inside diameter D, ofcylinder134, is flared outward to diameter D′ at the top ofcylinder134 as illustrated inFIG. 10. Diameter D′ is slightly greater than the outside diameter of O-ring146 thus creating anannular gap152 between O-ring146 and inside diameter D′.

Aspiston assembly132 is drawn axially intocylinder134, during the power stroke offastener driver68, O-ring146 slidingly engages the inside wall diameter D ofcylinder134 thereby forming a pneumatic seal betweeninside wall153 ofcylinder134 andpiston assembly132. Aspiston assembly132 progresses intocylinder134, a vacuum is created within the top portion ofcylinder134, between advancingpiston assembly132 and the sealedend cap154.

Upon disengagement of frictionclutch plate66 fromflywheel28, the vacuum created within the top portion ofcylinder134 drawspiston assembly132 back toward anend cap154 thereby resettingactivation plate86,drum88, andclutch plate66, as an assembly, to their restart position.

As O-ring146 passes from inside diameter D to diameter D′, on its return stroke, any air that may have by passed O-ring146, during the power stroke, is compressed and permitted to flow past O-ring146 throughannular gap152 and to the atmosphere throughcylinder134, thereby preventing an accumulation of entrapped air abovepiston assembly132. Aresilient end stop156 is preferably positioned within end cap to absorb any impact that may occur aspiston assembly132 returns to its start position at the top ofcylinder134.

Asdrum88 returns to itsstart position tang157 radially extending fromdrum88 engagesabutment block158 affixed to frame72, seeFIG. 11, thereby preventing over travel ofdrum88 as it returns to its start position.

It will be appreciated that the above-describedfastener drive assembly16 is illustrative and that aspects of the invention have application in other types of fastener drive assemblies.

Additional structural and operational details of thefastener drive assembly16 is completely described within the two co-pending patent applications identified in the “Related Patent Applications” section above and are incorporated herein by reference.

Speed Controller

FIG. 18 depicts acontrol system200 for anailing tool10 that advantageously uses rotary speed sensing of a inertial member, depicted as aflywheel202, to more consistently and efficiently drive a fastener into a workpiece. Thecontrol system200 responds to inputsignals204 received and processed by anelectronic control module206 to command a motive device, such as aflywheel motor208, to accelerate theflywheel202. Thecontrol module206 further commands aclutch actuator210 to transfer kinetic energy from theflywheel202 to a fastener.

A signal representative of the rotational rate (e.g., RPM) that aplurality212 of radially arrayed pairs of magnetic poles rotate with theflywheel202 is generated by atransducer214 that senses each closest pair of registeredmagnetic poles216,218 of theplurality212. In addition to flywheel speed signal, thecontrol system200 responds to other types of inputs. For example, the input signals204 may include atrigger input220, a safety input222, a userspeed adjustment input224, a continuous flywheel mode switch input226, a fastenertype sensor input228, and afastener transducer input230 for sensing the presence of a fastener positioned for driving.

Afastener indexer232 may advantageously respond to an electrical command from thecontrol module206. The electric interface to a separable indexing magazine (not shown) may be readily designed and assembled with electrical interconnects. This advantageously compares to pneumatic power tools with indexing wherein more complicated pneumatic plumbing at the interface of the magazine and main body is required.

Thecontrol module206 may respond to an enabling condition input234. In some instances, the availability of electrical power in combination with actuation of a trigger or depression of a safety may be deemed an enabling condition for powering thenailing tool10. Alternatively or in addition, the enabling condition input234 may represent other input signals that enable or disable thenailing tool10. For instance, the enabling condition input234 may include a sensed motor overheat condition, an ON/OFF switch, a battery power voltage level, or presence of an AC electrical power input. The latter may cause thecontrol module206 to switch power source, or to charge a battery.

Battery input236 may represent a source of power for thecontrol module206. In addition, thecontrol module206 may respond to the voltage level of thebattery input236 by altering time-out values when the control module expects to see acceleration and actuation performed. For example, for a given battery voltage level, theflywheel motor208 should accelerate to a given target speed in a certain time range, whereas this time range would be expected to change in relation to the voltage level. Thus, mechanical failures would be more accurately detected by more accurately predicting the performance thereof.

Theelectronic control module206 includesinterfaces240–256 for these input signals204. Aspeed sensor240 may convert the speed signal from thetransducer214 into another form. For instance, the speed sensor may convert an analog signal into a near DC signal (digital signal) suitable for digital signal processing. A thin film switch “A”242 converts amechanical trigger input220 into an electrical trigger signal. A thin film switch “B”244 converts a mechanical safety input222 into an electrical safety signal. A presetspeed range interface246 may fully comprise a speed selection or define a flywheel speed range for userspeed adjustment input224. The presentspeed range interface246 may define a range constrained by a combination of the operable range of theflywheel motor208 and/orclutch actuator210 and the force requirements expected for the fastener and type of workpiece. Acontinuous mode input248 receives a selection for continuous or intermittent mode for the flywheel. It should be appreciated that continuous mode or intermittent mode may be used at the exclusion of the other mode. Alternatively or in addition, the selection may be determined based on another consideration such as state of charge of the battery (e.g., switching to intermittent mode to save electrical power when a battery is partially discharged). A fastener type input interface250 senses or accepts a selection from the fastenertype sensor input228, which may advantageously adjust speed and timing considerations. A fastener sensor interface252 responds thefastener transducer input230 to convert the signal into a form suitable for digital processing. Thecontrol module206 may respond to the presence or absence of a fastener ready for driving in a number of fashions. For example, dry firing may be prevented to avoid wear or a jam of a partially loaded or improper fastener; an indication of the need to load the magazine may be given, a continuous mode for the flywheel may be discontinued, etc. For applications with an indexing magazine, anindex control interface254 provides an index signal suitable for thefastener indexer232.

Thecontrol module206 is depicted as including apower supply256 that responds to the enabling condition input234 and thebattery input236. It should be appreciated that the power supply may comprise a power source for thecontrol module206 only, wherein power drain on the battery is prevented by shutting down thecontrol module206 except when commanded to drive a fastener or when in continuous mode and thetool10 is enabled. Thepower supply256 may further represent logic to select a source of electrical power and/or to charge an attached battery. In addition, thepower supply256 may represent additional safety features to prevent electrical power from inadvertently reaching actuating components.

Theelectronic control module206 provides amotor control interface260 to convert a control signal into a form suitable for the flywheel motor208 (e.g., a logic signal to a pulse width modulated (PWM) power signal). Aclutch control interface262 converts a control signal into a form suitable for the clutch actuator210 (e.g., a logic signal to power signal).

Thecontrol system200 may advantageously include additional features to the user to include anaim indicator264 that is controlled by anindicator control interface266 in thecontrol module206. For example, in response to an enabling condition such as depression of the safety against a workpiece, a focused light or laser pointer may be directed at the expect point of the fastener. The illumination thereof may assist the user in seeing the workpiece more clearly in dim lighting or to better appreciate the aim of the tool.

Theelectronic control module206 advantageously includes adigital controller300 that is programmed for additional features. To that end, aprocessor302 accesses instructions and data by indirect addressing through apointer304 of aRandom Access Memory306. The processor and/or memory access analog-to-digital (A/D)inputs308, such as from thespeed sensor240, that are used and stored in digital form. Although not depicted, another example may be thespeed adjustment input224 and presetspeed range interface246 as being analog inputs. Thememory306 includesinstructions310; aswitch timer312 for monitoring a stuck or inadvertently held switch; interruptscode314 for handling time sensitive signals or abnormal processing; amotor timer316 for monitoring overlong motor operation that could result in overheating; aswitch debounce buffer318 for precluding inadvertent or spurious switch signals from being acted upon; aspeed target register320 for holding a preset or calculated value for a desired or appropriate flywheel speed; anactuation timer register322 for holding a preset or calculated value for monitoring for abnormally long time for transfer kinetic energy to the driver by actuation; a no-operation (no op)timer324 for timing when to deactivate; or other data structures orunused memory326

It will be appreciated that theinstructions310 include diagnostic code to perform RAM checking, verifying that all memory locations are working properly prior to use and that theprogram counter304 is indexing correctly. The diagnostic code further checks that jumps and returns from subroutine locations return back to the correct location. In addition, the diagnostic code checks that when theprocessor302 tells a pin to go high or low that the line attached to the pin responds accordingly.

Thecontrol module206 includes a watchdog timer circuit330 that prevents a processing failure. Throughout processing, it will be appreciated that the watchdog timer circuit330 is periodically reset by theprocessor302, lest a time limit be reached that initiates resetting or disabling thecontrol module206.

InFIG. 19, an illustrative sequence of steps for utilizing thecontrol system200 to affect control of thetool10 is depicted as amain routine400. Before driving a fastener, user settings are available (block402). For instance, a user setting may include an enabling condition such as an ON setting or a momentary actuation of a control (e.g., trigger, safety). A user setting may include a MODE setting, such as continuous, intermittent, or automatic (e.g., the control system determines the appropriate mode). The user setting may include a speed adjust setting, to include a factory preset range appropriate for the fastener drive assembly, a range appropriate for the type of fastener sensed, or a user selected range.

In the illustrative embodiment, a user input, such as depression of the safety switch, begins processing (block404) by enabling the control system (block406). Immediately, the control module performs diagnostics to preclude failures that may cause an inadvertent activation and actuation of the tool (block408), discussed in more detail below. It will be appreciated that certain diagnostic features continue to be performed throughout operation.

Once diagnostics are complete, with a determination is made as to whether the safety is depressed (block410). If so, an aim indicator is activated (block412). This feature is included to illustrate features that may be performed to give visual indications to the user about the operation or condition of the tool.

Thereafter, a determination is made as to whether the tool is in continuous mode (block414). This determination may be preset, user selected, or automatically selected based on considerations such as battery voltage. If in continuous mode inblock414, then a further determination is made as to whether an input has been made to ready the tool for actuation, for instance a depression of the trigger (block416). And if so, the continuous mode is initiated as described below. Otherwise, an additional determination is made as to whether a no op timer has expired (block418). If no operations have been received within a suitable time, then the control module is disabled (block420) to prevent battery drain and preclude inadvertent actuation. If inblock418 the no op time-out has not occurred, then processing continues to wait for a trigger command to initiate the continuous operating of the flywheel.

Returning to block414, if continuous mode is not selected or appropriate, then themain routine400 is in an intermittent mode that advantageously accelerates the flywheel to a target speed each time a fastener is to be driven. Thus, battery power is conserved between driving cycles. Since residual kinetic energy of the flywheel is conserved by the fastener drive assembly, the cycle time is still short even in intermittent mode. In intermittent mode, a determination is made as to whether a valid command to drive a fastener has been received (block422), and if so, initiating intermittent acceleration of the flywheel will be discussed below, as well as the forced sequence of the safety and the trigger for a valid command. If a valid command is not received inblock422, then a further determination is made as to whether a no op time-out limit has been reached (block424), and if so the control module is disabled (block420) and routine400 is complete.

FIG. 20 depicts the diagnostics routine500 referenced inFIG. 19. Certain diagnostic tests are performed upon powering up the control module and other tests continue in background during operation of the tool. For example, a watchdog timer (block502) is depicted, wherein a dedicated circuit times the period since the last update from the processor. If the watchdog timer is not updated before timing out, the control module is assumed to be processing abnormally and the tool is placed in a safety lockout mode (block503). This watchdog timer continues operation throughout themain routine400.

Also, digital parameters are initialized and any calibrations are performed (block504). For example, interrupt vectors are set so that any resets will be appropriately handled. Also, analog devices like oscillators are calibrated. Then the processor memory is tested by checking for any failure to toggle and to read a memory location (Z BIT) (block505). If Z BIT fails (block506), then safety lock-out mode is set (block503), else any unused memory is loaded with a reset code (e.g., interrupt vector) (block508). In addition, a check is made as to whether the program counter (pointer) is corrupt (block510), and if so safety lockout mode is set (block512). If the program is not corrupt inblock510, then a delay occurs to allow for the power supply to the control module to stabilize (block514). If not stable (block516), then safety lockout mode is set (block518). If stable inblock516, then the trigger time-out counter is set up so that overly long trigger commands due not result in actuation (block520). Also, switch debounce code is set up so that momentary or spurious trigger or switch signals are ignored (block522). Thereafter, routine500 returns to themain routine400 ofFIG. 19.

FIG. 21 depicts the intermittent mode fromblock416 ofFIG. 19. In particular, this portion of themain routine400 begins with a valid command from the user indicating that the flywheel is to be accelerated to the target speed and the driver is to be driven by the flywheel. To that end, the speed target is determined (block600), which could be based on a preset value, a user selection, a preset speed range adjusted by a user selection, a selection based on a sensed fastener type, or a range based on a sensed fastener type as adjusted by a user selection. With the target set, a motor command is initiated (block602).

Advantageously, the motor command begins with a Pulse Width Modulated (PWM) soft start is used. Thus, the duty cycle of the PWM command ramps up to a full command level, reducing the initial electrical current demand on the battery and surge to the motor. Thereby, power consumption is greatly reduced and the service life of the motor is extended.

With the flywheel accelerating in response to the motor command, a determination is made as to whether the safety is still held (block604). Withdrawal of the safety from the workpiece causes the motor command to be deactivated (block606) and the control module to be disabled (block608).

If the command is still valid inblock604, then a further determination is made as to whether the motor time-out has expired (block610). If so, due to a failure in the fastener drive assembly (e.g., stuck clutch, motor failure, weak battery), the safety lockout mode is set (block612). If the motor has not timed out inblock610, then the current sensed speed is compared to the target. If the target is not reached (block614), then processing returns to block602, continuing with a full motor command. If the target speed is reached inblock614, then the motor command is deactivated (block616).

A speed reduction threshold is determined for imparting or transferring kinetic energy from the flywheel to the linearly moving fastener driver. Thus, not only is a known amount of kinetic energy available in the flywheel, but a known amount is transferred to the driver and thus to the fastener for a consistent depth of drive. Moreover, since the flywheel is not completely stopped during or after transferring the kinetic energy, the remaining kinetic energy is available for a subsequent operation. The speed reduction may be based on a look-up table for the given conditions, based on a fixed ratio of a current speed, or a fixed scalar amount below the target, or other measures.

The clutch is engaged to transfer the kinetic energy to the driver (block620). Then a determination is made as to whether the threshold is reached (block622). If not reached, then a further determination is made as to whether the actuation time-out has been reached (block624), and if so, safety lock-out mode is set (block626). If inblock622 the time-out is not reached, then actuation is still in progress by returning to block620. Returning to block622, if the reduction threshold is reached, then the clutch is deactivated (block628). If installed and enabled, the fastener index is actuated (block630). Then the control module is disabled (block632) and main routine400 ends.

FIG. 22 depicts the continuous mode portion after a trigger command inblock416 of themain routine400 ofFIG. 19. In particular, the speed target is determined (block700) and the motor is started (block702) in a manner similar to that described respectively forblocks600 and602. Then a determination is made as to whether the motor time-out has expired, indicating an inability to accelerate the motor in the expected time (block704). If expired, then safety lockout mode is set (block706). If not timed out, then a further determination is made as to whether the target has been reached (block708). If not, then flywheel acceleration continues by returning to block702.

Advantageously, continuous mode allows addition safety/trigger sequences for a valid command. For instance, rather than requiring the safety signal to precede the trigger signal, (“trigger fire”), the trigger signal may precede the safety signal (“bottom fire”). Again, a trigger time-out (e.g., 3 seconds) is applicable just as is the safety time-out (e.g., 3 seconds) to minimize inadvertent actuation. Bottom fire is included as an option in continuous mode for applications wherein the user desires very short cycle time between drives or has a personal preference for this technique.

If the target is reached inblock708, then the speed is held (block710). For example an operating range may be entered wherein the motor command is recommenced when a lower limit is reached and removed when an upper limit is reached. Then, a determination is made as to whether a valid command has been received from the user (block712). If not, a check is made as to whether the no op time-out has occurred (block714), and if not, the flywheel speed is continuously maintained by returning to block710. If the no-op timer has expired inblock714, then the motor command is deactivated (716) and the control module is disabled (block718).

Returning to block712 wherein a valid command has been received, then the clutch is actuated in a manner similar to that described above for the intermittent mode, whereinblocks720–734 correspond respectively to block616–630. However, after deactuating the clutch inblock732 and actuating a fastener index in block634, control returns to block710 to continue holding speed in a continuous fashion awaiting the next valid command to drive a fastener.

FIG. 23A graphically illustrates a valid user command that initiates acceleration of themotor24 and actuation of thesolenoid26 ofFIG. 1 over a time period of “t0” to “t7”. At time “t1”, an enabling event, depicted as depression of the safety, provides power to the control system. The “Power or Safety” remains on throughout the depicted time scale to time “t7”. At time “t2”, trigger signal is received, which also remains present throughout the remainder the graph, representing the tool placed against the workpiece followed by depression of the trigger. Also at time “t2”, the motor command (“Motor Signal”) begins.

The portion of the motor signal between times “t2” and “t3” ofFIG. 23A are depicted in greater detail inFIG. 23B, which shows the soft start portion of the motor signal. In particular, the PWM motor signal begins with an on time of 2 μsec and off time of 510 μsec, incrementing each cycle by 10 μsec until reaching a full command of 510 μsec on time and 10μ off time. It will be appreciated that other approaches to soft starting the motor may be implemented as well as omitting soft start.

Returning toFIG. 23A, with the motor signal beginning at time “t2”, the parameter of rotational speed of the flywheel and motor is sensed (“motor speed”). The initial value of motor speed at time “t2” may be nonzero if the flywheel has residual kinetic energy from a previous driving cycle. At about time “t3”, the sensed speed enters the lowest speed of the speed range available for actuation. At time “t5”, the sensed speed reaches the target speed, whereupon several changes occur. The motor command is deactivated. In addition, a solenoid signal commands actuation, transferring the kinetic energy from the flywheel to the linearly moving driver to the fastener as shown by the decreasing motor speed. At time “t6”, the motor speed is sensed at having reduced to a threshold indicating the desired actuation, and thus the solenoid signal is deactivated.

FIGS. 23C–23F depict instances where an invalid command is given, resulting in no actuation of the tool.FIG. 23C presents a trigger signal at time “t1” that precedes the safety signal at time “t2”, which in the illustrative embodiment precludes activating the motor and actuating the solenoid.FIG. 23D presents a safety depressed at time “t1”, but the safety signal reaches a time-out at time “t4” before the trigger signal is received, thus precluding activation and actuation.FIG. 23E presents a safety signal at time “t1” and a trigger signal at time “t2”, which is the required sequence and within the time-out value for the safety. Although the safety signal remains present, the trigger signal is withdrawn after time “t4” before the motor speed has reached the speed target (“speed set point”). Without a valid command being removed, the motor signal is removed and actuation does not occur.FIG. 23F presents a situation similar toFIG. 23E except that the safety signal is the one that is removed after time “t4” before the motor speed reaches the speed target. Again, the motor signal is removed and actuation does not occur.

FIGS. 24A–24B illustrate the adaptability of the control system to a wide operating range of fastener types and battery charge.FIG. 24A graphically illustrates a scenario where the flywheel accelerates rapidly with a fully charged battery and a low speed set point for the speed target. Thus at time “t1” the low speed set point is reached and the solenoid signal is present for a relatively short period until time “t2”. Then, between time “t4” and “t5”, the battery voltage is shown as reaching a fully discharged level and the tool having been set to a high-speed set point. Thus, the acceleration of the motor speed from time “t5” to time “t6” to the high-speed set point takes longer. Moreover, the solenoid signal is required to be present for a longer period from time “t6” to “t7” by actuating more slowly with a lower solenoid signal.

FIG. 24B illustrates a feature of the control system to accommodate increased tolerance within the clutch components due to wear or manufacturing variation yet still detect a failure condition. In the first trace representing a clutch with a low gap, the motor accelerates the flywheel to the target speed at time “t1”. Then, a brief solenoid signal starts at time “t1”. After a brief period, the flywheel has slowed to the necessary speed drop off and the solenoid signal is deactivated, having provided the necessary amount of kinetic energy to the driver. In the second trace representing a clutch with a high gap, the motor accelerates the flywheel to the target speed at time “t6”, prompting the solenoid signal to start. The solenoid signal last for a longer period than the first trace. At time “t7”, the necessary speed drop off is reached and the solenoid signal is deactivated. The third trace represents a clutch that fails to engage. At time “t10”, the motor has accelerated the flywheel to the target speed and the solenoid signal starts. With the clutch failing to engage, the motor speed drops off slowly, still higher than the expected value at time “t11”. Then, at time “t12”, the clutch time-out value is reached, indicating the failure, and the solenoid signal is discontinued.

FIG. 25 depicts anexemplary control circuit800 for a flywheel operated hand tool, such as thenailing tool10 ofFIG. 1 that advantageously provides selectable continuous or intermittent modes and economical speed sensing.

A speed sensor802 is picks up alternating north and southmagnetic fields804 on a ring magnet with an inductive transducer806. In particular, a series pair of coils808 have their shared node is grounded and their opposite ends connected to a differential amplifier, or comparator U1, such as model no. TA75S393F. Thus, as each pair offields804 of the 32 alternating poles are encountered, the push-pull arrangement or differential arrangement enhances signal integrity and noise immunity of the differential speed signal of about 10–15 mV. The comparator U1 is biased between power supply VDD and ground. The positive bias is also coupled to ground via capacitor C1 suppress high frequency noisy disturbances from the power supply.

The output node of the comparator U1 is coupled to ground via a capacitor C2 to rectify and low pass filter the differential speed output that is passed to the +T input of a monostable multivibrator (one shot) U2, such as model no. MM74HC4538 by Fairchild Semiconductor Corporation. The one shot U2 is an integrated circuit that, when triggered, produces an output pulse width that is independent of the input pulse width, and can be programmed by an external resistor-capacitor (RC) network to set the pulse width. To that end, the RC input of the one shot U2 is coupled to the common node of a series resistor R1 and capacitor C3, the series coupled between power supply VDD and ground, respectively. The inverted input CS of the one shot U2 is coupled to the common node of a series resistor R2 and capacitor C4, the series coupled between power VDD and ground, respectively. The inverted outputQ of the one shot U2 is connected to the inverted input −T. The bias V+ of the one shot U2 is coupled to power supply VDD and to ground via capacitor C5. Thus configured, the one shot U2 outputs at noninverted output Q a series of pulses, the spacing between pulses being a function of the rate that the poles of ring magnet pass by the speed transducer808.

The pulse train at output Q of one shot U2 is connected to anode810 via a resistor R3. Thenode810 is also coupled to ground via capacitor C6. Thus, the signal atnode810 is low pass filtered, creating a near DC signal whose amplitude is related to rate of pulses. Thus, the sensed speed signal has been converted to a form suitable for digital processing.

A controller U3, such as an 8-pin RISC microprocessor performs the digital processing, model PIC12C671. The analog input GP1 of the controller U3 receives the near DC signal fromnode810. This near DC signal is compared to a speed target reference signal at analog input GP0. The controller U3 changes the analog reference signal into a digital signal to be compared to the digitized speed signal with a resolution of one bit. The speed target reference signal is produced by preset speed adjust range formed by a voltage divider of trimmable resistors R4 and R5 coupled between power supply VDD and ground. Inserting an infinitelyvariable potentiometer812 between resistors R4 and R5 advantageously provides a user speed adjustment. The pick off point of thepotentiometer812 is coupled to the analog input GP0 and also coupled to ground via capacitor C7 for noise suppression. It will be appreciated that the resistors R4 and R5 may be selected for a desired speed range within which thepotentiometer812 selects a target speed. The voltage thus produced at analog input GP0 may advantageously be selected for a desired voltage level corresponding to a target speed. When enabled by a safety signal at input GP2, the processor U3 awaits a trigger signal at input GP3, as described above in the timing diagrams ofFIG. 23A–23F before producing a motor signal at output GP4 and thereafter a solenoid actuation signal at output GP5.

The user initiates these actions by selecting a mode, either continuous or intermittent, at modeselect switch814, enabling the tool withsafety switch816, and then commanding the driving of a fastener with atrigger switch818.

The safety signal is received in either continuous or intermediate mode, which affects the manner of operation of processor U3. Specifically, in continuous mode, switch814 couples battery voltage VBATT to a resistor R6 whose value is selected to scale the battery voltage to the desired voltage VDD for thecontrol system800. The resulting power supply voltage VDD is further regulated by being coupled to ground via the parallel combination of a capacitor C8 and zener diode Z1. Thus, in continuous mode, the control system remains enabled, awaiting a safety and trigger signal to initiate the tool.

To that end, themode switch814 in continuous mode also couples the battery voltage to a first input of an ANDgate820, such as an SN74AHC1G08. The other input to the ANDgate820 receives battery voltage VBATT when thesafety switch816 is closed, inverted byinverter822, such as an SN74AHC1G04. The output of the ANDgate820 controls the input GP2 via a biasing circuit824. In particular, the output of the ANDgate820 is connected to input GP2 via resistor R7. The input GP2 is also coupled to power supply VDD via a resistor R8 and to ground via capacitor C9. When the trigger switch is closed, ground is coupled the input GP3 of the processor U3 via resistor R9. The input GP3 is connected to power supply VDD via resistor R10 and to ground via a capacitor C10.

When themode switch812 is in intermittent mode, the resistor R6 is connected to battery voltage VBATT when thesafety switch816 is closed. Also, the first input of the ANDgate820 is connected to ground.

The processor U3 commands aDC motor826 with a motor signal at output GP4 that is coupled via resistor R11 to the base of a buffer, depicted as a small signal transistor Q1 such as a 2N4401. The base is also coupled to ground via resistor R12 to ensure that the transistor will be off if voltage is not applied to the base. The collector is connected to power supply VDD. The emitter is also connected to the base of a rectifier Q2, such as an IRL3803 that advantageously has a low RDS (on) characteristics minimizing energy dissipation, that is heat shielded. The emitter is also coupled to ground via resistor R13 to ensure that rectifier Q2 if off when not supplied with a signal. The turned-on rectifier Q2 thereby couples to ground a negative terminal respectively of aDC motor826, a MOSFET configured as a diode Q3 (such as a model MTD20N03HDL) that advantageously has a high current carrying capacity in a small package. A positive terminal respectively of the diode Q3 and theDC motor826 are coupled to battery voltage VBATT. Thus, theDC motor826 is activated when rectifier Q2 closes.

The processor U3 commands asolenoid828 with a solenoid signal at output GP5 that is coupled via resistor R14 to the base of a MOSFET configured as diode Q4 (such as a model MTD20N03HDL). The base is also coupled to ground via resistor R15 to ensure that the transistor will be off if voltage is not applied to the base. The rectifier Q4 has a negative terminal coupled to ground and a positive terminal coupled to a negative terminal of thesolenoid828. The positive terminal of thesolenoid828 is coupled to battery voltage VBATT, thus solenoid828 activates when rectifier Q4 is closed by the solenoid signal. The rectifier Q4 advantageously withstands the electrical current spikes associated with inductive loads of solenoids.

FIG. 26 presents anindex circuit830 for providing an electrical index signal, thereby avoiding the additional complexity of pneumatic index approaches. Moreover, the index circuit advantageously uses a one shot U4 that is part of the same package as one shot U2. Theindex circuit830 is triggered by the solenoid signal from GP4 of the processor U3 to an inverted −T input, as would be appropriate for a solenoid that is triggered on a falling edge of a solenoid signal rather than a rising edge. The one shot U4 is configured with a positive bias V+ to power supply VDD and also coupled to ground via capacitor C10. A negative bias V− is grounded. A noninverted output Q is connected to input +T to place the device into a non-retriggerable, monostable mode of operation. An inverted input R is coupled to a shared node of a series combination of a resistor R18 and capacitor C11 that are connected across power supply VDD and ground, providing a reset RC network to hold the device in reset until power supply VDD is up and stable. Similarly, an input RC of the one shot U4 sets up the output timing, i.e. time the output pulse is high. In particular, the input RC is coupled to a shared node of a series combination of a resistor R19 and capacitor C12 connected between power supply VDD and ground, respectively. The one shot U4 has an output pulse of appropriate duration and delay from the solenoid signal to advance the next fastener after the previous fastener is driven. The index pulse from output Q is given an appropriate voltage by passing through a series resistor R16 to a base of a rectifier Q5 (a MOSFET configured as a diode such as a model MTD20N03HDL. The base is also coupled to ground through a resistor R17 to ensure that rectifier Q5 is off when no voltage is applied. A negative terminal of the rectifier Q5 is grounded. A positive terminal rectifier Q5 is connected to a negative terminal of anindexing solenoid832. A positive terminal of theindexing solenoid832 is connected to battery voltage VBATT. Thus, when the indexing signal closes the rectifier Q5, theindexing solenoid832 is activated.

In use, a user loads themagazine42 of thenailing tool10 with a strip of fasteners, and installs a chargedbattery22. The tool is in a mode, such as Intermittent, conserving battery power by accelerating a flywheel each time that a fastener is to be dispensed or driven. As thenose assembly36 is placed against a workpiece, closing asafety device34, the safetymechanical linkage38 contacts a highly reliable thinfilm safety switch52, powering thecontrol module18. Atrigger30 is depressed, activating another highly reliable thinfilm trigger switch50 via a triggermechanical linkage32. If the safety and trigger switches are actuated within appropriate time intervals and sequence (e.g., safety depressed and held no more than 3 seconds prior to trigger), then the processor U3 calculates a target speed for the flywheel set as appropriate for thefastener drive assembly16 and/or an appropriate setting for the fastener and workpiece. As the flywheel accelerates, the speed signal from anoncontact speed sensor60 is compared to the target speed. Once reached, themotor24 is de-energized and then a solenoid actuation signal couples a clutch to theflywheel28 to impart kinetic energy to a linearly movingfastener driver68. The processor U3 uses a reduction threshold to determine when theflywheel28 has imparted an appropriate amount of kinetic energy, thereafter allowing theflywheel28 to continue spinning with any remaining energy available for the next cycle. By monitoring flywheel speed, fault conditions are detected such as a slow motor acceleration that could be due to low battery voltage, motor degradation or a stuck clutch. Similarly, by detecting an actuation time-out, the failure of theclutch drive assembly64 to engage is detected, preventing jamming of thetool10 if attempting to cycle again.

By virtue of the foregoing, aportable tool10 provides a consistent drive in a single stroke, yet efficiently uses electrical power from thebattery22 without detrimental surges by using aDC motor24 to accelerate aflywheel28. Moreover, consistent drives are ensured across a range of battery voltages and component tolerance variations (e.g., clutch wear). The consistent rotary sensing and control of a rotary member (e.g., flywheel28) has application more broadly to hand tools in accurately and robustly setting a desired speed.

While the present invention has been illustrated by description of several embodiments and while the illustrative embodiments have been described in considerable detail, it is not the intention of the applicant to restrict or in any way limit the scope of the appended claims to such detail. Additional advantages and modifications may readily appear to those skilled in the art. For example, aspects of the invention are applicable to other sources of power, such as corded power tools or pneumatic power tools. As another example, although a programmed approach is described herein, it will be appreciated that digital logic or analog controls may be used.

As a further example, although a noncontact speed sensor is disclosed, applications of the present invention may include other types of speed sensing. For instance, an optical encoding approach may be used, weigan sensor, variable reluctance sensors, Hall effect sensors, feedback from the motor such as a tachometer signal, and other techniques.

As yet a further example, the describedcontrol circuit800 employs a battery voltage VBATT having a nominal value with resistors and a zener diode Z1 being used to step down the battery voltage to the power supply voltage VDD. However, it will be appreciated that a power supply (e.g., a switching power supply) capable of regulating the voltage to the integrated circuit components may be used while providing a battery voltage signal to a processor. Thereby the processor may adapt its command, timing, and other features to accommodate a wider range of battery voltage, thus extending service life. For instance, a processor having additional available inputs such as an 18-pin processor, model PIC16C71 may be used.

As an addition example, a speed adjustment circuit may employ other types of voltage references, such as a sized digital resistor. In addition, the processor may calculate or lookup in a table a digital reference against which the sensed speed signal is compared.

As another example, although a specific safety and trigger sequence is described, other sequences and time-out schemes may be employed. Moreover, even a single trigger scheme without a safety may be employed.

Claims (45)

1. A control module for a hand tool powered by DC power having a rotary member;

comprising:

a target speed adjustment circuit operable to electronically communicate a target speed signal, wherein said target speed signal represents a target speed for the rotary member;

a speed sensor circuit operable to electronically communicate a rotary speed signal, wherein said rotary speed signal represents a rotary speed of the rotary member, wherein said rotary speed is determined by a sensor;

a trigger circuit electronically operable to communicate a trigger signal, wherein said trigger signal represents engagement of a trigger by a user; and

a controller having a plurality of inputs and outputs; wherein the inputs of the controller comprise input signals comprising the target speed signal, the rotary speed signal, and the trigger signal; wherein the controller is operably configured to command the rotary member with electronic communication of a first command signal in response to a function comprising a first function of the input signals.

2. The control module ofclaim 1, wherein the controller is a microprocessor.

3. A control module for a hand tool powered by DC power having a rotary member;, comprising:

a target speed adjustment circuit operable to electronically communicate an adjustable target speed signal, wherein said adjustable target speed signal represents a target speed for the rotary member and that is representative of user target speed input;

a speed sensor circuit operable to electronically communicate a rotary speed signal, wherein said rotary speed signal represents a rotary speed of the rotary member, wherein said rotary speed is determined by a sensor;

a trigger circuit electronically operable to communicate a trigger signal, wherein said trigger signal represents engagement of a trigger by a user; and

a controller having a plurality of inputs and outputs; , wherein the inputs of the controller comprise input signals comprising the adjustable target speed signal, the rotary speed signal, and the trigger signal;, wherein the controller is operably configured to command the rotary member with electronic communication of a first command signal in response to a function comprising a first function of the input signals;, wherein the controller is operably configured to command a clutch mechanism with electronic communciation communication of a second command signal in response to a function comprising a second function of the input signals;, wherein the clutch mechanism is operable to mechanically impart kinetic energy of the rotary member to a driving mechanism.

4. The control module ofclaim 3, said clutch mechanism comprising a solenoid.

5. A control module for a hand tool powered by DC power having a rotary member; , comprising:

a target speed adjustment circuit operable to electronically communicate an adjustable target speed signal, wherein said adjustable target speed signal represents a target speed for the rotary member and that is representative of user target speed input;

a speed sensor circuit operable to electronically communicate a rotary speed signal, wherein said rotary speed signal represents a rotary speed of the rotary member, wherein said rotary speed is determined by a sensor;

a trigger circuit electronically operable to communicate a trigger signal, wherein said trigger signal represents engagement of a trigger by a user; and

a controller having a plurality of inputs and outputs; , wherein the inputs of the controller comprise input signals comprising the adjustable target speed signal, the rotary speed signal, and the trigger signal; , wherein the controller is operably configured to command the rotary member with electronic communication of a first command signal in response to a function comprising a first function of the input signals;

wherein the trigger circuit further comprises: a mechanical control for receiving a user input for operation of the hand tool;, and a thin film switch in physical communication with the mechanical control and in electrical communication with the controller.

6. A control module for a hand tool powered by DC power having a rotary member; , comprising:

a target speed adjustment circuit operable to electronically communicate an adjustable target speed signal, wherein said adjustable target speed signal represents a target speed for the rotary member and that is representative of user target speed input;

a speed sensor circuit operable to electronically communicate a rotary speed signal, wherein said rotary speed signal represents a rotary speed of the rotary member, wherein said rotary speed is determined by a sensor;

a trigger circuit electronically operable to communicate a trigger signal, wherein said trigger signal represents engagement of a trigger by a user; and

a controller having a plurality of inputs and outputs, wherein the inputs of the controller comprise input signals comprising the adjustable target speed signal, the rotary speed signal, and the trigger signal; , wherein the controller is operably configured to command the rotary member with electronic communication of a first command signal in response to a function comprising a first function of the input signals;, wherein the first command signal is received by a direct current electric motor, wherein the direct current electric motor is in mechanical communication with the rotary member.

7. The control module ofclaim 1, further comprising a battery.

8. A control module for a hand tool powered by DC power having a rotary member; , comprising:

a target speed adjustment circuit operable to electronically communicate an adjustable target speed signal, wherein said adjustable target speed signal represents a target speed for the rotary member and that is representative of user target speed input;

a speed sensor circuit operable to electronically communicate a rotary speed signal, wherein said rotary speed signal represents a rotary speed of the rotary member, wherein said rotary speed is determined by a sensor;

a trigger circuit electronically operable to communicate a trigger signal, wherein said trigger signal represents engagement of a trigger by a user; and

a controller having a plurality of inputs and outputs; , wherein the inputs of the controller comprise input signals comprising the adjustable target speed signal, the rotary speed signal, and the trigger signal; , wherein the controller is operably configured to command the rotary member with electronic communication of a first command signal in response to a function comprising a first function of the input signals;

wherein the target speed adjustment circuit further comprises a variable potentiometer, wherein the variable potentiometer is operable to vary the target speed signal and where said adjustable target speed signal comprises a preset target speed range within which a user may adjust said target speed of said rotary member.

9. The control module ofclaim 8, wherein the variable potentiometer is operable to be varied by a speed adjustment knob.

10. A control module for a hand tool powered by DC power having a rotary member; , comprising:

a target speed adjustment circuit operable to electronically communicate an adjustable target speed signal, wherein said adjustable target speed signal represents a target speed for the rotary member and that is representative of user target speed input;

a speed sensor circuit operable to electronically communicate a rotary speed signal, wherein said rotary speed signal represents a rotary speed of the rotary member, wherein said rotary speed is determined by a sensor;

a trigger circuit electronically operable to communicate a trigger signal, wherein said trigger signal represents engagement of a trigger by a user; and

a controller having a plurality of inputs and outputs; , wherein the inputs of the controller comprise input signals comprising the adjustable target speed signal, the rotary speed signal, and the trigger signal; , wherein the controller is operably configured to command the rotary member with electronic communication of a first command signal in response to a function comprising a first function of the input signals; further comprising and

a mode circuit electronically operable to communicate a mode signal, wherein the mode signal represents a desired mode of constancy of rotation of the rotary member;, wherein the mode circuit comprises a mode selection switch, wherein said mode selection switch is responsive to a user's mode selection between continuous and non-continuous mode, wherein the mode signal further represents a user's mode selection of desired mode of constancy of rotation of the rotary member,;

wherein the inputs of the controller further comprise an input signal comprising a mode signal, wherein the controller is responsive to the mode signal by commanding the rotation of the rotary member in accordance with the user's mode selection.

11. A control module for a hand tool powered by DC power having a rotary member;, comprising:

a target speed adjustment circuit operable to electronically communicate an adjustable target speed signal, wherein said adjustable target speed signal represents a target speed for the rotary member and that is representative of user target speed input;

a speed sensor circuit operable to electronically communicate a rotary speed signal, wherein said rotary speed signal represents a rotary speed of the rotary member, wherein said rotary speed is determined by a sensor;

a trigger circuit electronically operable to communicate a trigger signal, wherein said trigger signal represents engagement of a trigger by a user; and

a controller having a plurality of inputs and outputs;, wherein the inputs of the controller comprise input signals comprising the adjustable target speed signal, the rotary speed signal, and the trigger signal;, wherein the controller is operably configured to command the rotary member with electronic communication of a first command signal in response to a function comprising a first function of the input signals; further comprising a mode circuit electronically operable to communicate a mode signal, and

a safety circuit electronically operable to communicate a safety signal, wherein the safety signal is operable to prevent kinetic energy from being imparted from the rotary member;

wherein the inputs of the controller further comprise an input signal comprising the safety signal, wherein the controller is configured to respond to a safety signal by commanding the prevention of the impartation of kinetic energy from the rotary member.

12. A control module for a hand tool powered by DC power having a rotary member;, comprising:

a target speed adjustment circuit operable to electronically communicate an adjustable target speed signal, wherein said adjustable target speed signal represents a target speed for the rotary member and that is representative of user target speed input;

a speed sensor circuit operable to electronically communicate a rotary speed signal, wherein said rotary speed signal represents a rotary speed of the rotary member, wherein said rotary speed is determined by a sensor;

a trigger circuit electronically operable to communicate a trigger signal, wherein said trigger signal represents engagement of a trigger by a user; and

controller having a plurality of inputs and outputs;, wherein the inputs of the controller comprise input signals comprising the adjustable target speed signal, the rotary speed signal, and the trigger signal;, wherein the controller is operably configured to command the rotary member with electronic communication of a first command signal in response to a function comprising a first function of the input signals; further comprising and

a safety circuit electronically operable to communicate a safety signal, wherein said safety signal is operable to allow kinetic energy to be imparted from the rotary member;

wherein the inputs of the controller further comprise an input signal comprising the safety signal, wherein the controller is configured to respond to a safety signal by allowing the impartation of kinetic energy from the rotary member.

13. The control module ofclaim 12, further comprising:

a mechanical safety control for receiving a safety input for detecting one or more safety conditions; and

a safety thin film switch in physical communication with the mechanical safety control and in electrical communication with the controller.

14. The control module ofclaim 13, wherein the mechanical safety control is responsive to pressure on a safety sensor.

15. The control module ofclaim 12, wherein the safety signal has a limited temporal duration, wherein said temporal duration is preset at a safety time-out value, wherein the safety signal ceases at the expiration of the temporal duration at the safety time-out value.

16. A control module for a hand tool powered by DC power having a rotary member;, comprising:

a target speed adjustment circuit operable to electronically communicate an adjustable target speed signal, wherein said adjustable target speed signal represents a target speed for the rotary member and that is representative of user target speed input;

a speed sensor circuit operable to electronically communicate a rotary speed signal, wherein said rotary speed signal represents a rotary speed of the rotary member, wherein said rotary speed is determined by a sensor;

a trigger circuit electronically operable to communicate a trigger signal, wherein said trigger signal represents engagement of a trigger by a user; and

a controller having a plurality of inputs and outputs;, wherein the inputs of the controller comprise input signals comprising the adjustable target speed signal, the rotary speed signal, and the trigger signal;, wherein the controller is operably configured to command the rotary member with electronic communication of a first command signal in response to a function comprising a first function of the input signals;, wherein the controller is responsive to one or more enabling conditions, wherein the controller is operable to command the impartation of kinetic energy from the rotary member in the presence of said one or more enabling conditions.

17. The control module ofclaim 16, wherein said one or more enabling conditions comprise:

a trigger signal;

a safety signal; and

a rotary speed signal, wherein said rotary speed signal is approximately equal to a target speed signal.

18. The control module ofclaim 16, wherein the controller is operable to prevent the impartation of kinetic energy from the rotary member in the absence of one or more enabling conditions.

19. A control module for a hand tool powered by DC power having a rotary member;, comprising:

a target speed adjustment circuit operable to electronically communicate an adjustable target speed signal, wherein said adjustable target speed signal represents a target speed for the rotary member and that is representative of user target speed input;

a speed sensor circuit operable to electronically communicate a rotary speed signal, wherein said rotary speed signal represents a rotary speed of the rotary member, wherein said rotary speed is determined by a sensor;

a trigger circuit electronically operable to communicate a trigger signal, wherein said trigger signal represents engagement of a trigger by a user; and

a controller having a plurality of inputs and outputs;, wherein the inputs of the controller comprise input signals comprising the adjustable target speed signal, the rotary speed signal, and the trigger signal;, wherein the controller is operably configured to command the rotary member with electronic communication of a first command signal in response to a function comprising a first function of the input signals;

wherein said rotary member further comprises a ring magnet comprising a plurality of radially arrayed pairs of magnetic poles and wherein the rotational speed of said rotary member is directly sensed by a transducer sensing alternating north and south magnetic fields during rotation of said rotary member.

20. The control module ofclaim 3, wherein said clutch mechanism comprises a conical clutch plate having a conical friction surface and wherein said rotary member comprises a conical cavity for receiving said conical friction surface upon engagement of the clutch mechanism.

21. The control module ofclaim 20, wherein said control module for a hand tool comprises a control module for a hand held fastener driving tool.

22. The control module ofclaim 21, wherein said adjustable target speed signal comprises a preset target speed range within which a user may adjust said target speed of said rotary member to compensate for at least one of variations in a workpiece and u desired depth of fastener insertion.

23. A control module for a hand tool powered by DC power having a rotary member;, comprising:

a target speed adjustment circuit operable to electronically communicate an adjustable target speed signal, wherein said adjustable target speed signal represents a target speed for the rotary member and that is representative of user target speed input;

a speed sensor circuit operable to electronically communicate a rotary speed signal, wherein said rotary speed signal represents a rotary speed of the rotary member, wherein said rotary speed is determined by a sensor;

a trigger circuit electronically operable to communicate a trigger signal, wherein said trigger signal represents engagement of a trigger by a user; and

a controller having a plurality of inputs and outputs, wherein the inputs of the controller comprise input signals comprising the adjustable target speed signal, the rotary speed signal, and the trigger signal;, wherein the controller is operably configured to command the rotary member with electronic communication of a first command signal in response to a function comprising a first function of the input signals;

wherein said target speed of said rotary member is independent of user displacement of said trigger.

24. The control module ofclaim 20, wherein said driving mechanism comprises a linearly moving fastener driver for driving a fastener into a workpiece.

25. A control module for a hand held fastener driving tool powered by DC power having a rotary member;, comprising:

a target speed adjustment circuit operable to electronically communicate an adjustable target speed signal, wherein said adjustable target speed signal represents a target speed for the rotary member and that is representative of user target speed input;

a speed sensor circuit operable to electronically communicate a rotary speed signal, wherein said rotary speed signal represents a rotary speed of the rotary member, wherein said rotary speed is determined by a sensor;

a trigger circuit electronically operable to communicate a trigger signal, wherein said trigger signal represents engagement of a trigger by a user; and

a controller having a plurality of inputs and outputs;, wherein the inputs of the controller comprise input signals comprising the adjustable target speed signal, the rotary speed signal, and the trigger signal;, wherein the controller is operably configured to command the rotary member with electronic communication of a first command signal in response to a function comprising a first function of the input signals;, wherein said controller is operably configured to command a clutch mechanism with electronic communication of a second command signal in response to a function comprising a second function of the input signals, and wherein the clutch mechanism is operable to mechanically impart kinetic energy of the rotary member to a driving mechanism.

26. The control module ofclaim 25, wherein said clutch mechanism comprises a conical clutch plate having a conical friction surface and wherein said rotary member comprises a conical cavity for receiving said conical friction surface upon engagement of the clutch mechanism.

27. The control module ofclaim 26, wherein said rotary member further comprises a ring magnet comprising a plurality of radially arrayed pairs of magnetic poles and wherein the rotational speed of said rotary member is directly sensed by a transducer sensing alternating north and south magnetic fields during rotation of said rotary member.

28. A hand tool, comprising:

a rotary inertial member;

an electric motor coupled to turn the rotary inertial member;

a magazine containing a plurality of fasteners;

a reciprocating driven mechanism positioned to sequentially drive one of the plurality of fasteners into a workpiece;

an energy transfer mechanism responsive to an engagement signal to couple the rotary inertial member to the reciprocating driven mechanism; and

a controller operatively configured to sense a parameter representative of rotational speed of the rotary inertial member, to command the electric motor to accelerate the rotary inertial member to a target speed in response to a user input, wherein the target speed is representative of an adjustable user-defined target speed input, and to generate an engagement signal in response to a determination of a firing condition.

29. The hand tool of claim 28, wherein the user input comprises a continuous mode selection.

30. The hand tool of claim 28, wherein the controller is further operatively configured to sense a time out condition and to cease commanding the electric motor to accelerate the rotary inertial member to the target speed.

31. The hand tool of claim 28, wherein the firing condition comprises satisfying a trigger fire mode.

32. The hand tool of claim 28, wherein the firing condition comprises satisfying a bottom fire mode.

33. The hand tool of claim 28, further comprising a portable electrical power source to power the controller and the electric motor.

34. The hand tool of claim 33, wherein the portable electrical power source comprises a battery.

35. The hand tool of claim 28, wherein the controller is further operatively configured to sense the parameter representative of the rotational speed decreasing to a second target speed lower and to then cease commanding the engagement signal to disengage the energy transfer mechanism.

36. The hand tool of claim 28, further comprising a feedback circuit responsive to rotation of the motor operable to provide the parameter representative of the rotational speed of the rotary inertial member.

37. The hand tool of claim 28, further comprising a sensor coupled to the rotary inertial member to produce the parameter representative of the rotational speed.

38. The hand tool of claim 28, wherein the controller is further operably configured to access a mode setting selected from a group consisting of a continuous mode and an intermittent mode, and, in response to the user input comprising a user dispense command, to initiate acceleration of the rotary inertial member toward and maintaining the target speed when the accessed mode setting is continuous mode, and to initiate acceleration of the rotary inertial member toward the target speed when the accessed mode setting is intermittent mode.

39. The hand tool of claim 28, wherein the energy transfer mechanism comprises a movable member positioned to selectively contact the rotary inertial member, the reciprocating driven mechanism tangentially coupled to an engaged combination of the rotary inertial member and the movable member.

40. The hand tool of claim 28, wherein the energy transfer mechanism is responsive to the engagement signal to couple an adjacent lateral face of the rotary inertial member to the reciprocating driven mechanism.

41. The hand tool of claim 28, wherein the energy transfer mechanism is responsive to the engagement signal to mechanically couple the rotary inertial member to the reciprocating driven mechanism, wherein the hand tool further comprises a battery providing electrical power to the electric motor and the controller.

42. A hand tool, comprising:

a rotary inertial member;

an electric motor coupled to turn the rotary inertial member;

a magazine containing a plurality of fasteners;

a reciprocating driven mechanism positioned to sequentially drive one of the plurality of fasteners into a workpiece;

an energy transfer mechanism responsive to an engagement signal to couple the rotary inertial member to the reciprocating driven mechanism; and

a controller operatively configured to sense a parameter representative of rotational speed of the rotary inertial member, to command the electric motor to accelerate the rotary inertial member to a target speed in response to a user input, and to generate an engagement signal in response to a determination of a firing condition, wherein the controller is further operatively configured to respond to the firing condition which comprises a trigger signal, a safety signal, and the parameter representative of the rotational speed being approximately equal to the target speed.

43. A hand tool, comprising:

a rotary inertial member;

an electric motor coupled to turn the rotary inertial member;

a magazine containing a plurality of fasteners;

a reciprocating driven mechanism positioned to sequentially drive one of the plurality of fasteners into a workpiece;

an energy transfer mechanism responsive to an engagement signal to couple the rotary inertial member to the reciprocating driven mechanism; and

a controller operatively configured to sense a parameter representative of rotational speed of the rotary inertial member, to command the electric motor to accelerate the rotary inertial member to a target speed in response to a user input, and to generate an engagement signal in response to a determination of a firing condition, wherein the user input comprises a user dispense command, wherein the controller is further operably configured to sense and time a held safety signal, to sense a trigger signal, and to determine the user dispense command when the held safety signal precedes and is simultaneous with the trigger signal so long as the held safety signal precedes the trigger signal by no more than a valid trigger time-out value.

44. The control module of claim 3, wherein the controller is a microprocessor.

45. The control module of claim 3, further comprising a battery.

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