US 20030228833 A1
There is provided with a power tool a housing having a motor mounted therein for driving a work element mounted below the bottom of the housing for working on a workpiece. The power tool has first and second handles extending from opposite sides thereof, with at least one handle having either or both an enlarged portion and an enhanced gripping portion to facilitate control over the tool. The gripping portion may have an enhanced texture surface, such as an elastomer surface, for an operator to grip the tool. In another form, the power tool may include a switch movable between a first position wherein the power tool is in active state and a second position wherein the power tool is in a de-active state. A lock may be connected to the power tool and movable between a release position wherein the switch is freely movable between its first and second positions and a lock position wherein the switch is locked in the second position so that the power tool can remain in the active state without assistance from an operator. The power tool may also include a recess for retaining an accessory to be used in connection therewith.
1. A power tool for working on a workpiece comprising:
a housing having front, rear and first and second side portions and top and bottom portions;
a motor mounted in the housing;
a work element for working on a workpiece being mounted below the bottom of the housing and being driven by the motor;
a first handle being connected to the housing, extending from the rear portion of the housing and having a first gripping portion;
a second handle being connected to the housing, extending from the front portion of the housing and have a second gripping portion; and
one or both of the first and second gripping portions having an enhanced texture surface for an operator to grip the tool.
2. A power tool according to
3. A power tool according to
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6. A power tool according to
7. A power tool according to
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9. A power tool according to
a switch positioned adjacent the first handle and electrically connected to the motor, wherein the switch is movable between a first position wherein the power tool is in active state and a second position wherein the power tool is in a de-active state; and
a lock connected to the power tool and movable between a release position wherein the switch is freely movable between its first and second positions and a lock position wherein the switch is locked in the second position so that the power tool can remain in the active state without assistance from an operator.
10. A power tool according to
11. A power tool according to
12. A power tool according to
13. A power tool according to
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15. A power tool according to
16. An electrically-powered polisher having a pad and a motor to drive the pad, the polisher comprising:
a housing for containing a motor to drive a pad located below the housing; and
a handle connected to the housing defining a recess for retaining an accessory to be used in conjunction with the polisher.
17. An electrically-powered polisher according to
 In FIGS. 1-8, there is illustrated a power tool 20 embodying features of the present invention for working (e.g., waxing, buffing, polishing, etc.) on a workpiece. The power tool 20 includes a housing 22, first and second handles 24 and 26, respectively, connected to the housing 22, and a work element, such as a pad 28, for working on a desired workpiece, such as the body of an automobile or hull of a boat. The power tool 20 includes a symmetrical design about a vertical reference plane (not shown) extending centrally from the forward end of the tool 20 a to a rearward end 20 b (see FIGS. 3 and 4). The cross-section illustrated in FIG. 7 is taken along the vertical reference plane.
 In a preferred embodiment, the tool 20 has a clamshell design with a first clamshell member 20 c and a second clamshell member 20 d which, when connected to each other, define a parting line 20 e which extends in the vertical reference plane about which the tool 20 is generally symmetrical, as shown in FIGS. 4 and 6. As further illustrated in FIG. 6, the clamshell members 20 c and 20 d are secured together by a number of screws 21 which are recessed into bores defined by second clamshell member 20 d and thread into internally threaded bores or post members 21 a defined by first clamshell member 20 c. The clamshell members 20 c and 20 d can be made of any suitably lightweight material and, in a preferred embodiment, are molded plastic parts.
 As illustrated in FIGS. 1-4, the housing 22 is generally cylindrical in shape and includes a front portion 22 a, rear portion 22 b, top portion 22 c, bottom portion 22 d (FIG. 7), and first and second side portions 22 e-f, respectively. Collectively the housing portions 22 a-f define an internal cavity 30 within which at least a portion of motor 32 is disposed (see FIG. 7). The first handle 24 extends from the upper rear portion 22 b of housing 22 and the second handle 26 extends from the upper front portion 22 a of housing 22. In addition, the bottom portion 22 d of housing 22 is generally flat and the upper portion 22 c forms a slightly convex arcuate surface. Furthermore, the edges of the housing 20 are generally arcuate to facilitate a generally smooth transition from one housing portion to another. For example, the edge between rear portion 22 b and bottom portion 22 d is rounded as illustrated in FIG. 7.
 The upper portion 22 c of housing 22 also includes a raised arcuate rim or wall portion 22 g near the rear of the housing which defines a vent or passage to the cavity 30, such as the elongated slot opening 22 h illustrated in FIG. 1. The wall portion 22 g curves along the periphery of the top surface 22 c so that it remains flush with the rear housing portion 22 b (see FIG. 3) and has gusset members 22 i and 22 j extending forward from the ends of the wall portion 22 g. In a preferred embodiment, the gusset members 22 i and 22 j each have two parallel gusset walls which taper downward to the top surface 22 c of housing 22 as they extend toward the front 20 a of the tool 20.
 As mentioned above, and illustrated in FIGS. 6, 7 and 8, the housing portions 22 a-f define a cavity within which motor 32 is disposed. The motor 32 is secured to the housing 22 using a mounting plate 34 and is supported and/or aligned laterally by ribs 22 k which extend from the inner surface of at least one of the housing portions 22 a-g. As illustrated, several of the ribs 22 k include an arcuate edge that compliments the body of the motor 32. The mounting plate 34 includes a generally flat and rectangular plate structure 34 a having a circular upstanding wall 34 b, a centrally located hub portion 34 c (FIG. 7) and tabs 34 d and 34 e which extend outward from opposing side portions of the plate 34 a.
 The circular wall 34 b of mounting plate 34 extends upward from the plate structure 34 a and forms an annular wall about a fan (not shown) which is positioned therein and driven by the motor shaft 32 a in order to circulate air through, and cool, the motor 32. The annular wall 34 b includes notches 34 f to assist in the circulation of air through the tool 20. For example, in the embodiment illustrated in FIGS. 6 and 7, the motor 32 rests on the upper edge of the circular wall 34 b and rotates the fan located therein in order to draw air through the vent 22 h located in upper housing portion 22 c, down through holes in the top of the motor 32, out the notches 34 f of the mounting plate 34, and eventually out of the cavity 30 via passages 22 n located in the lower half of first and second side portions 22 e and 22 f (see FIGS. 1-3). The circulation of air cools the motor 32 during operation, which aids in preventing the overheating of motor 32.
 The hub portion 34 c of mounting plate 34 extends upward and downward from the center of the plate structure 34 a and defines a bore through which the motor shaft 32 a is disposed and a socket within which bearing 36 is nested. As illustrated in FIG. 8, the motor output shaft 32 a passes through the bearing 36 and bore of the hub portion 34 c. The bearing 36 assists the motor in operating more efficiently by aligning and guiding the rotational operation of the output shaft 32 a and reducing the frictional forces encountered thereby. As will be discussed in further detail below, a portion of the hub 34 c extending below the plate structure 34 a helps to align the motor 32 with the bottom 22 d of housing 22 and helps mount the plate 34 within cavity 30.
 The tabs 34 d and 34 e of mounting plate 34 define bores into which elongate screws or bolts (not shown) are thread in order to mount and secure the motor 32 to the mounting plate 34. More particularly, the threaded bolts are fed through tab structures 32 b and 32 c (see FIGS. 6-7), which are located adjacent the top of the motor 32 and aligned with the mounting plate tabs 34 d and 34 e, and are thread into the mounting plate tabs 34 d-e. In the embodiment illustrated in FIG. 7, the motor tab structures 32 b and 32 c have recessed portions into which the bolt heads are nested, and the mounting plate tabs 34 d and 34 e have recessed portions into which nuts are nested. Preferably, the recesses of the mounting plate tabs 34 d and 34 e will be complimentary in shape to the nuts in order to prevent the nuts from rotating while nested therein to assist in tightening the elongate bolts.
 The motor 32 and mounting plate 34 are secured to the housing 22 by sliding at least a portion of the mounting plate 34 into a slot defined by the inner surface of at least one of the housing portions 22 a-g. As illustrated in FIG. 6, and in a preferred embodiment, the corners of plate structure 34 a are inserted into slots 22 m defined by the lower most rib 22 k extending from the inner surfaces of first and second side portions 22 e-f and the inner surface of bottom portion 22 d. The bottom portion 22 d further defines a circular opening within which the portion of hub 34 c extending down below the plate structure 34 a is disposed. Thus, this portion of hub 34 c and the opening in the bottom portion 22 d help align and maintain the motor 32 and mounting plate 34 in their desired location within the cavity 30 of the housing 22. In addition, the slot and insert configuration between the housing 22 and the mounting plate 34 help prevent the motor 32 from rotating once in position so that maximum torque may be supplied to a work element, such as pad 28. In alternate embodiments, the plate structure 34 a and bottom portion 22 d may have additional openings aligned with one another for assisting in the circulation of air over the motor 32.
 Extending downward below the housing 22 is an arcuate shield or skirt member 40, which forms an annular wall about the exposed end of the motor shaft 32 a and at least a portion of counterweight 38 (see FIG. 8). The shield 40 is connected to the lower portion 22 d of housing 22 and, in a preferred embodiment, is made integral therewith.
 The motor 32 is mechanically connected to the pad assembly 28 to drive it in an orbital path below the housing 22. More particularly, the motor output shaft 32 a extends through the bottom portion 22 d of housing 22 and is threaded into a first threaded bore 38 a defined by the counterweight 38. As illustrated in FIGS. 6-8, the counterweight 38 is connected to the pad assembly 28 by a bolt, such as left handed bolt 42, which threads into a second threaded bore 38 b in the counterweight 38. The second counterweight bore 38 b is parallel to, and located generally adjacent to, the first counterweight bore 38 a. Thus, rotation of the output shaft 32 a results in a corresponding rotation in the counterweight 38 and the pad assembly 28 connected thereto.
 As further illustrated in FIGS. 6-8, the pad assembly 28 preferably consists of a pad support 44, a first pad 28 a, a second pad 28 b, and a third pad 28 c. The pads 28 a-c are overlaid and connected to one another and to the pad support 44 by an adhesive (not shown) and, preferably, include a closed polyethylene pad, an ether foam pad, and a closed micro-cell polyethylene pad, respectively. The preferred pads 28 a-c have a thickness of ¼″, ⅝″ and ⅛″ respectively. In alternate embodiments, however, various types and sizes of pads may be used. For example, varying combinations of the above mentioned pads may be used in either a two pad configuration or in a single pad configuration, rather than a three pad coil figuration.
 The pad support 44 has a generally planar disc portion 44 a supporting a circular hub portion 44 b extending upward from the center of the disc and an annular wall 44 c extending upward from the disc portion 44 a intermediate the edge of the disc portion 44 a and hub portion 44 b. A plurality of gusset members extend along the sides of the hub portion 44 b down to the disc portion 44 a (see FIG. 6). As mentioned above, the annular wall 44 c is positioned intermediate the outer perimeter of the disc 44 a and the hub portion 44 b and is preferably located about two-thirds of the radial distance from the center of the disc 44 a toward the perimeter of the disc 44 a. Thus, the counterweight 38 rotates within the annular wall 44 c of the pad support 44, and the annular wall 44 c remains under cover of the shield 40. With such a configuration, the skirt member 40 and the annular wall 44 c of the pad support 44 combine to prevent, or at least hinder, direct access to the counterweight 38.
 The hub portion 44 b of pad support 44 defines a hollow center region that houses bearings 46 a-b and spacer 48. The bolt 42 extends through the central openings in the bearings 46 a-b and the spacer 48 and is threaded into the second bore 38 b of the counterweight 38. The first pad 28 a, the second pad 28 b and the third pad 28 c also have central openings or passageways through which the bolt 42 passes in order to be threaded into the counterweight 38. The end of bolt 42 includes an enlarged head to secure the pad support 44, bearings 46 a-b and spacer 48, to the tool 20. During operation, the pad assembly 28 will orbitally rotate about the z-axis of the tool (defined by output shaft 32 a) when the motor 32 drives the shaft 32 a and the counterweight 38.
 For maintenance purposes, at least one small opening or notch 44 d may be defined by the annular wall 44 c of the pad support 44 so that a hand tool or other instrument can be inserted into the interior region between the pad support 44 and the skirt member 40 to prevent the counterweight 38 from rotating while the bolt 42 is being unscrewed and removed film the counterweight 38. This enables the pad assembly 28 to be removed from the tool 20 for access to the counterweight 38 and other internal components (e.g., the motor shaft 32 a, bearing 46 a, etc.). Such access may be required to repair or replace parts, including the counterweight 38 and pad assembly 28 or those parts internal thereto.
 The counterweight 38 includes a first horizontal portion 38 c, which defines bores 38 a and 38 b of the counterweight 38. More particularly, the first horizontal portion 38 c is generally rectangular in shape and cross-section and has bores 38 a-b disposed therein between first and second ends of the structure. The first bore 38 a is internally threaded for receiving the motor output shaft 32 a and has a sleeve or collar extending upward from the top surface of the horizontal portion 38 c in order to increase the length of the bore 38 a. The second bore 38 b is internally threaded for receiving the bolt 42 connecting the pad assembly 28 to the tool 20 and has a sleeve or collar extending downward from the bottom surface of the horizontal portion 38 c in order to increase the length of the bore 38 b. The lengthened bores 38 a and 38 b increase the amount of the shaft 32 a and bolt 42 disposed therein, which subsequently strengthens the mechanical connection made between the counterweight 38 and shaft 32 a and between counterweight 38 and bolt 42.
 A second horizontal portion 38 e is connected to the first horizontal portion 38 c via a generally vertical interconnecting portion 38 d. More particularly, the interconnecting portion 38 d connects the second horizontal portion 38 e such that it is generally parallel to the first horizontal portion 38 c. Collectively, the connecting portion 38 d and second horizontal portion 38 e form a generally L shaped structure having a central opening 38 f (FIG. 6) that generally divides the connecting portion 38 d and second horizontal portion 38 e into two parallel legs which allows for a desired reduction in counterweight mass.
 A first end member 38 g extends from the second horizontal portion 38 e on the end opposite the interconnecting portion 38 d. The first end member 38 g is arcuately shaped about the end of the second horizontal portion 38 e, with the end of the second horizontal portion 38 e being connected to the inner curved surface of the end member 38 g and the end member 38 g having a generally rectangular cross-section at any given point there along. The radius of curvature of the end portion 38 g preferably corresponds to that of the annular wall 44 c of pad support 44 so that the end member 38 g can rotate within the annular wall 44 c without interference by the wall 44 c.
 A second end member 38 h is connected to the first horizontal portion 38 c on the side opposite the interconnecting member 38 d. Thus, the first and second end members 38 g and 38 h are located on opposite sides of the counterweight 38. The second end member 38 h is generally rectangular in shape and is generally centered off of the end of the first horizontal portion 38 c. This configuration allows the counterweight 38 to be made out of less material, but yet supply a sufficient amount of revolutions per minute (RPMs) to orbit the pad assembly 28 as desired.
 As illustrated in FIGS. 1 and 3-6, the first handle 24 includes a pair of elongated members 24 a and 24 b which project outward from the rear portion 22 d of the housing 22 near the top thereof. This shape provides an operator with a plurality of locations to facilitate an effective grip to maintain control over the tool 20. More particularly, the first and second side members 24 a and 24 b connect along the parting line 20 e to form the handle 24. The side portions 24 a and 24 b are secured together by screws 21 or other fasteners which are inserted into recessed bores located in the right side portion 24 b of handle 24. The first handle 24 has a longitudinal axis that is generally perpendicular to the z-axis and within the vertical reference plane discussed above. In a preferred embodiment, the handle 24 has a generally oval-shaped cross-section at any given point and a distal end 24 c which is enlarged with respect to the remainder of the handle 24. In addition, the upper surface of the handle 24 d is generally flat compared to the remainder of the contour, which, as shown by the lower surface 24 e is generally arcuate to provide an operator with a more comfortable grip and to account for the differing hand sizes of operators.
 The enlarged end 24 c allows the operator to “feel” the end of the handle without the need to visually locate it. This allows the operator to focus more on the workpiece rather than requiring the operator to break visual contact with the workpiece to determine the location of the end of the handle 24. For example, the enlarged end 24 c provides the handle with a structural end stop for an operator to feel. Furthermore, the enlarged end 24 c can also assist an operator in drawing the tool 20 backward when working on a workpiece.
 Internally, the first and second side portions 24 a-b of handle 24 include a plurality of ribs 24 f which both strengthen the handle 24 and support the recesses and threaded posts into which screws 21 are inserted and thread. Furthermore, the handle 24 and the rear portion 22 b of housing 22 define a socket within which actuator 50 is disposed. In the embodiment illustrated in FIGS. 6 and 7, the actuator 50 includes a trigger member 52, which is generally rectangular in shape and cross-section and has a generally hollow interior.
 The trigger 52 has an inward concave lower surface 52 a which is to be engaged for actuation by at least one of an operator's fingers. Located on opposite side walls of the trigger 52 are gudgeons 52 b (FIG. 6) which are inserted into complimentary bores defined by posts 22 p extending inward from the inner surfaces of the clamshell members 20 c and 20 d of tool 20. Thus, the trigger 52 is able to pivot about the axis defined by the gudgeons 52 b. Furthermore, located within the trigger 52 is a pedestal 52 c having a recessed upper surface within which an end of spring 54 is nested. The pedestal 52 c further includes a centrally located post 52 d which extends upward from the center region of the recessed upper surface of pedestal 52 c and is used to actuate pushbutton 56. More particularly, the other end of spring 54 is positioned over the button of pushbutton switch 56 like a sleeve. The pushbutton switch is mounted in the first handle 24 above the end of the trigger 52 having post member 52 d, with the spring 54 biasing the trigger 52 (and post 52 d) out of engagement with the switch 56. In the embodiment illustrated, switch 56 consists of a pushbutton switch which is a push on-push off type switch, such as pushbutton switch model No. J188B manufactured by Judco Manufacturing Inc. of Harbor City, Calif. The switch 56 regulates power supplied to the motor 32 and is movable between an active position, or “on” state, to allow power to the motor 32 and a de-active position, or “off” state, to prohibit power to the motor 32.
 The switch 56 is actuated between active and de-active positions via the post 52 d of trigger 52. More particularly, when the trigger 52 is squeezed by the operator, it pivots about the axis defined by the gudgeons 52 b. This drives the post 52 d towards the pushbutton 56 and compresses the spring 54 between the body of the pushbutton 56 and the pedestal 52 c. As a result, the post 52 d is pressed into contact with the pushbutton 56. Thus, the operator may activate or deactivate the tool 20 by pivoting or squeezing the trigger 52. Once released, the spring 54 returns the trigger 52 to its biased position out of engagement with the switch 56.
 In alternate embodiments, however, other types of actuators 50, with alternate features, may be used. For example, the actuator 50 may include a momentary on switch and/or a locking momentary on switch which can be temporarily locked in the “on” position. In one embodiment, a locking momentary on pushbutton, such as pushbutton switch HELI KP-D1 manufactured by Changzhou Create Electric Appliance Co. Ltd. of Changzhou, China, may be used. To accommodate such an actuator, one of the side portions 24 a-b of first handle 24 may define an opening, such as aperture 24 g illustrated in FIGS. 1 and 3-4, through a lock member is disposed for selectively locking the momentary on switch into the “on” position. In a preferred embodiment, the operator may lock the actuator into the “on” position by pivoting the trigger 52 into the “on” position, depressing a locking pushbutton disposed in aperture 24 g to lock the trigger in the “on” position, and releasing the trigger 52. The locking pushbutton prevents the trigger 52 from being fully returned to its biased “off” position, thereby temporarily locking the actuator 50 in the “on” state. The tool 20 may then be deactivated by pivoting (or squeezing) the trigger again toward the “on” position until the spring activated lock pushbutton disengages the trigger so that the trigger may be returned to its biased “off” position. In yet other embodiments, other actuators and actuator features may be incorporated into the tool 20 as are known in the art.
 As illustrated in FIGS. 6 and 7, the rear portion 24 c of handle 24 includes a power cord 58 for supplying power to the tool 20 (i.e., for supplying power to the apparatus from a power supply external to the power tool). Preferably, the power cord 58 has two conductive and shielded wires 58 a and 58 b and an outer insulator jacket 58 c (e.g., a double insulation wiring configuration). The rear handle portion 24 c made up of side portions 24 a and 24 b includes two semi-circular notches 60 located on each side portion 24 a-b which cooperate to form a strain relief 61 for the power cord 58. More particularly, the notches 60 form a rounded collar about a flange portion 58 d of the insulator jacket 58 c (see FIG. 7). This helps to prevent the power cord 58 from being separated from the handle 24 and power tool 20. The preferred strain relief 61 also includes a clamp mechanism, such as block 60 c, which has a curved bottom surface and bores located on opposite ends. The power cord 58 rests ill a curved cradle 60 d and the block 60 c is fastened down over the power cord 58 via screws 60 e to clamp the power cord 58 in the cradle 60 d, with the curved surface of the block 60 c engaging and compressing the outer jacket 58 c in order to provide additional strain relief for the power cord 58.
 One end of the power cord 58 includes an electrical connector, such as male plug member 58 e, which can be connected to various types of power supplies, either directly or via an extension cord (not shown). On the other end of the power cord 58, wire 58 a is connected to electronic circuitry located within the tool 20, such as a terminal of full wave rectifier 62, which is fastened to the inner surface of clamshell member 20 c via screw 62 a. The other wire, wire 58 b, is connected to a terminal of the pushbutton switch 56. A second terminal of the pushbutton 56 is electrically connected by a wire to a second terminal on the rectifier 62, and additional wiring electrically connects third and fourth terminals on the rectifier 62 to first and second terminals on motor 32 in order to complete the electrical circuit between the power supply, rectifier 62, motor 32 and actuator 50. Thus, when the tool 20 is connected to a power supply and actuator 50 is placed into the “on” position, power will be supplied to the motor 32 in order to drive the work element 28 connected to the tool 20. When the actuator 50 is placed into the “off” position, no power will be supplied to the motor 32, and the apparatus 20 will remain in an inoperative or de-active state.
 In the alternate embodiment discussed above using the HELI KP-D1 switch, both wires 58 a-b may be connected to input terminals of the switch and output wires from the switch may be connected to the rectifier 62. Additional wires from the rectifier would then be electrically connected to the motor 32 in order to complete the electrical circuit between the power supply, rectifier 62, motor 32 and actuator 50. Thus allowing the tool 20 to be operated with a momentary on pushbutton switch rather than a push on-push off type switch. As mentioned above, it should be understood that alternate actuators and wiring schemes may be used in order to operate the power tool 20.
 As illustrated in FIGS. 1-7, the second handle 26 has a generally block-shaped configuration which projects outward from the front portion 22 a of the housing 22 near the top thereof in order to provide the operator with a forward handle to facilitate an effective grip to help maintain control over the tool 20. More particularly, the first and second side portion is 26 a and 26 b (see FIG. 6) connect along the parting line 20 e to form the second handle 26. The side portions 26 a-b are secured together by at least one of the screws 21 connecting the clamshell members 20 c-d, which again are inserted into recessed bores located in the right side portion 26 b of handle 26 and thread into threaded post members extending from the left side portion 26 a of handle 26. The second handle 26 has a longitudinal axis that is generally perpendicular to both the z-axis and the longitudinal axis of the first handle 24. In a preferred embodiment, the handle 24 has a generally rectangular cross-section and a distal end portion 26 c which is enlarged with respect to the remainder of the handle 26. In addition, the upper surface of the handle 26 d is generally flat or planer (see FIGS. 3 and 7) while the lower surface 26 e is convexly curved to provide an operator with a more comfortable grip. The second handle 26 is wider and shorter than the first handle 24 and is most often gripped with an operator's palm and/or fingers wrapped around the front or distal end portion 26 c of the handle 26 rather than around the sides of the handle, as is the case with respect to the rear handle 24.
 In addition, the enlarged end portion 26 c of handle 26 is wider and thicker than the remainder of handle, which provides the operator with more surface area to grip the tool 20. Thus, the enlarged end 26 c helps facilitate a stronger grip and control over the tool 20. Furthermore, the enlarged end 26 c can also assist the operator in directing the tool 20 forward and backwards, as well as side-to-side, when working on a workpiece. Like the first handle 24, the interior of the first and second side portions 26 a and 26 b of handle 26 include a plurality of ribs 26 f, which both strengthen the handle 26 and support the recesses and threaded posts into which at least one of the screws 21 is thread.
 As illustrated in FIGS. 1-6, both the first and second handles 24 and 26 have outer elastomer surfaced grips 64 to facilitate enhanced gripping for control over the tool 20. In a preferred embodiment, the elastomer grips 64 are provided on the upper surfaces 24 d and 26 d of handles 24 and 26 to facilitate enhanced gripping control over the power tool 20. The elastomer grip is preferably added by way of an injection overmolding process. More particularly, the handles 24 and 26 are preferably formed by a plastic injection molding process, which is later followed by injection of a grip layer material to form grip 64. A preferred material for the elastomer grip 64 is an elastomer/plastic blend, such as, for example, SANTOPRENE, which is a product of Advanced Elastomer Systems, L.P. of Akron, Ohio. The overmolded grip may be formed with a smooth outer surface or with a textured outer surface and provides a non-slip rubber (or rubber-like) gripping surface for the operator's hand to grasp. Preferably, the operator will grip the top surface 24 d of the first handle 24 with his or her palm and wrap his or her thumb off to one side of the handle 24 and fingers off to the other side of the handle 24. In contrast, the operator will preferably grip the top surface 26 d of the second handle 26 with his or her palm and wrap his or her fingers around the forward end 26 c of the handle 26, leaving his or her thumb off to the side of the handle 26. In alternate embodiments, additional portions of the handles 24 and 26 (or the entire surface of the handles) may be covered with an elastomer overmolding. For example, an overmolded grip portion may be included on the lower surface 24 e of first handle 24. Furthermore, in yet other embodiments, only one of the handles 24 or 26 may include the elastomer grip 64.
 It should be understood that other materials may be used for the overmolding portions. For example, other thermal plastic elastomers or elastomer/plastic blends, such as rubber, nylon, butyl, EPDM, poly-trans-pentenarmer, natural rubber, butadiene rubber, SBR, ethylene-vinyl acetate rubber, acrylate rubber, chlorinated polyethylene, neoprene and nitrile rubber, may also be used for the overmolded grip 64. Another material which may be used for the overmolding is HERCUPRENE, which is manufactured by the J-Von Company of Leominster, Mass.
 It should also be understood that alternate embodiments of the apparatus 20 may be provided with no elastomer overmolding whatsoever. For example, the tool 20 may be provided with a simple smooth plastic handle, or a textured plastic handle, created from a plastic injection molding process. More particularly, the overmolding may be replaced with a textured surface, such as Rawal #MT-11605, a mold texturization process provided by Mold-Tech/Rawal of Carol Stream, Ill. Similarly, other mold texturization processes may be used to create a variety of textured surfaces.
 Turning now to FIGS. 9-10, there is illustrated an alternate embodiment of tool 20 embodying features in accordance with the present invention. In this embodiment, the tool 20 includes an accessory 66, which can be stored on the tool 20 and used in conjunction therewith. For convenience, features of alternate embodiments illustrated in FIGS. 9-10 that correspond to features already discussed with respect to the embodiments of FIGS. 1-8 are identified using the same reference numeral in combination with an apostrophe (′) merely to distinguish one embodiment from the other, but otherwise such features are similar.
 More particularly, the tool in FIGS. 9-10, hereinafter 20′, includes a recess, such as elongated slot 68 defined by handle 24′, for receiving and maintaining an accessory, such as a brush like tool 66 illustrated therein. The slot 68 is preferably rectangular in shape and is deep enough to allow at least a majority of the brush 66 to be inserted therein. In the embodiment illustrated, the slot 68 is deep enough to allow the brush 66 to be fully inserted therein so that the top of the brush 66 is flush with, or recessed below, the upper handle surface 24 d′ of tool 20′. The slot 68 may also include recessed groove portions 68 a and 68 b, which provide access to a portion of the brush 66 so that the operator may more easily remove the brush 66 from slot 68. The brush 66 is preferably of a shape that corresponds in a complimentary fashion to the slot 68 and includes a grippable feature, such as a groove 66 a along its upper surface to further assist the operator in removing the brush 66 from slot 68. Extending out from the lower surface of the brush 66 are bristles 66 b which may be used to sweep up or away residual particles of the workpiece or materials used on the workpiece, such as dry wax. The brush 66 may also be provided with a releasable locking mechanism, such as resilient shoulder portions 66 c and 66 d, which may secure the brush 66 into slot 68 by filling the space created below corresponding ridge members 68 c and 68 d located in the slot 68. With such a configuration, the accessory may be moved between a locked location on the tool 20′ (see FIG. 9) and an unlocked position remote from the tool 20′ (see FIG. 10) so that the accessory may be used in conjunction therewith. In alternate embodiments, an accessory item, may be located in the second handle 26′ instead of, or in addition to, being located in the first handle 24′.
 Although certain example methods and apparatus have been described herein, the scope of coverage of this patent is not limited thereto. On the contrary, this patent covers all methods, apparatus, and articles of manufacture fairly falling within the scope of the appended claims either literally or under the doctrine of equivalents.
FIG. 1 is a perspective view of a power tool embodying features of the present invention;
FIG. 2 is a front elevational view of the power tool of FIG. 1;
FIG. 3 is a left side elevational view of the power tool of FIG. 1;
FIG. 4 is a plan view of the power tool of FIG. 1;
FIG. 5 is a bottom view of the power tool of FIG. 1;
FIG. 6 is an exploded view of the power tool of FIG. 1;
FIG. 7 is a cross-sectional view of the power tool of FIG. 1 taken along line 7-7 in FIG. 2;
FIG. 8 is a cross-sectional view of the power tool of FIG. 1 taken along line 8-8 in FIG. 3;
FIG. 9 is a partial perspective view of an alternate power tool embodying features of the present invention; and
FIG. 10 is a partial exploded view of the power tool of FIG. 9.
 This invention relates generally to a power tool and, more particularly, to an electrically-powered polisher capable of rotating a pad to polish a workpiece.
 The tool industry offers a variety of power tools for performing work on various types of workpieces. One common shortcoming, however, is that the power tools do not offer handles with enhanced gripping surfaces for an operator to use to grip the tool. For example, many power tools, such as polishers, are used outdoors in hot climates where operation of the tool often causes the operator to sweat, and possibly even involve operation of the tool in damp environments, such as, for example, near a recently washed vehicle. This often results in the operator having a difficult time in gripping and/or controlling the power tool due to a lack of enhanced gripping surfaces.
 In addition, current power tool configurations may force the operator to continually hold a trigger in the “on” position in order to actuate the power tool. This forces the operator to expend more energy while operating the tool and can result in making the operator sweat more, thereby, complicating the already difficult task of maintaining a firm grip on the power tool.
 Furthermore, the use of accessories in conjunction with the operation of the power tool may also be necessary. For example, power tools tend to leave residual particles from the workpiece or from substances used on the workpiece that could be picked up at the time of operation. It would be advantageous if the accessories were readily available or proximate to the power tool itself. This would promote maintaining a clean and obstacle free work environment.
 This application is a continuation-in-part of pending application No. 29/162,046, filed Jun. 7, 2002, which is hereby incorporated herein by reference in its entirety.