Patent Application
20160095277
The present teachings relate to walk-behind turf care mowers, and particularly to walk-behind turf care mowers having a continuously variable power split device for controlling the frequency-of-clip of such mowers independent of the ground speed of the mower.
The statements in this section merely provide background information related to the present disclosure and cannot constitute prior art.
Walk-behind reel mowers, commonly used for cutting, grooming and maintaining grass at golf courses, sporting venues, parks, consumer lawns, etc., typically include one, or more, reel assembly, sometimes referred to as a head unit, that generally includes a motor, a bedbar assembly, a blade reel and a drive drum. The blade reel comprises a plurality of cutting blades helically disposed about a shaft that is rotationally mounted within a frame of the reel assembly. The drive drum is generally a cylindrical drum that is rotated by the motor to propel the mower along the ground as the blade reel rotates the cutting blades in contact with a bedknife blade of the bedbar assembly to cut the grass.
A frequency of clip (FOC) is an important consideration when maintaining many grass surfaces, such as golf course greens. The FOC is generally measured by the distance the mower travels forward before the next cutting blade reaches the bedknife blade. Different climates, grasses, weather conditions, and desired height and quality of cut require different clip frequency settings. In a traditional, fixed-ratio mower, the ratio of the speed of the blade reel to the ground speed of the mower (i.e., the rotational speed of the drive drum) is typically not adjustable, or limited to a fixed set of adjustments. Often, in order to change the FOC, the blade reel must be removed and replaced with another reel unit having a greater or lesser number of cutting blade. Such limitations can result in the undesirable conditions of sub-optimal FOC settings, reduced productivity and/or increased consumption of time.
Advances have been made to overcome the shortcomings of the fixed ratio mower. For example, mowers have been constructed that utilize two separate motors, e.g., DC electric motors, wherein each motor rotates a separate one of the drive drum and the blade reel. Although such systems overcome some of the limitations of the fixed ratio mowers, such systems incur significant penalties in cost, weight and complexity related to the additional components and structural configuration.
The present disclosure provides a walk-behind grass mower structured and operable to distribute torque and rotational speed input from a single power generator, to each of a drive drum and a blade reel of the mower at independently controllable torque transfer ratios. In various embodiments, the mower comprises a power generator, a blade reel, a drive drum, and a power split device. The split power device can include a single power input shaft, a reel output shaft, a drum output shaft, and at least one continuously variable transmission hub operably connecting the reel output shaft and/or the drum output shaft to the power input shaft such that torque and rotational speed delivered by the power input shaft is transferrable to the reel and/or drum output shafts at any infinitely variable ratio. The power split device can be structured and operable to transfer the torque and rotational speed delivered by the power input shaft to both the reel and drum output shafts such that a rotational speed of the blade reel and a rotational speed of the drive drum are both generated from the power delivered by the power input shaft and are both independently controlled.
Further areas of applicability of the present teachings will become apparent from the description provided herein. It should be understood that the description and specific examples set forth in this disclosure are intended for purposes of illustration only and are not intended to limit the scope of the present teachings.
The drawings described herein, which are not necessarily drawn to scale, are for illustration purposes only and are not intended to limit the scope of the present teachings in any way.
Corresponding reference numerals indicate corresponding parts throughout the several views of drawings.
The following description is merely exemplary in nature and is in no way intended to limit the present teachings, application, or uses. Throughout this specification, like reference numerals will be used to refer to like elements.
Referring now to
Generally, when the mower 10 is in operation, the drive drum 22 is in contact with the ground and is rotated, or driven, via torque generated by the power generator 18 to propel the mower 10 across the ground at a desired rate of travel (e.g., feet/second) that is controlled by the rotational or angular speed of the drive drum 22. The rotational speed of the drive drum 22, and hence the rate of forward travel of the mower 10, is controlled by operation of the power split device 14, as described below. Additionally, when the mower 10 is in operation, a front roller bar 34 of the mower 10 is adjusted to set the blade reel 26 and a bedknife blade (not shown) of the mower 10 at a desired cut height above the ground, e.g., 0.25 to 0.75 inches, and the blade reel 26 is rotated, or driven, via power generated by the power generator 18 at a desired rotational speed. The rotational speed of the blade reel 26 is controlled by operation of the power split device 14, as described below.
More particularly, the blade reel 26 is rotated to rotate a plurality of grass cutting blades 38, of the blade reel 26, past the bedknife blade, whereby grass will be caught between the rotating cutting blades 38 and a bedknife blade and cut/clipped to the set cut height. The rotational speed of the blade reel 26 is controlled by operation of the power split device 14, independent from the control of the rotational speed of the drive drum 22, as described below. More particularly, the power split device 14 receives a single input rotational speed from the power generator 18 and outputs rotational speed to the drum drive 22 at any selected torque input-to-output ratio, and to the blade reel 26 at any selected torque input-to-output ratio such that the rotational speed of the drive drum 22 and the blade reel 26 can be independently controlled. Accordingly, via the power split device 14, the mower 10 can be operated to provide any desired frequency of clip (FOC), which is a function of forward travel speed of the mower 10. More particularly, the power split device 14 controls the FOC by independently controlling input-to-output torque ratios to the drive drum 22 and the blade reel 26 utilizing a single input rotational speed provided by the power generator 18, thereby independently controlling the rotational speed of the drive drum 22 and the blade reel 26. The torque input-to-output ratio will sometimes be referred to herein as torque transfer ratios.
Referring now to
The power split device 14 additionally comprises a drum output shaft 54 operably connected at a distal end 54A to the drive drum 22 and a reel output shaft 58 operably connected at a distal end 58A to the blade reel 26. The drum output shaft 54 and the reel output shaft 58 can respectively be operatively connected to the drive drum 22 and the blade reel 26 using any suitable power transfer mechanism, device or system, 56 and 60, e.g., a gear set, a geared transmission, a series of pulleys and belts, etc. Furthermore, the power split device 14 comprises a drum torque transfer assembly 62 that operably connects a proximal end 54B of the drum output shaft 54 to the power input shaft 40 and is structured and operable to transfer power from the input shaft 40 to the drum output shaft 54 at any selected torque transfer ratio. Still further, the power split device 14 comprises a reel torque transfer assembly 66 that operably connects a proximal end 58B of the reel output shaft 58 to the power input shaft 40 and is structured and operable to transfer power from the input shaft 40 to the reel output shaft 58 at any selected torque transfer ratio, independently from the operation of the drum torque transfer assembly 62.
The power split device 14 is communicatively connected (e.g., wired and/or wirelessly) to a power split device controller 70, described further below. Specifically, the controller 70 controls operation of the power split device 14, and particularly the operation of the drum torque transfer assembly 62 and the reel torque transfer assembly 66, such that the drum torque transfer assembly 62 and the reel torque transfer assembly 66 are independently controlled. More specifically, the torque transfer ratios of the power delivered by the power generator 18 to both the drum torque transfer assembly 62 and the reel torque transfer assembly 66 are independently controlled. Therefore, the rotational, or angular, speed of the drive drum 22 and the blade reel 26 are produced via the single power generator 18 and are independently controlled via the power split device 14 and controller 70, such that the mower 10 can be operated at any desired forward travel speed and at any desired FOC.
Referring now to
Each CVT hub comprises a housing and, internally disposed therein, any CVT power transfer mechanism structured and operable to provide a continuous (theoretically infinite) variety of torque input-to-output ratios, including but not limited to; planetary gear sets coupled to electric actuators (sometimes referred to as electrically-variable CVTs or E-CVTs), steel or rubberized belts coupled to variable geometry pulleys (sheaves), or by employing other techniques such as the combination of spherical bearings and non-Newtonian fluids.
In various embodiments, the power split device 14 includes a reel clutch mechanism 74 structured and operable to engage and disengage the delivery of power from the power input shaft 40 to the reel output shaft 58. In various implementations, the reel clutch mechanism 74 can be any suitable mechanical, electrical or electromechanical clutch mechanism structured and operable to manually or automatically engage and disengage the real output shaft 58 with and from the reel torque transfer assembly 74. Alternatively, the reel clutch mechanism 74 can be any suitable mechanical, electrical or electromechanical clutch mechanism structured and operable to manually or automatically engage and disengage the reel torque transfer assembly 66 with and from the power input shaft 40. In various embodiments, the power split device 14 includes a housing 78 that encloses the drum torque transfer assembly 62, the reel torque transfer assembly 66 and the reel clutch mechanism 74. The reel clutch mechanism 74 can be used to disengage the blade reel 26 from power delivered from the power input shaft 40 when the mower 10 is not being used to cut grass, but is merely being conveyed from one cutting surface to another.
Referring now to
The controller 70 generally includes at least one electronic storage device 82, at least one processor 86, and/or other circuitry suitable for storing and executing the torque distribution software. Each electronic storage device 82 comprises a computer readable medium, such as a hard drive, flash memory, an ASIC or any other electronic data storage device for storing such things as software packages or programs and algorithms (e.g., the torque distribution software), digital information, data, look-up tables, spreadsheets, databases and/or the like that can be used to implement torque distribution control in accordance with various embodiments. The processor(s) 86 is/are operable to execute the torque distribution software. The controller 70 is in operable communication with a user interface 90 that is accessible by the mower operator for selecting a desired FOC and for inputting data used to program the controller 70. In various embodiments, the user interface 90 can included with the controller 70, as exemplarily illustrated in
For example, in various embodiments, an external computer device, e.g., a laptop, tablet, smart phone, or other computer device, can be connected to the controller 70, via the I/O communication interface(s) 102 or wireless communication means described herein, to download the torque distribution software to the electronic storage device 82 and/or to access (or use) the torque distribution software to program the controller 70 with a desired setting. Alternatively, in various embodiments, the controller 70 can be structured and operable such that the selection buttons 94 can be used, independently or in combination with an external computer device to download the torque distribution software to the electronic storage device 82 and/or to access (or use) the torque distribution software to program the controller 70 with a desired setting. Furthermore, in various embodiments, the I/O communication interface(s) 102, or wireless communication means described herein, can also be used to upload information from the controller 70, such as elapsed cutting time for the mower 14 or other desired mower information. It is also envisioned that, in various implementations, the controller 70 is structured and operable to receive feedback data from feedback sensors (not shown) of the mower 10 that are operable to provide feedback regarding the speed of, and more particularly the rotational speed input by the power input shaft 40 and output by the drum and reel output shafts 54 and 58. Additionally, in various implementations, the controller 70 can, via execution of the torque transfer software and in accordance with programmed settings, control the speed of, and more particularly the rotational speed output by, the power generator 18 based on information/data from the feedback sensors.
Referring now to
As described above, the drum output shaft distal end 54A and the reel output shaft distal end 58A can be operatively connected to the respective drive drum 22 and blade reel 26 using any suitable torque transfer mechanism, device or system 56 and 60, e.g., a gear set, a geared transmission, a series of pulleys and belts, etc. In various implementations, one and/or both torque transfer mechanisms, devices or systems 56 and 60 can be structured and operable to transfer the torque and rotational speed delivered from the respective drum and reel output shaft distal ends 54A and 58A to the respective drive drum 22 and blade reel 26 (e.g., to axle shafts of the respective drive drum 22 and blade reel 26) at any desired fixed torque transfer ratio.
Referring now to
It is envisioned that, by utilizing feedback sensor data during execution of the torque transfer software, the controller 70 can, in various embodiments, automatically adjust the drum CVT hub 62 and/or the reel CVT hub 66, to alter the drive drum rotational speed and/or the blade reel rotational speed to compensate for any power generator speed changes (e.g., load imposed RPM ‘droop’). Hence, the torque transfer ratio of the power split device 14 (i.e., the torque transfer ratios of the drum CVT hub 62 and the reel CVT hub 66) and the rotational speed output by the power generator 18 can be automatically controlled by the power split device controller 70 to ensure a steady forward travel speed and FOC of the mower 10 is maintained.
In various other embodiments, as exemplarily illustrated in
As described above, the drum output shaft distal end 54A and the reel output shaft distal end 58A can be operatively connected to the respective drive drum 22 and blade reel 26 using any suitable torque transfer mechanism, device or system suitable 56 and 60, e.g., a gear set, a geared transmission, a series of pulleys and belts, etc. In various implementations, one and/or both torque transfer mechanisms, devices or systems 56 and 60 can be structured and operable to transfer the torque delivered from the respective drum and reel output shaft distal ends 54A and 58A to the respective drive drum 22 and blade reel 26 (e.g., to axle shafts of the respective drive drum 22 and blade reel 26) at any desired fixed torque input-to-output ratio.
In operation, the user will input the desired FOC via the controller user interface 90. Based on the given mechanical configuration of the mower 10 (e.g., the number of cutting blades 38 on the blade reel 26), the power split device controller 70 will determine (e.g., through execution of the torque transfer software) the fixed rotational speed of the blade reel 26 and the corresponding rotational speed for the drive drum 22 needed to achieve the desired FOC. More specifically, the controller 70 can be configured to determine the fixed rotational speed of the blade reel 26 that will result from the particular fixed gear ratio of the reel fixed ratio hub 66 and a particular rotational speed of the power input shaft 40 that corresponds to the operational speed of the power generator 18 and the power generator shaft 30, e.g., 2500-3000 RPMs. In various embodiments, the controller 70 will determine (e.g., via execution of the torque transfer software) the torque transfer ratio needed to transfer the amount of torque and rotational speed to the drum output shaft 54, via the drum CVT hub 62, necessary to achieve the rotational speed of the drum drive 22 that will provide the desired FOC as a function of the determined fixed rotational speed of the blade reel 26. Then, upon engagement of the power generator clutch mechanism 44, the controller 70 will actuate and control operation of the drum CVT hub 62 to provide the determined torque transfer ratio.
It is envisioned that, by utilizing feedback sensor data during execution of the torque transfer software, the controller 70 of some embodiments can automatically adjust the drum CVT hub 62 to alter the drive drum rotational speed to compensate for any power generator speed changes (e.g., load imposed RPM ‘droop’). Hence, the torque transfer ratios of the power split device 14 (i.e., the torque transfer ratios of the drum CVT hub 62 and the reel fixed ratio hub 66) and the rotational output by the power generator 18 can be automatically controlled by the power split device controller 70 to ensure a steady forward travel speed and FOC of the mower 10 is maintained.
Alternatively, in yet other embodiments, the reel torque transfer assembly 66 comprises a CVT hub (referred to herein as the reel CVT hub 66) and the drum torque transfer assembly 62 comprises a fixed ratio hub (referred to herein as the drum fixed ratio hub 62). Transposing the blade reel 26 and the drive drum 22 in
As described above, the drum output shaft distal end 54A and the reel output shaft distal end 58A can be operatively connected to the respective drive drum 22 and blade reel 26 using any suitable torque transfer mechanism, device or system suitable 56 and 60, e.g., a gear set, a geared transmission, a series of pulleys and belts, etc. In various implementations, one and/or both torque transfer mechanisms, devices or systems 56 and 60 can be structured and operable to transfer the torque and rotational speed delivered from the respective drum and reel output shaft distal ends 54A and 58A to the respective drive drum 22 and blade reel 26 (e.g., to axle shafts of the respective drive drum 22 and blade reel 26) at any desired fixed torque input-to-output ratio.
In operation, the user will input or select the desired FOC via the controller user interface 90. Based on the known fixed ratio of the drum fixed ratio hub 62 the controller 70 will determine, (e.g., based at least in part on execution of the torque transfer software) the rotational speed of the drive drum 22, and hence the forward travel speed of the mower 10, that will result from a particular rotational speed of the power input shaft 40 that corresponds to the operational speed of the power generator 18 and the power generator shaft 30, e.g., 2500-3000 RPMs. Subsequently, based on the determined rotational speed of the drive drum 22, the controller 70 will determine, via execution of the torque transfer software, the torque transfer ratio needed to transfer the amount of torque and rotational speed to the reel output shaft 58, via the reel CVT hub 66, necessary to achieve the rotational speed of the blade reel 26 that will provide the desired FOC. Then, upon engagement of the power generator clutch mechanism 44, the controller 70 will actuate and control operation of the reel CVT hub 66 to provide the determined torque transfer ratio.
It is envisioned that, by utilizing feedback sensor data during execution of the torque transfer software, the controller 70 of some embodiments can automatically adjust the reel CVT hub 66 to alter the rotational speed of the blade reel 26 to compensate for any power generator speed changes (e.g., load imposed RPM ‘droop’). Hence, the torque transfer ratios of the power split device 14 (i.e., the torque transfer ratios of the drum fixed ratio hub 62 and the reel CVT hub 66) and the rotational speed output by the power generator 18 can be automatically controlled by the power split device controller 70 to ensure a steady forward travel speed and FOC of the mower 10 is maintained.
Referring now to
Alternatively, as exemplarily illustrated in the flow chart 300 of
Still further, as exemplarily illustrated in the flow chart 400 of
It is envisioned that the power split device 14, as described above, can be implemented in a riding mower wherein the drive drum 22 is replaced by one or more traction wheels of the mower, and the mower includes a plurality of blade reels 26. In such embodiments, the power split device 14 would be structured and operable to controllably distribute torque and rotational speed from the single power generator 18 to either or both of the at least one traction wheel and the plurality of blade reels 26 via one or more respective drum CVT hubs 62 and/or one or more respective reel CVT hubs 66. Optionally, at least one of the at least one traction wheel and the plurality of blade reels 26 can be driven via a respective one or more fixed ratio hubs, as described above.
The description herein is merely exemplary in nature and, thus, variations that do not depart from the gist of that which is described are intended to be within the scope of the teachings. Such variations are not to be regarded as a departure from the spirit and scope of the teachings. Therefore, it is to be understood that the embodiments of the present disclosure are not to be limited to the specific embodiments disclosed and that modifications and other embodiments are intended to be included within the scope of the disclosure. Moreover, although the foregoing descriptions and the associated drawings describe example embodiments in the context of certain example combinations of elements and/or functions, it should be appreciated that different combinations of elements and/or functions can be provided by alternative embodiments without departing from the scope of the disclosure.
