This application claims priority on the basis of Canadian patent application No. 2,651,295 filed Jan. 27, 2009.
This invention relates to coupler devices for releasably connecting a boom arm, such as that found on a power excavator or backhoe to a tool, such as a material handling bucket, and combinations incorporating such coupler devices.
It is known to provide excavators, power shovels and backhoes with different sizes and types of material handling implements, such as buckets to allow various operations. Known types of material handling tools, in addition to buckets, include grapples, pulverizers, and stump harvesters. To explain further, in the case of commonly used buckets on backhoe machines, a large bucket may be required for mounting on a boom arm of the machine to carry out certain types of digging operations, while a smaller bucket may be more suitable for another digging job. It is desirable to be able to change from one bucket or implement to another relatively easily and quickly and in a safe manner and, for this reason, a variety of so called quick couplers have been developed and used to facilitate such changeovers. These coupling devices are generally releasably connected to the boom arm of a machine, such as a backhoe, by means of large connecting pins which form pivot axes. The coupler can include a coupling frame which is adapted for connection to the boom arm by means of the connecting pins. Often the coupling device includes a hydraulic cylinder actuator to facilitate the attachment between the coupler and the tool.
U.S. Pat. No. 6,499,904 issued to Nye Manufacturing Ltd. describes a quick coupler for an excavator which uses a hydraulically operated actuator. This coupler has a coupling frame for connection to the boom, this frame having wedge members provided on opposite, vertically extending sides thereof. These wedge members are adapted to engage in channels formed by connecting members mounted on the tool. This coupler has a locking mechanism for securing the wedge members in the channels. The locking mechanism is mounted on the coupling frame and includes the hydraulically operated actuator and two slidable locking bars movable by this actuator between locking and unlocked positions. In the locking position, the locking bars extend into co-operating openings provided on the tool and thereby prevent the coupler from detaching from the tool.
Recent U.S. Pat. No. 6,379,075 issued Apr. 30, 2002 to GH Hensley Industries, Inc. describes a quick coupler that can be used to removably attach an excavation bucket to an outer boom end. A top portion of the coupler is pinned to the outer boom end and it has a bottom portion with spaced apart recesses configured to releasably receive portions of stick and curl pins on the bucket. An arcuate latch hook is translationally drivable by a hydraulic cylinder assembly toward one of the implement pins to releasably lock it in its associated coupler recess. A redundant safety mechanism is incorporated into this coupler and acts to hold the latch hook in its locking position. This second safety mechanism includes hydraulic and mechanical locking mechanisms and a spring structure that resiliently biases the latch hook towards its locking position.
The aforementioned '075 patent is also able to indicate to an operator of the excavator that the latch hook is in the unlocked position by a visual feature. In particular rear end portions of spring guide members project rearwardly beyond a rear end plate of the coupler to visually alert the operator that the latch hook is in the unlocked position and these rear end portions can be painted a bright color such as red so that they can be readily seen.
There remains a need for an improved coupler device for releasably connecting a boom arm to a tool, this device having a coupling frame with wedge members on opposite sides thereof adapted to engage in respective channels formed by connecting members mounted on the tool. In particular there is a need for such a coupler device with a fluid actuated holding mechanism for securing the wedge members in the channels and also a locking mechanism for locking the wedge members in the channels.
According to one embodiment of the present invention, a coupler device for releasably connecting a boom arm to a heavy tool, such as a material handling bucket includes a coupling frame adapted for connection to the boom and having wedge connectors on opposite sides thereof, these wedge connectors being adapted to engage respective co-operating channel connectors mounted on the tool. The coupler device has a primary holding mechanism for securing the wedge connectors in the channel connectors. The holding mechanism includes a holder pivotally mounted on the coupling frame for movement between a holding position and a release position and a power actuator mounted on the coupling frame, connected to the holder, and capable of pivoting the holder between the holding and release positions. The coupler device further includes a locking mechanism for locking the wedge connectors in the channel connectors, this mechanism being mounted in the coupling frame and including at least one locking member movable between a locked position in which the wedge connectors are prevented from disengaging from the channel connectors and an unlocked position.
In an exemplary version of this coupler device, the holder comprises two parallel, spaced apart plate members and a sleeve member extending between and rigidly connecting the plate members. The holder mechanism includes a pivot pin extending through the sleeve member and mounted in the coupling frame.
According to another embodiment of a coupler according to the invention, a coupler device for releasably connecting a boom arm to a tool, such as a material handling bucket includes a coupling frame adapted for connection to the boom arm and having wedge members on opposite, vertically extending sides thereof projecting outwardly in a transverse direction from the vertically extending sides. The wedge members are each adapted to engage in a channel formed by a respective one of two connecting members mounted on the tool. There is also provided a fluid actuated holding mechanism for securing the wedge members in the channels, this holding mechanism including a holder pivotably mounted on the coupling frame for movement between a holding position and a release position. The holding mechanism includes a main fluid actuator connected to the holder at one end thereof and to the coupling frame at an opposite end thereof. The fluid actuator in use is capable of pivoting the holder between the holding and release positions. The coupler also includes a locking pin mechanism for locking the wedge members in the channels, this locking pin mechanism including at least one locking pin movably mounted on the coupling frame for movement between a locked position in which the wedge members are prevented from coming out of the channels during use of the coupler device and an unlocked position.
In an exemplary version of this coupler device, the locking pin mechanism includes a linear fluid actuator mounted on the coupling frame and having a hydraulic cylinder and an actuating rod slidable in the cylinder and connected to one of the at least one locking pin. The linear fluid actuator is adapted to move the locking pin between the locked position and the unlocked position.
According to a further embodiment of the invention, a combination of a tool attachment apparatus and a coupling device for releasably coupling a tool to a boom arm includes two connecting receivers adapted to be rigidly connected to a side of the tool and forming the tool attachment apparatus. When connected to the tool, these receivers are spaced-apart from one another. Each of the connecting receivers is adapted to form a wedge-shaped channel which is open at one end thereof. The coupling device of the combination comprises a coupling frame adapted for connection to the boom arm and having wedge members on opposite sides thereof adapted to slide into the wedge-shaped channels through their open ends and to engage the connecting receivers. The coupling device has a primary holding mechanism for securing the wedge members in the receivers, this holding mechanism including a holder pivotably mounted on the coupling frame for movement about a pivot axis extending transversely of the coupling frame. The holding mechanism further includes a power actuator mounted on the coupling frame, connected to the holder, and capable of pivoting the holder about the axis between a holding position and a release position. The coupling device further includes a locking mechanism for maintaining the wedge members in the receivers, this mechanism being mounted in the coupling frame and including at least one locking member having a locking position and an unlocked position.
In an exemplary version of this combination, the locking mechanism includes a hydraulic cylinder actuator having an actuator rod connected to one of the at least one locking member. The locking mechanism is adapted to slide the at least one locking member between the locking position and the unlocked position.
These and other aspects of the disclosed coupler device and combination of tool attachment apparatus and coupling device will become more readily apparent to those having ordinary skill in the art from the following detailed description taken in conjunction with the accompanying drawings.
So that those having ordinary skill in the art to which the present disclosure pertains will more readily understand how to make and use the subject invention, exemplary embodiments thereof will be described in detail herein below with reference to the drawings.
With reference to
The illustrated material handling or digging bucket 14 can be fitted with standard claw teeth 30 and has the usual open front side at 32 that extends between two spaced apart sidewalls 34, only one of which is shown in
The coupler device 10 includes a coupling frame 52 adapted for connection to the boom arm 12 and having wedge members 54, 56 on opposite, vertically extending sides thereof projecting outwardly in a transverse direction from these vertically extending sides. The wedge members are each adapted to engage in one of the channels 44 formed in a respective one of the two connecting members mounted on the bucket. As shown, each wedge member has a sloping top edge 58 and a bottom edge 60. It will be appreciated that the acute angle B formed between the top edge and bottom edge corresponds to the angle A of the channel. For welding and weight reduction purposes, each wedge member 54, 56, can be provided with a central hole 62 if desired. Located in a rear end section of each wedge member is a circular hole 64, through which can extend a locking pin 66 as explained further hereinafter. Also the rear end section of each connecting member is provided with a suitable hole 68 which can be somewhat elongated so as to have an oval shape (see
Turning now to the illustrated, exemplary form of the coupling frame 52, the frame includes two, parallel connecting plates 70, 72 which form opposite sides of the frame. In one embodiment of this frame, these plates are made of 1.25 inch steel plate. Joining these plates are several steel connecting plates including a bent front plate 74 which can also be 1.25 inch thick, a curved rear end plate 76 and a vertically extending inner plate 78. In one particular version, the end plate 76 is 0.75 inch thick and the inner plate 78 is one inch thick. All three of these plates are shown in cross-section in
An additional connecting plate which rigidly connects the two plates 70, 72 is a relatively large, bottom plate 86 which is a flat plate, the shape of which can be seen from
Returning to the construction of the connecting plates 70, 72, these plates are provided with circular holes, 90, 92 into which the ends of the hinge pins 26, 28 extend. On both sides of the connecting plates, there can be provided bosses 94 to 97 extending around the holes in order to strengthen the plates in these regions. Circular caps 98, 100 can be detachably connected to respective ends of the hinge pins in order to secure these pins to the plates 70, 72. Several bolts or screws 102 can be used to attach these caps.
As shown in
The coupler device 10 includes a fluid actuated holding mechanism indicated generally at 110 for securing the wedge members 54, 56 in their respective channels. The holding mechanism includes a holder 112 pivotably mounted on the coupling frame 52 for movement between a holding position shown in
In an exemplary form of the hydraulic circuit 180, the main hydraulic cylinder for the actuator 123 is connected to a counterbalance check valve 182 which, during use of the coupler device, prevents the actuator rod 124 from retracting into the main hydraulic cylinder and pivoting the holder 112 to the release position in event of accidental failure of hydraulic pressure in the hydraulic circuit. In one exemplary version of the coupler device, this counter balance valve is located in the main hydraulic cylinder of the actuator 123 where it is more protected from possible damage that would cause it to fail.
The coupler device 10 is also equipped with a locking pin mechanism which includes the aforementioned locking pins 66. This locking pin mechanism, indicated generally at 130, is able to lock the wedge members 54, 56 in their respective channels 44. The locking pin mechanism includes at least one locking pin, and in the illustrated exemplary embodiment two locking pins 66, movably mounted on the coupling frame 52 for movement between a locked position shown in
In an exemplary form of the locking pin mechanism 130, the locking pin 66 have at least an outer end portion 150 which is brightly coloured and visible by a user of the machine when the locking pin is in the locked position and the coupler device is fully connected to the connecting members of the tool, for example the excavating bucket. The use of a colour such as the colour red makes it relatively easy for the user to confirm that the tool has been properly and fully locked onto the coupler device.
With reference now to the hydraulic circuit 180 illustrated in
Connected to the line 222 is a first sequence valve 216, the outlet of which is connected via a hydraulic line 236 to the closed end of the hydraulic cylinder 134. The valve 216 is a spring-loaded valve that opens at 5,000 psi, this pressure being sensed by pilot line 240. A by-pass line 242 with a one-way check valve 244 extends around the sequence valve to enable return flow of hydraulic fluid from the closed end of the hydraulic cylinder 134. It will be appreciated that once the rod 124 is fully extended, the hydraulic pressure in the line 222 will increase to 5,000 psi at which time the sequence valve 216 will open and allow hydraulic fluid to flow to the actuator 132. In this way, the rod 136 will be extended in order to move the locking pins to the locked position but only after the actuator rod 124 has been fully extended.
In order to unlock and detach the coupler device 10, hydraulic fluid is pumped through the line 234 until the actuator rod 136 is fully retracted. When full retraction occurs, the hydraulic pressure in the line 234 will increase to 5,000 psi. The sequence valve 218 is another spring-loaded valve that opens at 5,000 psi. Thus, once this pressure is reached, hydraulic fluid will flow through the line 224 to the rod end of the actuator 123, thereby retracting the rod 124. The sequence valve 218 is bypassed by a hydraulic line 250 containing a one-way check valve 252. The by-pass line allows hydraulic fluid to exit from the actuator 123 when the rod 124 is being extended. Also shown in the hydraulic circuit diagram are two pilot lines 254 and 256 provided for the return of hydraulic oil from their respective sequence valves.
Also shown in
Optionally, there can be mounted in the electrical circuit for the switch 214, a buzzer 260 and a warning light 262. The switch, buzzer and warning light can be mounted in a cab mounted control box indicated by link line 265. The buzzer will sound and the light will be turned on when the switch 214 is closed and the control valve moves to its second position 232. Thus, the buzzer will sound and the light will come on when the locking pin mechanism is moving to or has reached the unlocked position and the holder is being pivoted to or has reached its release position. Thus, warnings are provided to the operator when the coupler device is not securely attached to the tool. The switch is connected to a power source 270 which can, for example, be a standard 12 volt battery.
With reference now to
While the present invention has been illustrated and described as embodied in exemplary embodiments, i.e. embodiments having particular utility for detachably connecting a boom arm of a machine to a tool, it is to be understood that the present invention is not limited to the details shown herein, since it will be understood the various omissions, modifications, substitutions and changes in the forms and details of the disclosed coupler device and combinations employing a coupler device may be made by those skilled in the art without departing in any way from the spirit and scope of the present invention. For example, those of ordinary skill in the art will readily adapt the present disclosure for various other applications without departing from the spirit or scope of the present invention.
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2651295 | Jan 2009 | CA | national |
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