Two-stage snow throwers (also known as snow blowers) receive snow in an auger housing mouth, wherein auger further cuts the snow and transfer the snow to impeller with discharges a snow through a chute. Existing two-stage snow throwers utilize complex auger housings, augers, impeller housings and chutes, increasing the complexity and cost of the overall snow thrower.
Frame 22 comprises one or more structures supporting the remaining components of snow thrower 20. In the example illustrated in which snow thrower 20 is a walk-behind snow thrower, frame 22 supports wheels 26, engine 28, drive transmission 30 (schematically shown), auger 32, impeller 34, snow discharge transmission 36 and snow discharge housing 38. Frame 22 further supports handles or grips 40 and controls 42. In other embodiments where snow thrower 20 comprises a riding snow thrower, frame 22 may additionally support a seat and may be supported by a greater number of wheels, inner rings or other ground propulsion members. In embodiments where snow thrower 20 is mounted to another vehicle, such as a lawnmower, all-terrain vehicle, truck or the like, frame 22 may or may not support axle 24 and wheels 26 and may be configured to be removably mounted to the vehicle. In embodiments where snow thrower 20 is powered by the engine or other torque source of the vehicle to which snow thrower 20 is mounted, frame 22 may not support an engine, such as engine 28, and may alternatively merely comprise a mounting structure or bracket supporting auger 32, impeller 34 and discharge housing 38 and facilitating their connection to the vehicle. Frame 22 may have a variety of different sizes, shapes and configurations depending upon the machine or method by which snow thrower 20 is moved across the terrain.
Wheels 26 are joined to an axle (not shown) so as to elevate and support frame 22 above the terrain 52. Wheels 26 further facilitate movement of snow thrower 20 across terrain 52. In the example illustrated, wheels 26 are rotationally driven to propel snow thrower 20. In other embodiments, wheels 26 may be physically pushed by a person or other vehicle. In some embodiments, wheels 26 may be replaced with one of more inner rings or other ground engaging members. In embodiments where snow thrower 20 is supported along the terrain by another vehicle, the axle as well as wheels 26 may be omitted.
Engine 28 comprises an internal combustion engine supported by frame 22 and operably coupled to wheels 26 by drive transmission 30 so as to drive wheels 26. Engine 28 is further operably coupled to auger 32 and impeller 34 by discharge transmission 36 so as to rotationally drive auger 32 about axis 56 and so as to rotationally drive impeller 34 about axis 54. In other embodiments, engine 28 may alternatively only drive auger 32 and impeller 34. In other embodiments, other mechanisms may be used to drive auger 32, impeller 34 or drive wheels 26.
Transmission 30 (schematically shown) comprises a series or arrangement of structures configured to transmit torque from engine 28 to wheels 26 via the axle. Likewise, auger transmission 36 comprises a series or arrangement of structures configured to transmit torque from engine 28 to auger 32 and impeller 34. Examples of such structures include, but are not limited to, drive shafts and driven shafts, chain and sprocket arrangements, belt and pulley arrangements, gear trains and combinations thereof. In one embodiment, transmission 36 is disposed on both sides of impeller 34, wherein transmission 36 extends between engine 28 and impeller 34 and wherein transmission 36 further extends between impeller 34 and auger 32. For example, in one embodiment, transmission 36 may include a bevel gear between impeller 34 and auger 32 for converting torque about axis 54 from impeller 34 to torque about axis 56 for auger 32.
Auger 32 comprises a mechanism configured to slice or cut through snow and to direct or move such snow towards impeller 34. As shown by
Auger flight assemblies 62 are substantially identical to one another but for the angular orientation of their respective flights or flight segments.
Flight supports 72, 74 are located at opposite portions of auger flight tube 70. Flight supports 72, 74 comprise structures extending from auger support tube 70 and secured to auger flights 76, 78. An example illustrated, each auger flight supports them to come Sunday for comprises a bar adding apertures 80 by which faster than a secure flights 76, 78 to such supports 72, 74. In other embodiments, apertures 80 may be omitted where other fasteners or other securing methods are used to join or secure flights 76, 78 to supports 72, 74. In the example illustrated, flight supports 72, 74 are angularly offset with respect to one another about axis. In the example illustrated, supports 72, 74 are angularly offset by 90 degrees with respect to one another. In other embodiments, supports 72, 74 may have other angular orientation depending upon the number of flight segments and the length of assembly 62. Although flight 62 is illustrated as including two such supports, in other embodiments, flights and 62 may include greater than two supports.
Inner teeth 86 project from blade 82 towards support tube 70 (shown in
Outer teeth 88 project from blade 82 away from the centerline of flight assembly 62, away from axis 54 and away from support tube 70. Outer teeth 88 further assist in cutting through snow or ice. In the example illustrated, teeth 88 are angularly offset from blade 82 for enhanced cutting through snow. As shown by
Attachment flanges 90, 92 extend from an inner edge of blade 82 and are configured to mount flight 76 to supports 72 and 74. In the example illustrated, each of flanges 90, 92 includes apertures 96 which are located size to align with apertures 80 of flight supports 72 and 74. As shown by
As shown by
According to one embodiment, flight segments 76 and 78 are formed from a flat annular ring or ribbon 97 (shown in
According to one embodiment, each flight is formed from a 12 gage sheet of metal conforming to ASTM A569. In other embodiments, each flight segment may be formed in other fashions and from other materials.
Elastomeric extensions 81 comprise elongate helical strips or bands of elastomeric material configured so as to be captured between auger flight segment 76, 77 and so as to project or extend outwardly beyond the outer edge of blade 82 and hourly beyond outer teeth 88. In one example, elastomeric extensions 81 sufficiently project beyond flight segment 76 so as to engage or contact the ground when snow thrower 20 is in a normal, at rest horizontal state on a horizontal terrain. As a result, elastomeric extensions 81 facilitate wiping or cleaning down to the ground when removing snow.
Although not shown, auger flight assembly 62′ additionally includes auger flight segments which match auger flight segments 78 and which capture elastomeric extension therebetween. The additional elastomeric extension captured between auger flight segment 78 and the matching auger flight segment is identical to auger flight extension 81 shown in
In other implementations, auger flight extensions 81 may be coupled to or joined to auger flight or auger flight segments 76 and 78 in other fashions. For example, in another implementation, auger flight extensions 81 may comprise elastomeric materials which are over molded onto flight segments 76, 78. In yet other implementations, auger flight 77 may be omitted, wherein auger flight extension 81 is mounted to one side of flight segment 76. In yet another example implementation, extension 81 and flight segments 76 may be configured to cooperate with one another so as to snap together for retaining extension 81 with respect to segment 76. For example, extension 81 may be provided with an elastomeric head portion that resiliently compressed or deform during insertion into a receiving cavity or clip provided on flight segment 76. Extension 81 may alternatively be joined to flight segment 76 a tongue and groove arrangements, wherein extension 81 is provided with one of a tongue and groove and wherein flight 76 is provided with the other of a tongue and groove to radially retain extension 81 with respect to flight segment 76.
In one implementation, elastomeric extension 81 are formed from rubber material. In yet another implementation, elastomeric extensions may be formed from an elastomeric polymer. Although illustrated as a imperforate continuous band or strip, in some other implementations, elastomeric extension 81 may comprise a series of elastomeric fingers, functioning more as a broom rather than a scraper.
Impeller 34 comprises a series of paddles or blades circumferentially arranged about axis 54 and configured to be rotationally driven about axis 54. Impeller 34 is configured to receive the snow gathered and directed to it by auger 32 and to further impel snow away from snow thrower 20.
Snow discharge housing 38 comprises one or more structures configured to guide and direct the movement and the discharge of snow. Snow discharge housing 38 includes auger housing 100, scraper bar 101, impeller housing 102 and discharge chute 104. Auger housing 100 forms the head of snow thrower 20 and partially extends about or partially surrounds auger 32. Auger housing 100 rotationally supports auger 32 for rotation about axis 56 which is perpendicular to axis 54 and the direction of forward travel.
As shown by
Impeller housing 102 extends about impeller 34 and opens into an interior of auger housing 100. Impeller housing 102 further opens into chute 104. Impeller housing 102 cooperates with impeller 34 such that snow impelled or moved by impeller 34 is directed up and through chute 104.
As shown by
Impeller can 102 (also known as impeller housing 102) comprises a stamped and deep drawn structure configured to surround impeller 34 and to be attached to chute 104. As shown by
In the example illustrated, each of auger housing 100 and can 102 are stamped, washed, painted and baked separately or individually. As a result, each of faces 112 and 122 are coated with paint across a majority, if not entirety, of the faces prior to faces 112 and 122 being placed in contact and abutment with one another. Because the juncture of auger housing 100 and can 102 avoids overlapping seams for welding, the juncture of auger housing 100 and can 102 avoids problems associated with captured lubrication stamping oil that is not washed away prior to painting and baking and it may damage the subsequent paint coating. Consequently, the finished appearance of housing 38 is enhanced, assembly is simplified and cost is reduced.
Chute 104 comprises one or more structures configured to receive snow impelled by impeller 34 and to direct such snow away from snow thrower 20. In the example illustrated, chute 104 is configured to be selectively rotated about a substantially vertical axis such that snow may be blown or thrown to either transverse side of snow thrower 20 and at various rear and forward angles with respect to snow thrower 20. In one embodiment, chute 104 is configured to be manually rotated about a vertical axis. In other embodiments, such rotation may be powered. In yet other embodiments, chute 104 may be stationary.
Handle assembly 308 comprises one or more structures facilitating gripping of chute assembly 306 and rotation of chute assembly 306. Handle assembly 308 includes lower handle 318 and upper handle 320. Lower handle 318 mounts to chute assembly 306. Upper handle 320 mounts to lower handle 318 and provides a surface by which handle assembly 308 may be manually gripped. In other embodiments, other handles may be provided for manipulating and rotating chute assembly 306.
Rotator assembly 310 serves as an interface between chute assembly 306 and the mounting bracket 322 extending from housing 302. Rotator assembly 310 further serves as a bearing mechanism by which chute assembly 306 may be rotated about a substantially vertical axis with respect to housing 102 and a remainder of snow thrower 20.
As shown by
Outer ring 332 comprises one or more structures coupled to or fixed to bracket 322 of housing 102 and extending about inner ring 330, wherein outer ring 332 includes a projection 340 extending into track 334 and moving along track 334 as inner ring 330 rotates relative to outer ring 332. In the example illustrated, outer ring 332 is formed by two clamshell halves or portions which are joined to one another about inner ring 330. In other embodiments, outer ring 332 may have other configurations.
Detents 334 comprise openings, indents, notches, depressions, voids or other cavities formed in outer ring 332 which are configured to releasably receive a portion of projection 336 encircle axis 335 and a plurality of predefined locations. Although illustrated as comprising rectangular openings extending completely through portions of outer ring 332, in other embodiments, detents 334 may comprise depressions are notches only partially projecting into portions of outer ring 332.
Projection 336 comprises a structure supported and retained by inner ring 330 that is configured to releasably or removably project into one or more of detents 334. Projection 336 comprises a structure that is movable between a locking position or state in which projection 336 is received and projects into one or more of detents 334 and a released state our position in which projection 336 is withdrawn from one or more of the detents 334. Projection 336 is resiliently biased towards the locking position or state.
In the example illustrated, projection 336 comprise a single integral unitary structure. In other embodiments, projection 336 may comprise multiple components. In the example illustrated, projection 336 comprises a leaf spring mounted to inner ring 330. In other embodiments, projection 336 may comprise a separate pin, latch or other structure resiliently biased by separate spring, such as a separate leaf spring or a separate compression spring. In yet other embodiments, projection 336 may comprise a structure interrelate formed as part of a single unitary body with inner ring 330. For example, projection 336 may comprise a leaf spring supporting a pin or other structure configured to project into detents 334, wherein the leaf spring and the pin are integrally formed as part of a single unitary body with inner ring 330.
As shown by
During rotation of chute assembly 306, nose 344 of projection 336 is compressed or forced away from detents 334. In other words, the leaf spring of projection 336 is resiliently deformed to a more flat and state, allowing nose to be withdrawn from detents 334 and allowing inner ring 330 and the associated chute assembly 106 to be rotated relative to outer ring 332 and the chute housing 102.
Although inner ring 330 is illustrated and described as being associated with chute assembly 106 while outer ring 332 is associated with or secured to impeller housing 102, in other embodiments, this relationship may be reversed. Although projection 336 is illustrated and described as being secured to inner ring 330 while detents 334 are associated with outer ring 332, in another embodiment, these relationships may be reversed. In other words, in another embodiment, projection 336 may alternatively be associated with outer ring 332 while detents 334 are associated with inner ring 330. Although rotator assembly 310 is illustrated as having a single projection 336, in other embodiments, rotator assembly 310 may be provided with multiple projections 336 about axis 335. Although inner ring 330 is illustrated and described as providing a groove or track 334 which slidably receives one or more extensions, projections or tabs 140 of outer ring 332, in other embodiments, inner ring 330 may alternatively include the projections or tabs 340 while outer ring 332 includes one or more grooves which serve as one or more tracks for slidably guiding tabs 340 during rotation about axis 335.
Overall, rotator assembly 320 provides a rotation interface between chute assembly 306 and impeller housing 102 that is inexpensive, less complex and more easily assembled as compared to current snow thrower chute rotation interfaces. In the example illustrated, rotator assembly 310 is formed from four main parts: inner ring 330, the two halves forming outer ring 332 and projection 336. Rotator assembly room 310 is efficiently assembled, not requiring fasteners for projection 336. In addition, rotator assembly 310 provides a plurality of discrete angular positions at which chute assembly 306 may be positioned and retained.
Drive adapter 430 comprises one or more structures configured to be mounted to inner ring 330 or the particular ring which is mounted to chute assembly 306. In the example illustrated, drive adapter 430 comprises a toothed collar having teeth 434 configured to be engaged by corresponding teeth of drive gear 423 (shown in
As shown by
Although the present disclosure has been described with reference to example embodiments, workers skilled in the art will recognize that changes may be made in form and detail without departing from the spirit and scope of the defined subject matter. For example, although different example embodiments may have been described as including one or more features providing one or more benefits, it is contemplated that the described features may be interchanged with one another or alternatively be combined with one another in the described example embodiments or in other alternative embodiments. Because the technology of the present disclosure is relatively complex, not all changes in the technology are foreseeable. The present disclosure described with reference to the example embodiments and set forth in the following claims is manifestly intended to be as broad as possible. For example, unless specifically otherwise noted, the claims reciting a single particular element also encompass a plurality of such particular elements.
The present application is a continuation application claiming priority under 35 USC Section 120 from co-pending application No. PCT/US 2012/020083 filed on Jan. 3, 2012 and entitled TWO STAGE SNOW THROWER CHUTE by Samuel J. Gerritts et al., full disclosure of which is hereby incorporated by reference. Application No. PCT/US 2012/020083 claims priority to U.S. Provisional application Ser. No. 61429454 filed on Jan. 4, 2011 by Daniel L. Steinike et al. and entitled TWO STAGE SNOW THROWER, the full disclosure of which is hereby incorporated by reference. Application No. PCT/US 2012/020083 claims priority to U.S. Provisional application Ser. No. 61434460 filed on Jan. 20, 2011 by Daniel L. Steinike et al. and entitled TWO STAGE SNOW THROWER CHUTE, the full disclosure of which is hereby incorporated by reference.
Number | Name | Date | Kind |
---|---|---|---|
153931 | Bushfield | Aug 1874 | A |
221207 | Avery | Nov 1879 | A |
1668166 | McKee et al. | May 1928 | A |
3078603 | Ertsgaard et al. | Feb 1963 | A |
3468041 | Mattson et al. | Sep 1969 | A |
3742626 | Ellis | Jul 1973 | A |
4110921 | Poker, Jr. | Sep 1978 | A |
5163239 | Lampe | Nov 1992 | A |
5174053 | Takeshita | Dec 1992 | A |
5177888 | Thorud | Jan 1993 | A |
5203102 | Motteli | Apr 1993 | A |
5209003 | Maxfield et al. | May 1993 | A |
5267402 | Russell et al. | Dec 1993 | A |
6938364 | White et al. | Sep 2005 | B2 |
6952893 | Sanderson | Oct 2005 | B1 |
7698839 | Phillips et al. | Apr 2010 | B1 |
7703223 | Walker et al. | Apr 2010 | B2 |
7730642 | Sugiura | Jun 2010 | B2 |
8240070 | Phillips et al. | Aug 2012 | B1 |
20020174572 | Prochnow et al. | Nov 2002 | A1 |
20060150444 | Friberg et al. | Jul 2006 | A1 |
20070022638 | Sueshige | Feb 2007 | A1 |
20090183395 | Sugiura | Jul 2009 | A1 |
20100058621 | Harmelink | Mar 2010 | A1 |
Entry |
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PCT international preliminary report on patentability for PCT/US 2012/020083 mailed on Jul. 18, 2013. |
Number | Date | Country | |
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20140150302 A1 | Jun 2014 | US |
Number | Date | Country | |
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61429454 | Jan 2011 | US | |
61434460 | Jan 2011 | US |
Number | Date | Country | |
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Parent | PCT/US2012/020083 | Jan 2012 | US |
Child | 13909019 | US |