The present disclosure relates to controlling a saddle position of a motor grader, and in particular to position sensing system for controlling the saddle position.
In a conventional motor grader, a draft frame of the grader, and therefore a moldboard, is positioned by three different cylinders attached via a four-bar linkage known as a saddle. In this conventional arrangement, the saddle position is limited to a number of discrete positions, which limits the use of the moldboard. Moreover, the saddle position is adjustable only with the moldboard on the ground, and requires manual adjustment.
It is desirable, however, to be able to adjust the saddle position and thus the moldboard to an infinite number of positions. Further, there is a desire to be able to adjust the saddle when the moldboard is disposed above the ground and without requiring manual intervention.
In one embodiment of the present disclosure, a draft frame positioning system of a motor grader having a main frame includes an adjustable draft frame configured to be moved to one of a plurality of positions; a moldboard coupled to the draft frame, the moldboard being movable based on the position of the draft frame; a saddle assembly coupled between the draft frame and the main frame, the saddle assembly comprising a first saddle arm, a second saddle arm, and a saddle top member coupled between the first and second saddle arms; and a saddle positioning cylinder configured to move between an extended position and a retracted position, the saddle positioning cylinder being coupled at one end to the main frame or saddle top member and at an opposite end to the saddle assembly; wherein, a movement of the saddle positioning cylinder induces movement of the draft frame to any of its plurality of positions.
In one example of this embodiment, the saddle positioning cylinder is coupled to the first or second saddle arm of the saddle assembly. In a second example, the saddle assembly comprises a saddle lock bar pivotally coupled between the first saddle arm and the second saddle arm; the saddle positioning cylinder coupled to the saddle lock bar. In a third example, the system may include a first lift cylinder coupled between the first saddle arm and the draft frame; a second lift cylinder coupled between the second saddle arm and the draft frame; and a side shift cylinder coupled between the draft frame and the saddle assembly.
In a fourth example, movement of the saddle positioning cylinder induces movement of the draft frame a first non-discrete position to a second non-discrete position. In a fifth example, the saddle assembly does not include a lock bar or locking pin such that the position of the draft frame is not defined by engaging the locking pin with the lock bar.
In a sixth example, a second saddle positioning cylinder is configured to move between an extended position and a retracted position, the second saddle positioning cylinder being coupled at one end to the main frame or the saddle top member and at an opposite end to the saddle assembly. In a related example, the saddle positioning cylinder may be coupled to the first saddle arm and the second saddle positioning cylinder is coupled to the second saddle arm. Further, the saddle positioning cylinder and the second saddle positioning cylinder may both be coupled to the saddle top member. In a further example of this embodiment, the movement of the saddle positioning cylinder is independent of the movement of the second saddle positioning cylinder.
In another embodiment of the present disclosure, a draft frame positioning system of a motor grader having a main frame includes an adjustable draft frame configured to be moved to one of a plurality of positions; a moldboard coupled to the draft frame, the moldboard being movable based on the position of the draft frame; a saddle assembly coupled between the draft frame and the main frame, the saddle assembly comprising a first saddle arm, a second saddle arm, and a saddle top member coupled between the first and second saddle arms; and a first saddle positioning cylinder configured to move between an extended position and a retracted position, the first saddle positioning cylinder being coupled at one end to the main frame or saddle top member and at an opposite end to the saddle assembly; a second saddle positioning cylinder configured to move between an extended position and a retracted position, the second saddle positioning cylinder being coupled at one end to the main frame or saddle top member and at an opposite end to the saddle assembly; wherein, a movement of the first saddle positioning cylinder is independent of a movement of the second saddle positioning cylinder; wherein, the movement of either the first or the second saddle positioning cylinder induces movement of the draft frame to one of any of its plurality of positions.
In one example of this embodiment, the first saddle positioning cylinder is coupled to the first saddle arm and the second saddle positioning cylinder is coupled to the second saddle arm. In another example, the first saddle arm and the second saddle arm are movable independently of one another. In yet another example, a first lift cylinder is coupled between the first saddle arm and the draft frame; a second lift cylinder is coupled between the second saddle arm and the draft frame; and a side shift cylinder is coupled between the draft frame and the saddle assembly. In a further example, movement of either the first or second saddle positioning cylinder induces movement of the draft frame from a first non-discrete position to a second non-discrete position. In yet a further example, the first saddle positioning cylinder and the second saddle positioning cylinder are coupled to the saddle top member.
In a further embodiment of the present disclosure, a motor grader includes a main frame; a draft frame adjustably coupled to the main frame, the draft frame configured to be adjusted to any of a plurality of positions; a moldboard configured to perform a grading operation, the moldboard coupled to the draft frame; a saddle assembly coupled between the draft frame and the main frame, the saddle assembly comprising a first saddle arm, a second saddle arm, and a saddle top member coupled between the first and second saddle arms; a saddle positioning cylinder configured to move between an extended position and a retracted position, the saddle positioning cylinder being coupled at one end to the main frame or saddle top member and at an opposite end to the saddle assembly; and a control system comprising a controller, a saddle positioning sensor, a first saddle arm sensor, and a second saddle arm sensor; wherein, a movement of the saddle positioning cylinder induces movement of the draft frame to any of its plurality of positions; wherein, the saddle positioning sensor is electrically coupled to the controller and is configured to detect a position of the saddle positioning cylinder and communicate the position to the controller.
In one example of this embodiment, the position of the draft frame is adjustably controlled automatically via the controller, the controller configured to automatically control movement of the saddle positioning cylinder. In another example, the motor grader may include a second saddle positioning cylinder configured to move between an extended position and a retracted position, the second saddle positioning cylinder being coupled at one end to the main frame or saddle top member and at an opposite end to the saddle assembly; and a second saddle positioning sensor electrically coupled to the controller and configured to detect a position of the second saddle positioning cylinder; wherein, a movement of the second saddle positioning cylinder is controlled independently of the saddle positioning cylinder; wherein, a movement of the second saddle positioning cylinder induces movement of the draft frame.
In a further example, the saddle positioning cylinder is coupled to the first saddle arm; and the second saddle positioning cylinder is coupled to the second saddle arm; wherein, movement of either the first saddle arm or the second saddle arm is independently controlled relative to the other.
The above-mentioned aspects of the present disclosure and the manner of obtaining them will become more apparent and the disclosure itself will be better understood by reference to the following description of the embodiments of the disclosure, taken in conjunction with the accompanying drawings, wherein:
Corresponding reference numerals are used to indicate corresponding parts throughout the several views.
The embodiments of the present disclosure described below are not intended to be exhaustive or to limit the disclosure to the precise forms in the following detailed description. Rather, the embodiments are chosen and described so that others skilled in the art may appreciate and understand the principles and practices of the present disclosure.
Referring to
An engine 28 is mounted on the rear frame 14 and supplies the driving power for all driven components of the motor grader. For example, the engine 28 is coupled for driving a transmission coupled to the rear wheels 18 at various selected speeds and either in forward or reverse modes. A hydrostatic front wheel assist transmission may be selectively engaged to power the front wheels 16, in a manner well known in the art. Further, the engine 28 may be coupled to a pump or a generator to provide hydraulic, pneumatic, or electrical power to the motor grader 10 as is known in the art.
Mounted to a front location of the front frame 12 is a drawbar 30, having a forward end universally connected to the front frame by a ball and socket arrangement 32 and having opposite right and left rear regions suspended from an elevated central section 34 of the main frame 12 by right and left lift linkage arrangements including right and left extensible and retractable hydraulic actuators (only right actuator 36 is shown). A side shift linkage arrangement is coupled between the elevated frame section 34 and a rear location of the drawbar 30 and includes an extensible and retractable side swing hydraulic actuator 38.
The right, left, and side swing hydraulic actuators 36, 38 may be repositionable to alter a cross slope of a moldboard or blade 46 via a four-bar linkage referred to as a saddle assembly 50 (see
The blade 46 may also be mounted on a side shift assembly (not shown) to slidably move between a first side and a second side. More specifically, a hydraulic side shift actuator (see
Also in
Referring now to
The first saddle arm 202 is also pivotally coupled to the saddle lock bar 208 via pivot connection 230, and the second saddle arm 204 is pivotally coupled to the saddle lock bar 208 via pivot connection 232. Thus, the first and second saddle arms 202, 204 are able to pivot relative to the saddle lock bar 208.
The saddle assembly 200 is coupled to a main frame 210 (or front frame 12).
In the depicted embodiment of
A conventional saddle assembly such as the one in
In order to set the position of the draw frame 30, the saddle assembly 200 position is set by a saddle locking pin (not shown) that engages the saddle lock bar 208 or saddle arms. In
With the retractable locking pin engaged in one of the holes 218, the draft frame position is set and it further defines the rotation of the saddle assembly 200 in relation to the main frame 210. Saddle position is thus limited to one of the positions defined by a hole or aperture 218 in the saddle lock bar 208 or saddle arms. In the example of
It is also noteworthy that in the embodiment of
In
In this illustrated embodiment, however, the saddle assembly 300 may include a first saddle arm 302, a second saddle arm 304, a saddle top member 306, and a saddle lock bar 308 as shown. Thus, the saddle assembly 300 of
In the embodiment of
Moreover, the first saddle arm 302 is pivotally coupled to the saddle top member 306 via pivot connection 326. Similarly, the second saddle arm 304 is pivotally coupled to the saddle top member 306 via pivot connection 328. In this manner, the first and second saddle arms are capable of pivoting relative to the top member 306.
The first saddle arm 302 is also pivotally coupled to the saddle lock bar 308 via pivot connection 330, and the second saddle arm 304 is pivotally coupled to the saddle lock bar 308 via another pivot connection (not shown). Thus, the first and second saddle arms 302, 304 are able to pivot relative to the saddle lock bar 308.
In the embodiment of
Although not shown in
In any event, the manual retractable locking pin of the conventional saddle assembly 200 is replaced by the saddle position cylinder 334 in
It is also possible to adjust the draft frame position to an infinite number of positions within the travel range of the saddle assembly 200, rather than the limited seven discrete positions of
Turning now to
In this illustrated embodiment, however, the saddle assembly 400 may include a first saddle arm 402, a second saddle arm 404, and a saddle top member 406. It is noteworthy that in this embodiment the saddle assembly 400 does not include a saddle lock bar. Thus, the saddle assembly 400 of
In
Moreover, the first saddle arm 402 is pivotally coupled to the saddle top member 406 via pivot connection 426. Similarly, the second saddle arm 404 is pivotally coupled to the saddle top member 406 via pivot connection 428. In this manner, the first and second saddle arms are capable of pivoting relative to the top member 406. The side swing cylinder 416 may be coupled to one of the saddle arms 402, 404 via a first pivot connection 430 or a second pivot connection 452 (depending upon the saddle arm).
In this embodiment, the saddle assembly 400 does not include a saddle lock bar, and thus the first and second saddle arms do not couple to the lock bar. Instead, the saddle locking pin and lock bar are replaced with a pair of position sensing cylinders coupled to the respective saddle arms. For instance, a first saddle sensing position cylinder 432 may be coupled to the first saddle arm 402 at a first location 448 and to the main frame 410 or saddle top member 406 at a second location 444. In
The first saddle sensing position cylinder 432 may include a base end 436 and a rod end 438. The base end 436 may be coupled to the main frame 410 or saddle top member 406, whereas the rod end 438 may be coupled to the first saddle arm 402.
A second saddle sensing position cylinder 434 is also shown in
In this embodiment, each of the saddle sensing position cylinders may be operably controlled independently of one another. As such, it is possible to individually control the travel of each saddle arm independently of the other saddle arm. With this independent saddle arm control, different motion and greater travel of the moldboard is possible compared to the saddle assemblies of
For instance, in the conventional saddle assembly 200 of
The advantage, however, of the saddle assembly design of
In the embodiment of
In
In this embodiment, the control system 600 is an electrohydraulic control system in which a control valve 606 may be operably controlled between an open and closed position by the controller 602 or user controls 604. Hydraulic fluid from a fluid reservoir 608 may be supplied by a pump or other known device (not shown) to the control valve 606. In
In this system 600, the first saddle arm 402 may include a position sensor 610 that is in electrical communication with the controller 602. Likewise, the second saddle arm 404 may include a position sensor 612 that is in electrical communication with the controller 602. Each of these position sensors may communicate the position of the saddle arm relative to the main frame 410 or draft frame. In some instances, the position sensors may be located at the pivotal connection between the saddle arm and top member, or saddle arm and lift cylinder. Alternatively, the position sensors may be mounted at any location on the saddle arm and its position may be detected relative to a fixed location and communicated to the controller 602. In any event, the controller 602 may be in continuous communication with the position sensors so that it is able to detect the actual position of both saddle arms at any given time.
The first lift cylinder 412 may include a position sensor 614 and the second lift cylinder 414 may include a position sensor 616. Both position sensors of the lift cylinders may be in electrical communication with the controller 602. For instance, the position sensors may be located within the respective cylinder to detect real-time stroke length of the rod.
The side shift or side swing cylinder 416 may also include its own position sensor 618 that is in electrical communication with the controller 602. Similar to the lift cylinders, the position sensor 618 may be located inside the cylinder 416 to detect its stroke length at any given time, and communicate the same to the controller 602.
Lastly, each of the saddle sensing position cylinders may include their own sensor. For example, the first saddle sensing position cylinder 432 may include a position sensor 620, and the second saddle sensing position cylinder 434 may include its own position sensor 622. Each of these position sensors may be located within the respective cylinder for detecting stroke length. As such, the sensors 620, 622 may communicate the stroke length of each cylinder to the controller 602.
As the controller 602 receives this information from each sensor, it is able to better control the positioning of the draft frame via the independent control of both saddle arms. In doing so, the moldboard may be controlled to achieve greater reach than conventional, four-bar linkage designs and thus provides better productivity during operation. Moreover, unlike conventional designs, the embodiments in this disclosure provide for automatic or partial automatic control of the draft frame positioning without requiring the moldboard to be placed on the ground first.
While embodiments incorporating the principles of the present disclosure have been described hereinabove, the present disclosure is not limited to the described embodiments. Instead, this application is intended to cover any variations, uses, or adaptations of the disclosure using its general principles. Further, this application is intended to cover such departures from the present disclosure as come within known or customary practice in the art to which this disclosure pertains and which fall within the limits of the appended claims.
Number | Name | Date | Kind |
---|---|---|---|
2247007 | Arndt | Jun 1941 | A |
2655743 | Ross | Oct 1953 | A |
3421589 | Rivinius | Jan 1969 | A |
3455400 | Hanser et al. | Jul 1969 | A |
3677350 | Johnson et al. | Jul 1972 | A |
3739861 | Johnson et al. | Jun 1973 | A |
3986563 | Stubben | Oct 1976 | A |
4175625 | Puckett | Nov 1979 | A |
4340119 | MacDonald | Jul 1982 | A |
4696350 | Ruhter et al. | Sep 1987 | A |
4852659 | Ross et al. | Aug 1989 | A |
8360165 | Leith | Jan 2013 | B2 |
20160153166 | Gentle et al. | Jun 2016 | A1 |
20170284067 | Tevis et al. | Oct 2017 | A1 |
Number | Date | Country |
---|---|---|
1484654 | Nov 1970 | DE |
102008037933 | Apr 2009 | DE |
8805482 | Jul 1988 | WO |
Entry |
---|
German Search Report issued in counterpart application No. 102019216397.1 dated Jul. 23, 2020 (10 pages). |
Number | Date | Country | |
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20200131732 A1 | Apr 2020 | US |