GB2493104A

GB2493104A - Power tool motor mounting

Info

Publication number: GB2493104A
Application number: GB201212916A
Authority: GB
Inventors: Sean T Kehoe; Benjamin Ludy; Troy C Thorson; Michael Naughton
Original assignee: Milwaukee Electric Tool Corp
Current assignee: Milwaukee Electric Tool Corp
Priority date: 2011-07-20
Filing date: 2012-07-20
Publication date: 2013-01-23
Anticipated expiration: 2032-07-20
Also published as: GB2493104B; GB201212916D0; DE102012212771A1

Abstract

A power tool (20 fig. 1) includes a motor 32 having a can 72 and a shaft 96 extending axially from the can 72, a gear case 40 having an inner surface that defines an opening 124, a bearing 68 positioned around a portion of the shaft 96 that extends from the can 72 and at least partially within the opening 124 in the gear case 40, and a motor mount 64 coupled to the motor 32 and having a flange 100 extending away from the motor 32, the flange 100 of the motor mount 64 and the inner surface 124 of the gear case 40 axially and laterally locating the motor 32 and the gear case 40 on the bearing 68. The motor mount 64 may be coupled to the motor 32 by shoulder pins 60 threaded into the can 72, inserted into openings 88 in the motor mount 64 and secured by setscrews (136 fig. 9) screwed into openings 140 in motor mount 64. The motor mount 64 may be secured to gear case 40 by threaded fasteners 132 passing through radially extending arms 84. Bearing 68 may be press-fit on a pinion 56 carried by shaft 96. The radially extending arms 84 may be flexed towards the gear case 40 to apply a load to bearing 68. The power tool may be a jigsaw (20 fig. 1), a rotary hammer drill (220 fig. 11) or a reciprocating saw (420 fig. 16).

Description

MOTOR MOUNT FOR A POWER TOOL

CROSS-REFERENCE 10 RELATED APPLICATIONS

[0001] This application claims priority to U.S. Provisional Patent Application No. 61/509,922, Filed July 20, 2011, the entire contents of which arc incorporated hy reference herein.

[0002] This application is also a continuation-in-part of U.S. Patent ApplicaUon No. 12/721,210, filed March 10, 2010; a continuation-in-part of U.S. Patent Application No. 13/326,525, filed December IS, 2011; and a continuation-in-part of U.S. Patent Application No. 13/435,554, filed March 30, 2012, which claims priority to U.S. Provisional Patent Application No. 61/470,620, tiled April I, 2011, the entire contents of all of which are incorporated by reference herein.

BACKGROUND

[0003] [he present invention relates to power tools and, more particularly, to motor mounts For power tools.

[0004] Power tools including mounts for connecting motors to gear boxes are known. Such mounts, however, typically do not guarantee close axial alignment or fixed axial and lateral positions of all components within the power tools. Ti proper axial alignment is not maintained, side loading of the motor shall and bearing may occur, which can lead to excessive current draw and possible mechanical Failure. Furthermore, axial misalignment or loading can occur due to improper motor locating by a motor mount. For example, the motor mount can bias the motor out of alignment with the gcar box, causing high current draw or other failures.

SUMMARY

[0005] In one embodiment, the invention provides a pow-er tool including a motor having a can and a shaft extending axially from the can, a gear case having an inner surface that defines an opening, a bearing positioned around a portion of the shaft that extends from the can and at least partially within the opening in the gear case, and a moLor mount coupled to the motor. The motor mount includes a tiange extending away from the motor. The flange of the motor mount and the inner surface of the gear case axially and laterally locate the motor and the gear case on the bearing.

[0006] In another embodiment, the invention provides a method of connecting a motor to a gear case of a power tool. The motor includes a can and a shaft thai extends axially from the can. The gear case includes an inner surface that defines an opening. The method includes providing a motor mounting system having a motor mount and a hearing. The motor mount has a flange. The method also includes coupling the motor mount to the motor such that the flange extends away from the motor, positioning the hearing around a portion of the shaft of the motor that extends from the can, inserting at least a portion of the bearing into the opening in the gear case, axially and laterally locating the gear case on the bearing with the inner surface of the gear ease, and axially and laterally locating the motor on the bearing with the flange of the motor mount.

[0007] In yet another embodiment, the invention provides a power tool including a housing and a motor positioned substantially within the housing. The motor includes a can, a shall extending axially from the can, and a pinion coupled to a portion of the shaft that extends from the can. The power tool also includes a gear case positioned substantially within the housing.

ftc gear ease includes an inner surface thai defines an opening The pow-er tool further includes a bearing positioned around the portion of the shaft that extends from the can and at least partially within the opening in the gear ease. The hearing includes an inner race that is secured to the pinion and an outer race. The power tool also includes a motor mount including a flange extending away from the motor and two radially-extending arms. The two arms are secured to the gear case. The power tool further includes two shoulder pins coupled to the can of the motor.

[he two shoulder pins extend into the motor mount to couple the motor mount to the motor. [he inner surface of the gear case directly contacts the outer race of the hearing to axially and laterally locale the gear case on the bearing. The flange of the motor mount directly contacts one of the outer race of the hearing and the inner surface of the gear case to axially and laterally locate the motor on the bearing.

[00081 Other aspects oF the invention will become apparent by consideration ol' the deLailed

description and accompanying drawings.

BRIEF DESCRIPTION OF TIlE DRAWINGS

[0009] Fig. 1 is a perspective view of ajigsaw with a housing portion removed, the jigsaw including a motor mounting system according to one embodiment of the invention.

[0010] Fig. 2 is a cross-sectional view of the motor mounting system shown in Fig. 1.

[0011] Fig. 3 is a perspective view of a motor for use with the jigsaw shown in Fig. 1.

[0012] Fig. 4 is a perspective view of the motor shown in Fig. 3 with shoulder pins attached thereto.

[0013] Fig. 5 is a perspective view of the motor shown in Fig. 4 with a motor mount attached thereto.

[0014] Fig. 6 is a perspective view of the motor mount shown in Fig. 5.

[0015] Fig. 7 is a perspective view of the motor and the motor mount shown in Fig. 5 with a hearing and a motor pin ion attached thereto.

[0016] Fig. 8 is a cross-sectional view of the motor, the motor mount, the hearing, and the motor pinion shown in Fig. 7.

[0017] Fig. 9 is a side view of the motor mounting system connected to a gear case of the jigsaw shown in Fig. 1.

[0018] Fig. ID is another side view of the motor mounting system connected to the gear case of the jigsaw shown in Fig. 1.

[0019] Fig. ii is a cross-sectional view of a rotary hammer, the rotary hammer including another embodiment of a motor mounting system.

[0020] Fig. 12 is an exploded perspective view of the motor mounting system shown in 11g. 11.

[0021] Fig. 13 is another exploded perspective view of the motor mounting system shown in Fig. 11.

[0022] Fig. 14 is a cross-sectional view of the motor mounting system shown in Fig. 11.

[0023] Fig. 15 is a cross-sectional view of another embodiment of a motor mounting system in use with the rotary hammer shown in Fig. 1 1.

[0024] Fig. lOis a cross-secLional view of a reciprocating saw, the reciprocating saw including yet another embodiment of a motor mounting system.

[0025] Fig. 17 is a cross-sectional view of the motor mounting system show-n in Fig. 16.

DETAILED DESCRIPTION

[0026] Before any embodiments of the invention are explained in detail, it is to he understood that the invention is not limited in its application to the details of construction and the arrangement of components set forth in the following description or illustrated in the following drawings. The invention is capable of other embodiments and of being practiced or olheing carried out in arios ways.

[0027] Fig. 1 illustrates a power tool 20 that includes a molor mounting system 24. Tn the illustrated embodiment, the power tool 20 is a jigsaw. In other embodiments, the power tool 20 may he, for example, a reciprocating saw, a handsaw, a circular saw, a drill, a rotary hammer, a screwdriver, a disc sander, or the like.

[0028] The illustrated jigsaw 20 includes a housing 28, a motor 32 positioned substantially within the housing 28, a power source 36 electrically coupled the motor 32, a gear case 40 positioned substantially within the housing 28, a drive mechanism 44 supported by the gear case and driven by the motor 32, and an output member 48 driven by the drive mechanism 44.

The motor 32 is powered by the power source 36 which, in the illustrated embodiment, is a battery pack. in other embodiments, motor 32 may he powered by an AC power source. The drive mechanism 44 includes a drive gear 52 (Fig. 2) and converts rotary motion from the motor 32 into linear reciprocating motion of the output member 48. In the illustrated embodiment, the output member 48 is a saw blade, in other embodiments, the output member 48 may be, for example, a drill hit or a screwdriver hit, depending on the type of power tool being used.

[0029] As shown in Fig. 2, the motor mounting system 24 is positioned within the housing 28 and mounts the motor 32 to the gear ease 40. The motor mounting system 24 fixes the motor 32 axially and laterally relative to the gear case 40 to maintain proper alignment between a motor pinion 56 of the motor 32 and the drive gear 52 of the drive mechanism 44. In the illustrated embodiment, the motor mounting system 24 includes two shoulder pins 60, a motor mount 64, and a hearing 68. Referring to Figs.3 and 4, the shoulder pins 60 are attached to a can 72 of the motor 32 and extend axially from the motor 32. Ihe illustrated shoulder pins 60 are screwed into openings 76 formed in an end surface 80 of the motor can 72. In other embodiments, the shoulder pins 60 may be attached to the motor can 72 using other suitable fastening means.

[0030] As shown in Figs. 5 and 6. the motor mount 64 is positioned on the end surface 80 of the motor can 72 and includes two radially-extending arms 84 that attach to the gear case 40, as further discussed below. The shoulder pins 60 extend into two openings 88 in the motor mount 64 to help position the motor mount 64 on the motor can 72. The motor mount 64 also defines a relatively large central opening 92 that provides clearance for a motor shall 96 extending axially from the can 72. A flange 100, or lip, surrounds the central opening 92 and extends outwardly from the motor mount 64.

[0031] Tn some embodiments, the motor mount 64 may include more than two radially-extending arms 84. For example, the motor mount 64 may include three or four arms that attach to the gear case 40. Similarly, the motor mount 64 may include more than two openings 88 for receiving shoulder pins 60. The illustrated motor can 72 includes four openings 76 that are conligured to receive shoulder pins 60. As such, the motor mounting system 24 may include three or four shoulder pins 60 so that a shoulder pin is screwed into each opening 76. In addition, the motor mount 64 may include three or four openings SS to receive the shoulder pins 60. In other embodiments, the motor can 72 may include fewer or more openings 76, the motor mounting system 24 may include a matching number of shoulder pins 60, and the motor mount 64 may include a matching number of opening 88.

[0032] As shown in Figs. 7 and 8, the bearing 68 and the motor pinion 56 are attached to the motor shaft 96, trapping the motor mount 64 between the motor can 72 and the bearing 68. In the illustrated embodiment, the bearing 68 is press-fit onto the motor pinion 56, and the motor pinion 56 is press-fit onto the shall 96. The bearing 68 surrounds the motor shaft 96 and is positioned within the flange 100 of the motor mount 64 (Fig. 2). An outer race 104 of the bearing 68 rests on the motor mount 64 and engages an inner surface I 08 of the flange 100. The inner surface 108 of the flange 100 thereby directly contacts the outer race 104 to locate the motor 32 on the bearing 68. A neck portion 112 of the motor pinion 56 extends through an inner race 116 of the hearing 68 and is fixed to the motor shaft 96 to rotate with the shaft 96. A gear portion 120 of the motor pinion 56 extends axially from the bearing 68 to engage the drive gear 52 (Fig. 2) of the drive mechanism 44.

[0033] Referring back to Fig. 2, after the motor mount 64 and the bearing 68 are coupled to the motor can 72, the motor pinion 56 and the bearing 68 are inserted into an opening 124 formed in the gear case 40. the opening 1 24 is defined by an inner surface I 28 of the gear case 40. Tn the illustrated embodiment, the inner surface 128 of the gear case 40 and the inner surface 108 of the flange 100 are generally concentric and having similar diameters. Upon insertion of the motor pinion 56, the outer race 104 of the bearing 68 engages a portion of the inner surface 128. the inner surface 128 of the gear case 40 thereby directly contacts the outer race 104 to locate the gear case 40 on the bearing 68.

[0034] The arms 84 of the motor mount 64 are then connected to the gear case 4(1 In the illustrated embodiment, the arms 84 are secured to the gear case 40 by threaded fasteners 132. In other embodiments, the arms 84 may he secured to the gear ease 40 by other suitable fastening means. When attached to the gear case 40, the motor mount 64 presses against a first face of the hearing 68 and the gear case 40 presses against a second face of the hearing 68 so that the hearing 68 is sandwiched between the motor mount 64 and the gear case 40. Thus, the bearing 68 and the motor pinion 56 are axially fixed relative to the gear case 40.

[0035] h the illustrated embodiment, the bearing 68 extends slightly out of the opening 124 in the gear case 40 such that, as Lhe threaded fasteners 132 are tightened, the arms 84 of the motor mount 64 flex toward the gear case 40. As the arms 84 flex, the flange 100 applies a load to the outer race 104 of the bearing 68. The force applied by the flange 100 inhibits the outer race 104 from spinning when the motor 32 is running. The motor mount 64 also laterally locales on the bearing 68 to maintain proper alignment between the motor pinion 56 and the drive gear 52, eliminating or reducing side loading on the motor shaft 96. In some embodiments, the flange may be manufactured with a tight tolerance to the bearing 68 to laterally locate on the outer race 1 04.

[0036] As shown in Figs. 9 and 10, once the motor mount 64 is connected to the gear case 40, set screws 136 in the motor mount 64 are tightened. The set screws 136 extend through side openings 140 (only one of which is shown in Fig. 6) in the motor mount 64 and engage the shoulder pins 60 (Fig. 4). lightening the set screws 136 helps hold the motor can 72 axially, radially, and laterally relative to the motor mount 64 and the gear case 40. The motor mount 64 thereby inhibits the motor 32 from sliding, rotating/spinning, or wobbling/pitching relative to the gear case 40 to maintain the motor can 72 in alignment with the motor shaft 96 and the bearing 68. Tn the illustrated embodiment, the motor mount 64 includes two set screws 136 that engage both shoulder pins 60. In other embodiments, the motor mount 64 may include a single set screw or the set screw-s 136 maybe omitted. In still other embodiments, the motor mount 64 may include three or four set screws 136 to match the number of shoulder pins 60 that are coupled to the motcr can 72.

[0037] Fig. 1! illustrates another pow-er tool 220 that includes a motor mounting system 224.

In the illustrated embodiment, the power tool 220 is a rotary hammer. The rotary hammer 220 includes a housing 228, a motor 232 positioned substantially within the housing 228, a power source 236 electrically coupled to the motor 232, a gear case 240 positioned substantially within the housing 228, and a drive mechanism 244 supported by the gear case 240 and driven by the motor 232. The drive mechanism 244 includes a drive gear 248 and converts rotary motion of the motor 232 into linear reciprocating motion of an internal hammer and rotary motion of an output member (e.g., a drill bit).

[0038] the motor mounting system 224 is positioned within the housing 228 and mounts the motor 232 to the gear case 240. As shown in Figs. 1 2-14, the motor mounting system 224 includes two shoulder pins 252, a motor mount 256, and a bearing 260. l'hc shoulder pins 252 mount within openings 264 formed in an end surface 268 of a can 272 of the motor 232 and extend axially from the can 272.

[0039] The illustrated motor mount 256 is positioned on the end surface 268 of the motor can 272 and includes two radially-extending arms 276 that attach to the gear case 240, as further discusscd below. The shoulder pins 252 extend into two openings 280 in thc motor mount 256 to help position the motor mount 256 on the motor can 272. The motor mount 256 also defines a relatively large central opening 284 that provides clearance for a motor shaft 288 extending axially from the can 272. A flange 292, or lip, surrounds the central opening 284 and extends outwardly from the motor mount 256.

[0040] The hearing 260 and a motor pinion 296 are attached to the motor shaft 288, trapping the motor mount 256 between the motor can 272 and the bearing 260. As shown in Fig. 14, the hearing 260 surrounds the motor shaft 288 and engages the motor mount 256. In particular, an outer race 300 of the bearing 261) rests on an edge 304 of the flange 292 of the motor mount 256.

A neck portion 308 of the motor pinion 296 extends through an inner race 312 of the hearing 260 and is fixed to the motor shaft 288 to rotate with the shaft 288. A gear portion 316 of the motor pinion 296 extends axially from the hearing 260 to engage the drive gear 248 of the drive mechanism 244.

[0041] Referring to Fig. 14, alter the motor mount 256 and the hearing 260 are coupled to the can 272, the motor pinion 296 and the hearing 260 arc inserted into an opening 320 formed in the gear case 240. The opening 320 is defined by a stepped inner surface 324 of the gear case 240.

Upon insertion of the motor pinion 296, the outer race 301) of the hearing 260 engages a small diameter portion 328 of the inner surface 324 and an outer surface 332 oF the Ilange 292 engages a large diameter portion 336 of the inner surface 324. In the illustrated embodiment, the outer surface 332 of the flange 292 and the outer race 300 of the bearing 260 are generally concentric and have similar diameters. The inner surface 324 of the gear ease 240 directly contacts the outer race 300 of the bearing 260 to locate the gear case 240 on the bearing 260. In addition, the outer surface 332 of the motor mount flange 292 directly contacts the inner surface 324 of the gear case 240 to locate the motor mount 256 on the gear ease 240. As such, the motor 232 and the gear case 240 both ultimately locate on thc bearing 260 to maintain proper lateral alignment between thc motor pinion 296 and the drive gear 248.

[0042] The arms 276 of the motor mount 256 are then connected to the gear case 240 by threaded fasteners (not shown). When attached to the gear case 240, the moter mount 256 presses against a first face of the hearing 260 and the gear case 240 presses against a second face of the bearing 260 so that the bearing 260 is sandwiched between the motor mount 256 and the gear ease 240. Thus, the bearing 260 and the motor pinion 296 are axially fixed relative to the gear ease 240.

[0043] Once the motor mount 256 is secured to the gear case 240, set screws 340 (Fig. 13) in the motor mount 256 are tightened to the shoulder pins 252. The set screws 340 help hold the motor 232 axially, radially, and laterally relative to the motor mount 256 and the gear case 240.

The motor mount 256 thereby inhibits the motor 232 from sliding, rotating/spinning, or wobbling/pitching relative to the gear ease 240 to maintain the motor can 272 in alignment with the motor shaft 288 and the bearing 260. In some embodiments, the motor mount 256 may only include a single set screw or the set screws 340 may he omitted.

[0044] Fig. IS illustrates a portion oF the power tool 220 that includes a modified motor mounting system 224'. the illustrated motor mounting system 224' is similar to the motor mounting system 224 discussed above, and only differences between the systems 224, 224' are described below.

[0045] In the illustrated embodiment, the system 224' includes a motor mount 256' having a flange 292' with an outer surface 331 that is generally concentric with and has a similar diameter to the outer race 300 of the bearing 260. In addition, the power tool 220 includes a gear ease 240' having a continuous inner surface 324 rather than a stepped inner surface. that is, the inner surface 324' oF gear ease 240' that engage/s the hearing 260 and the/motor mount 256' has a generally constant diameter instead of a smaller diameter portion and a larger diameter portion.

In such an embodiment, the inner surface 324' of the gear case 240' directly contacts the outer race 300 of the hearing 260, while the outer surface 332' of the motor mount 256' directly contacts the inner surface 324 of the gear case 240'. The motor mount 256' thereby locates on the bearing 260 through the gear case 240' to maintain proper lateral alignment between the motor pinion 296 and the drive gear 248.

[0046] Fig. 16 illustrates another power tool 420 that includes a motor mounting system 424.

Tn the illustrated embodiment, the power vol 420 is a reciprocating saw-. The reciprocating saw 420 includes a housing 428, a motor 432 posiLioncd substantially within the housing 428, a power source (not shown) electrically coupled to the motor 432, a gear ease 436 positioned suhstantially within the housing 428, and a drive mechanism 440 supported by the gear case 436 and driven by the motor 432. The drive mechanism 440 includes a drive gear 444 and converts rotary motion of the motor 432 into linear reciprocating motion of an output member (e.g., a saw blade).

[0047] As shown in Fig. 17, the motor mounting system 424 is positioned within the housing 428 and mounts the motor 432 to the gear ease 436. The motor mounting system 424 includes two shoulder pins (not shown), a motor mount 448, and a bearing 452. Similar to the shoulder pins 60, 252 discussed above, the shoulder pins mount within openings formed in an end surface of a can 456 of the motor 432 and extend axially from the can 456.

[0048] The illustrated motor mount 448 is positioned on the end surface of the motor can 456 and includes two radially-extending arms 460 that attach to the gear case 436, as further discussed below. The shoulder pins extend into two openings in the motor mount 448 to help position the motor mount 448 on the motor can 456. The motor mount 448 also defines a relatively large central opening that provides clearance for a motor shaft 464 extcnding axially from the can 456. A flange 468, or lip, surrounds the central opening and extends outwardly from the motor mount 448.

[0049] The hearing 452 and a motor pinion 472 are attached to the motor shaft 464, trapping the motor mount 448 hetween the motor can 456 and the hearing 452. The bearing 452 surrounds the motor shaft 464 and engages the motor mount 448. In particular, an outer race 476 of the bearing 452 rests on an edge 480 of the flange 468 of the motor mount 448. A neck portion 484 of the motor pinion 472 extends through an inner race 488 of the hearing 452 and is fixed to the motor shaft 464 to rotate with the shaft 464. A gear portion 492 of the motor pinion I 0 472 extends axially from the bearing 452 to engage the drive gear 444 of the drive mechanism 440.

[0050] After the moter mount 448 and the bearing 452 are coupled to the can 456, the molor pinion 472 and the hearing 452 are inserted ink an opening 496 formed in the gear case 436.

The opening 496 is defined by a continuous inncr surface 500 of [tic gcar casc 436. That is, the inner surface 500 has a generally constant diameter. Upon insertion of the motor pinion 472, the outer race 476 of the bearing 452 and an outer surface 504 of the flange 468 engage the inner surface 500. Tn the illustrated embodiment, the outer surface 504 of the flange 468 and the outer race 476 of the hearing 452 are generally concentric and have similar diameters. The inner surface 500 of the gear case 436 directly contacts the outer race 476 of the hearing 452 to locate the gear case 436 on the bearing 452. Tn addition, the outer surface 504 of the motor mount flange 468 directly contacts the inner surface 500 of the gear ease 436 to locate the motor mount 448 on the gear case 436. [he bearing 452 and the motor mount 448 are therefore concentrically aligned on the same surface of the gear case 436. As such, the motor 432 and the gear case 436 both ultimately locate on the bearing 452 to maintain proper lateral alignment between the motor pinion 472 and the drive gear 444.

[0051] The arms 460 of the motor mount 448 arc then connected to the gear case 436 hy threaded fasteners (not shown). When attached to the gear case 436, the motor mount 448 presses against a first face of the hearing 452 and the gear case 436 presses against a second face of the bearing 452 so that the hearing 452 is sandwiched hetween the motor mount 448 and the gear case 436. Thus, the hearing 452 and the motor pinion 472 are axially fixed relative to the gear case 436.

[0052] Once the motor mount 448 is secured to the gear case 436, set screws (not shown) in the motor mount 448 arc tightened on the shoulder pins. The set screws help hold the motor 438 axially, radially, and laterally relative to the motor mount 448 and the gear case 436. The motor mount 448 thereby inhihits the motor can 432 from sliding, rotating/spinning, or wobbling/pitching relative to the gear ease 436 to maintain the motor can 456 in alignment with the motor shaft 464 and the hearing 452. In some embodiments, the motor mount 448 may only include a single set screw or the set screws may he omitted. I!

[0053] The above-described motor mounting systems help rigidly fix a motor both axially and laterally relative to a gear box within a power tool, counteracting excessive wear and damage that may occur from vibrations during use. The motor mounting systems also hold a pinion hearing in place in a manner thai does not allow the hearing's outer race to spin while the moter is running. in addition, the motor mounting systems help achieve proper axial alignment between a motor and a gear box to reduce side-loading and other performance-affecting issues with designs thai are capable of being mass produced in high-speed industrial assembly environments.

[0054] Although the invention has been described with reference to certain preferred embodiments, variations and modifications exist within the scope and spirit of one or more independent aspects of the invention. For example, although each of the motor mounting systems 24, 224, 224', 424 is illustrated and described with reference to a different, specific power tool, the motor mounting systems 24, 224, 224', 424 maybe interchanged between any of the illustrated power tools 20, 220, 420 or maybe used with other power tools.

[0055] Various features and advantages of the invention are set forth in the following claims.

Claims

<claim-text>CLAiMS 1. A power tool comprising: a motor including a can and a shall extending axially from the can; a gear casc including an inner surface that dcfincs an opening: a hearing positioned around a portion of the shaft that extcnds from thc can and at least partially within the opening in the gcar case: and a motor mount coupled to the motor, thc motor mount including a flange extending away from the motor; wherein the flange of the motor mount and the inner surface of the gear case axially and latcrally locate the motor and the gear case on the bearing.</claim-text> <claim-text>2. The power tool of claim 1, wherein the inner surface of the gear case directly contacts an outer race of the hearing to locale the gear case on the hearing.</claim-text> <claim-text>3. The pow-er tool of daim 2, wherein the flange includes an inner surface that directly contacts the outer race of thc bcaring to locate thc motor on the hearing.</claim-text> <claim-text>4. The power tool of claim 3, wherein the inner surface of the gear case and the inner surface of the flange are generally concentric and have similar diameters.</claim-text> <claim-text>5. The power tool of claim 2, wherein the flange includes an outer surface that directly contacts the inner surface of the gear case to locale the motor on the hearing.</claim-text> <claim-text>6. The power tool of claim 5, wherein the outer surface of the flange and the outer race of the hearing are generally concentric and have similar diameters.</claim-text> <claim-text>7. The power tool of claim 6, wherein the inner surface of the gear case is generally continuous.</claim-text> <claim-text>8. The power tool of claim I, wherein the hearing includes a first face and a second face, and wherein the first face of the bearing contacts the motor mount and the second face of the bearing contacts the gear case.9. l'he power tool of claim 1, wherein the motor includes a pinion coupled to the portion of the shaft that extends from the can, and wherein the bearing includes an inner race thai is secured to the pinion.1 0. The pow-er tool of claim 9, wherein the inner race of the bearing is press-fit onto the pinion.ii. The power tool of claim 1, wherein the motor mount includes two radially-extending arms, and wherein the two arms are secured to the gear case to couple the motor mount to the gear case.12. the power tool of claim 11, wherein the two radially-extending arms are flexed toward the gear case to apply a load to the hearing.13. The pow-er tool of claim 11, wherein the two radially-extending arms are secured to the gear case with threaded fasteners.I 4 The. pow-er tool of claim I, further comprising two shoulder pins coupled to the cm of the motor, wherein the two shoulder pins extend into the motor mount to couple the motor mount to the motor.15. The power tool oF claim IA, wherein the motor mount includes a set screw, and wherein the set screw engages one or the two shoulder pins to inhibit movement of the motor mount relative to the motor.16. A method of connecting a motor to a gear case of a power tool, the motor including a can and a shall that extends axially from the can, the gear case including an inner surface that defines an opening, the method comprising: providing a motor mounting system including a motor mount and a hearing, the motor mount having a flangc; coupling the motor mount to the motor such that the flange extends away from the motor: positioning the bearing around a portion of the shaft of the motor that extends from the can; inserting at least a portion of the hearing into the opening in the gear case; axially and laterally locating the gear case on the hearing with the inner surface of the gem-case: and axially and laterally locating the motor on the bearing with the flange of the motor mount.17. I'hc method of claim 16, wherein locating the gear case on the bearing includes directly contacting an outer race of the hearing with the inner surface of the gear case.18. The method of claim 17, wherein the motor mount includes a flange having an inner surface, and wherein locating the motor on the hearing includcs directly contacting the outer race of the hearing with the inner surface of the flange.19. The method of claim 17, wherein the motor mount includes a flange having an outcr surface, and wherein locating the motor on the hearing includes directly contacting the inner surface of the gear case with the outer surface of the flange.20. The method of claim 16, further comprising attaching a pinion to the portion of the shall of the motor that extends from the can, and securing an inner race of the hearing to the pinion.21. The method of claim 16, wherein the motor mount includes two radially-extending arms, and further comprising securing the two arms to the gem-case to couple the motor mount to the gear case.22. The method of claim 21, further comprising flexing the radially-extending arms toward the gear case to apply a load to the bcaring.23. The mcthod of claim 16, wherein providing the motor mounting system also includes providing two shoulder pins, and further comprising coupling the two shoulder pins to the can of the motor, wherein coupling the motor mount to the motor includes positioning the motor mount on the motor such that the two shoulder pins extend into the motor mount.24. The method of claim 23, wherein the motor mount includes a set screw that engages one of the two shoulder pins, and further comprising tightening the set screw to inhibit movement of the motor mount relative to the motor.25. A power tool comprising: a housing; a motor positioned substantially within the housing, the motor including a can, a shaft extending axially from the can, and a pinion coupled to a portion of the shaft that extends from the can; a gear case positioned substantially within the housing, the gear case including an inner surface that defines an opening; a bearing positioned around the portion of the shaft that extends from the can and at least partially within the opening in the gear case, the hearing including an inner race that is secured to the pinion and an outer race; a motor mount including a flange extending away from the motor and two radially-extending arms, the two arms being secured to the gear case; and two shoulder pins coupled to the can of the motor, the two shoulder pins extending into the motor mount to couple the motor mount to the motor: wherein the inner surface of the gear case directly contacts the outer race of the hearing to axially and laterally locate the gear case on the hearing, and wherein the flange of the motor mount directly contacts one of the outer race of the hearing and the inner surface of the gear case to axially and laterally locate the motor on the bearing.26. The power tool oF claim 25, wherein the flange includes an inner surface that directly contacts the outer race of the hearing to locate the motor on the bearing.27. The power tool of claim 25, wherein the flange includes an outer surface that directly contacts the inner surface of the gear case to locate the motor on the hearing.28. the power tool of claim 25, wherein the hearing inchides a first face and a second face, and wherein the first face of the bearing contacts the motor mount and the second face of the bearing contacts the gear case.29. The pow-er tool of claim 25, wherein the two radially-extending arms of the motor mount are flexed toward the gear ease to apply a load to the bearing.30. The power tool of daim 25, wherein the motor mount includes a set screw, and wherein the set screw engages one of the two shoulder pins to inhibit movement of the motor mount relative to the motor.</claim-text>