Couplers for releasable connection of construction attachments to front-end loaders and the like are well-known. Typically, the loader coupler is operably connected to the front-end loader (sometimes simply referred as a “loader”) or like machine by a pivoting “pin-on” connection. The loader coupler structure includes first and second pick-up points and corresponding first and second locks. The various construction attachments adapted to be releasably engaged by the coupler include first and second parallel spaced-apart ribs that are respectively engaged by the first and second loader pick-up points, and the first and second locks are engaged to capture the first and second ribs to the coupler so that the attachment is operably connected to the loader in order to perform work. Examples of such couplers and coupling systems are disclosed in commonly owned U.S. Pat. Nos. 4,708,579; 5,415,235; 5,529,419; and 5,692,850.
More recently, so-called hybrid loader couplers have been developed. These hybrid loader couplers include two separate sets or pairs of pick-up points that are adapted to mate with two different types of ribs spacings/structures of the attachments. A lock system is provided to capture the rib structures to coupler, regardless of which type of rib structure is engaged by the coupler. Examples of hybrid loader couplers are disclosed in commonly owned U.S. Pat. Nos. 7,225,566 and 7,182,546.
A need has recently been identified for a hybrid loader coupler that better maintains the preferred geometrical relationship between the attachment and the loader machine as compared to the above-referenced loader couplers, and that provides an improved locking system for capturing the attachment ribs to the coupler.
In accordance with one aspect of the present development, a loader coupler comprises a body including a front region, a rear region, an upper region, a lower region, and left and right lateral sides, a tilt actuator pin-on location, and left and right arm pin-on locations. Left and right laterally spaced-apart inner rib mounts are provided on the body and are adapted to mate respectively with left and right ribs of a first type of attachment coupling structure. Left and right inner locking regions are defined by the body and are vertically aligned with the left and right inner rib mounts, respectively. Left and right laterally spaced-apart outer rib mounts are provided on the body and are adapted to mate respectively with left and right ribs of a second type of attachment coupling structure. Left and right outer locking regions are defined by the body and are vertically aligned with the left and right outer rib mounts, respectively. A lock system includes left and right plunger assemblies that each move between a locked and unlocked position. The left and right plunger assemblies each include a first lock plunger located on a first lock plunger axis and a second lock plunger located on a second lock plunger axis. The left and right first lock plungers extend into the left and right inner locking regions when the left and right plunger assemblies are located in the locked position. The left and right first lock plungers are at least partially withdrawn from the left and right inner locking regions when the left and right plunger assemblies are located in the unlocked position. The left and right second lock plungers extend into the left and right outer locking regions when the left and right plunger assemblies are located in the locked position. The left and right second lock plungers are at least partially withdrawn from the left and right outer locking regions when the left and right plunger assemblies are located in the unlocked position.
In accordance with another aspect of the present development, a lock system for releasably capturing an associated attachment having either a first type of attachment coupling structure or a second type of attachment coupling structure to loader coupler body is provided. The lock system includes left and right plunger assemblies that each move between an extended position and a retracted position. The left and right plunger assemblies each include a first lock plunger and a second lock plunger.
In accordance with another aspect of the present development, a lock plunger assembly is provided for releasably capturing to loader coupler body an associated attachment having either a first type of attachment coupling structure or a second type of attachment coupling structure. The lock plunger assembly includes a plunger assembly base. First and second parallel, spaced-apart lock plungers are connected to the base and project outwardly from the base in a common direction.
Referring now to all of
The two innermost (fifth) ribs 10e define a tilt actuator pin-on location PT (
The rear R of the coupler body B further comprises left and right pin-on locations PL, PR by which the coupler body is operatively connected to associated left and right arms of a loader or other associated machine, respectively, for pivoting movement of the body relative to the associated machine arms. In the illustrated embodiment, the outermost two ribs 10a,10b of the left/right coupler portions LP/RP define a channel therebetween that is adapted to receive the associated left/right machine arms. The ribs 10a,10b define respective aligned apertures A2 and the associated arms are secured to the coupler body B by insertion of pins through the aligned apertures A2 of the pin-on locations PL, PR and through an aligned bore in the associated machine arm.
In the illustrated example, the coupler body B comprises only a single tilt actuator pin-on location PT. In an alternative embodiment, the coupler body B comprises left and right laterally spaced-apart tilt actuator pin-on locations that are part of the left and right coupler portions LP, RP, respectively. In one example, these left and right tilt actuator pin-on locations are defined between the outer ribs 10a,10b of the left and right coupler portions LP, RP, with a structure corresponding to the left and right arm pin-on locations PL, PR, but spaced respectively above the locations PL, PR. With such an alternative structure, the coupler body B is adapted to be operably coupled to associated left and right machine arms at the locations PL, PR and is also adapted to be operably coupled to associated left and right tilt actuators at the left and right tilt actuator pin-on locations.
For both the left and right coupler portions LP, RP, the first, second and third ribs 10a,10b,10c are interconnected with a box frame 20 and also by an outer cross-bar 30 located adjacent the upper edge U of the coupler body. The illustrated outer cross-bars 30 each comprise a one-piece cylindrical bar or like structure installed in aligned apertures of the first, second and third ribs 10a,10b,10c, although it could be a multi-piece bar. The box frame 20 comprises spaced apart front and rear outer plates 22a,22b installed between and interconnecting the first and second ribs 10a,10b (see
The coupler body B further comprises a main upper support 40 that extends between and is connected to the fourth and fifth ribs 10d,10e of both the left and right coupler portions LP, RP and that extends between and interconnects the innermost (fifth) ribs 10e of the left and right coupler portions LP, RP. The main upper support 40 is located adjacent the upper edge U. In the illustrated embodiment, the main upper support 40 comprises a central one-piece tubular member 42 that is connected to both the innermost ribs 10e of the left/right coupler portions LP, RP and that extends laterally outward toward the left and right sides SL, SR of the body, extending through and connected to the left/right fourth ribs 10d.
Left and right inner cross-bars 44 are located between the third and fourth ribs 10c,10d of the left and right coupler portions LP, RP, respectively. The left/right inner cross-bars 44 have an outer ends installed in an aperture defined in the left/right third ribs 10c, and have inner ends that are, in the illustrated embodiment, installed in open left/right ends of the central tubular member 42. It can be seen in
A face plate 50 extends laterally from the third rib 10c of the left coupler portion LP to the third rib 10c of the right coupler portion RP and extends in a general vertical direction from a location adjacent the main upper support 40 to a location adjacent the body lower edge L. The face plate 50 is connected to the third, fourth and fifth ribs 10c,10d,10e of both the left and right coupler portions LP, RP so as to tie the left and right coupler portions together. The face plate is preferably a one-piece construction. As shown in the sectional views of FIGS. 5A,5B,5C the ribs 10c,10d,10e include slots 52 into which an upper edge 50u of the face plate 50 is received and so that it abuts the main upper support 40. A lower cross-bar 54 is connected to a rear surface of the face plate 50 and extends laterally between and is connected to the left/right fourth ribs 10d. The coupler body B includes numerous other support ribs/gussets G (see e.g.,
For both the left and right coupler portions LP, RP, between the third and fourth ribs 10c,10d, the body B comprises inner rib pick-up points or rib mounts M1 that are defined by the inner cross-bars 44, preferably by a cylindrical surface thereof. Similarly, for both the left and right coupler portions LP, RP, between the second and third ribs 10b,10c, the body B comprises outer rib pick-up points or rib mounts M2 that are defined by the outer cross-bars 30, preferably by a cylindrical surface thereof.
As described in more detail below, the left and right inner mounts M1 are adapted to mate with first type of attachment rib or coupling structure F1 (
With reference again to
The left and right portions LP, RP of the coupler body B each further comprise an outer locking regions such as a channel K2 (
As shown in
To releasably secure the first type of attachment coupling structure F1 (and the attachment AT1 connected thereto) to the coupler body B, or to releasably secure the second type of attachment coupling structure F2 (and the attachment AT2 connected thereto) to the coupler body B, the quick coupler Q further comprising a lock system 70, which is described now with primary reference to
The left and right rods R1,R2 are respectively operably connected to left and right lock plunger assemblies 80. Each plunger assembly 80 comprises: (i) a base plate 82 connected by welding, fasteners or otherwise to the rod R1,R2; and, (ii) first and second spaced-apart lock plungers L1,L2 that project laterally outward from the base plate in a common direction. The first and second lock plungers L1,L2 are preferably arranged horizontally and parallel to each other and are preferably defined by respective cylindrical members. A locator boss/plunger or like projection G3 is located between the two lock plungers and also projects outwardly from the base plate 82. The left and right lock plunger assemblies 80 are thus movably connected to the coupler body B for movement between extended (locked—FIGS. 9A,9B,9C) and retracted (unlocked—
In the illustrated embodiment, for both the left and right coupler portions LP, RP, the ribs 10c,10d define respective plunger apertures 90c,90d (see also FIGS. 5B,5C) that are coaxial with respect to a first lock plunger axis. The aperture 90d includes a boss 91 that can be greased. The first lock plunger L1 is slidably supported in the boss 91 and is selectively movable outward to an extended (locked) position where it extends into and preferably spans the inner lock channel K1 and is received in the aperture 90c as shown in
Similarly, for both the left and right coupler portions LP,RP, as shown e.g., in FIGS. 1 and 5B-5D, the ribs 10b,10c,10d define respective plunger apertures 92b,92c,92d that are coaxial with respect to a second lock plunger axis. A boss 93 (
When the coupler Q is fully mated with the first type of attachment coupling structure F1 as described above, the eye apertures EA of the left and right female ribs R1 are located in the left and right inner locking channels K1 and are aligned with the first lock plungers L1, and movement of the left and right plunger assemblies 80 from their retracted (unlocked) positions to their extended (locked) positions will cause the first lock plungers L1 to extend through the aligned eye apertures EA to capture the ribs R1 to the coupler body for use of the bucket or other attachment to which the ribs R1 are connected. Likewise, when the coupler Q is fully mated with the second type of attachment coupling structure F2 as described above, the eye apertures EA of the left and right female ribs R2 are located in the left and right outer locking channels K2 and are aligned with the second lock plungers L2, and movement of the left and right plunger assemblies 80 from their retracted positions to their extended positions will cause the second lock plungers L2 to extend through the aligned eye apertures EA to capture the ribs R2 to the coupler body for use of the bucket or other attachment to which the ribs R2 are connected. When the plunger assemblies 80 are in their retracted (unlocked) positions, the coupler body B is able to be freely mated and separated from either the first type of attachment coupling structure F1 or the second type of attachment coupling structure F2, because the first and second locking plungers L1,L2 do not obstruct the inner and outer locking channels K1,K2 for either the left or right coupler portion LP,RP.
Those of ordinary skill in the art will recognize that a main advantage flowing from the separate first and second locking plungers L1,L2 for the left and right plunger assemblies 80 is that the eye apertures EA of the first type of attachment coupling structure F1 and the eye apertures EA of the second type of attachment coupling structure F2 need not be located along a common locking axis as would be the case if a single locking plunger was used to capture both the first and second types of attachment coupling structures F1,F2 to the coupler body. This, then, allows the inner rib mounts M1 and outer rib mounts M2 to be located where desired to optimize the geometry when an attachment AT1 or AT2 is operably connected to the coupler, i.e., the mounts need not be located to preserve a single common locking plunger axis.
Attachments such as the attachments AT1,AT2 are optionally equipped with a hydraulically or electrically powered third-function actuator such as a thumb, grapple, powered broom, or other powered actuator as in generally known in the art. In such case, the attachment comprises one or more hydraulic or electric control lines that feed and return from the third-function actuator, including fittings (plug or coupling) that mate with corresponding fittings (plug or coupling) of a hydraulic or electric system of the loader machine or other machine to which the coupler Q is operatively connected. According to the present development, the coupler Q optionally comprises a system for third-function hydraulic/electric connection. With reference to
The claims, as originally presented and as they may be amended, encompass variations, alternatives, modifications, improvements, equivalents, and substantial equivalents of the embodiments and teachings disclosed herein, including those that are presently unforeseen or unappreciated, and that, for example, may arise from applicants/patentees and others.
This application claims priority from and benefit of the filing date of U.S. provisional application Ser. No. 60/857,668 filed Nov. 8, 2006 and said provisional application Ser. No. 60/857,668 is hereby expressly incorporated by reference into the present specification.
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Number | Date | Country | |
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20080141566 A1 | Jun 2008 | US |
Number | Date | Country | |
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60857668 | Nov 2006 | US |