EP3819083B1 - Impact tool with ring gear alignment features - Google Patents
Impact tool with ring gear alignment features Download PDFInfo
- Publication number
- EP3819083B1 EP3819083B1 EP20194822.1A EP20194822A EP3819083B1 EP 3819083 B1 EP3819083 B1 EP 3819083B1 EP 20194822 A EP20194822 A EP 20194822A EP 3819083 B1 EP3819083 B1 EP 3819083B1
- Authority
- EP
- European Patent Office
- Prior art keywords
- ring gear
- housing
- endbell
- front endbell
- power tool
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
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Images
Classifications
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B25—HAND TOOLS; PORTABLE POWER-DRIVEN TOOLS; MANIPULATORS
- B25F—COMBINATION OR MULTI-PURPOSE TOOLS NOT OTHERWISE PROVIDED FOR; DETAILS OR COMPONENTS OF PORTABLE POWER-DRIVEN TOOLS NOT PARTICULARLY RELATED TO THE OPERATIONS PERFORMED AND NOT OTHERWISE PROVIDED FOR
- B25F5/00—Details or components of portable power-driven tools not particularly related to the operations performed and not otherwise provided for
- B25F5/02—Construction of casings, bodies or handles
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B25—HAND TOOLS; PORTABLE POWER-DRIVEN TOOLS; MANIPULATORS
- B25F—COMBINATION OR MULTI-PURPOSE TOOLS NOT OTHERWISE PROVIDED FOR; DETAILS OR COMPONENTS OF PORTABLE POWER-DRIVEN TOOLS NOT PARTICULARLY RELATED TO THE OPERATIONS PERFORMED AND NOT OTHERWISE PROVIDED FOR
- B25F5/00—Details or components of portable power-driven tools not particularly related to the operations performed and not otherwise provided for
- B25F5/001—Gearings, speed selectors, clutches or the like specially adapted for rotary tools
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B25—HAND TOOLS; PORTABLE POWER-DRIVEN TOOLS; MANIPULATORS
- B25B—TOOLS OR BENCH DEVICES NOT OTHERWISE PROVIDED FOR, FOR FASTENING, CONNECTING, DISENGAGING OR HOLDING
- B25B21/00—Portable power-driven screw or nut setting or loosening tools; Attachments for drilling apparatus serving the same purpose
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B25—HAND TOOLS; PORTABLE POWER-DRIVEN TOOLS; MANIPULATORS
- B25B—TOOLS OR BENCH DEVICES NOT OTHERWISE PROVIDED FOR, FOR FASTENING, CONNECTING, DISENGAGING OR HOLDING
- B25B23/00—Details of, or accessories for, spanners, wrenches, screwdrivers
Definitions
- the present disclosure relates, generally, to power tools and, more particularly, to impact tools including a ring gear alignment feature. More particularly, the present invention relates to a hand-held power tool according to the preamble of claim 1. Such a power tool is known from US 2005/183870 A1 .
- an illustrative embodiment of the present disclosure provides a hand-held power tool which comprises a housing, a motive source, a front endbell, an output shaft, a front housing, a gear set assembly, a first set of piloting features, and a second set of piloting features.
- the housing supports the motive source and includes a front endbell.
- the output shaft protrudes from an output end at the front endbell of the housing.
- the output shaft is also functionally coupled to the motive source such that the output shaft rotates in response to activation of the motive source when the motive source is supplied with power.
- the front housing defines an interior space.
- the output shaft is located in the interior space of the front housing.
- the gear set assembly is located in the interior space of the front housing, and is configured to transfer rotation from the motive source to an output spindle.
- the gear set assembly also includes a ring gear characterized by an annular ring body having a plurality of teeth located on the interior periphery of the annular ring body and a surface located on an exterior periphery of the annular ring body opposite the interior periphery.
- the ring gear surrounds a portion of the output shaft and abuts the front endbell of the housing.
- the surface of the exterior periphery of the ring gear abuts an interior surface of the front housing.
- the first set of piloting features is located on the interior surface of the front housing and on the surface of the exterior periphery of the ring gear, and is configured to prevent movement of the ring gear relative to the motive source and the front housing.
- the second set of piloting features is located on the front housing and on the endbell of the housing, and is configured to prevent the front housing from moving relative to the housing.
- the front housing being a hammer case; the impact mechanism being supported in the hammer case; the front housing being attached to the housing with fasteners; the gear set assembly including a planetary gear set; the first set of piloting features further comprise one or more grooves formed in the interior surface of the front housing, and one or more corresponding ridges formed on the surface of the exterior periphery of the annular ring body of the ring gear, wherein the one or more grooves are configured to receive the one or more corresponding ridges to prevent movement between the front housing and the ring gear; the first set of piloting features having one or more grooves formed in the surface of the exterior periphery of the annular ring body of the ring gear, and one or more corresponding ridges formed on the interior surface of the front housing, wherein the one or more grooves are configured to receive the one or more corresponding ridges to prevent movement between the front housing and the ring gear; the second set of piloting features having one or more
- a hand-held power tool which comprises a housing, a motive source, a front endbell, an output shaft, a front housing, and a gear set assembly.
- the housing supports motive source, and includes the front endbell.
- the output shaft protrudes from an output end at the front endbell of the housing, and is functionally coupled to the motive source such that the output shaft rotates in response to activation of the motive source when the motive source is supplied with power.
- the front housing defines an interior space, and the output shaft is located in that interior space.
- the gear set assembly is located in the interior space of the front housing, and is configured to transfer rotation from the motive source to an output spindle.
- the gear set assembly also includes a ring gear characterized by an annular ring body having a plurality of teeth located on the interior periphery of the annular ring body and a surface located on an exterior periphery of the annular ring body opposite the interior periphery.
- the ring gear surrounds a portion of the output shaft and abuts the front endbell of the housing.
- the front housing and ring gear further include one or more piloting features, each of the one or more piloting features being configured to mate the front housing with the ring gear.
- embodiments of the present disclosure may also comprise: one or more piloting features configured to mate the front housing with the front endbell; the one or more piloting features including one or more grooves formed in an interior surface of the front housing, and one or more corresponding ridges formed on a surface of an exterior periphery of the ring gear, wherein the one or more grooves are configured to receive the one or more corresponding ridges to prevent movement between the front housing and the ring gear; the one or more piloting features further comprise one or more grooves formed in the surface of the exterior periphery of the ring gear, and one or more corresponding ridges formed on the interior surface of the front housing, wherein the one or more grooves are configured to receive the one or more corresponding ridges to prevent movement between the front housing and the ring gear.
- a hand-held power tool which comprises a housing, a motive source, a front endbell, an output shaft, a front housing, and a gear set assembly.
- the housing supports the motive source.
- the housing includes the front endbell.
- the output shaft protrudes from an output end at the front endbell of the housing, and is functionally coupled to the motive source such that the output shaft rotates in response to activation of the motive source when the motive source is supplied with power.
- the front housing defines an interior space, and the output shaft is located in that interior space.
- the gear set assembly is located in the interior space of the front housing, and is configured to transfer rotation from the motive source to an output spindle.
- the gear set assembly also includes a ring gear characterized by an annular ring body having a plurality of teeth located on the interior periphery of the annular ring body, and a surface located on an exterior periphery of the annular ring body opposite the interior periphery.
- the ring gear surrounds a portion of the output shaft and abuts the front endbell of the housing.
- the ring gear is inserted molded into the front endbell of the housing such that ring gear is restrained against both axial and rotational movement relative to the front endbell.
- the power tool 10 is illustratively embodied as a cordless, electric power tool.
- the power tool 10 is shown in FIG. 1 as a pistol-grip style cordless electric impact tool, which includes an impact mechanism in-line with an output of the tool 10.
- the power tool 10 may be embodied as another type of impact tool, such as an angle impact tool in which the output of the tool 10 is disposed at an angle (e.g., a right angle) to the impact mechanism.
- power tool 10 may include a native source such as a motor including an electric motor, or a pneumatic motor, for example.
- the illustrative power tool 10 includes a tool housing 12 and a hammer case 14 as shown in FIG. 1 .
- the hammer case 14 is also known as the front housing 14.
- the tool housing 12 defines a body 16, a back cap 18, and a handle 20.
- the body 16 defines an interior space 22 in which a motor assembly 24 of the tool 10 is positioned.
- motor assembly 24 may include a motive source such as an electric motor(either corded or cordless), air, or other fluid motor.
- the back cap 18 is coupled to the body 16 when the tool 10 is assembled to close off the interior space 22 and define a back end 26 that is positioned opposite the hammer case 14 of the tool 10.
- the back cap 18 is coupled to the body 16 using fasteners 28 (best seen in FIG. 4 ) that extend through the back cap 18 and into the motor assembly 24 (see Figs. 5 , 7, and 8 ).
- the handle 20 of the tool housing 12 extends away from the body 16 and is configured to be graspable by a user of the tool 10.
- a power source connection 30 is positioned at an end 32 of the handle 20 opposite the body 16.
- the power source connection 30 may be configured to connect to any source of power, such as, for example, a battery, a source of motive fluid, or an outlet connected to an electrical grid.
- a power source 34 of the power tool 10 is a battery attached to the power source connection 30.
- the tool 10 includes a number of user-selectable input devices, which may be embodied as triggers, switches, or knobs configured to allow the user to adjust one or more features of the power tool 10.
- the handle 20 includes trigger 36 configured to, among other things, turn an electric motor 38 (see Fig. 6 ) on/off in use of the tool 10.
- a Forward/Neutral/Reverse (“F/N/R”) switch 40 is positioned in the handle 20 near the body 16 and the trigger 36.
- the F/N/R switch 40 is configured to control the direction of rotation of the motor 38.
- a control knob 42 is positioned on the back cap 18 of the tool 10 (as best seen in FIG. 4 ) and is configured to adjust the mode of operation of the power tool 10.
- the hammer case 14 is positioned on the body 16 of the tool housing 12 opposite the back cap 18.
- the hammer case 14 includes a tool end 44 configured to couple to the tool housing 12 and an output end 46 that includes an aperture 48 through which an output spindle 50 of the tool 10 protrudes.
- the hammer case 14 defines an interior space 52 in which a gear assembly 54 and an impact mechanism (not shown) are housed.
- the hammer case 14 is removably coupled to the tool housing 12 through one or more fasteners (not shown).
- the hammer case 14 may be removably coupled to the tool housing 12 via other mechanisms (e.g., a snap fit).
- the motor assembly 24 includes the electric motor 38, a front endbell 56, and a rear endbell 58.
- the electric motor 38 is illustratively embodied as a brushless DC electric motor.
- the electric motor 38 includes a rotor 60 configured to drive an output shaft 62 to output mechanical power and a stationary component (i.e., a stator) 64 that extends around the rotor 60.
- the output shaft 62 is functionally coupled to the output spindle 50 via the gear assembly 54.
- the rear endbell 58 is positioned in the interior space 22 to be near the back cap 18 and the front endbell 56 is positioned such that it is enclosed in the interior space 22 of the tool housing 12 and the interior space 52 of the hammer case 14 (as best seen in FIG. 7 ).
- the rotor 60 and the stator 64 of the motor 38 are positioned between the two end bells 56, 58.
- the front endbell 56 and the rear endbell 58 cooperate to align the rotor 60 and the stator 64 so that the rotor 60 and the stator 64 extend parallel to a central axis 66 of the motor 38.
- the illustrative gear assembly 54 may be embodied as, or include, a planetary gear set that is configured to transfer rotation of the output shaft 62 of the motor 38 to an impact mechanism of the tool 10 housed in the hammer case 14.
- the gear assembly 54 includes a ring gear 68 positioned in the interior space 52 of the hammer case 14.
- the ring gear 68 surrounds the output shaft 62 and abuts the front endbell 56.
- the ring gear 68 is formed as an annular ring body with an inner surface 70 that includes a plurality of gear teeth 72 and an outer surface 74 configured to abut an inner surface 76 of the hammer case 14.
- piloting features 90 are integrated into the hammer case 14, the front endbell 56, and the ring gear 68.
- the piloting features 90 are configured to align the hammer case 14, the front endbell 56, and the ring gear 68 with one another.
- the piloting features 90 are also configured to prevent rotation of the ring gear 68 relative to the motor assembly 24 and the hammer case 14.
- the piloting features 90 include one or more grooves 92 formed in the inner surface 76 of the hammer case 14, one or more corresponding ridges 94 formed on the outer surface 74 of the ring gear 68, and one or more corresponding ridges 96 formed on an outer surface 98 of the front endbell 56.
- Each groove 92 is sized to receive both a corresponding ridge 94 and a corresponding ridge 96.
- Each groove 92 extends axially along the inner surface 76 of the hammer case 14 from the tool end 44.
- the dimensions of each ridge 94 are approximately the same as the dimensions of each corresponding ridge 96.
- Each ridge 94 is positioned along the outer surface 74 of the ring gear 68 and each ridge 96 is positioned along the outer surface 98 of the front endbell 56.
- both sets of ridges 94, 96 are spaced evenly around the outer surfaces of their respective structures, the ring gear 68 and the front endbell 56.
- the hammer case 14 defines an inner diameter that is sized to match an outer diameter of the ring gear 68 and an outer diameter of the front endbell 56.
- tool 10 is illustratively shown as including four grooves 92, four ridges 94, and four ridges 96, it will be appreciated that the tool 10 may include any number of grooves 92, corresponding ridges 94, and corresponding ridges 96 in other embodiments.
- the user aligns the ridges 94 with corresponding ridges 96, aligns the grooves 92 of the hammer case 14 with the now aligned ridges 94, 96, and advances the hammer case 14 axially along the central axis 66 toward the tool housing 12 until the tool end 44 of the hammer case 14 contacts the tool housing 12.
- the grooves 92 first pass over the ridges 94 and then pass over the ridges 96.
- the piloting features 90 are configured to secure the ring gear 68 relative to the front endbell 56 such that the ring gear 68 cannot rotate relative to the motor assembly 24.
- the grooves 92 of the hammer case 14 define a flange surface 100 that is configured to clamp the ring gear 68 against the front endbell 56 when the hammer case 14 is securely fastened to the tool housing 12.
- the ring gear 68 is coupled directly to the front endbell 56.
- the position of the ring gear 68 relative to the front endbell 56 is instead secured through the piloting features 90 of the hammer case 14.
- the hammer case 14 is piloted by the front endbell 56, while the hammer case 14 pilots the ring gear 68.
- Such an embodiment reduces the number of parts of the tool 10 and may reduce the length of the tool 10 by removing connectors between the ring gear 68 and the front endbell 56.
- the piloting features 90 may include any number of grooves 92 and ridges 94, 96.
- the illustrative piloting features 90 of FIGS. 7 and 8 include four grooves 92 spaced evenly around the inner surface 76 (see Fig. 6 ) of the hammer case 14, four corresponding ridges 94 spaced evenly around the outer surface 74 (see Fig. 6 ) of the ring gear 68, and four corresponding ridges 96 spaced evenly around the outer surface 98 of the front endbell 56.
- Each groove 92 is configured to mate with both a ridge 94 and a ridge 96.
- FIG. 1 shown in FIG.
- the piloting features 102 include three grooves 104 formed in the hammer case 14 with three corresponding ridges 106 formed in the ring gear 68 and three corresponding ridges in the front endbell 56 (not shown).
- the piloting features 108 include six grooves 110 formed in the hammer case 14 with six corresponding ridges 112 formed in the ring gear 68 and six corresponding ridges in the front endbell 56 (not shown).
- piloting features 90, 102, 108 have been illustrated and described herein as including grooves 92, 104, 110 formed in the hammer case 14 and ridges 94, 96, 106, 112 formed on the ring gear 68 and front endbell 56, it is contemplated that the piloting features 90, 102, 108 may take other forms in other embodiments of the power tool 10.
- the piloting features might alternatively include ridges formed on the hammer case 14 and corresponding grooves formed in the ring gear 68 and front endbell 56.
- a front endbell 256 is configured to surround the ring gear 268, and thereby align and secure the ring gear 268 in relation to the motor assembly 24 of the power tool 10.
- a hammer case 214 is configured to operatively couple to the tool housing 12, the front endbell 256, and the ring gear 268.
- the front endbell 256 includes an annular flange 202 formed in a front end 204 of the front endbell 256.
- the annular flange 202 includes an inner surface 206 that is configured to from a cavity 208 that is sized to receive a portion of the ring gear 268.
- the inner surface 206 operatively couples to an outer surface 210 of the ring gear 268 when the ring gear 268 is assembled in the power tool 10.
- the front endbell 256 is configured to secure the ring gear 268 and prevent the ring gear 268 from rotating during normal operation of the power tool 10.
- the hammer case 214 is configured to be secured to an outer surface 210 of the tool housing 12.
- the hammer case 214 includes a housing flange 212 and a gear assembly surface 216 formed in a motor end 218 of the hammer case 214.
- the housing flange 212 is configured to operatively couple to the outer surface 210 of the tool housing 12, and thereby secure the hammer case 214 to the tool housing 12.
- the gear assembly surface 216 is configured to abut the annular flange 202 of the front endbell 256 and the ring gear 268 of the gear assembly 54 ( see, also, Fig. 5 ). By so doing, the hammer case 214 cooperates with the front endbell 256 to secure the ring gear 268 to the power tool 10.
- FIG. 12 another embodiment of alignment features 300 for a ring gear 368 of a power tool 10 is shown.
- the ring gear alignment features 300 are configured to align the ring gear 368 with the motor assembly 24 (see Fig. 11 ) and allow the power tool 10 to function properly.
- the ring gear 368 is insert molded to a front endbell 356 of the motor assembly 24.
- a hammer case 314 is operatively coupled to the ring gear 368, the front endbell 356, and the tool housing 12 and is configured to seal the interior space 22 of the power tool 10.
- the hammer case 314 includes a nose piece 302 attached to it.
- the hammer case 314 includes a tapered section 304 and a flange 306 formed in the tool end 44 of the hammer case 314.
- the tapered section 304 of the hammer case 314 is configured to operatively couple to an inner surface 310 of the tool housing 12.
- the flange 306 is configured to operatively couple to the outer surfaces 322, 328 of the ring gear 368.
- the ring gear 368 is formed as an annular ring body that includes an inner ring surface 318 having a plurality of teeth 320 formed therein and an outer surface 322 having one or more fastener guide bores 324 formed therein.
- the ring gear 368 extends between a motor end 326 and another opposite end.
- a lip 330 is formed in the motor end 326 of the ring gear 368 causing the motor end 326 to define a motor end opening 332 having a smaller diameter than an opposite end opening 334 defined in the opposite end of the ring gear 368.
- the lip 330 is configured to cooperate with the front endbell 356 to secure the ring gear 368 to the motor assembly 24 ( see, also, Figs. 11 and 12 ).
- the ring gear 368 is secured to the motor assembly 24 by insert molding the ring gear 368 directly into the front endbell 356.
- one or more grooves 336 are formed in the motor end 326 of the ring gear 368 and are configured to secure ring gear 368 to the front endbell 356.
- hot plastic enters into the grooves 336.
- the grooves 336 cooperate with the plastic of the front endbell 356 to secure the ring gear 368 to the front endbell 356 such that the ring gear 368 cannot rotate relative to the front endbell 356.
- the grooves 336 may be replaced by other raised or recessed features that cooperate with the front endbell 356 to secure the ring gear 368 against rotation relative to the front endbell 356.
- the front endbell 356 includes an outer body 338 sized to receive the ring gear 368.
- the outer body 338 is configured to operatively couple to the outer surface 322 of the ring gear 368 (see Figs. 13 and 14 ).
- One or more fastener guide bores 340 are formed in the outer body 338.
- the fastener guide bores 340 of the front endbell 356 are configured to align with the corresponding fastener guide bores 324 formed in the ring gear 368.
- the fastener guide bores 324, 340 cooperate with fasteners (not shown) to secure the motor assembly 24 and the gear assembly 54 in the tool housing 12.
- fasteners are able to pass through the motor assembly 24 and be received by the hammer case 314.
- the front endbell 356 also includes an inner body 342 configured to interact with the lip 330 of the ring gear 368 and secure the ring gear 368 to the front endbell 356.
- the plastic of the front endbell 356 forms around the lip 330 thereby joining the ring gear 368 to the front endbell 356.
- the insert molding process is accomplished by injecting thermoplastic into a mold in which the ring gear 368 has been placed. The thermoplastic eventually hardens and thereby forms the front endbell 356.
- the inner body 342 of the front endbell 356 is also configured to pilot a camshaft 372 of the impact mechanism 370 of the tool 10.
- the camshaft 372 is integrally formed to include a planetary gear holder at a distal end 374 of the camshaft 372.
- the inner body 342 of the front endbell 356 is formed to include a recessed annular surface 344 that engages the distal end 374 of the camshaft 372 when the tool 10 is assembled.
- the inner body 342 of the front endbell 356 is also formed to include a wall 346 that extends away from the recessed annular surface 344 (the wall 346 also forming a part of the inner body 342 that engages and retains the lip 300 of the ring gear 368, as described above).
- a wall 346 that extends away from the recessed annular surface 344 (the wall 346 also forming a part of the inner body 342 that engages and retains the lip 300 of the ring gear 368, as described above).
- an inner diameter of the wall 346 surrounds a portion of an outer diameter of the distal end 374 of the camshaft 372 such that the front endbell 356 pilots the camshaft 372.
- This configuration eliminates the need for a separate bearing and/or additional components to support the distal end 374 of the camshaft 372, thereby reducing the complexity and overall length of the tool 10.
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- Mechanical Engineering (AREA)
- Portable Power Tools In General (AREA)
- Percussive Tools And Related Accessories (AREA)
- Mounting Of Bearings Or Others (AREA)
Description
- The present disclosure relates, generally, to power tools and, more particularly, to impact tools including a ring gear alignment feature. More particularly, the present invention relates to a hand-held power tool according to the preamble of claim 1. Such a power tool is known from
US 2005/183870 A1 . - Many power tools include gear assemblies configured to translate rotational forces produced by a motor into rotation of an output spindle of the power tool. In such power tools, it is generally desirable to have the positions of the motor and the gear assembly fixed relative to one another for proper operation of the power tool. It would, therefore, be beneficial to have certain features on the power tool include piloting features to assist assembling certain structures and keep them fixed relative to other structures.
US 2013/247706 A1 ,US 2005/183870 A1 ,JP 2012 149669 A US 2009/221222 A1 ,EP 2599568 A1 , andUS 2011/188232 A1 may be useful for understanding the background. - It is an object of the present invention to provide a hand-held power tool and a method of manufacturing the hand-held power tool. This object can be achieved by the features as defined by the independent claims. Further enhancements are characterised by the dependent claims. To that end, an illustrative embodiment of the present disclosure provides a hand-held power tool which comprises a housing, a motive source, a front endbell, an output shaft, a front housing, a gear set assembly, a first set of piloting features, and a second set of piloting features. The housing supports the motive source and includes a front endbell. The output shaft protrudes from an output end at the front endbell of the housing. The output shaft is also functionally coupled to the motive source such that the output shaft rotates in response to activation of the motive source when the motive source is supplied with power. The front housing defines an interior space. The output shaft is located in the interior space of the front housing. The gear set assembly is located in the interior space of the front housing, and is configured to transfer rotation from the motive source to an output spindle. The gear set assembly also includes a ring gear characterized by an annular ring body having a plurality of teeth located on the interior periphery of the annular ring body and a surface located on an exterior periphery of the annular ring body opposite the interior periphery. The ring gear surrounds a portion of the output shaft and abuts the front endbell of the housing. The surface of the exterior periphery of the ring gear abuts an interior surface of the front housing. The first set of piloting features is located on the interior surface of the front housing and on the surface of the exterior periphery of the ring gear, and is configured to prevent movement of the ring gear relative to the motive source and the front housing. The second set of piloting features is located on the front housing and on the endbell of the housing, and is configured to prevent the front housing from moving relative to the housing.
- In the above and other embodiments of the present disclosure may also comprise: the front housing being a hammer case; the impact mechanism being supported in the hammer case; the front housing being attached to the housing with fasteners; the gear set assembly including a planetary gear set; the first set of piloting features further comprise one or more grooves formed in the interior surface of the front housing, and one or more corresponding ridges formed on the surface of the exterior periphery of the annular ring body of the ring gear, wherein the one or more grooves are configured to receive the one or more corresponding ridges to prevent movement between the front housing and the ring gear; the first set of piloting features having one or more grooves formed in the surface of the exterior periphery of the annular ring body of the ring gear, and one or more corresponding ridges formed on the interior surface of the front housing, wherein the one or more grooves are configured to receive the one or more corresponding ridges to prevent movement between the front housing and the ring gear; the second set of piloting features having one or more corresponding ridges formed on an outer surface of the front endbell of the housing, wherein each of the one or more grooves of the front housing is sized to receive both a corresponding ridge formed on the surface of the exterior periphery of the annular ring body of the ring gear and the one or more corresponding ridges formed on an outer surface of the front endbell, wherein each of the one or more grooves extends axially along the interior surface of the front housing; dimensions of each of the one or more ridges formed on the surface of the exterior periphery of the annular ring body of the ring gear are substantially similar to dimensions of each of the one or more corresponding ridges formed on the outer surface of the front endbell; the interior surface of the front housing defines an inner diameter of the outer periphery of the ring body of the ring gear and an outer diameter of the front endbell; the one or more grooves of the front housing align with the one or more ridges formed on the surface of the exterior periphery of the annular ring body of the ring gear and the one or more corresponding ridges formed on the outer surface to advance the front housing axially along a central axis toward the housing to engage and secure to the housing; the one or more grooves of the front housing include a flange surface configured to clamp the ring gear against the front endbell when the front housing is secured to the housing; the first set of piloting features further comprise one or more ridges formed on the front housing and one or more corresponding grooves formed on the surface of the outer periphery of the ring gear and the one or more corresponding grooves formed on the front endbell; the front endbell being configured to surround at least a portion of the ring gear to align and secure the ring gear in relation to the motive source, wherein the front housing is configured to operatively couple the housing, the front endbell, and the ring gear together; the front endbell including an annular flange formed in a front end of the front endbell, wherein the annular flange includes an inner surface configured to from a cavity sized to receive a portion of the ring gear; the inner surface of the annular flange of the endbell operatively couples to an outer surface of the ring gear when the ring gear to prevent the ring gear from rotating during normal operation; the front housing is configured to be secured to the outer surface of the housing, wherein the front housing includes a housing flange and a gear assembly surface, wherein the housing flange is configured to operatively couple to the outer surface of the housing to secure the front housing to tool housing, and wherein the gear assembly surface is configured to abut the annular flange of the front endbell and the ring gear so the front housing cooperates with the front endbell to hold the ring gear; the first set of piloting features including the ring gear insert molded to the front endbell, wherein the front housing is operatively coupled to the ring gear, the front endbell, and wherein front housing includes a nose piece located adjacent the output spindle; the front housing including a tapered section and a flange, wherein the tapered section of the front housing is configured to operatively couple to an inner surface of the housing, and wherein the flange is configured to operatively couple to outer surfaces of the ring gear; the ring gear including a lip formed on an interior portion of the ring gear, wherein the lip is configured to cooperate with the front endbell; the ring gear being secured to the front endbell, wherein securement features are formed on the ring gear which are filled with a plastic material that holds the ring gear to the front endbell, wherein the securement features are selected from the group consisting of at least one raised structure and one or more recess; the ring gear being secured to the front endbell, and wherein the hand-held power tool neither comprises securement features that include one or more fasteners engage fastener guide bores formed in the front endbell and are configured to align with corresponding fastener guide bores formed in the ring gear; and the ring gear being molded into part of the front housing.
- Another illustrative embodiment of the present disclosure provides a hand-held power tool which comprises a housing, a motive source, a front endbell, an output shaft, a front housing, and a gear set assembly. The housing supports motive source, and includes the front endbell. The output shaft protrudes from an output end at the front endbell of the housing, and is functionally coupled to the motive source such that the output shaft rotates in response to activation of the motive source when the motive source is supplied with power. The front housing defines an interior space, and the output shaft is located in that interior space. The gear set assembly is located in the interior space of the front housing, and is configured to transfer rotation from the motive source to an output spindle. The gear set assembly also includes a ring gear characterized by an annular ring body having a plurality of teeth located on the interior periphery of the annular ring body and a surface located on an exterior periphery of the annular ring body opposite the interior periphery. The ring gear surrounds a portion of the output shaft and abuts the front endbell of the housing. The front housing and ring gear further include one or more piloting features, each of the one or more piloting features being configured to mate the front housing with the ring gear.
- In the above and other embodiments of the present disclosure may also comprise: one or more piloting features configured to mate the front housing with the front endbell; the one or more piloting features including one or more grooves formed in an interior surface of the front housing, and one or more corresponding ridges formed on a surface of an exterior periphery of the ring gear, wherein the one or more grooves are configured to receive the one or more corresponding ridges to prevent movement between the front housing and the ring gear; the one or more piloting features further comprise one or more grooves formed in the surface of the exterior periphery of the ring gear, and one or more corresponding ridges formed on the interior surface of the front housing, wherein the one or more grooves are configured to receive the one or more corresponding ridges to prevent movement between the front housing and the ring gear.
- Another illustrative embodiment of the present disclosure provides a hand-held power tool which comprises a housing, a motive source, a front endbell, an output shaft, a front housing, and a gear set assembly. The housing supports the motive source. The housing includes the front endbell. The output shaft protrudes from an output end at the front endbell of the housing, and is functionally coupled to the motive source such that the output shaft rotates in response to activation of the motive source when the motive source is supplied with power. The front housing defines an interior space, and the output shaft is located in that interior space. The gear set assembly is located in the interior space of the front housing, and is configured to transfer rotation from the motive source to an output spindle. The gear set assembly also includes a ring gear characterized by an annular ring body having a plurality of teeth located on the interior periphery of the annular ring body, and a surface located on an exterior periphery of the annular ring body opposite the interior periphery. The ring gear surrounds a portion of the output shaft and abuts the front endbell of the housing. The ring gear is inserted molded into the front endbell of the housing such that ring gear is restrained against both axial and rotational movement relative to the front endbell.
- The concepts described in the present disclosure are illustrated by way of example and not by way of limitation in the accompanying figures. For simplicity and clarity of illustration, elements illustrated in the figures are not necessarily drawn to scale. For example, the dimensions of some elements may be exaggerated relative to other elements for clarity. Further, where considered appropriate, reference labels may be repeated among the figures to indicate corresponding or analogous elements.
-
FIG. 1 is perspective view of an illustrative power tool; -
FIG. 2 is a side elevation view of the power tool ofFIG. 1 ; -
FIG. 3 is a front elevation view of the power tool ofFIG. 1 ; -
FIG. 4 is a rear elevation view of the power tool ofFIG. 1 ; -
FIG. 5 is a cross-section view of a motor assembly, a hammer case, and a ring gear of the power tool ofFIG. 1 ; -
FIG. 6 is a magnified cross-section view the interfaces between the motor assembly, the hammer case, and the ring gear of the power tool ofFIG. 1 ; -
FIG. 7 is a perspective view of the motor assembly, the hammer case, and the ring gear of the power tool ofFIG. 1 ; -
FIG. 8 is a cut-away perspective view of the motor assembly, the hammer case, and the ring gear of the power tool ofFIG. 1 ; -
FIG. 9 is a top view of another embodiment of the hammer case and the ring gear that may be used with the power tool ofFIG. 1 ; -
FIG. 10 is a top view of yet another embodiment of the hammer case and the ring gear that may be used with the power tool ofFIG. 1 ; -
FIG. 11 is a cut-away side elevation view of still another embodiment of ring gear alignment features that may be used with the power tool ofFIG. 1 ; -
FIG. 12 is a cut-away side elevation view of yet another embodiment of ring gear alignment features that may be used with the power tool ofFIG. 1 ; -
FIG. 13 is a top plan view of the ring gear shown inFIG. 12 ; -
FIG. 14 is a bottom plan view of the ring gear shown inFIG. 12 ; and -
FIG. 15 is a perspective view of a motor assembly and the ring gear shown inFIG. 12 . - While the concepts of the present disclosure are susceptible to various modifications and alternative forms, specific exemplary embodiments thereof have been shown by way of example in the drawings and will herein be described in detail. It should be understood, however, that there is no intent to limit the concepts of the present disclosure to the particular forms disclosed, but on the contrary, the intention is to cover all modifications, equivalents, and alternatives falling within the scope of the invention as defined by the claims.
- Referring now to
FIGS. 1-4 , anillustrative power tool 10 is shown. Thepower tool 10 is illustratively embodied as a cordless, electric power tool. In particular, thepower tool 10 is shown inFIG. 1 as a pistol-grip style cordless electric impact tool, which includes an impact mechanism in-line with an output of thetool 10. It should be appreciated, however, that in other embodiments, thepower tool 10 may be embodied as another type of impact tool, such as an angle impact tool in which the output of thetool 10 is disposed at an angle (e.g., a right angle) to the impact mechanism. It is appreciated thatpower tool 10 may include a native source such as a motor including an electric motor, or a pneumatic motor, for example. - The
illustrative power tool 10 includes atool housing 12 and ahammer case 14 as shown inFIG. 1 . Thehammer case 14 is also known as thefront housing 14. Thetool housing 12 defines abody 16, aback cap 18, and ahandle 20. Thebody 16 defines aninterior space 22 in which amotor assembly 24 of thetool 10 is positioned. It is appreciated thatmotor assembly 24 may include a motive source such as an electric motor(either corded or cordless), air, or other fluid motor. Theback cap 18 is coupled to thebody 16 when thetool 10 is assembled to close off theinterior space 22 and define aback end 26 that is positioned opposite thehammer case 14 of thetool 10. Theback cap 18 is coupled to thebody 16 using fasteners 28 (best seen inFIG. 4 ) that extend through theback cap 18 and into the motor assembly 24 (seeFigs. 5 ,7, and 8 ). - In the illustrative embodiment, the
handle 20 of thetool housing 12 extends away from thebody 16 and is configured to be graspable by a user of thetool 10. Apower source connection 30 is positioned at anend 32 of thehandle 20 opposite thebody 16. Thepower source connection 30 may be configured to connect to any source of power, such as, for example, a battery, a source of motive fluid, or an outlet connected to an electrical grid. In the illustrative embodiment, apower source 34 of thepower tool 10 is a battery attached to thepower source connection 30. - The
tool 10 includes a number of user-selectable input devices, which may be embodied as triggers, switches, or knobs configured to allow the user to adjust one or more features of thepower tool 10. For example, thehandle 20 includestrigger 36 configured to, among other things, turn an electric motor 38 (seeFig. 6 ) on/off in use of thetool 10. A Forward/Neutral/Reverse ("F/N/R")switch 40 is positioned in thehandle 20 near thebody 16 and thetrigger 36. The F/N/R switch 40, among other things, is configured to control the direction of rotation of themotor 38. Acontrol knob 42 is positioned on theback cap 18 of the tool 10 (as best seen inFIG. 4 ) and is configured to adjust the mode of operation of thepower tool 10. - The
hammer case 14 is positioned on thebody 16 of thetool housing 12 opposite theback cap 18. Thehammer case 14 includes atool end 44 configured to couple to thetool housing 12 and anoutput end 46 that includes anaperture 48 through which anoutput spindle 50 of thetool 10 protrudes. Thehammer case 14 defines aninterior space 52 in which agear assembly 54 and an impact mechanism (not shown) are housed. In the illustrative embodiment, thehammer case 14 is removably coupled to thetool housing 12 through one or more fasteners (not shown). In other embodiments, thehammer case 14 may be removably coupled to thetool housing 12 via other mechanisms (e.g., a snap fit). - Referring now to
FIGS. 5 and 6 , themotor assembly 24 includes theelectric motor 38, afront endbell 56, and arear endbell 58. Theelectric motor 38 is illustratively embodied as a brushless DC electric motor. Theelectric motor 38 includes arotor 60 configured to drive anoutput shaft 62 to output mechanical power and a stationary component (i.e., a stator) 64 that extends around therotor 60. Theoutput shaft 62 is functionally coupled to theoutput spindle 50 via thegear assembly 54. - The
rear endbell 58 is positioned in theinterior space 22 to be near theback cap 18 and thefront endbell 56 is positioned such that it is enclosed in theinterior space 22 of thetool housing 12 and theinterior space 52 of the hammer case 14 (as best seen inFIG. 7 ). Therotor 60 and thestator 64 of themotor 38 are positioned between the twoend bells front endbell 56 and therear endbell 58 cooperate to align therotor 60 and thestator 64 so that therotor 60 and thestator 64 extend parallel to acentral axis 66 of themotor 38. - The
illustrative gear assembly 54 may be embodied as, or include, a planetary gear set that is configured to transfer rotation of theoutput shaft 62 of themotor 38 to an impact mechanism of thetool 10 housed in thehammer case 14. Thegear assembly 54 includes aring gear 68 positioned in theinterior space 52 of thehammer case 14. Thering gear 68 surrounds theoutput shaft 62 and abuts thefront endbell 56. Thering gear 68 is formed as an annular ring body with aninner surface 70 that includes a plurality ofgear teeth 72 and anouter surface 74 configured to abut aninner surface 76 of thehammer case 14. - Referring now to
FIGS. 5-8 , pilotingfeatures 90 are integrated into thehammer case 14, thefront endbell 56, and thering gear 68. The piloting features 90 are configured to align thehammer case 14, thefront endbell 56, and thering gear 68 with one another. The piloting features 90 are also configured to prevent rotation of thering gear 68 relative to themotor assembly 24 and thehammer case 14. - In the illustrative embodiment, the piloting
features 90 include one ormore grooves 92 formed in theinner surface 76 of thehammer case 14, one or morecorresponding ridges 94 formed on theouter surface 74 of thering gear 68, and one or morecorresponding ridges 96 formed on anouter surface 98 of thefront endbell 56. Eachgroove 92 is sized to receive both acorresponding ridge 94 and acorresponding ridge 96. Eachgroove 92 extends axially along theinner surface 76 of thehammer case 14 from thetool end 44. In the illustrative embodiment, the dimensions of eachridge 94 are approximately the same as the dimensions of eachcorresponding ridge 96. Eachridge 94 is positioned along theouter surface 74 of thering gear 68 and eachridge 96 is positioned along theouter surface 98 of thefront endbell 56. In the illustrative embodiment, both sets ofridges ring gear 68 and thefront endbell 56. Thehammer case 14 defines an inner diameter that is sized to match an outer diameter of thering gear 68 and an outer diameter of thefront endbell 56. Althoughtool 10 is illustratively shown as including fourgrooves 92, fourridges 94, and fourridges 96, it will be appreciated that thetool 10 may include any number ofgrooves 92, correspondingridges 94, and correspondingridges 96 in other embodiments. - When assembling the
tool 10, the user aligns theridges 94 with correspondingridges 96, aligns thegrooves 92 of thehammer case 14 with the now alignedridges hammer case 14 axially along thecentral axis 66 toward thetool housing 12 until thetool end 44 of thehammer case 14 contacts thetool housing 12. As thehammer case 14 is advanced along thecentral axis 66, thegrooves 92 first pass over theridges 94 and then pass over theridges 96. - The piloting features 90 are configured to secure the
ring gear 68 relative to thefront endbell 56 such that thering gear 68 cannot rotate relative to themotor assembly 24. Thegrooves 92 of thehammer case 14 define aflange surface 100 that is configured to clamp thering gear 68 against thefront endbell 56 when thehammer case 14 is securely fastened to thetool housing 12. - In some prior art designs, the
ring gear 68 is coupled directly to thefront endbell 56. In the illustrative embodiment, the position of thering gear 68 relative to thefront endbell 56 is instead secured through the pilotingfeatures 90 of thehammer case 14. For example, thehammer case 14 is piloted by thefront endbell 56, while thehammer case 14 pilots thering gear 68. Such an embodiment reduces the number of parts of thetool 10 and may reduce the length of thetool 10 by removing connectors between thering gear 68 and thefront endbell 56. - As noted above, the piloting features 90 may include any number of
grooves 92 andridges features 90 ofFIGS. 7 and 8 include fourgrooves 92 spaced evenly around the inner surface 76 (seeFig. 6 ) of thehammer case 14, four correspondingridges 94 spaced evenly around the outer surface 74 (seeFig. 6 ) of thering gear 68, and fourcorresponding ridges 96 spaced evenly around theouter surface 98 of thefront endbell 56. Eachgroove 92 is configured to mate with both aridge 94 and aridge 96. In another illustrative example, shown inFIG. 9 , the pilotingfeatures 102 include threegrooves 104 formed in thehammer case 14 with three correspondingridges 106 formed in thering gear 68 and three corresponding ridges in the front endbell 56 (not shown). In another illustrative example, shown inFIG. 10 , the pilotingfeatures 108 include sixgrooves 110 formed in thehammer case 14 with six correspondingridges 112 formed in thering gear 68 and six corresponding ridges in the front endbell 56 (not shown). - While the piloting features 90, 102, 108 have been illustrated and described herein as including
grooves hammer case 14 andridges ring gear 68 andfront endbell 56, it is contemplated that the piloting features 90, 102, 108 may take other forms in other embodiments of thepower tool 10. By way of illustrative example, the piloting features might alternatively include ridges formed on thehammer case 14 and corresponding grooves formed in thering gear 68 andfront endbell 56. - Referring to
FIG. 11 , another embodiment of alignment features 200 for aring gear 268 of thepower tool 10 is shown. In this illustrative embodiment, afront endbell 256 is configured to surround thering gear 268, and thereby align and secure thering gear 268 in relation to themotor assembly 24 of thepower tool 10. Additionally, ahammer case 214 is configured to operatively couple to thetool housing 12, thefront endbell 256, and thering gear 268. Thefront endbell 256 includes anannular flange 202 formed in afront end 204 of thefront endbell 256. Theannular flange 202 includes aninner surface 206 that is configured to from acavity 208 that is sized to receive a portion of thering gear 268. Theinner surface 206 operatively couples to anouter surface 210 of thering gear 268 when thering gear 268 is assembled in thepower tool 10. Thefront endbell 256 is configured to secure thering gear 268 and prevent thering gear 268 from rotating during normal operation of thepower tool 10. - In this embodiment of the alignment features 200, the
hammer case 214 is configured to be secured to anouter surface 210 of thetool housing 12. Thehammer case 214 includes ahousing flange 212 and agear assembly surface 216 formed in amotor end 218 of thehammer case 214. Thehousing flange 212 is configured to operatively couple to theouter surface 210 of thetool housing 12, and thereby secure thehammer case 214 to thetool housing 12. Thegear assembly surface 216 is configured to abut theannular flange 202 of the front endbell 256 and thering gear 268 of the gear assembly 54 (see, also,Fig. 5 ). By so doing, thehammer case 214 cooperates with thefront endbell 256 to secure thering gear 268 to thepower tool 10. - Referring to
FIG. 12 , another embodiment of alignment features 300 for aring gear 368 of apower tool 10 is shown. The ring gear alignment features 300 are configured to align thering gear 368 with the motor assembly 24 (seeFig. 11 ) and allow thepower tool 10 to function properly. In this embodiment of the alignment features 300, thering gear 368 is insert molded to afront endbell 356 of themotor assembly 24. - Also shown in
FIG. 12 , ahammer case 314 is operatively coupled to thering gear 368, thefront endbell 356, and thetool housing 12 and is configured to seal theinterior space 22 of thepower tool 10. In the illustrative embodiment, thehammer case 314 includes anose piece 302 attached to it. Thehammer case 314 includes a taperedsection 304 and aflange 306 formed in thetool end 44 of thehammer case 314. The taperedsection 304 of thehammer case 314 is configured to operatively couple to aninner surface 310 of thetool housing 12. Theflange 306 is configured to operatively couple to theouter surfaces ring gear 368. - As shown in
FIG. 13 , thering gear 368 is formed as an annular ring body that includes aninner ring surface 318 having a plurality ofteeth 320 formed therein and anouter surface 322 having one or more fastener guide bores 324 formed therein. Thering gear 368 extends between amotor end 326 and another opposite end. Alip 330 is formed in themotor end 326 of thering gear 368 causing themotor end 326 to define amotor end opening 332 having a smaller diameter than an opposite end opening 334 defined in the opposite end of thering gear 368. Thelip 330 is configured to cooperate with thefront endbell 356 to secure thering gear 368 to the motor assembly 24 (see, also,Figs. 11 and 12 ). In the illustrative embodiment, thering gear 368 is secured to themotor assembly 24 by insert molding thering gear 368 directly into thefront endbell 356. - As shown in
FIG. 14 , one ormore grooves 336 are formed in themotor end 326 of thering gear 368 and are configured to securering gear 368 to thefront endbell 356. During the insert molding process, hot plastic enters into thegrooves 336. After the plastic cools, thegrooves 336 cooperate with the plastic of thefront endbell 356 to secure thering gear 368 to thefront endbell 356 such that thering gear 368 cannot rotate relative to thefront endbell 356. It is contemplated that, in other embodiments, thegrooves 336 may be replaced by other raised or recessed features that cooperate with thefront endbell 356 to secure thering gear 368 against rotation relative to thefront endbell 356. - As shown in
FIG. 15 , thefront endbell 356 includes anouter body 338 sized to receive thering gear 368. Theouter body 338 is configured to operatively couple to theouter surface 322 of the ring gear 368 (seeFigs. 13 and 14 ). One or more fastener guide bores 340 are formed in theouter body 338. When assembled, the fastener guide bores 340 of thefront endbell 356 are configured to align with the corresponding fastener guide bores 324 formed in thering gear 368. The fastener guide bores 324, 340 cooperate with fasteners (not shown) to secure themotor assembly 24 and thegear assembly 54 in thetool housing 12. When the fastener guide bores 324, 340 are aligned, fasteners are able to pass through themotor assembly 24 and be received by thehammer case 314. - The
front endbell 356 also includes aninner body 342 configured to interact with thelip 330 of thering gear 368 and secure thering gear 368 to thefront endbell 356. During the insert molding process, the plastic of thefront endbell 356 forms around thelip 330 thereby joining thering gear 368 to thefront endbell 356. In the illustrative embodiment, the insert molding process is accomplished by injecting thermoplastic into a mold in which thering gear 368 has been placed. The thermoplastic eventually hardens and thereby forms thefront endbell 356. - As best seen in
FIGS. 12-15 , theinner body 342 of thefront endbell 356 is also configured to pilot acamshaft 372 of theimpact mechanism 370 of thetool 10. As shown inFIG. 12 , thecamshaft 372 is integrally formed to include a planetary gear holder at adistal end 374 of thecamshaft 372. Theinner body 342 of thefront endbell 356 is formed to include a recessedannular surface 344 that engages thedistal end 374 of thecamshaft 372 when thetool 10 is assembled. Theinner body 342 of thefront endbell 356 is also formed to include awall 346 that extends away from the recessed annular surface 344 (thewall 346 also forming a part of theinner body 342 that engages and retains thelip 300 of thering gear 368, as described above). As best seen inFIG. 12 , when thetool 10 is assembled, an inner diameter of thewall 346 surrounds a portion of an outer diameter of thedistal end 374 of thecamshaft 372 such that thefront endbell 356 pilots thecamshaft 372. This configuration eliminates the need for a separate bearing and/or additional components to support thedistal end 374 of thecamshaft 372, thereby reducing the complexity and overall length of thetool 10. - While certain illustrative embodiments have been described in detail in the figures and the foregoing description, such an illustration and description is to be considered as exemplary and not restrictive in character, it being understood that only illustrative embodiments have been shown and described and that all changes and modifications that come within the scope of the claims are desired to be protected. There are a plurality of advantages of the present disclosure arising from the various features of the apparatus, systems, and methods described herein. It will be noted that alternative embodiments of the apparatus, systems, and methods of the present disclosure may not include all of the features described yet still benefit from at least some of the advantages of such features. Those of ordinary skill in the art may readily devise their own implementations of the apparatus, systems, and methods that incorporate one or more of the features of the present disclosure.
Claims (12)
- A hand-held power tool comprising:a housing (12) supporting a motive source (24);wherein the housing (12) includes a front endbell (356);an output shaft (62) protruding from an output end (46) at the front endbell (356) of the housing (12);wherein the output shaft (62) is coupled to the motive source (24) such that the output shaft (62) rotates in response to activation of the motive source (24) when the motive source is supplied with power;a front housing (14) defining an interior space (52);wherein the output shaft (62) is located in the interior space (52) of the front housing (14); anda gear set assembly (54) located in the interior space (52) of the front housing (14);wherein the gear set assembly (54) is configured to transfer rotation from the output shaft to an output spindle (50);wherein the gear set assembly (54) includes a ring gear (368), the ring gear (368) comprising an annular ring body having a plurality of teeth (72) located on an interior periphery of the annular ring body and a surface (74) located on an exterior periphery of the annular ring body opposite the interior periphery;wherein the ring gear (368) surrounds a portion of the output shaft (62) and abuts the front endbell (356) of the housing (12); andwherein the ring gear (368) and the front endbell (356) of the housing (12) are insert molded together such that the ring gear (368) is restrained against both axial and rotational movement relative to the front endbell (356);characterised in thatthe front housing (14) is coupled to the ring gear (368) and the front endbell (56);the front housing (14) includes a tapered section (304) coupled to an inner surface of the housing (12); andthe front housing (14) includes a flange (306) coupled to the surface located on the exterior periphery of the annular ring body opposite the interior periphery thereof, wherein the flange (306) is configured to operatively couple to the outer surfaces (322, 328) of the ring gear (368).
- The hand-held power tool of claim 1, wherein the front housing (14) includes a nose piece (302) located adjacent the output spindle (50).
- The hand-held power tool of any preceding claim, wherein the ring gear (368) includes a lip (330) formed on an interior portion of the ring gear (368) and at a first end of the ring gear (368);wherein the first end of the ring gear (368) is coupled to the front endbell (356);wherein the lip (330) defines a first opening (332) of the ring gear having a first diameter;wherein the ring gear (368) includes a second opening (334) defined at a second end of the ring gear (368) opposite the first end of the ring gear (368);wherein the second opening (334) includes a second diameter that is greater than the first diameter; andwherein the lip (330) is configured to cooperate with the front endbell (356) to secure the ring gear (368) to the motive source (24).
- The hand-held power tool of claim 3, wherein an inner body (342) of the front endbell (356) includes a recessed annular surface (344) and a wall (346) extending away from the recessed annular surface (344); and
wherein the wall (346) of the front endbell (356) contacts the lip (330) of the ring gear (368) to restrain the ring gear (368) against axial movement. - The hand-held power tool of claim 4, further comprising: a camshaft (372) piloted by the inner body (342) of the front endbell (356), the cam shaft (372) is coupled to the ring gear (368) and the output spindle (50); and
wherein the wall (346) of the front endbell (356) surrounds a portion of the camshaft (372) such that the front endbell (356) pilots the camshaft (372). - The hand-held power tool of any preceding claim, wherein the front endbell (356) includes a front endbell fastener guide bore (340), and the ring gear (368) includes a ring gear fastener guide bore (324);wherein the ring gear assembly is configured to be secured relative to the housing (12) when the front endbell fastener guide bore (340) is aligned with the ring gear fastener guide bore (324); andthe fastener guide bores (324, 340) cooperate with fasteners to secure the motive source (24) and the gear set assembly (54) in the tool housing (12).
- The hand-held power tool of claim 6, wherein the ring gear fastener guide bore (324) is formed in the surface located on the exterior periphery of the annular ring body.
- The hand-held power tool of claim 1, wherein the ring gear (368) includes a first end coupled to the front endbell (356);wherein the first end of the ring gear (368) includes a first securement feature selected from the group consisting of: at least one raised structure and at least one recessed structure;wherein the front endbell (356) includes a second securement feature that is the other of: at least one raised structure and at least one recessed structure; andwherein the second securement feature contacts the first securement feature to restrain the ring gear (368) against axial movement.
- A method of manufacturing the hand-held power tool of any preceding claim, comprising:providing a melted thermoplastic material to a mold in which the ring gear (368) is positioned to form the front endbell (356);coupling the housing (12) to the front housing (14); andcoupling the front housing (14) to the ring gear (368).
- The method of claim 9, further comprising:
arranging a portion of the melted thermoplastic material adjacent a lip (330) formed at a first end of the ring gear (368) to join the front endbell (356) to the ring gear (368). - The method of any of claims 10 and 12, further comprising:arranging a portion of the melted thermoplastic material to be in contact with a securement feature of the ring gear (368);wherein the securement feature is selected from the group consisting of: at least one raised structure and at least one recessed structure.
- The method claim 11, wherein the securement feature is defined at a first end of the ring gear (368) positioned adjacent the motive source.
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US201562171741P | 2015-06-05 | 2015-06-05 | |
EP16804550.8A EP3302881B1 (en) | 2015-06-05 | 2016-06-03 | Impact tools with ring gear alignment features |
PCT/US2016/035797 WO2016196979A1 (en) | 2015-06-05 | 2016-06-03 | Impact tools with ring gear alignment features |
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EP16804550.8A Division EP3302881B1 (en) | 2015-06-05 | 2016-06-03 | Impact tools with ring gear alignment features |
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EP3819083A1 EP3819083A1 (en) | 2021-05-12 |
EP3819083B1 true EP3819083B1 (en) | 2023-05-24 |
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EP20194822.1A Active EP3819083B1 (en) | 2015-06-05 | 2016-06-03 | Impact tool with ring gear alignment features |
EP16804550.8A Active EP3302881B1 (en) | 2015-06-05 | 2016-06-03 | Impact tools with ring gear alignment features |
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EP16804550.8A Active EP3302881B1 (en) | 2015-06-05 | 2016-06-03 | Impact tools with ring gear alignment features |
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EP (2) | EP3819083B1 (en) |
CN (2) | CN112276871A (en) |
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US4284109A (en) * | 1979-10-19 | 1981-08-18 | Cooper Industries, Inc. | Electric conductor wrapping tool |
TW572152U (en) * | 2002-11-08 | 2004-01-11 | Power Network Industry Co Ltd | Three-stage gearshift mechanism |
JP4084319B2 (en) * | 2004-02-23 | 2008-04-30 | リョービ株式会社 | Electric tool |
TWI278385B (en) * | 2006-05-30 | 2007-04-11 | Ikegami Mold Engineering Co Lt | Inspection machine for mold of injection molding and connecting device for said inspection machine and mold |
US7513845B2 (en) * | 2006-08-01 | 2009-04-07 | Eastway Fair Company Limited | Variable speed transmission for a power tool |
US7604528B2 (en) * | 2008-02-28 | 2009-10-20 | Techway Industrial Co., Ltd. | Electric grinding gun |
GB2474221B (en) * | 2008-08-06 | 2012-12-12 | Milwaukee Electric Tool Corp | Precision torque tool |
US8251158B2 (en) * | 2008-11-08 | 2012-08-28 | Black & Decker Inc. | Multi-speed power tool transmission with alternative ring gear configuration |
US8317350B2 (en) * | 2009-02-25 | 2012-11-27 | Black & Decker Inc. | Power tool with a light for illuminating a workpiece |
JP5510807B2 (en) * | 2010-03-08 | 2014-06-04 | 日立工機株式会社 | Impact tools |
JP5357840B2 (en) * | 2010-07-06 | 2013-12-04 | パナソニック株式会社 | Electric tool |
JP5655580B2 (en) * | 2011-01-17 | 2015-01-21 | 日本電産シンポ株式会社 | Transmission case |
DE102011055869A1 (en) * | 2011-11-30 | 2013-06-06 | Röhm Gmbh | drilling |
DE102012213723B4 (en) * | 2012-03-26 | 2023-11-02 | Robert Bosch Gmbh | Gear shifting device for a switchable transmission of a machine tool |
DE102012211914B4 (en) * | 2012-04-05 | 2023-06-15 | Robert Bosch Gmbh | Hand tool with a planetary gear |
CN204334195U (en) * | 2015-01-08 | 2015-05-13 | 张志雄 | A kind of disc type gear motor |
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2016
- 2016-06-03 EP EP20194822.1A patent/EP3819083B1/en active Active
- 2016-06-03 CN CN202011120909.2A patent/CN112276871A/en active Pending
- 2016-06-03 CN CN201680031488.1A patent/CN107614204B/en active Active
- 2016-06-03 EP EP16804550.8A patent/EP3302881B1/en active Active
Also Published As
Publication number | Publication date |
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EP3302881B1 (en) | 2020-09-23 |
EP3819083A1 (en) | 2021-05-12 |
EP3302881A1 (en) | 2018-04-11 |
CN107614204B (en) | 2020-11-06 |
CN107614204A (en) | 2018-01-19 |
CN112276871A (en) | 2021-01-29 |
EP3302881A4 (en) | 2019-01-23 |
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