阅读说明：本技术 提升臂调平系统 (Lift arm leveling system ) 是由 大卫·格拉瑟 丹尼尔·J·克里格 于 2019-08-30 设计创作，主要内容包括：所公开的实施例包括具有提升臂(316-1；316-2；416)和利用四连杆机构(354-1；354-2；352-1；352-2)的铲斗调平系统的动力机械(100；200；300；400),诸如前端装载机和公用车辆,当所述提升臂被升高和降低时所述四连杆机构机械地调平所附接的机具。(The disclosed embodiments include power machines (100; 200; 300; 400), such as front end loaders and utility vehicles, having lift arms (316-1; 316-2; 416) and bucket leveling systems that utilize four-bar linkages (354-1; 354-2; 352-1; 352-2) that mechanically level an attached implement as the lift arms are raised and lowered.)

1. A lift arm assembly (350-2; 450) of a power machine (100; 200; 300; 400) having an attachment structure for securing an implement (436) to the lift arm assembly, the lift arm assembly comprising:

a lift arm comprising a main lift arm portion (316-2; 416) pivotably attached to a frame (110; 310; 410) of the power machine at a first pivot attachment (312; 412), and a telescoping portion (318; 418) extendable and retractable relative to the main lift arm portion;

a variable length link (328-2; 428) pivotably attached to the frame (110; 310; 410) at a second pivot attachment (326; 426); and

a fixed length link (322; 422) pivotally attached at a third pivot attachment (314; 414) to the telescopable portion of the main lift arm portion and pivotally attached at a fourth pivot attachment (320; 420) to the variable length link (328-1; 328-2; 428);

wherein the lift arm, frame, variable length links and fixed length links form a lift arm four-bar linkage having two variable length links.

2. The lift arm assembly of claim 1, further comprising:

a tilt cylinder (235; 340; 440) pivotally attached to the fixed length leveling link (322; 422) at a fifth pivot attachment (338; 438); and

an implement connection point (334; 434) for mounting one of the implement (436) and an implement carrier to the lift arm assembly, the implement connection point including a sixth pivot attachment (330; 340) on the lift arm and a seventh pivot attachment (332; 432) on the tilt cylinder (235; 340; 440);

wherein the fixed length link (322; 422), the tilt cylinder (235; 340; 440), the one of the implement (436) and the implement carrier, and the lift arm form a tilt control four-bar linkage (352-1; 352-2), and wherein the lift arm four-bar linkage and the tilt control four-bar linkage provide mechanical self-leveling of the implement (436) coupled to the lift arm assembly as the lift arm assembly is pivotally raised and lowered relative to the frame.

3. The lift arm assembly of claim 1, wherein the telescoping portion (318; 418) of the main lift arm is configured to extend and retract relative to the main lift arm portion (316-2; 416) under power of a telescoping actuator (319).

4. The lift arm assembly of claim 3, wherein the one of the implement and the implement carrier is pivotably attached to the telescoping portion (318; 418) of the lift arm at a sixth pivot attachment (330; 430).

5. The lift arm assembly of claim 4, wherein the variable length link (328-2; 428) is hydraulically coupled to the telescopic actuator (319) such that the variable length link extends and retracts as the telescoping portion (318; 418) of the lift arm extends and retracts.

6. The lift arm assembly of claim 5 wherein the variable length linkage (328-2; 428) is a cylinder.

7. The lift arm assembly of claim 1 wherein the second pivot attachment (326; 426) between the variable length link (328-2; 428) and the frame (110; 310; 410) is positioned above and behind the first pivot attachment (312; 412) between the lift arm and the frame.

8. The lift arm assembly of claim 8 wherein the second pivot attachment (326; 426) between the variable length link (328-2; 428) and the frame (110; 310; 410), and the first pivot attachment (312; 412) between the lift arm and the frame are arranged such that a line of action (324) extending between the first and second pivot attachments forms an angle of at least about 105 degrees with respect to a horizontal direction.

9. The lift arm assembly of claim 2, wherein the lift arm assembly is configured such that a first line of action (462) between the first pivot attachment (312; 412) and the third pivot attachment (314; 414) is substantially parallel to a second line of action (460) between the second pivot attachment (326; 426) and the fourth pivot attachment (320; 420) when the main lift arm portion (316-2; 416) is in a fully lowered position and the telescoping portion (318; 418) is retracted within the main lift arm portion.

10. The lift arm assembly of claim 1, wherein the lift arm assembly is configured such that the fourth pivot attachment (320; 420) is positioned rearward of a line of action (480) extending between the third pivot attachment (314; 414) and the fifth pivot attachment (338; 438).

11. The lift arm assembly of claim 1, further comprising a port relief valve (502) configured to couple a tilt cylinder (235; 340; 440) with a tank (504) to limit travel of the tilt cylinder when one of the tilt cylinder, the implement (436), and an implement carrier interferes with the lift arm.

12. A power machine (100; 200; 300; 400) configured to provide mechanical self-leveling of an implement (436), the power machine comprising:

a frame (110; 310; 410);

a power source (222) mounted to the frame;

a power conversion system (224) operatively coupled to the power source;

a lift arm (316-1; 316-2; 416) pivotally attached to the frame at a first pivot attachment (312; 412);

a lift actuator (238; 415) in communication with the power conversion system and coupled between the frame and the lift arm, and selectively operable to raise and lower the lift arm relative to the frame;

a first leveling link (328-1; 328-2; 428) pivotally attached to the frame (110; 310; 410) at a second pivot attachment (326; 426);

a second leveling link (322; 422) pivotally attached to the lift arm at a third pivot attachment (314; 414) and pivotally attached to the first leveling link (328-1; 328-2; 428) at a fourth pivot attachment (320; 420);

a tilt actuator (235; 340; 440) in communication with the power conversion system and pivotably attached to the second leveling link (322; 422) at a fifth pivot attachment (338; 438); and

an implement attachment mechanism (334; 434) configured to mount the implement (436) to the lift arm such that the combination of the implement and the implement attachment mechanism is pivotably attached to the lift arm (316-1; 316-2; 416) at a sixth pivot attachment (330; 430) and pivotably attached to the tilt actuator (235; 340; 440) at a seventh pivot attachment (332; 432);

wherein the frame (110; 310; 410), the lift arm (316-1; 316-2; 416), the second leveling link (322; 422), and the first leveling link (328-1; 328-2; 428) form a first four-bar linkage (354-1; 354-2), wherein the second leveling link (322; 422), the tilt actuator (235; 340; 440), the implement attachment mechanism, and the lift arm (316-1; 316-2; 416) form a second four-bar linkage (352-1; 352-2), and wherein the first and second four-bar linkages provide mechanical self-leveling of the implement (436) mounted to the lift arm when the lift arm is pivotally raised and lowered relative to the frame.

13. The power machine of claim 12, wherein one of the first and second four-bar linkages includes two rods having variable lengths.

14. The power machine of claim 12, wherein the lift arm (316-2; 416) is a telescoping lift arm having a telescoping portion (318; 418) configured to selectively extend and retract relative to the main lift arm portion (316-2; 416) under power of a telescoping actuator (319).

15. The power machine of claim 14, wherein the implement attachment mechanism is pivotably attached to the telescoping portion (318; 418) of the lift arm (316-2; 416) at the sixth pivot attachment (330; 430).

16. The power machine of claim 14, wherein the second leveling link (322; 422) is pivotably attached to the telescoping portion (318; 418) of the lift arm (316-2; 416) at the third pivot attachment (314; 414).

17. The power machine of claim 14, wherein the first leveling link (328-2; 428) is a variable length leveling link.

18. The power machine of claim 17, wherein the first leveling link (328-2; 428) is operatively coupled to the telescopic actuator (319) such that the first leveling link extends and retracts as the telescoping portion (318; 418) of the lift arm (316-2; 416) extends and retracts.

19. The power machine of claim 18, wherein the first leveling linkage (328-2; 428) is a cylinder.

20. The power machine of claim 14, wherein the lift arm assembly is configured such that a first line of action (462) between the first pivot attachment (312; 412) and the third pivot attachment (314; 414) is substantially parallel to a second line of action (460) between the second pivot attachment (326; 426) and the fourth pivot attachment (320; 420) when the lift arm (316-2; 416) is in a fully lowered position and the telescoping portion (318; 418) is retracted into the lift arm.

21. The power machine of claim 12, wherein the second pivot attachment (326; 426) and the first pivot attachment (312; 412) are arranged such that a line of action (324) extending between the first pivot attachment and the second pivot attachment forms an angle of at least about 100 degrees with respect to a horizontal direction.

22. The power machine of claim 12, wherein the second pivot attachment (326; 426) is positioned above and behind the first pivot attachment (312; 412).

23. The power machine of claim 12, wherein the second pivot attachment (326; 426) and the first pivot attachment (312; 412) are arranged such that a line of action (324) extending between the first and second pivot attachments forms an angle of between about 100 degrees and 110 degrees with respect to a horizontal direction.

24. The power machine of claim 12, wherein the lift arm assembly is configured such that the fourth pivot attachment (320; 420) is positioned rearward of a line of action (480) extending between the third pivot attachment (314; 414) and the fifth pivot attachment (338; 438).

25. The power machine of claim 12, wherein the tilt actuator is a tilt cylinder, and further comprising a port relief valve (502) configured to couple the tilt cylinder (235; 340; 440) with a tank (504) to limit travel of the tilt cylinder when one of the tilt cylinder and the implement (436) interferes with the lift arm.

Background

The present disclosure relates to power machines. More specifically, the present disclosure relates to a bucket or implement leveling system for a lift arm of a power machine (such as a front end loader).

For purposes of this disclosure, power machines include any type of machine that generates power for accomplishing a particular task or tasks. One type of power machine is a work vehicle. Work vehicles are typically self-propelled vehicles having a work implement, such as a lift arm (although some work vehicles may have other work implements), which may be manipulated to perform work functions. Work vehicles include loaders, excavators, utility vehicles, tractors, and trenchers, to name a few examples.

Different types of power machines, such as loaders and utility vehicles, include lift arm structures having an implement carrier pivotally coupled at a distal end of the arm. Often, a bucket or other implement is coupled to the lift arm by mounting the bucket to the implement carrier. When the lift arm is raised and lowered, it may be advantageous to maintain the bucket at a substantially constant orientation relative to the ground, which may require changing the orientation of the bucket relative to the lift arm. There are mechanical bucket leveling systems for maintaining a generally constant bucket orientation relative to the ground. Some of these systems require a large number of additional linkages or components or have drawbacks and limitations in their operation.

The discussion above is merely provided for general background information and is not intended to be used as an aid in determining the scope of the claimed subject matter.

Disclosure of Invention

The disclosed embodiments include power machines, such as front end loaders and utility vehicles, having a telescoping lift arm assembly and a bucket leveling system. The bucket leveling system utilizes a geometry that allows for optimization or improvement of bucket leveling performance through two four-bar linkages. For example, the disclosed embodiments allow the bucket leveling to be implemented mechanically without the use of additional linkages required in some systems.

In an exemplary embodiment, a first leveling link or a constant length leveling link is pivotally coupled to the lift arm and tilt cylinder. A leveling cylinder or a variable length leveling link is pivotally coupled to the frame and the first leveling link. Two four-bar linkages providing the bucket leveling are formed using the frame, the lift arm, the leveling link, the leveling cylinder or a variable length leveling link, the implement carrier, and the tilt cylinder.

In some exemplary embodiments, the first four-bar linkage comprises two variable length links. A first one of the variable length connecting rods is provided by a levelling cylinder. The second of the variable length links is provided by a telescopic lifting arm. In some exemplary embodiments, the pivot on the frame for the leveling cylinder is positioned above and behind the pivot on the frame for the lift arm. In some exemplary embodiments, the pivot on the leveling link is positioned behind a line of action formed between the pivot on the leveling link for the tilt cylinder and the pivot on the leveling link for the implement carrier.

The disclosed embodiments include a power machine and a lift arm assembly for a power machine having improved mechanical self-leveling features. One general aspect includes a lift arm assembly (350-2; 450) of a power machine (100; 200; 300; 400) having an attachment structure for securing an implement (436) to the lift arm assembly, the lift arm assembly comprising: a lift arm comprising a main lift arm portion (316-2; 416) pivotably attached to a frame (110; 310; 410) of the power machine at a first pivot attachment (312; 412), and a telescoping portion (318; 418) extendable and retractable relative to the main lift arm portion; a variable length link (328-2; 428) pivotably attached to the frame (110; 310; 410) at a second pivot attachment (326; 426); and a fixed length link (322; 422) pivotally attached at a third pivot attachment (314; 414) to the telescopable portion of the main lift arm portion and pivotally attached at a fourth pivot attachment (320; 420) to the variable length link (328-1; 328-2; 428); wherein the lift arm, frame, variable length links and fixed length links form a lift arm four-bar linkage having two variable length links.

Implementations may include one or more of the following features. The lift arm assembly, the lift arm assembly further comprises: a tilt cylinder (235; 340; 440) pivotally attached to the fixed length leveling link (322; 422) at a fifth pivot attachment (338; 438); and an implement connection point (334; 434) for mounting one of the implement (436) and an implement carrier to the lift arm assembly, the implement connection point including a sixth pivot attachment (330; 340) on the lift arm and a seventh pivot attachment (332; 432) on the tilt cylinder (235; 340; 440); wherein the fixed length link (322; 422), the tilt cylinder (235; 340; 440), one of the implement (436) and the implement carrier, and the lift arm form a tilt control four-bar linkage (352-1; 352-2), and wherein the lift arm four-bar linkage and the tilt control four-bar linkage provide mechanical self-leveling of the implement (436) coupled to the lift arm assembly when the lift arm assembly is pivotably raised and lowered relative to the frame. The lift arm assembly, wherein the lift arm assembly is configured such that a first line of action (462) between the first pivot attachment (312; 412) and the third pivot attachment (314; 414) is substantially parallel to a second line of action (460) between the second pivot attachment (326; 426) and the fourth pivot attachment (320; 420) when the main lift arm portion (316-2; 416) is in a fully lowered position and the telescoping portion is retracted within the main lift arm portion.

The lift arm assembly wherein the telescoping portion (318; 418) of the main lift arm is configured to extend and retract relative to the main lift arm portion (316-2; 416) under power of a telescoping actuator (319). The lift arm assembly, wherein one of the implement and the implement carrier is pivotably attached to the telescoping portion (318; 418) of the lift arm at the sixth pivot attachment (330; 430). The lift arm assembly wherein the variable length link (328-2; 428) is hydraulically coupled to the telescopic actuator (319) such that the variable length link extends and retracts as the telescoping portion (318; 418) of the lift arm extends and retracts. The lift arm assembly wherein the variable length linkage (328-2; 428) is a cylinder.

The lift arm assembly wherein the second pivot attachment (326; 426) between the variable length link (328-2; 428) and the frame (110; 310; 410) is positioned above and behind the first pivot attachment (312; 412) between the lift arm and the frame. The lift arm assembly wherein the second pivot attachment (326; 426) between the variable length link (328-2; 428) and the frame (110; 310; 410), and the first pivot attachment (312; 412) between the lift arm and the frame are arranged such that a line of action (324) extending between the first and second pivot attachments forms an angle of at least about 105 degrees with respect to a horizontal direction.

The lift arm assembly, wherein the lift arm assembly is configured such that the fourth pivot attachment (320; 420) is positioned rearward of a line of action (480) extending between the third pivot attachment (314; 414) and the fifth pivot attachment (338; 438). The lift arm assembly further includes a port relief valve (502) configured to couple the tilt cylinder (235; 340; 440) with a tank (504) to limit travel of the tilt cylinder when one of the tilt cylinder, the implement (436), and an implement carrier interferes with the lift arm.

One general aspect includes a power machine (100; 200; 300; 400) configured to provide mechanical self-leveling of an implement (436), the power machine comprising: a frame (110; 310; 410); a power source (222) mounted to the frame; a power conversion system (224) operatively coupled to the power source; a lift arm (316-1; 316-2; 416) pivotally attached to the frame at a first pivot attachment (312; 412); a lift actuator (238; 415) in communication with the power conversion system and coupled between the frame and the lift arm, and selectively operable to raise and lower the lift arm relative to the frame; a first leveling link (328-1; 328-2; 428) pivotally attached to the frame (110; 310; 410) at a second pivot attachment (326; 426); a second leveling link (322; 422) pivotally attached to the lift arm at the third pivot attachment (314; 414) and pivotally attached to the first leveling link (328-1; 328-2; 428) at the fourth pivot attachment (320; 420); a tilt actuator (235; 340; 440) in communication with the power conversion system and pivotably attached to the second leveling link (322; 422) at a fifth pivot attachment (338; 438); and an implement attachment mechanism (334; 434) configured to mount the implement (436) to the lift arm such that the combination of the implement and the implement attachment mechanism is pivotably attached to the lift arm (316-1; 316-2; 416) at a sixth pivot attachment (330; 430) and pivotably attached to the tilt actuator (235; 340; 440) at a seventh pivot attachment (332; 432); wherein the frame (110; 310; 410), the lift arm (316-1; 316-2; 416), the second leveling link (322; 422), and the first leveling link (328-1; 328-2; 428) form a first four-bar linkage (354-1; 354-2), wherein the second leveling link (322; 422), the tilt actuator (235; 340; 440), the implement attachment mechanism, and the lift arm (316-1; 316-2; 416) form a second four-bar linkage (352-1; 352-2), and wherein the first and second four-bar linkages provide mechanical self-leveling of the implement (436) mounted to the lift arm when the lift arm is pivotally raised and lowered relative to the frame.

Implementations may include one or more of the following features. The power machine, wherein one of the first and second four-bar linkages includes two levers having variable lengths. The power machine wherein the lifting arm (316-2; 416) is a telescopic lifting arm having a telescopic portion (318; 418) configured to be selectively extended and retracted relative to the main lifting arm portion (316-2; 416) under power of a telescopic actuator (319). The power machine wherein the implement attachment mechanism is pivotably attached to the telescoping portion (318; 418) of the lift arm (316-2; 416) at the sixth pivot attachment (330; 430). The power machine wherein the second leveling link (322; 422) is pivotably attached to the telescoping portion (318; 418) of the lift arm (316-2; 416) at the third pivot attachment (314; 414). The power machine wherein the first leveling link (328-2; 428) is a variable length leveling link. The power machine wherein the first leveling link (328-2; 428) is operatively coupled to the telescopic actuator (319) such that the first leveling link extends and retracts as the telescoping portion (318; 418) of the lift arm (316-2; 416) extends and retracts. The power machine wherein the first leveling link (328-2; 428) is a cylinder. The power machine wherein the lift arm assembly is configured such that a first line of action (462) between the first pivot attachment (312; 412) and the third pivot attachment (314; 414) is substantially parallel to a second line of action (460) between the second pivot attachment (326; 426) and the fourth pivot attachment (320; 420) when the lift arm (316-2; 416) is in a fully lowered position and the telescoping portion (318; 418) is retracted into the lift arm. The power machine wherein the second pivot attachment (326; 426) and the first pivot attachment (312; 412) are arranged such that a line of action (324) extending between the first and second pivot attachments forms an angle of at least about 100 degrees relative to horizontal. The power machine wherein the second pivot attachment (326; 426) is positioned above and behind the first pivot attachment (312; 412). The power machine wherein the second pivot attachment (326; 426) and the first pivot attachment (312; 412) are arranged such that a line of action (324) extending between the first and second pivot attachments forms an angle of between about 100 degrees and 110 degrees with respect to a horizontal direction. The power machine wherein the lift arm assembly is configured such that the fourth pivot attachment (320; 420) is positioned rearward of a line of action (480) extending between the third pivot attachment (314; 414) and the fifth pivot attachment (338; 438). The power machine, wherein the tilt actuator is a tilt cylinder, and further comprising a port relief valve (502) configured to couple the tilt cylinder (235; 340; 440) with a tank (504) to limit travel of the tilt cylinder when one of the tilt cylinder and the implement (436) interferes with the lift arm.

This summary and abstract are provided to introduce a selection of concepts in a simplified form that are further described below in the detailed description. This summary is not intended to identify key features or essential features of the claimed subject matter, nor is it intended to be used as an aid in limiting the scope of the claimed subject matter.

Drawings

FIG. 1 is a block diagram illustrating a functional system of a representative power machine in which embodiments of the present disclosure may be advantageously practiced.

Fig. 2 is a block diagram illustrating components of a power system of a loader, such as the loader illustrated in fig. 1.

FIG. 3-1 is a schematic view of a lift arm assembly having a bucket leveling system utilizing two four-bar linkages.

Fig. 3-2 is a schematic view of a lift arm assembly having a bucket leveling system utilizing two four-bar linkages with telescoping lift arms.

FIG. 4 is a schematic side view of a lift arm assembly and bucket leveling system showing the lift arm assembly in a lowered position and a raised position.

FIG. 5 is a schematic side view of portions of the lift arm assembly and bucket leveling system of FIG. 4, illustrating pivot locations on the leveling links in an exemplary embodiment.

FIG. 6-1 is a schematic side view illustrating a lift arm assembly and bucket leveling system showing a tilt cylinder that advantageously has a long stroke length and a port relief valve that prevents over-travel of the tilt cylinder when the lift arm is in a raised position.

FIG. 6-2 is a schematic side view of a lift arm assembly and bucket leveling system without the limitation of the increased length tilt cylinder shown in FIG. 6-1.

Detailed Description

The concepts disclosed in the present discussion are described and illustrated with reference to exemplary embodiments. However, these concepts are not limited in their application to the details of construction and the arrangement of components in the illustrative embodiments, and can be practiced or carried out in various other ways. The terminology in this document is used for the description and should not be regarded as limiting. The use of words such as "including," "comprising," "having," and variations thereof herein is meant to encompass the items listed thereafter and equivalents thereof as well as additional items.

The disclosed embodiments include power machines, such as front-end loaders and utility vehicles, having lift arm and bucket leveling systems. The bucket leveling system utilizes a geometry that allows optimization and improvement of bucket leveling performance through two four-bar linkages, as compared to conventional bucket leveling systems that utilize additional components. For example, the disclosed embodiments allow the bucket leveling to be implemented mechanically without the use of additional linkages required in some systems to assist with three four-bar linkages. In an exemplary embodiment, a first leveling link or a constant length leveling link is pivotally coupled to the lift arm and tilt cylinder. A leveling cylinder or a variable length leveling link is pivotally coupled to the frame and the first leveling link. Using the frame, the lift arm, the leveling link, the leveling cylinder or variable length leveling link, the implement carrier, and the tilt cylinder to form two four-bar linkages that provide the bucket leveling.

These concepts may be practiced on a variety of power machines as will be described below. A representative power machine upon which embodiments may be practiced is illustrated in diagrammatic form in FIG. 1. For the sake of brevity, only one power machine is illustrated and discussed as a representative power machine. However, as mentioned above, the embodiments below may be practiced on any of a number of power machines, including power machines of different types than those specifically illustrated. For purposes of this discussion, a power machine includes a frame, at least one work element, and a power source that may provide power to the work element to accomplish a work task. One type of power machine is a self-propelled work vehicle. Self-propelled work vehicles are a type of power machine that includes a frame, a work element, and a power source that can provide power to the work element. At least one of the work elements is a motive system for moving the power machine under power.

FIG. 1 is a block diagram illustrating the basic system of a power machine 100, which may be any of a number of different types of power machines into which the embodiments discussed below may be advantageously incorporated. The block diagram of FIG. 1 identifies various systems on the power machine 100 and the relationships between various components and systems. As mentioned above, at the most basic level, for purposes of this discussion, a power machine includes a frame, a power source, and a work element. The power machine 100 has a frame 110, a power source 120, and a work element 130. Since the power machine 100 shown in fig. 1 is a self-propelled work vehicle, it also has a traction element 140 and an operator station 150, the traction element 140 itself being the work element provided for moving the power machine over a support surface, the operator station 150 providing the operating position of the work element for controlling the power machine. A control system 160 is provided for interacting with other systems to perform various work tasks at least partially in response to control signals provided by an operator.

Some work vehicles have work elements that may perform specialized tasks. For example, some work vehicles have a lift arm to which an implement, such as a bucket, is attached, for example, by a pinned arrangement. The work element (i.e., the lift arm) may be manipulated to position the implement to perform the task. In some cases, the implement may be positioned relative to the work element, such as by rotating a bucket relative to a lift arm, to further position the implement. Under normal operation of such a work vehicle, the bucket is intended to be attached and in use. Such a work vehicle may be able to receive other implements by disassembling the implement/work element combination and reassembling another implement in place of the original bucket. However, other work vehicles are intended for use with a wide variety of implements, and have an implement interface such as implement interface 170 shown in fig. 1. At its most basic, implement interface 170 is a connection mechanism between the frame 110 or work element 130 and an implement, which may be as simple as a connection point for attaching an implement directly to the frame 110 or work element 130, or may be more complex, as discussed below.

On some power machines, the implement interface 170 may include an implement carrier that is a physical structure movably attached to the work element. The implement carrier has an engagement feature and a locking feature to receive and secure any one of a plurality of implements to the work element. One characteristic of such a machine carrier is: once an implement is attached to the implement carrier, the implement carrier is fixed to the implement (i.e., is not movable relative to the implement) and moves with the implement carrier when the implement carrier moves relative to the work element. The term "implement carrier" as used herein is not merely a pivotal connection point, but rather is a dedicated device that is dedicated to receiving and securing to a variety of different implements. The implement carrier itself may be mounted to a work element 130, such as a lift arm or the frame 110. The implement interface 170 may also include one or more power sources for providing power to one or more work elements on the implement. Some power machines may have multiple work elements with implement interfaces, each of which may, but need not, have an implement carrier for receiving an implement. Some other power machines may have a work element with multiple implement interfaces such that a single work element may receive multiple implements simultaneously. Each of these implement interfaces may, but need not, have an implement carrier.

Some power machines may have an implement or an implement similar to a device attached to the power machine, for example by pinning to a lift arm having a tilt actuator that is also directly coupled to the implement or implement-type structure. A common example of such an implement that is rotatably pinned to a lift arm is a bucket, where one or more tilt cylinders are attached (e.g., by welding or with fasteners) to a bracket that is directly secured to the bucket. Such power machines do not have an implement carrier, but rather have a direct connection between the lift arm and the implement.

Frame 110 includes a physical structure that can support various other components attached thereto or positioned thereon. The frame 110 may include any number of individual components. Some power machines have a rigid frame. That is, no part of the frame is movable relative to another part of the frame. Other power machines have at least one portion that is movable relative to another portion of the frame. For example, an excavator may have an upper frame portion that rotates relative to a lower frame portion. Other work vehicles have an articulated frame such that one portion of the frame pivots relative to another portion to perform a steering function.

Frame 110 supports the power source 120, which is configured to provide power to one or more work elements 130, including one or more traction elements 140, and in some cases, to provide power for use by an attached implement via an implement interface 170. Power from the power source 120 may be provided directly to any of the work elements 130, traction elements 140, and implement interface 170. Alternatively, power from the power source 120 may be provided to a control system 160, which in turn selectively provides power to elements capable of using the power to perform work functions. Power sources for power machines typically include an engine, such as an internal combustion engine, and a power conversion system, such as a mechanical transmission or a hydraulic system, configured to convert output from the engine into a form of power that can be used by the work elements. Other types of power sources may be incorporated into the power machine, including an electric power source, or a combination of power sources commonly known as hybrid power sources.

Fig. 1 shows a single work element designated as work element 130, but each power machine may have any number of work elements. A work element is typically attached to the frame of the power machine and is movable relative to the frame while performing a work task. Additionally, the traction element 140 is a special case of a work element, as the work function of a traction element is typically to move the power machine 100 over a support surface. The traction element 140 is shown separate from the work element 130, as many power machines have additional work elements in addition to the traction element, but this is not always the case. A power machine may have any number of traction elements, some or all of which may receive power from the power source 120 to propel the power machine 100. The traction elements may be, for example, track assemblies, wheels attached to an axle, and the like. The traction element may be mounted to the frame such that movement of the traction element is limited to rotation about an axis (such that steering is achieved by a sliding action), or alternatively, the traction element may be pivotally mounted to the frame to achieve steering by pivoting the traction element relative to the frame.

The power machine 100 includes an operator station 150 that includes an operating position from which an operator may control operation of the power machine. In some power machines, operator station 150 is defined by an enclosed or partially enclosed cab. Some power machines on which the disclosed embodiments may be practiced may or may not have a cab or cabin of the type described above. For example, a walk-behind loader may not have a cab or cabin, but rather an operating position that serves as an operator station from which the power machine may be suitably operated. More broadly, power machines other than work vehicles may have operator stations that are not necessarily similar to the operator stations and operator cabs mentioned above. Additionally, some power machines, such as power machine 100, whether they have a cockpit or an operating location, may be capable of being operated remotely (i.e., from a remotely located operating station) instead of, or in addition to, an operating station adjacent to or on the power machine. This may include applications where: wherein at least some operator control functions of the power machine associated with an implement coupled to the power machine may be operated from an operating position. Alternatively, for some power machines, a remote control device may be provided (i.e., remote from both the power machine and any implement coupled to the power machine) that may control at least some of the operator control functions on the power machine.

Fig. 2 includes, among other things, a diagram of various components of a power system 220 of a power machine 200, which power machine 200 may be a power machine 100 such as that illustrated in fig. 1. Power system 220 includes one or more power sources 222 that may generate and/or store power for use on various machine functions. On the power machine 200, the powertrain 220 includes an internal combustion engine. Other power machines may include generators, rechargeable batteries, various other power sources, or any combination of power sources that may provide power for a given power machine component. The power system 220 also includes a power conversion system 224, the power conversion system 224 being operatively coupled to the power source 222. The power conversion system 224 is in turn coupled to one or more actuators 226, which actuators 226 may perform functions on the power machine. Power conversion systems in various power machines may include various components, including mechanical transmissions, hydraulic systems, and the like. The power conversion system 224 of the power machine 200 includes a pair of hydraulically driven pumps 224A and 224B that can be selectively controlled to provide power signals to drive motors 226A and 226B. In turn, each of the drive motors 226A and 226B is operatively coupled to a shaft, with drive motor 226A being coupled to shafts 228A and 228B, and drive motor 226B being coupled to shafts 228C and 228D. The axles 228A-228D, in turn, are coupled to the traction elements 219A-219D, respectively. The drive pumps 224A and 224B may be mechanically, hydraulically, and/or electrically coupled to an operator input device to receive actuation signals for controlling the drive pumps.

The arrangement of the drive pump, motor, and shaft in the power machine 200 is only one example of an arrangement of these components. As discussed above, the power machine 200 may be a utility vehicle or may be a front end loader such as a skid steer loader, a track loader, or an articulated loader, and thus includes traction elements on each side of the power machine. For example, in skid steer loaders, the traction elements are controlled together by the output of a single hydraulic pump (either by a single drive motor or using separate drive motors). Various other configurations and combinations of hydraulically driven pumps and motors may be employed, which may be advantageous. Additionally, the disclosed embodiments may be used with other types of power machines.

The power conversion system 224 of the power machine further includes a hydraulic implement pump 224C, the hydraulic implement pump 224C also being operably coupled to the power source 222. The hydraulic implement pump 224C is operatively coupled to the work actuator circuit 238C. The work actuator circuit 238 includes a lift cylinder 238 and a tilt cylinder 235 and control logic (such as one or more valves) for controlling their actuation. The control logic selectively allows actuation of the lift and/or tilt cylinders in response to operator input. In some machines, the work actuator circuit further includes control logic for selectively providing pressurized hydraulic fluid to an attached implement.

The above description of the power machine 100 is provided for illustrative purposes to provide an illustrative environment on which the embodiments discussed below may be practiced. Although the discussed embodiments may be practiced on power machines such as those generally described by the power machine 100 illustrated in the block diagram of fig. 1, the concepts discussed below are not intended to limit their application to the environments specifically described above unless otherwise noted or recited.

Referring now to fig. 3-1 and 3-2, there is shown a schematic illustration of the lift arm assemblies 350-1 and 350-2 of the power machines 300-1 and 300-2 having components for providing mechanical self-leveling of the bucket or other implement attached to the implement carrier 334. Each lift arm assembly includes two four-bar linkages that together provide improved self-leveling operation for the bucket or implement attached to the implement carrier 334. The lift arm assembly shown in fig. 3-1 includes a lift arm 316-1 that forms part of the four bar linkage. The lift arm assembly shown in fig. 3-2 differs from the lift arm assembly shown in fig. 3-1 only in that: the lifting arm 316-2 is a telescopic type lifting arm having a telescopic section 318 that is telescopic from the main section 316-2 under the power of a telescopic cylinder or actuator 319. It must be noted that the lift arm assemblies shown in fig. 3-1 and 3-2 are provided schematically to illustrate certain features, such as the two four-bar linkages in each lift arm assembly used to provide the mechanical self-leveling aspects of the disclosed embodiments. It must be understood that the particular geometries illustrated in fig. 3-1 and 3-2 are not intended to reflect particular pivot point locations, orientations of components, scales of components, or other features unless explicitly stated otherwise. Additional illustrations of the lift arm assembly features are provided in fig. 4-6.

In each of the lift arm assemblies, the lift arm 316-1 or 316-2 is pivotally attached to the frame 310 at a pivot attachment or coupling 312. A solid leveling link 328-1 is pivotally attached to the frame 310 and pivot attachment or coupling 326 in the lift arm assembly 350-1. The lift arm assembly 350-2 has a variable length leveling link 328-2 in the form of a leveling cylinder, which variable length leveling link 328-2 is pivotally attached to the frame 310 at a pivot attachment or coupling 326. In an exemplary embodiment, it has been found that improved leveling performance over a range of lift arm positions is achieved with the pivot attachment 326 of the leveling link 328-1 or leveling cylinder 328-2 positioned above or below the pivot attachment 312 of the lift arm 316 (toward the cabin of the power machine). In certain exemplary embodiments, it has been found that the pivot attachment 326 of the leveling link 328-1 or leveling cylinder 328-2 may be advantageously positioned above and behind the pivot attachment 312 of the lift arm such that the line of action 324 extending between the pivot attachments 312 and 326 forms an angle θ of at least about 105 ° with respect to horizontal. However, this geometric relationship is not required in all embodiments.

Leveling links 322 are also provided in each of the lift arm assemblies to assist in the mechanical self-leveling function. The leveling link 322 (which is a fixed length link) includes three pivot attachments. The first leveling link 322 is pivotally attached to the lift arm 316 at the pivot attachment 314. This pivot attachment 314 may be attached to a main lift arm portion in a lift arm 316-1 or to a telescoping lift arm portion 318 in a lift arm 316-2. The second pivot attachment on each leveling link 322 is a pivot attachment 320 located between the leveling link 328-1 or leveling cylinder 328-2 and the leveling link 322. The third pivot attachment on each leveling link 322 is a pivot attachment 338 located between the tilt cylinder 340 and the leveling link 322.

Also shown in fig. 3-1 and 3-2 is an implement carrier or interface 334, the implement carrier or interface 334 being configured to allow a bucket or other implement to be mounted on the lift arm 316. The implement carrier 334 is pivotally attached to the lift arm at a pivot attachment 330. In the embodiment shown in fig. 3-1, the pivot attachment 330 between the implement carrier 334 and the lift arm 316-1 is present in the main lift arm portion, while the pivot attachment 330 attached to the lift arm 316-2 in fig. 3-2 occurs on the telescoping portion 318. The implement carrier 334 is also pivotally attached to the tilt cylinder 340 at a pivot attachment.

In the embodiment shown in fig. 3-2, the leveling cylinder 328-2 may be hydraulically coupled to the telescoping cylinder or actuator 319, with the telescoping cylinder or actuator 319 controlling the extension and retraction of the telescoping portion 318 of the lift arm 316-2. The hydraulic coupling is schematically illustrated as a hydraulic connection 321, but may include various valves or other hydraulic components. When the lift arm extension actuator extends/retracts to extend/retract the telescoping portion 318, the leveling cylinder 328-2 also extends/retracts. This facilitates maintaining the positioning of the leveling links 322 relative to the telescoping portion 318 of the lift arm 316-2.

As noted above, each of the described lift arm assemblies shown in fig. 3-1 and 3-2 provide self-leveling using two four-bar linkages instead of using three four-bar linkages as is common in the prior art. In the lift arm assembly shown in fig. 3-1, the two four bar linkages are designated 354-1 and 352-1. In the lift arm assembly shown in fig. 3-2, the two four bar linkages are designated 354-2 and 352-2. The first four bar linkage 354-1 or 354-2 includes a frame 310, a lift arm 316-1 or 316-2 (including a telescoping portion 318), a leveling link 322, and a leveling cylinder (or other length adjustable leveling link) 328-2 or a solid leveling link 328-1. The attachments for the first four bar linkage include a pivot attachment 312 between the lift arm and the frame 310, a pivot attachment 314 between the lift arm and the leveling link 322, a pivot attachment 320 between the leveling link 328-1 or the leveling cylinder 328-2 and the leveling link 322, and a pivot attachment 326 between the leveling link 328-1, the leveling cylinder 328-2, and the frame 310.

The second four bar linkage includes the leveling link 322, the tilt cylinder 340, the lift arm 316, and a portion of the implement carrier 334. The pivot attachments for the second four bar linkage include a pivot attachment 314 between the lift arm 316 and the leveling link 322, a pivot attachment 330 between the lift arm 316 and the implement carrier 334, a pivot attachment between the tilt cylinder 340 and the implement carrier 334, and a pivot attachment 338 between the tilt cylinder 340 and the leveling link 322. A notable feature of the lift arm assembly discussed with reference to fig. 3-1 and 3-2 and discussed below in fig. 4-6 is that the tilt cylinder is pivotally coupled directly between the leveling link 422 and the implement carrier 434, rather than by an additional link. In some embodiments, as discussed above, certain power machines may not have an implement carrier, but may have an implement such as a bucket pinned directly to a lift arm and a leveling link. For purposes of clarity, the structure on either the implement carrier or the implement that forms part of the second four bar linkage is referred to as the implement portion.

Referring now to fig. 4, a schematic illustration of a lift arm assembly 450 of a power machine 400 having similar components to those discussed above with reference to fig. 3-2 for providing mechanical self-leveling of the bucket 436 or another implement is shown. The lift arm assembly 450 includes the two four-bar linkages discussed above that together provide improved self-leveling operation. In fig. 4, the lift arm assembly 450 is shown in both a fully lowered position and in a raised position to illustrate features such as movement of the leveling links 422 relative to the lift arms 416.

In the lift arm assembly 450, the lift arm 416 is pivotally attached to the frame 410 at a pivot attachment or coupling 412. A variable length leveling link 428, also in the form of a leveling cylinder, is also pivotally attached to the frame 410 at a pivot attachment or coupling 426. As discussed above, the pivot attachment 426 of the leveling cylinder 428 is positioned above and behind the pivot attachment 412 of the lift arm 416, e.g., also having a line of action extending between the pivot attachments 412 and 426 at an angle θ of at least about 105 ° relative to horizontal (see, e.g., fig. 3-1 and 3-2).

A fixed length leveling link 422 is also provided to assist the mechanical self-leveling function. As with the leveling link 322, the leveling link 422 includes three pivot attachments. The first leveling link 422 is pivotally attached to the lift arm 416 at a pivot attachment 414. This is in the illustrated embodiment, this pivot attachment 414 may be attached to a telescoping lift arm portion 418, giving the first four-bar linkage two separate variable length links. The second pivot attachment on the leveling link 422 is a pivot attachment 420 located between the leveling cylinder 428 and the leveling link 422. The third pivot attachment on the leveling link 422 is a pivot attachment 438 located between a tilt cylinder 440 and the leveling link 422.

An implement carrier or interface 434 is configured to allow a bucket 436 or other implement to be mounted on the lift arm 416. An implement carrier 434 is pivotally attached to the telescoping portion of the lift arm at pivot attachment 430. The implement carrier 434 is also pivotally attached to the tilt cylinder 440 at pivot attachment 432.

As illustrated with reference to the lift arm assembly 350-2 shown in fig. 3-2, the leveling cylinder 428 may be hydraulically coupled to the telescopic cylinder or actuator (not shown in fig. 4) that controls the extension and retraction of the telescoping portion 418 of the lift arm 416. Thus, when the lift arm telescopic actuator extends/retracts to extend/retract the retract telescoping portion 418, the leveling cylinder 428 also extends/retracts to create two variable length links in the first four bar linkage. The components of the two four bar linkages are discussed above with reference to fig. 3-2.

As shown in fig. 4, when the lift arm 416 is in the fully lowered position and the telescoping lift hip section 418 is retracted within the main lift hip section, the line of action 462 between the lift arm pivot 412 (on the frame 410) and the pivot 414 of the leveling link 422 (with the lift arm) is approximately parallel to the line of action 460 between the leveling cylinder pivot 426 (on the frame 410) and the pivot 420 of the leveling link 422 (with the leveling cylinder). In an exemplary embodiment, the line of action is parallel to within 1 degree in this fully lowered position of the lifting arm. The angle between these two lines of action 460 and 462 opens upwards between 5 and 10 degrees when the lifting arm is raised. It must be noted that this geometric configuration, while beneficial in some embodiments, need not be in all embodiments.

As can be seen in fig. 4, when the lift arm 416 is raised and the tilt cylinder 440 is held at a fixed length, the length of the leveling cylinder 428 does not change but the leveling cylinder 428 pivots about pivots 426 and 420, thereby pivoting the leveling link 422 about the leveling link/lift arm pivot 414. This will maintain the orientation of the bucket 436 with respect to the ground or horizontal plane throughout the range of lift arm motion. Additionally, it can be seen in fig. 4 that the non-implement carrier pivot 438 for the tilt cylinder 440 moves relative to the lift arm 416/418. This feature also helps provide improved bucket leveling performance over the range of lift arm motion.

Referring now to FIG. 5, additional features of the lift arm assembly shown in FIG. 4 are shown in greater detail. In an exemplary embodiment, it has been found that the pivot attachment 420 between the leveling link 422 and the leveling cylinder 428 is optimally positioned behind or behind the line of action 480 defined as extending between the leveling link pivots 414 and 438 (e.g., toward the leveling cylinder pivot 426 and the frame 410). By positioning the pivot 420 rearward of this line of action between the leveling link/lift arm pivot 414 and the leveling link/tilt cylinder pivot 438, packaging and placement of components (e.g., the size, shape, and physical configuration of the implement carrier 434 or the implement in embodiments without an implement carrier, the tilt cylinder 440, etc.) is less complicated.

Referring now to fig. 6-1, another feature of some embodiments of the lift arm assembly shown in fig. 4 is schematically illustrated. As shown in fig. 6-1, the lift arm assembly or system may include a tilt cylinder 440 having a stroke long enough to achieve a sufficient tow back angle. The backhoe angle is defined as the angle formed between the bottom 506 of the bucket 436 and the ground or horizontal. The increased tilt cylinder length allows the tow back angle to be approximately 70 degrees. However, having an ultra-long stroke for the tilt cylinder may make the tilt cylinder or other components vulnerable when the cylinder is fully extended when the lift arm is in certain positions. A port relief valve 502 is coupled to the tilt cylinder 440 such that the pressure within the cylinder 440 is vented to a tank 504. The port safety device is shown on the back side of the tilt cylinder 440, but in other arrangements where the rod side of the tilt cylinder 440 is pivotally coupled to the leveling link 422, the port safety device may instead be positioned on the rod side of the tilt cylinder. The port safety on the tilt cylinder 440 is provided to limit the stroke of the tilt cylinder if the tilt cylinder, the bucket, or other attachment interferes with the lift arm. This prevents damage to the tilt cylinder, bucket or other structure (such as the lift arm) and allows additional travel, and allows the lift arm to be raised against any contact between the bucket and a tilt stop to achieve a better back drag angle. By comparison, the same lift arm assembly and system (but with extended tilt cylinder travel and without the port relief valve 502) can only achieve a smaller tow back angle (52 degrees in this example) below the desired amount.

Although the present invention has been described with reference to preferred embodiments, workers skilled in the art will recognize that changes may be made in form and detail without departing from the scope of the discussion.