The present invention relates to motor arrangements for pneumatic tools.
In one embodiment, the invention provides a motor arrangement for a pneumatic tool including a work attachment. The motor arrangement includes a single-piece motor cylinder defining a motor chamber, an inlet passage having an inlet longitudinal axis and adapted to receive a flow of motive fluid, forward and reverse passages communicating with the motor chamber, a throttle port, and at least one exhaust port communicating with the motor chamber for exhaust of motive fluid from the motor chamber. The motor arrangement also includes a motor rotor supported for rotation within the motor chamber and having an output shaft adapted for connection to the work attachment to drive operation of the work attachment. The rotor is operable to rotate in a forward direction in response to motive fluid flowing into the motor chamber from the forward passage and in a reverse direction in response to motive fluid flowing into the motor chamber from the reverse passage. The motor arrangement also includes a valve actuable to selectively place one of the forward and reverse passages in communication with the inlet passage for the provision of motive fluid from the inlet passage to the selected one of the forward and reverse passages. A throttle mechanism including a throttle actuator extends through the throttle port and is actuable to control the flow of motive fluid through the inlet passage.
In another embodiment, the invention provides a motor assembly for use in a pneumatic tool. The motor assembly includes an inlet conduit having an inlet longitudinal axis, a proximal end, and a distal end opposite the proximal end. An inlet passage communicates through the distal end and extends along the inlet longitudinal axis. The inlet conduit also includes a forward port in the exterior surface and communicating with the inlet passage, and a reverse port in the exterior surface and communicating with the inlet passage. A motor chamber wall is integrally formed with the proximal end of the inlet conduit, and defines an internal motor chamber, a first planar surface extending radially from the proximal end of the inlet conduit, and forward and reverse supply passages communicating between the first planar surface and the motor chamber. A motor rotor is supported within the motor chamber for rotation about a motor axis that is parallel to the inlet longitudinal axis. The motor rotor is adapted to rotate in a forward direction in response to motive fluid flowing into the motor chamber from the forward supply passage, and to rotate in a reverse direction in response to motive fluid flowing into the motor chamber from the reverse supply passage. The motor arrangement also includes a rotary valve including a valve passage. The rotary valve is supported by and rotatable about the proximal end of the inlet conduit between forward and reverse positions. The rotary valve places the valve passage in communication between the forward port and forward supply passage when in the forward position, and places the valve passage in communication between the reverse port and reverse supply passage when in the reverse position. The inlet passage is adapted to receive motive fluid from a source of motive fluid. The rotary valve is adapted to conduct motive fluid from the forward port to the forward supply passage to drive forward rotation of the rotor when the rotary valve is in the forward position, and is adapted to conduct motive fluid from the reverse port to the reverse supply passage to drive reverse rotation of the rotor when the rotary valve is in the reverse position.
In another embodiment, the invention provides a pneumatic tool including an inlet bushing adapted for communication with a source of motive fluid and a motor cylinder. The motor cylinder includes a motor chamber, a valve interface surface, an outer housing mounting surface, a throttle port, an inlet passage, an inlet bushing interface to which the inlet bushing is mounted such that motive fluid may be supplied to the inlet passage through the inlet bushing, and forward and reverse supply passages communicating between the valve interface surface and the motor chamber. A motor rotor is supported within the motor chamber for rotation about a motor axis in a forward direction in response to motive fluid flowing into the motor chamber through the forward supply passage, and in a reverse direction in response to motive fluid flowing into the motor chamber through the reverse supply passage. A valve is adjacent the valve interface and is actuable between a forward position in which the valve communicates between the inlet passage and the forward supply passage for driving the motor rotor in the forward direction, and a reverse position in which the valve communicates between the inlet passage and the reverse supply passage for driving the motor rotor in the reverse direction. A throttle mechanism extends through the throttle port and is actuable to control the flow of motive fluid into the inlet passage from the inlet bushing. An outer housing is mounted to the outer housing mounting surface of the motor cylinder and an exhaust passage is defined between the outer housing and the motor cylinder to conduct motive fluid exhausted from the motor chamber out of the tool. A majority of the exhaust passage extends parallel to the motor axis.
In another embodiment, the invention provides a pneumatic tool including a motor cylinder having an outer surface, a motor chamber, and a flange portion with at least one cylinder mounting hole. A motor rotor is supported in the motor chamber for rotation. A motive fluid inlet supplies motive fluid to the motor chamber to drive rotation of the motor rotor. The pneumatic tool also includes a work attachment having at least one attachment mounting hole, the work attachment being interconnected to the motor rotor and operable to perform work in response to rotation of the motor rotor. At least one fastener extends through the at least one cylinder mounting hole and the at least one attachment mounting hole to mount the work attachment to the flange portion of the motor cylinder. An outer housing surrounds the motor cylinder and has an inner surface sized and shaped for a snug fit around the flange portion of the motor cylinder, such that the at least one fastener is hidden from view by the work attachment and outer housing when the tool is assembled.
Other aspects of the invention will become apparent by consideration of the detailed description and accompanying drawings.
Before any embodiments of the invention are explained in detail, it is to be 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 of being carried out in various ways. Also, it is to be understood that the phraseology and terminology used herein is for the purpose of description and should not be regarded as limiting. The use of “including,” “comprising,” or “having” and variations thereof herein is meant to encompass the items listed thereafter and equivalents thereof as well as additional items. Unless specified or limited otherwise, the terms “mounted,” “connected,” “supported,” and “coupled” and variations thereof are used broadly and encompass both direct and indirect mountings, connections, supports, and couplings. Further, “connected” and “coupled” are not restricted to physical or mechanical connections or couplings.
With reference to
The motor chamber portion 205 includes a motor chamber longitudinal axis that is collinear with the main axis 195, and the inlet conduit portion 210 includes an inlet longitudinal axis or inlet axis that is also collinear with the main axis 195. The motor chamber portion 205 has a larger diameter than the inlet conduit portion 210. In other embodiments, the motor chamber portion 205 and inlet conduit portion 210 may be shaped other than illustrated.
The inlet conduit portion 210 includes a proximal end 215 integrally formed with the motor chamber portion 205 at a junction, an opposite distal end 220, and an exterior surface 225 extending between the proximal and distal ends 215, 220. An inlet passage 230 communicates with the distal end 220 (where it includes internal threads, as illustrated), extends substantially the entire length of the inlet conduit portion 210, and terminates at the proximal end 215. As used herein, a passage or port is said to “communicate” with or through a structure (e.g., the distal end 215 in the case of the inlet passage 230 or the exterior surface 225 or other surface in the case of other passages and ports described below) when it defines an aperture in the structure, and is said to communicate with another passage or port when it permits fluid flow into the other passage or port. The inlet passage 230 extends along and has a longitudinal axis collinear with the main axis 195. Communicating with the inlet passage 230 through the exterior surface 225 are a forward port 240, a reverse port 245, and a throttle port 250. A seal seat 255 is formed in and extends around the entire outer diameter of the exterior surface 225 of the inlet conduit portion 210 near the proximal end 215.
The motor chamber portion 205 of the motor cylinder 125 includes a motor chamber wall 260 that has an exterior surface 265 and that defines a first substantially planar surface 270 extending radially away from the proximal end 215 of the inlet conduit portion 210 at the junction. The first planar surface 270 surrounds the proximal end 215 and is consequently generally ring-shaped. The motor chamber wall 260 also defines a motor chamber 275 (
With reference to
With reference to
A ring-shaped pressure biasing surface 440 is defined by the step between the primary bore 420 and the counter bore 425 at the first end 410. Forward and reverse undercuts or open channels 445, 450 in the primary bore 420, acting in conjunction with the exterior surface 225 of the inlet conduit portion 210 when assembled, define forward and reverse biasing passages that intersect the pressure biasing surface 440.
The enlarged structural portion 430 defines a second planar surface 460 at the second end 415 of the rotary valve 135, a mounting finger 475 with an enlarged head 480, and a forward power reduction (“FPR”) port or groove 485. Extending through the enlarged structural portion 430 is a valve passage 500. The valve passage 500 communicates between the primary bore 420 and the second planar surface 460. A pair of stabilizing protrusions 510 are provided in the second end 415 of the rotary valve 135, and provide flat surfaces that are co-planar with each other and with the second planar surface 460.
The rest of the second end 415 is recessed with respect to the co-planar surfaces of the protrusions 510 and the second planar surface 460, and the three co-planar surfaces provide a three-legged riding surface for the second end 415 of the rotary valve 135 against the first planar surface 270. That is why there is a gap between the second end 415 and the first planar surface 270 in the cross-section views in the drawings (see, for example,
The resilient deflectable member 435 includes a relatively thin-walled cross piece 530 with a detent protrusion 535 with a smooth partially-spherical surface. The cross piece 530 extends over an exhaust path aperture 540 in the rotary valve 135.
Referring now to
When the rotary valve 135 is in the forward position (as illustrated), the valve passage 500 communicates between the forward port 240 and the forward supply passage 280, and the reverse biasing passage 450 communicates with the reverse port 245. With additional reference to
When the rotary valve 135 is in the reverse position, the valve passage 500 communicates between the reverse port 245 and the reverse supply passage 285, and the forward biasing passage 445 communicates with the forward port 240. With the rotary valve 135 in the reverse position, motive fluid flows from the inlet passage 230, through the reverse port 245, through the valve passage 500, through the reverse supply passage 285, and to the motor chamber 275 where it expands and causes the rotor 130 to rotate in a reverse direction (opposite the forward direction). At the same time, motive fluid flows from the inlet passage 230, through the forward port 240, through the forward biasing passage 445, and into the biasing chamber 600.
With additional reference to
The outer housing 120, 115 includes an interior or inner surface 610 (i.e., facing the motor cylinder 125, valve 135, and bushing 175, see
The inner surface 610 of the front housing 120 includes forward, reverse, and FPR detent grooves 625, 626, 627 into which the detent protrusion 535 of the deflectable member 435 of the rotary valve 135 is resiliently received when the rotary valve 135 is in the respective forward, reverse, and FPR positions. The detent protrusion 535 and detent grooves 625, 626, 627 together define a detent mechanism that resiliently holds the rotary valve 135 in the forward, reverse, and FPR positions (i.e., selected operating positions). In other embodiments, this arrangement may be reversed (e.g., with the deflectable member 435 on the front housing 120 and the detent grooves 625, 626, 627 on the rotary valve 135) or a different mechanism may be used.
While the illustrated embodiment provides only forward, reverse, and FPR detent grooves 625, 626, 627, other embodiments may include additional detent grooves to resiliently retain the rotary valve 135 in multiple FPR positions. Multiple FPR positions would permit the FPR port 485 to only partially register with the forward supply port 280, to restrict the amount of motive fluid that bypasses the motor chamber 275. One or more additional detent grooves may be provided to register a reverse power regulation (“RPR”) port 628 (see
As seen in
With additional reference to
In the biasing chamber 600, the pressure of the motive fluid (whether supplied through the forward or reverse biasing passage 445, 450) forces the second face of the first seal 145 against the depending portion 630 of the front housing 120, but the pressure does not apply a direct force against the front housing 120 (only indirectly through the first seal 145). The pressure is also applied to the pressure biasing surface 440 to give rise to a biasing force that urges the rotary valve 135 forward (i.e., to the left in
A face seal arises between the first and second planar surfaces 270, 460 to resist the loss or leakage of motive fluid between the first and second planar surfaces 270, 460. Because the second planar surface 460 does not extend around the entire circumference of the second end 415 of the rotary valve 135, the biasing force is concentrated on the rotary valve second planar surface 460 and the two stabilizing protrusions 510. This provides a smaller surface area for transferring the biasing force to the first planar surface 270 than if the second planar surface extended around the entire circumference of the second end 415 of the rotary valve 135, and consequently a higher pressure applied by the second planar surface 460 against the first planar surface 270 and a better seal. The face seal is also advantageous because it does not include sealing members that will wear down during repeated actuation of the rotary valve 135; instead the smooth planar surfaces 270, 460 slide with respect to each other without significant wear. Thus, substantially all motive fluid flowing through the valve passage 500 and into the forward and reverse supply passages 280, 285 reaches the motor chamber 275 (unless the rotary valve 135 is in the FPR position in which some of the motive fluid is vented to exhaust intentionally). Leakage from the interface between the valve passage 500 and forward and reverse supply passages 280, 285 due to motive fluid flowing between the first and second planar surfaces 270, 460 is minimized or completely eliminated.
With reference to
A slot 660 (
The ring 160 includes a recess 685 ribs or other abutment surfaces that engage the opposite sides of the actuator head 670, and the ring 160 covers the valve actuator 140. The user interface to control forward, reverse, and FPR operation of the tool 100 is therefore the ring 160. Because the ring 160 covers the actuator head, it eliminates any visible or exposed connection interface (e.g., a screw) which can be unsightly or become loosened during tool use. Enclosing the actuator head 670 within the ring 670 also reduces the likelihood of accidental disengagement of the valve actuator 140 from the rotary valve 135.
An operator toggles the tool 100 between the forward, reverse, and FPR operations by rotating the ring 160 in one direction or the other, which overcomes the detent force of the detent mechanism (detent protrusion 535 and detent grooves 625, 626, 627) and causes the actuator head 670 to slide along the outer surface 615 of the front housing 120. This in turn causes movement of the rotary valve 135 through the stem 675. Rotating the ring 160 thereby switches direction of operation of the tool 100. The operator is rewarded with a tactile feedback as the detent mechanism (detent protrusion 535 and detent grooves 625, 626, 627) clicks into the forward, reverse, and FPR positions.
The front housing 120 includes pockets in its interior surface 610 into which the housing support projections 213 of the motor cylinder 125 fit snugly. The interconnection of the pockets and housing support projections 213 properly locates (axially and radially) the front housing 120 with respect to the motor cylinder 125, and resists torsional loads between the front housing 120 and motor cylinder 125. A compliant gasket 710 sits between and provides a pressure tight seal between the work attachment 110 and the front housing 120 to resist leaking of exhaust motive fluid.
With the housing support projections 213 bottomed out in the pockets of the front housing 120, the front end of the outer housing extends around the flange portion of the motor cylinder 125 with a close clearance fit. The first ring seal 165, valve actuator 140, ring 160, and second ring seal 170 are then installed on the ring seat 655 portion of the front housing 120. Next the rear housing 115, exhaust cap 190, and inlet bushing 175 are assembled, with the first inlet seal 180 around the inlet bushing 175 above the threaded portion 310, and with the second inlet seal 185 and inlet washer 187 sandwiched between a portion of the inlet bushing 175 and a portion of the exhaust cap 190. The threaded end 310 of the inlet bushing 175 is threaded into the threaded portion of the inlet passage 230.
As the inlet bushing 175 is threaded into the inlet passage 230, it applies an axial thrust load on the rear housing 115 through the inlet washer 187, second inlet seal 185, and exhaust cap 190. As it is squeezed between the inlet bushing 175 and exhaust cap 190, the second inlet seal 185 provides a pressure-tight seal therebetween, and acts as a compliant member to accommodate tolerance stackups of the rigid components in the assembly. The rear housing 115 in turn applies a thrust load on the front housing 120 through a step in the rear housing 115 and the rear end of the front housing 120 (including the depending portion 630.
With work attachment 110 mounted to the motor cylinder 125 and the front housing mounted around the motor cylinder 125, the fasteners 305 are hidden from view outside of the tool 100 because they are within the work attachment 110 and the cavity bounded by the interior surface 610 of the outer housing 115, 120. Additionally, the outer surface of the work attachment 110 and the outer surface 615 of the outer housing 115, 120 are substantially aligned when the tool 100 is assembled, to create a substantially continuous tool outer surface that includes the outer surfaces of both the work attachment 110 and the outer housing 115, 120. Hiding the fasteners 305 in this manner provides a sleek appearance to the tool 100, resists tampering and disassembly of the tool, and physically shields the fasteners 305 from being caught on wires, edges, and other structures in a confined space, construction environment, or other work environment.
In
In
Thus, the invention provides, among other things, a motor arrangement for a pneumatic tool. Various features and advantages of the invention are set forth in the following claims.
The present application is a continuation of U.S. application Ser. No. 12/115,172, filed May 5, 2008, the entire contents of which are herein incorporated by reference.
Number | Name | Date | Kind |
---|---|---|---|
2267781 | Albertson | Dec 1941 | A |
3223182 | Mikiya | Dec 1965 | A |
3465646 | Kiester et al. | Sep 1969 | A |
3949944 | Bent | Apr 1976 | A |
3951217 | Wallace et al. | Apr 1976 | A |
4173828 | Lustig et al. | Nov 1979 | A |
4222443 | Chromy | Sep 1980 | A |
4235850 | Otto, Jr. | Nov 1980 | A |
4355564 | Gidlund | Oct 1982 | A |
4379492 | Hiraoka | Apr 1983 | A |
4403679 | Snider | Sep 1983 | A |
4434858 | Whitehouse | Mar 1984 | A |
4488604 | Whitehouse | Dec 1984 | A |
4625999 | Valentine et al. | Dec 1986 | A |
4708210 | Rahm | Nov 1987 | A |
4735020 | Schulz et al. | Apr 1988 | A |
4740144 | Biek | Apr 1988 | A |
4776561 | Braunlich et al. | Oct 1988 | A |
4779382 | Rudolf et al. | Oct 1988 | A |
5022469 | Westerberg | Jun 1991 | A |
D323961 | Fushiya et al. | Feb 1992 | S |
D335808 | Bruno et al. | May 1993 | S |
5210918 | Wozniak et al. | May 1993 | A |
5293747 | Geiger | Mar 1994 | A |
5346021 | Braunlich | Sep 1994 | A |
5346024 | Geiger et al. | Sep 1994 | A |
D352645 | Ichikawa | Nov 1994 | S |
5443196 | Burlington | Aug 1995 | A |
5505676 | Bookshar | Apr 1996 | A |
D372850 | Dubuque et al. | Aug 1996 | S |
5626198 | Peterson | May 1997 | A |
D380949 | Sung | Jul 1997 | S |
5813477 | Clay et al. | Sep 1998 | A |
D414093 | Zurwelle | Sep 1999 | S |
6039231 | White | Mar 2000 | A |
6109366 | Jansson et al. | Aug 2000 | A |
6179063 | Borries et al. | Jan 2001 | B1 |
6250399 | Giardino | Jun 2001 | B1 |
D444363 | Hayakawa et al. | Jul 2001 | S |
D447029 | Sun et al. | Aug 2001 | S |
6460629 | Bookshar et al. | Oct 2002 | B2 |
D476870 | Hayakawa et al. | Jul 2003 | S |
6691798 | Lindsay | Feb 2004 | B1 |
6789447 | Zinck | Sep 2004 | B1 |
6796385 | Cobzaru et al. | Sep 2004 | B1 |
D497785 | Izumisawa | Nov 2004 | S |
D502071 | Snider | Feb 2005 | S |
6880645 | Izumisawa | Apr 2005 | B2 |
6929074 | Lai | Aug 2005 | B1 |
6935437 | Izumisawa | Aug 2005 | B2 |
D510513 | Aglassinger | Oct 2005 | S |
D511284 | Henssler et al. | Nov 2005 | S |
7036795 | Izumisawa | May 2006 | B2 |
7040414 | Kuo | May 2006 | B1 |
D525502 | Chen | Jul 2006 | S |
D529353 | Wong et al. | Oct 2006 | S |
D530171 | Baker | Oct 2006 | S |
7140179 | Bass et al. | Nov 2006 | B2 |
D569206 | Takahagi et al. | May 2008 | S |
7461704 | Chen | Dec 2008 | B2 |
20020035890 | Kusachi et al. | Mar 2002 | A1 |
20040014411 | Jonas | Jan 2004 | A1 |
20050279519 | Clark | Dec 2005 | A1 |
20070181322 | Hansson et al. | Aug 2007 | A1 |
Number | Date | Country | |
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20110036606 A1 | Feb 2011 | US |
Number | Date | Country | |
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Parent | 12115172 | May 2008 | US |
Child | 12914076 | US |