Lawnmowers can be configured as garden tractors, riding mowers, and walk-behind mowers. Some walk-behind mowers can include a prime mover mounted to the deck of the lawnmower. Mower decks associated with garden tractors, riding mowers and walk-behind mowers can be removably attached to the frame of these self-propelled machines. More than one blade can be mounted in the cutting chamber of the deck for any of these embodiments of a lawnmower.
Lawnmowers can be configured to either mulch clippings, which are generated as mowing is performed, or to discharge the clippings through a discharge chute or a discharge opening. Mulching mowers cut the clippings into fine particles and blow the clippings back into the lawn. Discharge mowers can either discharge the clippings directly onto the lawn surface or into a bag that is attached to the lawnmower. The clippings can then be disposed of elsewhere. Some lawnmowers can be converted between mulching lawnmowers and discharge lawnmowers by inserting or removing a removable conversion assembly within the cutter housing and/or the discharge chute such that the operator of the lawnmower removes or installs the removable assembly in order to place the lawnmower in the discharge mode and the mulching mode, respectively. Instead of a removable conversion assembly, some lawnmowers have a movable mulching assembly that remains mounted within the cutter housing and/or the discharge chute and is movable by the operator of the lawnmower between a mulching position and a discharging position within the cutter housing. Some mulching systems are variable mulching systems in which one or more movable components can be moved into any one of a plurality of positions between the mulching position and the discharging position such that some of the clippings are mulched and some of the clippings are directly discharged without mulching, via the discharge chute, into a collection bag or onto the ground.
According to an aspect of the disclosed subject matter, a cutter housing assembly for a lawnmower can include a cutter housing that has a first cutting chamber with a first circular chamber wall that includes a first discharge opening, and a second cutting chamber with a second circular chamber wall that includes a second discharge opening. A first ring gate with a first ring opening and a first blocking segment can be concentric with the first circular chamber wall and rotatably attached to the cutter housing so as to be rotatable between: (a) an opened position in which the first ring gate is positioned with the first ring opening having a first overlap with the first discharge opening to provide a discharge mode, and (b) a closed position in which the first ring gate is positioned with the first ring opening having a decreased overlap, relative to the first overlap, with the first discharge opening to provide a mulch mode. A second ring gate, with a second ring opening and a second blocking segment, can be concentric with the second circular chamber and rotatably attached to the cutter housing so as to be rotatable between: (a) an opened position in which the second ring gate is positioned with the second ring opening having a first overlap with the second discharge opening to provide a discharge mode, and (b) a closed position in which the second ring gate is positioned with the second ring opening having a decreased overlap, relative to the first overlap, with the second discharge opening to provide a mulch mode. At least one actuator can be operatively engaged with at least one of the first ring gate and second ring gate, and controllable by a user to rotate at least one of the first ring gate and second ring gate between the opened position and the closed position, respectively, wherein the first ring gate rotates within the first cutting chamber and is concentric with the first cutting chamber.
According to another aspect of the disclosed subject matter, a cutter housing assembly for a lawnmower can include a first cutting side wall and top wall that define a first cutting chamber with a first discharge opening located within a side of the first cutting wall, the top wall including at least one slot. A ring gate, with a first ring opening and first blocking segment, can include at least one flange extending into the at least one slot of the top wall so as to be selectively rotatable in the slot between: (a) an opened position in which the ring gate is positioned with the first ring opening having a first overlap with the first discharge opening to provide a discharge mode, and (b) a closed position in which the ring gate is positioned with the first ring opening having a decreased overlap, relative to the first overlap, with the first discharge opening to provide a mulch mode. A first rotation actuator can include a motor operatively engaged with the at least one flange of the ring gate, and the first rotation actuator controllable by a user for rotating the ring gate between the opened position and the closed position, wherein the ring gate is configured to rotate within the first cutting chamber and is concentric with the first cutting chamber. A second cutting chamber with a second chamber side wall can include a second discharge opening, wherein the ring gate further includes a secondary ring opening and a secondary blocking segment configured such that, in the opened position the secondary ring opening has a secondary overlap with the second discharge opening, and (b) in the closed position the secondary ring opening has a decreased overlap, relative to the secondary overlap, with the second discharge opening.
According to another aspect of the disclosed subject matter, a lawnmower can include a cutter housing assembly that includes a first cylindrically shaped cutting chamber having a discharge opening, and a second cylindrically shaped cutting chamber located immediately adjacent to and in fluid communication with the first cylindrically shaped cutting chamber via a second opening. A first cylindrically shaped ring gate can be located within and concentric with the first cylindrically shaped cutting chamber, the first cylindrically shaped ring gate including a side wall and at least one opening in the side wall. A second cylindrically shaped ring gate can be located within and concentric with the second cylindrically shaped cutting chamber, the second cylindrically shaped ring gate including a second side wall and at least one opening in the second side wall. An actuator operatively can be connected to the first cylindrically shaped ring gate and the second cylindrically shaped ring gate and configured to rotate each of the first cylindrically shaped ring gate and the second cylindrically shaped ring gate.
The disclosed subject matter of the present application will now be described in more detail with reference to exemplary embodiments of the apparatus and method, given by way of example, and with reference to the accompanying drawings, in which:
A few inventive aspects of the disclosed embodiments are explained in detail below with reference to the various figures. Exemplary embodiments are described to illustrate the disclosed subject matter, not to limit its scope, which is defined by the claims. Those of ordinary skill in the art will recognize a number of equivalent variations of the various features provided in the description that follows.
Mulching assemblies are known that convert a lawnmower between a discharge mode and a mulch mode. Some mulching assemblies remain mounted in the cutter housing of the lawnmower and require many components, including different doors, levers, and rotating gears that facilitate conversion from a full mulching mode to a discharge mode. However, these many components can result in a labor-intensive assembly for manufacturing and/or for operation and maintenance. Thus, the manufacturing and operating cost for lawnmowers with automatic cutting/mulching conversion devices can be greater as compared to a lawnmower that includes a removable mulching conversion assembly. However, removal and installation processes for removable mulching conversion assemblies are typically inconvenient and time consuming. Thus, there is a need for an automatic mulching conversion assembly that can reduce manufacturing and operation cost and lessen or avoid any inconvenience perceived by the operator when converting the lawnmower between the discharge mode and the mulching mode.
In accordance with aspects of the disclosure, a variable mulch system for a single or multi bladed lawnmower deck or cutter housing can include rings or ring gates that surround cutting chambers. The rings can include holes or opening to allow for grass and other clippings to move from chamber to chamber and/or to be discharged. As the ring gates rotate, around the same axis as each of their respective blades, one or more openings/holes in each ring and/or openings/holes in the particular chamber are closed off. As the openings/holes are closed off, partial mulching and partial discharge can take place. Once the ring, for a particular chamber, is rotated such that the opening/hole is completely blocked, full mulching can take place. The rings, i.e. adjustable ring gates, can be suspended from a top of the cutter housing and ride in channels in the top of the cutter housing. The rings can be rotated by a push/pull cable system, a crank and gear system, or an electronically powered gear system, for example.
In accordance with at least one embodiment, a blade system of a lawnmower can include three cutting chambers for cutting grass. The chambers can be interconnected via openings/holes so the cut grass or other clippings can pass through from one chamber to another. Accordingly, a grass flow path can be provided. Once grass is transferred to the last chamber, the grass can be discharged onto the lawn via an opening/hole in the last chamber and in the last ring. The openings/holes can be adjustably opened and closed by an internal adjustable ring gate, attached to each chamber.
Accordingly, the disclosure provides a mower with a plurality of circular housing walls that can have openings forming a grass flow path, and gates defining walls that are concentric with the housing walls, such that the gates overlap the walls and rotate between positions to open and close the openings, in accordance with the disclosed subject matter.
As shown in
The lawnmower 10 can also include a discharge chute 17 and a collection bag 16. The discharge chute can be located at the rear of the cutter housing 11 and adjacent to the wheel 14 at the right rear of the cutter housing 11, for example. The discharge chute 17 can be oriented to discharge the vegetation clippings toward the side of the lawnmower 10 or toward the rear of the lawnmower 10. In the exemplary embodiment of
As shown in
The operator can control movement of the lawnmower 30 on a lawn, terrain, or other surface using a steering wheel 33, one or more control pedals 34, and/or other control mechanisms. The control pedals 34 can be provided on or adjacent to the foot supports 32 of the lawnmower 30. For example, a control pedal 34 can be configured as an accelerator to provide control of travel speed of the lawnmower 30 and can also be associated with a clutch and transmission to control forward/reverse direction and speed ranges for the lawnmower 30. The lawnmower 30 can include a pair of front wheels 35 and a pair of rear wheels 36.
The lawnmower 30 can include a cutter housing 37. The cutter housing 37 can also be referred to as a deck or as a mower deck or as a cutter deck of the lawnmower 30. The cutter housing 37 can support one or more blades 40, 41 as shown in
The lawnmower 30 can include a frame or chassis 39. The frame 39 can provide a main supporting structure of the lawnmower 30 to which various components of the lawnmower 30 are attached.
The frame of the lawnmower can also support a body 44 of the lawnmower 30. The body 44 can provide an outer, finished surface that can cover the frame 39, prime mover 38, and other components or portions of components of the lawnmower 30. The body 44 can include an engine hood 45. The engine hood 45 can cover at least a portion of the prime mover 38, as described above, which can be in the form of a gasoline engine. The foot support(s) 32, as described above, can be integrally formed and/or supported by the body 44 of the lawnmower 30.
The lawnmower 30 can also include a collection bag 46 supported by the frame 39 of the lawnmower. A discharge opening and/or passageway 47 can be provided to transfer clippings from a cutting chamber 48 to the collection bag 46 when the lawnmower 30 is in a discharge mode. The body 44 of the lawnmower 30 can include a collection bag cover 49 that is positioned over and/or covers the collection bag 46.
The lawnmower 30 can include a cutter housing lift assembly that controls height of the cutter housing 37 relative to the ground (and to frame 39). The cutter housing 37 can be provided with housing wheels or housing rollers 51. The housing rollers 51 can limit how close the cutter housing 37 or particular portion of the cutter housing 37 gets into the lawn.
The lawnmower shown in
The cutter housing 37 can include a top wall 55 and one or more sidewalls 56 that extend downward from the top wall 55 and toward the ground. The top wall 55 can be demarcated from the sidewall(s) 56 by the top wall 55 having a substantially horizontal disposition and the sidewalls 56 having a substantially vertical disposition. The top wall 55 can be demarcated from the sidewall(s) 56 by being constructed of respective parts and/or being separated by a particular feature of the lawnmower 30, such as a distinct bend or ridge in the cutter housing. The top wall 55 can be integrally formed with the sidewall(s) 56. The top wall 55 and the sidewall(s) 56 can form at least portions of the first cutting chamber 53 and the second cutting chamber 54 shown in
The cutter housing 37 shown in
Each of the cutting chambers 71, 72, 73 can be provided with a respective rotating blade. The rotating blades can include a first blade 76, a second blade 77, and a third blade 78. Each of the rotating blades can be supported by a shaft with associated pulley. The shaft can be pivotably supported by a bearing housing that is provided in the top wall 63 of the cutter housing 61. Each of the shafts can be mechanically powered by the prime mover of the particular lawnmower, in conjunction with a mechanical power transfer arrangement, such as a pulley(s) and belt arrangement as described above.
The cutter housing 61 can include a front wall 67 as well as a front lower flange 88. The front lower flange 88 can extend along a front extent of the cutter housing 61. The front lower flange 88, front wall 67, and top wall 63 can collectively form a channel to add structural support to the cutter housing 61.
The cutter housing 61 of
The cutter housing 61 of
As described above, a lawnmower of the disclosure can include a lift assembly, i.e. a cutter housing lift assembly that controls height of the cutter housing or deck. The height of the cutter housing 61 can be controlled so as to be positioned between a raised position and a lowered position, as well as positioned in interim positions between the raised position and the lowered position. The height of the cutter housing 61 can be controlled by a lever that is manipulated by the operator of the particular lawnmower.
As shown in
The conversion assembly 110 can include one or adjustable ring gates 120, such as a first adjustable ring gate 121 and a second adjustable ring gate 141. In the opened position 111, the adjustable ring gates 120 can be respectively positioned so that the discharge openings 90 are opened to provide a discharge mode in all the cutting chambers 70 of the cutter housing 61. In the closed position 112, the adjustable ring gates 120 can be positioned so that the discharge openings 90 are closed to provide a mulch mode. One adjustable ring gate 120 can be in the opened mode while another adjustable ring gate is in the closed mode.
As shown in
The first adjustable ring gate 121 can include a first ring body 122. The first ring body 122 can be in the form of a cylinder or segment of a cylinder and include an upper edge 123 and a lower edge 124. Additionally, the first ring body can include an inner surface 125 and an outer surface 126. The first ring body 122 can include a first ring opening or hole 127 and a second ring opening or hole 129. The first ring body 122 can further include a first blocking segment 131 and a second blocking segment 132.
The first ring opening 127 can be defined, along a top of the first ring opening 127, by and/or associated with a first joining segment 128. The first joining segment 128 connects the blocking segments 131, 132 (of the first ring body 122) about the first ring opening 127. Accordingly, respective edges of the blocking segments 131, 132 serve to define sides of the first ring opening 127. The second joining segment 130 connects the blocking segments 131, 132 (of the first ring body 122) about the second ring opening 129. Accordingly, respective edges of the blocking segments 131, 132 serve to define sides of the second ring opening 129.
In the opened position 111, the first adjustable ring gate 121 can be positioned with the first ring opening 127 having a first overlap with the first discharge opening 91. Since the first ring opening 127 overlaps with the first discharge opening 91, the first discharge opening 91 is opened. Accordingly, such arrangement can provide for a discharge mode. In the closed position 112, the first adjustable ring gate 121 can be positioned with the first ring opening 127 having a decreased overlap, relative to the first overlap, of the first discharge opening 91 so as to provide a mulch mode. In other words, the opened position 111 can correspond to the first adjustable ring gate 121 having the arrangement shown in
As described above, from a bottom perspective, clockwise rotation of the adjustable ring gate 121 results in closure of the first discharge opening 91 whereas counterclockwise rotation of the adjustable ring gate 121 results in opening of the first discharge opening 91. However, it should be appreciated that such rotational relationship between opening of the first discharge opening 91 and closing of the first discharge opening 91 can vary, i.e., can be reversed and/or varied in travel amount. Such variance can depend on position of the first ring opening 127 on the first ring body 122, the particular rotation actuator utilized, and the particular rotational travel range of the first adjustable ring gate 121 relative to the cutter housing 61, for example.
The first adjustable ring gate 121 can also include the second ring opening 129. Construct of the first adjustable ring gate 121, and specifically the position of the second ring opening 129 on the first ring body 122, can provide for opening (and closing) of the second discharge opening by the second ring opening 129 to coordinate with opening (and closing) by the first ring opening 127 of the first discharge opening.
In the opened position 111, the first adjustable ring gate 121 can be positioned with the second ring opening 129 having a second overlap, with the second discharge opening 92. Since the second ring opening 129 overlaps with the second discharge opening 92, the second discharge opening 92 is opened. Accordingly, such arrangement can provide for a discharge mode. In the closed position 112, the first adjustable ring gate 121 can be positioned with the second ring opening 129 having a decreased overlap, relative to the first overlap, of the second discharge opening 92 so as to provide a mulch mode. In other words, the opened position 111 can correspond to the first adjustable ring gate 121 having the arrangement shown in
As described above, a rotation actuator can be used to rotate the first adjustable ring gate 121 to a desired rotational position so as to change between mulch mode and discharge mode. More specifically, a first rotation actuator 161 can operatively engage with the first adjustable ring gate 121 so as to impart rotational movement of the first adjustable ring gate 121. The first rotation actuator 161 can be controllable by the user for rotatably moving the first adjustable ring gate between the opened position 111 and the closed position 112, as well as interim positions.
Relatedly, the first adjustable ring gate 121 can be rotatably supported by the cutter housing 61. The first adjustable ring gate 121 can include a plurality of support flanges or tabs, such as first support flanges, 133. As shown in
The first support flange 133 can be constructed in different ways. Each first support flange 133 can include a tab or flange that extends vertically upward from the upper edge 123 (to define the connecting flange 135) and which is then bent over (to define the support plate 134). With such construct, the support plate 134, being a bent end at a top of the connecting flange 135, may only extend in one direction from the connecting flange. The support plate 134,153 can be formed from stamped metal. Alternatively, each support plate 134,153 can be a separate piece of metal or other material that is welded, for example spot welded, or otherwise attached to a respective connecting flange 135. With such construct, the support plate 134 can be attached at a central portion thereof to the connecting flange 135. Thus, the support plate 134 can bridge over the first slot 140 so as to engage with both sides of the first slot 140.
The first adjustable ring gate 121 can also include a first drive flange 136. The first drive flange 136 can include a gear rack 137 and a connecting flange 138. The connecting flange 138 can extend from the upper edge 123 of the first ring body 122, through the thickness of the top wall 63 (of the cutter housing 61) and attach to the gear rack 137. That is, the gear rack 137 can be supported by the connecting flange 138. The gear rack 137 can also serve to rotatably support the first adjustable ring gate 121 in that the gear rack 137 is precluded, due to its structure, from sliding through the respective first slot 140.
The gear rack 137, of the first drive flange 136, can include a plurality of teeth. Such teeth, of the first drive flange 136, can engage with a first rotation actuator 161. The first rotation actuator 161 can operatively engage with the gear rack 137 so as to drive the first adjustable ring gate 121 to a desired rotational amount.
The first rotation actuator 161 can include a pinion gear 163. The pinion gear 163 can be part of or operatively connected to a gear assembly 164. The gear assembly 164 can be driven or powered by a motor 165. The gear assembly 164 and/or motor 165 can be affixed to the top wall 63 of the cutter housing 61 by suitable brackets, flanges, mechanical fastener, welding, and/or other attachment arrangements. As shown in
As described above, rotational travel of the first adjustable ring gate 121 can be constrained or limited by constrained movement of the first support flanges 133 within respective first slots 140, as well as by constrained movement of the first drive flange 136 within a respective first slot 140. It is appreciated that sensors may be utilized to control rotation of the first adjustable ring gate 121. Use of such sensors can be used to determine when a rotational position has been attained so as to provide a desired opened position 111. Use of sensors can also be used to determine when a rotational position has been attained so as to provide a desired closed position 112. Upon a desired position being attained with movement in one direction, the motor or other power mechanism 165 can be shut off so as not to damage the first rotation actuator 161, the first slot arrangement 139, the first support flanges 133 and/or the first drive flange 136. Such a sensor to limit or control movement can include a physical limiter sensor, such as a button being abutted against an approaching stop. Alternately, the sensor to limit movement can include an encoder that senses/counts indicia such as marks or ticks on an adjacent moving part. For example, an encoder can be positioned adjacent the pinion wheel and count rotation of the pinion wheel so as to control or limit rotation of the first adjustable ring gate 121.
As shown in
Hereinafter, further details of the second adjustable ring gate 141 of the disclosure will be described.
As shown in
The second adjustable ring gate 141 can be of similar structure to the first adjustable ring gate 121. However, one distinction is that the second adjustable ring gate 141 can be provided to include a single ring opening or hole 147, such as a third ring opening 147 of the conversion assembly 110. The second adjustable ring gate 141 can include a second ring body 142 of the conversion assembly 110. The second ring body 142 can be in the form of a cylinder or segment of a cylinder and include an upper edge 143 and a lower edge 144. Additionally, the second ring body 142 can include an inner surface 145 and outer surface 146. The second ring body 142 can include a third ring opening as described above. The second ring body 142 can also include a third blocking segment 151 of the conversion assembly 110. The third ring opening 147 can be defined, along a top of the third ring opening 147, by and/or associated with a third joining segment 148 of the conversion assembly 110. The third joining segment 148 can connect respective ends of the third blocking segment 151 of the conversion assembly 110, about the third ring opening 147. For example, the third joining segment 148 can be a strip of material that runs along a top of the third ring opening 147 and serves to connect opposing ends of the third blocking segment 151. Accordingly, respective edges or ends of the third blocking segment 151 can serve to define sides of the third ring opening 147, in conjunction with the third joining segment 148 defining an upper extent of the third ring opening 147.
In similar manner to the first adjustable ring gate 121, the second adjustable ring gate 141 can be positioned in an open position 113 (akin to the opened position 111 of the first adjustable ring gate 121) and a closed position 114 (akin to the closed position 112 of the first adjustable ring gate 121), as characterized herein for purposes of distinction. In the open position 113, the second adjustable ring gate 141 can be positioned with the third ring opening 147 having a third overlap with the third discharge opening 93. Since the third ring opening 147 overlaps with the third discharge opening 93, the third discharge opening 93 is opened. Accordingly, such arrangement can provide for a discharge mode with regard to the third cutting chamber 73. In the closed position 114, the second adjustable ring gate 141 can be positioned with the third ring opening 147 having a decreased overlap, relative to the third overlap, of the third discharge opening 93 so as to provide a mulch mode. In other words, the open position 113 can correspond to the second adjustable ring gate 141 having the arrangement shown in
As illustrated in
A further rotation actuator can be used to rotate the second adjustable ring gate 141 to a desired rotational position so as to change between mulch mode and discharge mode. More specifically, a second rotation actuator 162 can operatively engage with the second adjustable ring gate 141 so as to impart rotational movement of the second adjustable ring gate 141. The second rotation actuator 162 can be controllable by the user for rotatably moving the second adjustable ring gate 141 between the open position 113 and the closed position 114, as well as interim positions.
Relatedly, the second adjustable ring gate 141 can be rotatably supported by the cutter housing 61. The second adjustable ring gate 141 can include a plurality of support flanges such as second support flanges 152. As shown in
The second support flange 152 can be constructed in different ways. Each second support flange 152 can include a tab or flange that extends vertically upward from the upper edge 143 (to define the connecting flange 154) and which is then bent over (to define the support plate 153). With such construct, the support plate 153, being a bent end at a top of the connecting flange 154, may only extend in one direction from the connecting flange 154. The support plate 153 and flange 154 can be made from stamped metal. Alternatively, each support plate 153 can be a separate piece of metal or other material that is welded or otherwise attached to a respective connecting flange 154. With such construct, the support plate 153 can be attached at a central portion thereof to the connecting flange 154. Thus, the support plate 153 can bridge over the second slot 159 so as to engage with both sides of the second slot 159.
The second adjustable ring gate 141 can also include a second drive flange 155. The second drive flange 155 can include a gear rack 156 and a connecting flange 157. The connecting flange 157 can extend from the upper edge 143 of the second ring body 142, through the thickness of the top wall 63 (of the cutter housing 61) and attach to the gear rack 156. That is, the gear rack 156 can be supported by the connecting flange 157. The gear rack 156 can also serve to rotatably support the second adjustable ring gate 141 in that the gear rack 156 is precluded, due to its structure, from sliding through the respective second slot 159.
The gear rack 156, of the second drive flange 155, can include a plurality of teeth. Such teeth, of the second drive flange 155, can engage with a second rotation actuator 162. The second rotation actuator 162 can operatively engage with the gear rack 156 so as to drive the second adjustable ring gate 141 to a desired rotational amount.
The second rotation actuator 162 can be of similar or same structure as the first rotation actuator 161. The second rotation actuator 162 can include a pinion gear 163. The pinion gear 163 can be part of or operatively connected to a gear assembly 164. The gear assembly 164 can be driven or powered by a motor 165. The gear assembly 164 and/or motor 165 or other drive mechanism can be affixed to the top wall 63 of the cutter housing 61 by suitable brackets, flanges, mechanical fastener, welding, and/or other attachment arrangements. As shown in
As described above, rotational travel of the second adjustable ring gate 141 can be constrained or limited by the second support flanges 152 within respective second slots 159, as well as by constrained movement of the second drive flange 155 within a respective second slot 159. It is appreciated that sensors may also or alternatively be utilized to control rotation of the second adjustable ring gate 141. Use of such sensors can determine when a rotational position has been attained so as to provide a desired opened position 111. Such sensors are described above with reference to the first rotation actuator 161.
The support slots 140, 159 as described herein can accommodate one, two or more support flanges and/or drive flanges. For example, as shown in
As described above, the conversion assembly 110 can include a first rotation actuator 161 (that rotates the first adjustable ring gate 121) and a second rotation actuator 162 (that rotates the second adjustable ring gate 141). The first rotation actuator 161 and the second rotation actuator 162 can collectively constitute a rotation actuator assembly 160. Alternatively, a single rotation actuator and/or a single power mechanism (for example motor) can rotate both the first adjustable ring gate 121 and the second adjustable ring gate 141. For example, respective pinion gears 163 can be positioned as shown in
The rotation actuator assembly 160, which can include the first rotation actuator 161 and the second rotation actuator 162, can be controlled by a suitable controller 167. Accordingly, a user or operator of the lawnmower can operate the conversion assembly 110 while the operator remains seated on the lawnmower. Such operation can be performed through a controller or regulator on a control panel of the lawnmower, for example. Such controller can be operatively attached to the electric motors 165, which are respectively associated with the first adjustable ring gate 121 and the second adjustable ring gate 141, through suitable control and/or power wires 168. Should the rotation actuator assembly 160 include a single motor, in contrast to the two motors shown in
For example,
The second end 173, of the lower rod 171, can include or be connected to a joint 175. For example, the joint 175 can be a universal joint that allows redirection of rotational movement of an upper rod 176. The upper rod 176 can extend upwardly from the joint 175. An upper end of the upper rod 176 can include a hand crank arrangement 177. The hand crank arrangement 177 can include a bend 178 and an off-center handle 179. A user can rotate the handle 179 so as to impart rotational movement to the upper rod 176 and lower rod 171, and in turn impart rotational movement to the gear 174.
It is appreciated that the various components of embodiments of the disclosure can be made from any of a variety of materials including, for example, metal, plastic, plastic resin, nylon, composite material, and/or rubber, for example, or any other material as may be desired.
A variety of production techniques can be used to make the apparatuses as described herein. For example, suitable casting and/or injection molding and other molding techniques, extrusion and other manufacturing techniques might be utilized. Also, metal stamping or cutting can be utilized. For example, metal stamping or cutting can be utilized in construction of the cutter housing 61, the first adjustable ring gate 121, and the second adjustable ring gate 141, as well as various other components described herein.
In accordance with the disclosed subject matter, features or characteristic of one embodiment may be used in conjunction with other embodiments of the disclosure, as may be desired.
While the subject matter has been described in detail with reference to exemplary embodiments thereof, it will be apparent to one skilled in the art that various changes can be made, and equivalents employed, without departing from the scope of the disclosure.
For example, the conversion assembly 110 has been described in use with a cutter housing having three cutting chambers. However, a conversion assembly 110 of the disclosure can be provided with a cutter housing having other number of cutting chambers, such as a single cutting chamber, two cutting chambers, or four cutting chambers, for example. In an arrangement having only one cutting chamber, the second adjustable ring gate 141 could be utilized without a first adjustable ring gate 121. In an arrangement having two cutting chambers, the first adjustable ring gate 121 could be utilized without the second adjustable ring gate 141.
Additionally, the conversion assembly 110 of the disclosure can be used with a wide variety of types of lawnmowers including a walk behind mower, self-propelled mower, tractor type, other ride-on type, or other type of lawnmower.
For example, embodiments are disclosed above in which components of the cutter housing assembly, such as components of the first adjustable ring gate 121 and/or second adjustable ring gate 141, are constructed of a single or unitary piece. However, embodiments are intended to include or otherwise cover components that include or are constructed of multiple pieces. For example, multiple pieces of the first adjustable ring gate 121 and/or second adjustable ring gate 141 can be separately stamped from metal and then connected together such as but not limited to welding, spot welding, adhesive or mechanical fasteners, for example.
Embodiments are disclosed above in which the cutter housing 61, the cutting chambers, the adjustable ring gates 121, 141, and the openings in the ring gates, include a specific shape, geometry, or construction. It is appreciated that shape and structure of components described herein may vary between different types of lawnmowers and different types of cutter housings. Accordingly, exemplary embodiments are also intended to include or otherwise cover assemblies that include variations in shape, geometry, or construction as dependent on assemblies and lawnmowers with which the shutter assembly is intended to be utilized.