• 专利附录
  • 专利说明
  • 权利要求
  • 类似技术
  • 同族专利
  • 引用文献
  • 法律状态
  • 优先权
    • 专利摘要:
    The present invention relates to a process and tool (25) for installing and removing various types of wear parts used with ground work equipment. The process and tool (25) allow the operator to remove and install the wear parts at a safe distance so that the operator is physically remote from the potential risks of the removal and installation process. The tool (25) can be operated manually by means of an operator or the tool (25) can be semi-automated or fully automated.
    公开号:BR112016008626B1
    申请号:R112016008626-0
    申请日:2014-10-20
    公开日:2021-02-17
    发明作者:Rod Clarke;Ryan J. Carpenter;Christopher M. Carpenter;Eric L. Bewley;Taylor M. Finley;Joseph E. Blomberg;Noah Cowgill
    申请人:Esco Group Llc;
    IPC主号:
    专利说明:

    [0001] [001] This application claims the priority benefits of Provisional Patent Application No. 61 / 893,833 filed on October 21, 2013 and entitled "Automated Wear Assembly Removal and Installation", which is incorporated in its entirety into this document by way of reference. FIELD OF THE INVENTION
    [0002] [002] The present invention relates to a tool and process of removal and / or installation for wear assemblies used in various types of work equipment on the ground. BACKGROUND OF THE INVENTION
    [0003] [003] In mining and construction, wear parts are commonly provided along the excavation edge of excavation equipment such as buckets for dredge machines, cable shovels, front shovels, hydraulic excavators, bucket wheel excavators, and the like. The wear parts protect the underlying equipment from undue wear and, in some cases, also perform other functions such as breaking the soil in front of the excavation edge. During use, wear parts typically encounter heavy and highly abrasive load conditions. As a result, they have to be replaced periodically.
    [0004] [004] These wear parts usually comprise two or more components such as a base that is attached to the excavation edge and a wear member that mounts over the base to penetrate the soil. The wear member tends to wear out more quickly and is typically replaced a number of times before the base (which can also be a replaceable wear member) also has to be recovered or replaced. An example of such a wear part is a digging tooth that is attached to the edge of a bucket for a digging machine. A tooth typically includes an adapter attached to the edge of a bucket and a tip attached to the adapter to initiate contact with the ground. A pin or other type of lock is used to secure the tip to the adapter.
    [0005] [005] Wear parts are often used in ground work equipment operated in remote locations. Arriving with new wear parts at remote locations and installing them on ground work equipment can be difficult. For example, in a mining environment, the wear parts that need replacing may be on work equipment on the ground that cannot be easily moved to a maintenance facility when routine maintenance is required. Because of this, wear parts are usually replaced while the ground working equipment is in the field. When wear parts are replaced in the field, the environment in which wear parts need to be replaced can be subject to extreme environments. For example, the temperature can be extremely cold (for example, freezing) or extremely hot, it can be snowing, raining hail, raining or windy and the soil can be muddy, uneven and / or unstable. In addition, the environment can be dusty which can present health risks for operators. Therefore, the environment in which the wear parts have to be replaced is varied and the environment is often difficult and / or unpredictable.
    [0006] [006] These wear parts are heavy and cannot be easily lifted by the installer, this increases the difficulty of replacing the wear parts. New wear parts are typically designed with cast eyes integrally connected to the wear parts. A lifting system is attached to the lifting eyes to assist in lifting the wear parts during installation. However, the installer may still be at potential risk if the lifting arrangements are unsafe and slip or create bottlenecks. The installer maneuvers the wear part towards the excavation equipment. Once the wear part is attached to the excavation equipment the wear part is held in place. Various methods known in the industry can be used to hold the wear parts in place. For example, wear parts can be attached or locked to the excavation equipment using, for example, welds, screws, wedges or threaded members. The locking mechanisms require the installer to arrive in close proximity to the wear parts before the wear part is attached. Regardless of whether the wear part is attached to the lifting system at the time of installation, the potential for the wear part to detach from the excavation equipment and fall or oscillate before implanting the locking mechanism puts the installer at potential risk.
    [0007] [007] As the wear parts contact the material to be excavated, the integral lifting eyes are worn leaving no way to obtain a fixing point on the worn wear part. To remove the worn part, some operators simply let the parts fall to the ground when the lock is removed or use a hammer to tap the wear part from the base if fines prevent the components from being released. The uncontrolled fall of the wear part and the use of a hammer subject operators to risks. In addition, operators are still left with the need to remove the wear parts from the soil to a pile or disposal tank. Another common way to remove worn out wear parts is with a complex lifting arrangement that uses chains, straps, or other mechanisms to secure the wear part. However, during removal, the installer may still be at potential risk if the lifting arrangements are unsafe and slip or create choke points. In addition, lifting arrangements that require chains, straps or other mechanisms to be under worn wear parts can be problematic when the lifting is removed. Once the wear part is moved to the discard pile, the lifting arrangements may come under the wear portion requiring the operator to roll or move the worn wear portion to remove the lifting arrangement. The potential for the wear part to tighten or otherwise harm the operator, as the heavy part is rolled or moved out of the lifting arrangement, puts the operator at potential risk. Another alternative way to maneuver the worn out part is to weld a lift ring to the part. This is not desirable due to the fact that mobile welding equipment is required at the machine site. In addition, the wear parts tend to be made of very hard steel which requires a careful and time-consuming process to achieve a high quality weld. If there is a bad weld, the lifting eye can be separated from the wear part causing uncontrolled movement of the wear part which becomes a potential risk for the installer. SUMMARY OF THE INVENTION
    [0008] [008] The present invention pertains to a process for installing and removing various types of wear members used with earth working equipment which include, for example, excavation equipment. With the present construction, the installer uses a tool to install and remove wear parts quickly and safely. The tool is especially beneficial in a mining environment that can be varied and unpredictable resulting in an environment where the process of installing and removing wear parts can be difficult and dangerous to complete. The tool allows the installer to be remote to the wear parts, that is, physically removed at a distance from potential hazards as the wear parts are removed from and / or installed in the excavation equipment. The tool can be operated manually via an operator or the tool can be a semi-automated or fully automated tool.
    [0009] [009] According to one aspect of the invention, a tool includes at least one auxiliary tool for maintaining a wear member, at least one manipulator for handling the auxiliary tool for engaging and removing the wear member from the work equipment in the earth, a controller and a movable base to move the tool to the ground work equipment. This tool can be used across an entire mine and / or moved to convenient locations to accommodate the removal of wear members from equipment that can be used in different locations or for service on a number of different equipment operating in a mine.
    [0010] [0010] According to another aspect of the invention, a tool includes at least one auxiliary tool, at least one manipulator for mobile support of the auxiliary tool, an input device for receiving data in relation to the equipment for working on the ground and a controller that operates the auxiliary tool (s) and manipulator (s) based on the received data. This tool can easily accommodate a wide variety of ground work equipment, wear members or a variety of circumstances that can be faced in a mine or other variable work environment.
    [0011] [0011] In accordance with another aspect of the invention, a tool includes a cartridge for receiving and maintaining a wear member mounted on the ground work equipment, a manipulator for mobile support of the cartridge and a controller for operating the manipulator for placing the wear member on the cartridge and remove it from the ground work equipment. The cartridge provides a safe and uniform way to maintain and remove the wear member with a high degree of safety.
    [0012] [0012] In accordance with another aspect of the invention, a tool attaches a handling member to the wear member to facilitate maintenance and removal of the wear member from work equipment on the ground, a manipulator that movably supports a tool auxiliary holding the handling member and a controller. The use of a handling member enables the tool to safely maintain a wide variety of wear members with a uniform hitch structure.
    [0013] [0013] According to another aspect of the invention, a tool includes at least one auxiliary tool to release a retainer without a hammer that holds a wear member for work equipment on the ground, at least one manipulator that supports, in a mobile way, the auxiliary tool, and a controller. In this way, the removal of wear members, especially large wear members such as used in a mining operation, using latches without a hammer can be performed with the user located remotely to further reduce hazards associated with the removal and installation of these wear members. .
    [0014] [0014] According to another aspect of the invention, a tool includes a single manipulator that movably supports at least one auxiliary tool to remove and install wear members on the ground work equipment and a controller. This tool is efficient in size and use of the tool components to perform, for example, a replacement of worn wear members with new replacement wear members.
    [0015] [0015] According to another aspect of the invention, a tool includes a manipulator that movably supports an auxiliary tool for maintaining and removing a wear member from the ground working equipment and a controller for operating the tool. it forms, at least partially, manual by a remote user to increase the safety of removing wear members, and especially large wear members such as used in a mine, from ground work equipment.
    [0016] [0016] According to another aspect of the invention, a mining tool for removing a wear member from the ground working equipment used in a mine includes at least one auxiliary tool for releasing a retainer that secures the wear member to the ground working equipment, at least one manipulator supporting the auxiliary tool and a controller to operate the auxiliary tool (s) and manipulator (s).
    [0017] [0017] According to one aspect of the invention, a tool is brought into the work equipment on the ground to remove and / or replace a wear member in such a way that the operator is remote to the wear part through at least part of the process to increase security for users. The ability to move the tool allows the tool to be used with various types of ground work equipment that cannot be easily moved to a maintenance facility and to service multiple numbers and / or types of equipment. The tool allows wear parts to be replaced even when the ground working equipment is located in the field. In a preferred construction, the tool is operated by an operator. In another preferred construction, the tool is semi-automated and is able to complete portions of the installation and removal process without an operator. In another preferred construction, the tool is fully automated and does not require an operator to complete the removal and installation of worn out parts.
    [0018] [0018] According to another aspect of the invention, a tool includes a manipulator and a controller for removing and / or installing a wear member on the ground work equipment. In a preferred build, an operator uses a user input device to remotely control the handler. In another preferred construction, the controller uses programmable logic to complete portions or the entire removal and / or installation process without an operator. In a preferred construction, the manipulator is a servoelectric manipulator. In another preferred construction, the manipulator is a hydraulic manipulator. In another preferred construction, the manipulator is pneumatic.
    [0019] [0019] According to another aspect of the invention, a tool is clamped in a fixed location and the ground working equipment is brought to the tool when wear parts need to be replaced. This allows work equipment on the ground that can be easily moved from one location to another to be brought into a maintenance facility where the environment can be more easily controlled.
    [0020] [0020] According to another aspect of the invention, a tool references a database to identify which type of wear parts are currently installed in the excavation equipment. In a preferred build, the tool references the database remotely. In other constructions, data for the database can be provided by, for example, elements in the equipment (such as bar codes, QR codes, transmitters, etc.), equipment wear identification devices, collection devices mobile data, the tool or other devices, inside the controller in the tool, manual insertion by a user, etc.
    [0021] [0021] According to another aspect of the invention, a tool receives information from a coding element attached to the excavation equipment. The coded mechanism can include information about the bucket serial number, the bucket capacity, the digging machine on which the bucket is installed, and the type of wear parts currently installed on the digging equipment. In a preferred construction, the encoding element is a Radio Frequency Identification (RFID). In another preferred construction, the coding element is a bar code. In another preferred construction, the bar code is a Quick Response Code (QR). In another preferred construction, the coding element is located in an excavation bucket.
    [0022] [0022] According to another aspect of the invention, a tool receives information from a wear part monitoring unit to identify which types of wear parts are currently installed in the excavation equipment. The wear part monitoring unit is a system for monitoring the health of wear parts in the excavation equipment.
    [0023] [0023] According to another aspect of the invention, a tool receives information from a wear part monitoring unit to identify which wear parts need to be replaced on an excavation machine.
    [0024] [0024] According to another aspect of the invention, a tool receives information from the sensors of a wear part monitoring unit to assist the tool in locating the wear parts that need replacing and assist the tool during installation. new wear parts on the ground working equipment.
    [0025] [0025] According to another aspect of the invention, a tool communicates with a database to record information about a process completed by the tool. In a preferred construction, the tool communicates at least one of: i) the time and date when the wear parts were removed and replaced, ii) how long it took to replace the wear parts, iii) machine on which the wear parts have been installed, iv) type of wear parts replaced and installed, v) torque required to remove a gripping mechanism that maintains the wear part on earth moving equipment, vi) torque used to install the gripping mechanism to maintain the wear part in the earthmoving equipment and vii) the geographic location where the wear parts were replaced.
    [0026] [0026] According to another aspect of the invention, a tool determines the orientation and location of a wear part in the excavation equipment that needs replacement with the use of sensors. The sensors allow the tool to know the location and orientation of the wear parts even when the ground work equipment is located underground and the wear parts have different orientations in relation to the ground. In a preferred construction, the sensors are passive. In another preferred construction, the sensors are active. In another preferred construction, the sensors are chosen from a group that includes receivers, transmitters and / or digital sensors. In another preferred construction, Global Positioning System (GPS) receivers are used to locate the wear part. In another preferred construction, electromagnetic wave receivers and transmitters are used to locate the wear part that needs replacement. In a preferred construction, electromagnetic waves have a longer wavelength than the visible spectrum (for example, infrared, microwave, or Radio Frequency [RF]). In another preferred construction, mechanical wave receivers and transmitters are used to locate the wear part that needs replacement. In a preferred construction, the mechanical waves are in the ultrasonic spectrum. In another preferred construction, laser receivers and transmitters are used to locate the wear part that needs replacement. In a preferred construction, a digital inclinometer unit and a digital compass are used to determine the orientation and location of the wear part that needs replacement. In a preferred construction, a camera and vision recognition software are used to identify the excavation equipment and determine the orientation and location of the wear part that needs replacement.
    [0027] [0027] According to another aspect of the invention, a tool uses an automated or semi-automated process to remove and install a wear part from the excavation equipment, operates autonomously and is also capable of being operated by an operator with a user input device. Allowing the automated tool to be operated by the operator allows other functions of the automated process to operate more efficiently. In addition, the user input device allows the automated process to continue in case the automated tool encounters an error. In a preferred construction, the user input device has a tactile, visual or audible response. In a preferred construction, the user input device is a joystick. In another preferred construction, the user input device is an operator who physically guides (for example, with his hands) the manipulator to the desired positions. In another preferred construction, the user input device is a wearable user interface.
    [0028] [0028] According to another aspect of the invention, a tool is automated to determine whether a wear part is properly oriented for removal by obtaining the orientation and location of the wear part from a digital sensor. In a preferred construction, a digital inclinometer unit is used to determine the inclination of the wear parts that need replacing. In a preferred construction, a camera and vision recognition software are used to identify the excavation equipment and determine whether the wear part that needs replacement is properly oriented for removal.
    [0029] [0029] According to another aspect of the invention, a tool includes a plurality of arms that are used to hold at least two opposite sides of the wear member. In a preferred construction, the multi-arm tool has at least two arms. In another preferred construction, the multi-arm tool has at least three arms. Two arms contact the sides of the wear member and one arm contacts the bottom of the wear member to secure the wear member to the tool.
    [0030] [0030] According to another aspect of the invention, a tool includes two or more auxiliary tools (or sub-tools) that are combined into a single tool for multiple use. In a preferred construction, a first auxiliary tool secures the wear member and a second auxiliary tool removes the gripping or retaining mechanism that holds the wear member at the base.
    [0031] [0031] According to another aspect of the invention, a tool includes a manipulator provided with an auxiliary tool (or sub-tool) that has an adjustment mechanism so that the tool can be adjusted without adjusting the orientation of the manipulator.
    [0032] [0032] According to another aspect of the invention, a magnetic belt is used to ensure that a wear part to be replaced is not disengaged prematurely from the excavation equipment. In a preferred construction, the magnetic belt uses at least one permanent magnet driven by air.
    [0033] [0033] According to another aspect of the invention, a tool includes two auxiliary tools to remove and install a wear part, a first auxiliary tool to prevent the wear part from falling and a second auxiliary tool to engage and disengage the wear part wear from a base. In a preferred construction, the first and second auxiliary tools are both supported by manipulators.
    [0034] [0034] According to another aspect of the invention, a manipulator with two arms is used to remove and install a wear part, a first arm to prevent the wear part from falling and a second arm to engage and disengage the wear part from a base.
    [0035] [0035] According to another aspect of the invention, a tool is automated and uses multiple auxiliary tools to perform an automated process to remove and install wear parts attached to the excavation equipment.
    [0036] [0036] According to another aspect of the invention, a tool uses an adjustable multi-jaw gripper to prevent the fall of a wear part from a base attached to the excavation equipment.
    [0037] [0037] According to another aspect of the invention, a cartridge fits around a wear part and holds the wear part for removal. In a preferred construction, the cartridge is attached to an automated tool. In another preferred construction, the cartridge is attached to a tool that requires an operator to maneuver the cartridge. In another preferred construction, the wear parts that need replacing are brought into the cartridge.
    [0038] [0038] According to another aspect of the invention, locators or guides are attached to the inner walls of a cartridge to assist in the proper positioning of a wear part within the cartridge.
    [0039] [0039] According to another aspect of the invention, a cartridge is used to dispatch, store, install and remove a wear part.
    [0040] [0040] According to another aspect of the invention, a cartridge has at least one fixing mechanism for raising the cartridge, for rotating the cartridge, for pulling the cartridge or for pushing the cartridge. A clamping mechanism that can be lifted, pulled or pushed allows a wear part trapped inside the cartridge to be installed and removed from a base attached to the excavation equipment.
    [0041] [0041] According to another aspect of the invention, a tool uses pressurized fluid to remove fines from a wear part. In a preferred construction, pressurized air with or without suspended abrasive grains is used to remove fines. In another preferred construction, pressurized liquid is used to remove fines.
    [0042] [0042] According to another aspect of the invention, a tool uses a vibrator to remove fines from a wear part. In a preferred construction, the vibrator is attached to the wear part with at least one electromagnet, electrically repolarized permanent magnet or air driven permanent magnet. In a preferred construction, the vibrator is isolated from the tool so that vibrations do not adversely affect the tool.
    [0043] [0043] According to another aspect of the invention, a tool attaches a handling part to a gripping mechanism, such as a retainer without a hammer, and uses the newly attached part to remove the gripping mechanism from the wear part . In a preferred construction, the tool uses a stud, a stud welder and a pneumatic wrench or hydraulic wrench to remove the gripping mechanism.
    [0044] [0044] According to another aspect of the invention, a tool uses force control and a tool that corresponds to an opening in a gripping mechanism to locate, create a positive engagement with the gripping mechanism, remove and install the gripping mechanism .
    [0045] [0045] According to another aspect of the invention, a tool uses a cutter to remove the gripping mechanism. In a preferred construction, the cutter is an arc cutter. In another preferred construction, the cutter is a waterjet cutter. In another preferred construction the cutter is rotated in a circle to remove the gripping mechanism. In another preferred construction, only a portion of the gripping mechanism is cut. In another preferred construction, the entire gripping mechanism is cut completely. In another preferred construction, the cutter is an electric arc-air torch. In another preferred construction, the cutter is a laser.
    [0046] [0046] According to another aspect of the invention, a tool uses a magnet to remove the gripping mechanism from a wear part and discards the gripping mechanism in a disposal compartment. In a preferred construction, the magnet is a permanent magnet driven by air, electromagnet or electrically repolarized permanent magnet.
    [0047] [0047] According to another aspect of the invention, a tool uses a vacuum to create a positive engagement with the gripping mechanism to remove the gripping mechanism from a wear part and discards the wear part in a disposal compartment .
    [0048] [0048] According to another aspect of the invention, a tool attaches at least one new part to the worn part and uses the newly fixed part to remove the wear part from the base. In a preferred construction, the tool uses a stud welder to fix the new part to the worn part.
    [0049] [0049] According to another aspect of the invention, a tool uses a vibrator to initially disengage a wear part from a base attached to the excavation equipment.
    [0050] [0050] According to another aspect of the invention, a tool uses a magnet to remove a wear part from a base and discards the wear part in a disposal compartment. In a preferred construction, the magnet is a permanent, air-driven magnet.
    [0051] [0051] According to another aspect of the invention, a tool uses a multi-jaw gripper to remove a wear part from a base and discards the wear part in a disposal compartment.
    [0052] [0052] According to another aspect of the invention, a disposal compartment has accessories to support the wear parts so that each wear part is kept in a fixed location.
    [0053] [0053] In accordance with another aspect of the invention, each replacement wear member is maintained in a fixed location and orientation on a pallet so that the tool can locate the new wear part and properly orient the part for installation.
    [0054] [0054] According to another aspect of the invention, a tool grips a wear part rigidly so that the wear part maintains a fixed orientation as the tool moves the wear part.
    [0055] [0055] According to another aspect of the invention, a tool is automated and verifies that a new wear part is fully seated on a base by comparing the current location of the gripping mechanism on the new wear part to the previously established location of the mechanism of grip on the worn-out limb.
    [0056] [0056] According to another aspect of the invention, a tool performs visual checks to ensure that a wear part is fully seated on the base. In a preferred construction, visual verification is performed with the use of a 2D vision camera.
    [0057] [0057] According to another aspect of the invention, a tool is automated and has been programmed with the geometry of a wear part being installed and has been programmed with the position to place a gripping mechanism on the wear part.
    [0058] [0058] According to another aspect of the invention, a tool is automated and has error handling in case the excavation equipment moves unexpectedly.
    [0059] [0059] According to another aspect of the invention, a process for removing a wear member from the ground working equipment in a mine includes operating a motorized manipulator to move an auxiliary tool in proximity to the wear member, operating the tool auxiliary to engage and maintain the wear member and remove the wear member from the ground working equipment through operation of the manipulator and / or the auxiliary tool.
    [0060] [0060] According to another aspect of the invention, a process for moving a retainer includes attaching a wear member to the ground working equipment in a mine to a release position and moving an auxiliary tool in proximity to the retainer to engage and release the retainer to allow removal of the wear member.
    [0061] [0061] According to another aspect of the invention, a process for removing a wear member from ground work equipment includes operating a manipulator to move an auxiliary tool in proximity to the wear member, operating the auxiliary tool to maintain the wear member while the operator remains remote to the wear member.
    [0062] [0062] To achieve a better understanding of the advantages and resources of the invention, reference can be made to the descriptive material below and to the attached Figures that describe and illustrate various configurations and concepts related to the invention. BRIEF DESCRIPTION OF THE DRAWINGS
    [0063] [0063] Figure 1 is a side view of a mining excavator.
    [0064] [0064] Figure 2 is a perspective view of an excavator-type bucket.
    [0065] [0065] Figure 3 is a perspective view of an edge of an excavator-type bucket.
    [0066] [0066] Figure 4 is a perspective view of a tooth assembly.
    [0067] [0067] Figure 5 is an exploded perspective view of the tooth assembly shown in Figure 4.
    [0068] [0068] Figure 6 outlines the steps of the general process to automate the removal and installation of the wear part according to the present invention.
    [0069] [0069] Figure 7 is a side view of a tool according to the present invention.
    [0070] [0070] Figure 8 is a side view of a tool changer according to the present invention.
    [0071] [0071] Figure 9 is a top view of a storage pallet according to the present invention;
    [0072] [0072] Figure 10 is a cross-sectional view of the storage pallet in Figure 9 taken along line 10-10.
    [0073] [0073] Figure 10a is a cross-sectional view of a storage pallet in a loader formation according to the present invention.
    [0074] [0074] Figure 10b is another cross-sectional view of the storage pallet shown in Figure 10a with a cartridge removed from the magazine.
    [0075] [0075] Figure 10c is another cross-sectional view of the storage pallet shown in Figure 10a with a cartridge close to being positioned in the magazine.
    [0076] [0076] Figure 11 is a side view of the second embodiment of a tool according to the present invention.
    [0077] [0077] Figure 12 is a rear perspective view of a bucket with a coding element of the present invention.
    [0078] [0078] Figure 13 is a perspective view of the tool in Figure 7 with digital receivers and sensors. Other details of the tool including the manipulator, storage pallets and tools are omitted to simplify the drawings.
    [0079] [0079] Figure 14 is a side view of a bucket at ground level with digital sensors according to the present invention.
    [0080] [0080] Figure 15 is a side view of a bucket shown in Figure 14 with the bucket tilted upwards for removing and installing the wear part.
    [0081] [0081] Figure 16 is a perspective view of a magnetic strap attached to a wear member and base according to the present invention.
    [0082] [0082] Figure 17 is a side view of a manipulator and a permanent magnet driven by air to secure the wear parts and the gripping mechanisms according to the present invention.
    [0083] [0083] Figure 18a is a perspective view of a cartridge that houses a new wear part according to the present invention.
    [0084] [0084] Figure 18b is a top view of the cartridge shown in Figure 18a with portions of the wear part and the interior of the cartridge shown in broken lines.
    [0085] [0085] Figure 18c is a front view of the cartridge shown in Figure 18a.
    [0086] [0086] Figure 18d is a side view of the cartridge shown in Figure 18a with portions of the wear part and the interior of the cartridge shown in broken lines.
    [0087] [0087] Figure 18e is a perspective view of a cartridge that houses a worn part according to the present invention.
    [0088] [0088] Figure 18f is a top view of the cartridge shown in Figure 18e with portions of the wear part and the interior of the cartridge shown in broken lines.
    [0089] [0089] Figure 18g is a front view of the cartridge shown in Figure 18e.
    [0090] [0090] Figure 18h is a side view of the cartridge shown in Figure 18e with portions of the wear part and the inside of the cartridge shown in broken lines.
    [0091] [0091] Figure 19a is a perspective view of a multi-jaw gripper for holding a wear part according to the present invention.
    [0092] [0092] Figure 19b is a top view of the multi-jaw claw of Figure 19a.
    [0093] [0093] Figure 19c is a side view of the multi-jaw claw of Figure 19a.
    [0094] [0094] Figure 19d is a front view of the multi-jaw claw in Figure 19a.
    [0095] [0095] Figure 20a is a perspective view of a pressure washing system for removing fines according to the present invention.
    [0096] [0096] Figure 20b is a perspective view of a ring spout for use with the Figure 20a pressure wash system.
    [0097] [0097] Figure 20c is a perspective view of a frame and sliding conveyor for use with the Figure 20a pressure wash system.
    [0098] [0098] Figure 21 is a side view of a vibrator for removing fines from wear parts according to the present invention.
    [0099] [0099] Figure 22a is a perspective view of a stud welder for fixing new parts to assist in the removal of wear parts according to the present invention. The manipulator and tool changer are omitted to simplify the drawing.
    [0100] [00100] Figure 22b is a perspective view of a wrench for turning new parts that have been attached to the wear parts according to the present invention.
    [0101] [00101] Figure 22c is a perspective view of a wear member with new parts attached to remove the wear member from the base according to the present invention.
    [0102] [00102] Figure 23 is a side view of a hexagonal tool for removing gripping mechanisms according to the present invention.
    [0103] [00103] Figure 24 is a perspective view of a cutter path for removing gripping mechanisms according to the present invention.
    [0104] [00104] Figure 25a is a perspective view of a cutting path to remove gripping mechanisms between a wear member and a base according to the present invention.
    [0105] [00105] Figure 25b is a top view of the wear member and base in Figure 25a.
    [0106] [00106] Figure 25c is a cross-sectional view of the wear member and base in Figure 25b taken along line 25c-25c.
    [0107] [00107] Figure 25d is a cross-sectional view of the wear member and base in Figure 25b with the gripping mechanism removed.
    [0108] [00108] Figure 26a is a side view of a custom tool for rigidly gripping the wear parts according to the present invention.
    [0109] [00109] Figure 26b is a cross-sectional view of the custom tool in Figure 26a taken along line 26b26b in Figure 26a.
    [0110] [00110] Figure 27a is a front perspective view of a manipulator with a customized tool for rigidly gripping the wear parts and removing the gripping mechanism according to the present invention.
    [0111] [00111] Figure 27b is a front side view of the custom tool shown in Figure 27a maintaining a wear part. DETAILED DESCRIPTION OF THE PREFERENTIAL MODE
    [0112] [00112] The present invention relates to a tool and a process for removing and installing various types of wear parts on ground work equipment which include, for example, excavation equipment and soil transport equipment. Excavation equipment is understood as a general term to refer to any of a variety of excavation machines used in mining, construction and other activities, and which, for example, include dredge machines, cable shovels, front shovels, excavators dredger and hydraulic cutters. Digging equipment also refers to the ground-penetrating components of these machines such as the bucket, blade, or the cutting head. Ground transport equipment is also understood as a general term to refer to a variety of equipment that is used to transport earth material and that, for example, includes mining truck gutters and bodies. The present invention is suitable for removing and installing wear parts from excavation equipment in the form of, for example, excavation teeth and guards. In addition, certain aspects of the present invention are also suitable for removing and installing a wear surface in the form of, for example, slides. For convenience of discussion, the process of removing and installing the wear part is discussed in terms of replacing a tip on a mining excavator. However, the removal and installation process can be used with other wear parts used with ground work equipment.
    [0113] [00113] Relative terms such as front, rear, top, bottom and the like are used for convenience of discussion. The terms front or front are used, in general, to indicate the usual direction of travel during use (for example, while digging), and top or top are used, in general, as a reference to the surface on which the material passes when, for example, it is collected inside the bucket. However, it is recognized that when operating various work machines on the ground, wear assemblies can be oriented in various ways and move in all types of directions during use.
    [0114] [00114] A mining excavator 1 is equipped with a bucket 3 to collect soil material during excavation (Figure 1). Bucket 3 has a shoulder 5 which is the excavation edge of bucket 3 (Figures 2 and 3). The excavation edge is that portion of the equipment that guides contact with the ground. Tooth mounts and guards are often attached to the excavation edge to protect the edge and break the soil in front of the edge. Multiple tooth assemblies 7 and guards 9, as disclosed in US Patent Application 13 / 547,353 which is incorporated into this document for reference, can be attached to the edge 5 of bucket 3 (Figures 4 and 5). The tooth shown 7 includes an adapter 11 welded (or otherwise attached) to the rim 5, an intermediate adapter 13 mounted on the adapter 11 and a tip (also called a tip) 15 mounted on the base 13. Although a tooth construction 7 shown, other tooth arrangements are possible. The tip 15 includes a rear opening cavity for receiving the nose 17, and a front end 19 for penetrating the ground. A gripping mechanism, typically called a retainer, pin or lock 21, is used to secure the wear member 15 to the base 13, and the base 13 to the nose 23 (Figures 2 and 3), although different locks can be used to secure the tip 15 and the base 13. In this order, the tip 15 is typically referred to as the wear member and the intermediate adapter 13 as the base. However, intermediate adapter 13 and adapter 11 are also wear members. For example, when intermediate adapter 13 needs replacement, it can be referred to as the wear member and adapter 11 as the base. Similarly, when adapter 11 needs replacement, it can be referred to as the wear member and the lip 5 as the base. During the life of the bucket, wear members 11, 13, 15 are usually replaced numerous times.
    [0115] [00115] Figure 6 illustrates the steps of a process for removing and installing worn wear members 15 in an excavation bucket 3. The process can be performed by an installer / operator or the process can be a semi-automated process (ie, various steps within the process can be automated) or a fully automated process. There are variations in the process. For example, it may be desirable to replace more than one wear member at a time and it may be desirable to first remove all wear members before installing new wear members.
    [0116] [00116] According to an embodiment of the invention, a tool 25 is used to remove and install wear members 15 (Figure 7). Tool 25 is brought to excavation equipment 1 that needs maintenance so that the wear parts can be replaced even when the ground work equipment is in a remote location and the wear parts need to be replaced in the field. Tool 25, for example, can be a service vehicle 27 as a mobile base with at least one manipulator 29 and at least one controller 31 such as a Central Processing Unit (CPU) with programmable logic. The controller can be a single CPU or a combination of CPUs located, for example, in the auxiliary tools, manipulators and / or service vehicle. The controllers can be located in a remote location or, as described below, they can be operated manually or operated in a partially manual manner. The service vehicle 27 can also be equipped with prop stabilizers 33, a power supply 35, a manipulator platform 37, storage compartments or pallets 39, and auxiliary tools or sub-tools 41 for use in conjunction with the manipulator 29. The service vehicle has wheels so that it can be moved easily from one location to another. In an alternative mode not shown, the service vehicle may have lanes or may have wheels and lanes. Service vehicle 27 is driven to mining excavator 1 by an operator located inside service vehicle 27. Alternatively, service vehicle 27 can be driven to normal mining excavator 1 or remotely via an input device user. For example, service vehicle 27 can be driven remotely with a joystick (not shown) and cameras (not shown) located on service vehicle 27. Alternatively, service vehicle 27 can be fully automated and programmed to drive to mining excavator 1 that needs replaced wear members 15.
    [0117] [00117] The service vehicle 27 is driven close enough to the excavator bucket 3 so that the handler 29 is able to reach the wear members 15 in the bucket 3. Once in position the hydraulic prop stabilizers 33 are lowered to provide a stable platform for the manipulator 29. The manipulator platform 37 can be located in the service vehicle 27 low enough that the manipulator 29 is able to reach the wear members 15 when the bucket 3 is resting on the ground. In some cases, the excavator operator may need to adjust bucket 3 so that bucket 3 is tilted upward or prop the bucket 3 on a platform 43 so that manipulator 29 is able to reach wear members 15 when manipulator 29 is located in service vehicle 27 (Figure 7). The service vehicle 27 can be equipped with lifting assemblies (not shown), turning and / or translating to lower, rotate and / or move the manipulator 29 so that the manipulator 29 is able to reach the wear members 15 in the bucket 3 .
    [0118] [00118] The manipulator 29 and auxiliary tools 41 can be powered from numerous power sources. For example, manipulator 29 and auxiliary tools 41 can be powered by the service vehicle, a generator or batteries.
    [0119] [00119] The manipulator platform 37 can be equipped with rails (not shown) for the manipulator 29 to slide towards the front of the service vehicle 27, towards the rear of the service vehicle 27, and / or towards any side of the service vehicle 27. Chains, hydraulic actuators or electric actuators commercially available (driving a rack or ball screw) (not shown) can be connected to the manipulator 29 to move the manipulator 29 along the tracks.
    [0120] [00120] The storage compartments or pallets 39 on the service vehicle 27 can be a part of the manipulator platform 37, integrated with the service vehicle 27, or can be removable from the service vehicle 27 so that all members wear 15 are loaded onto the service vehicle 27 in the storage compartments 39 before the service vehicle 27 is dispatched to the field (Figures 7, 9, and 10). The storage compartments 39 can be equipped with accessories or jigs 45 to support the wear members 15 so that each wear member 15 has a fixed orientation and location in relation to the manipulator 29 once installed on the service vehicle 27.
    [0121] [00121] Manipulator 29 can be customized or it can be a commercial standardized servoelectric manipulator or a commercial standardized hydraulic manipulator or a commercial standardized pneumatic manipulator. The manipulator 29 can have an integrated force sensor or it can be equipped with a standard aftermarket force sensor device. Examples of manipulators 29 that can be used include, but are not limited to, a Fanuc m-900ia-400L servoelectric robot with integrated force sensor, an ABB IRB 7600-500 servoelectric robot equipped with an ATI Force / Torque Sensor, a robot Motoman HP500D servoelectric equipped with an aftermarket ATI Force / Torque Sensor or a Vulcan Action 500 hydraulic manipulator.
    [0122] [00122] Service vehicle 27 may be equipped with one or more of a variety of auxiliary tools 41 usable for removing and / or installing wear members 15. Auxiliary tools 41 are preferably located at a fixed location in relation to the manipulator 29. The manipulator 29 can be equipped with an industry standard tool changer 47 to allow the manipulator 29 to quickly switch from an auxiliary tool to another auxiliary tool to perform various functions of the removal and installation process. The tool changer 47 has a first side 49 that connects to the manipulator 29 and a second side 51 that connects to the auxiliary tool 41 (Figure 8). The two sides 49 and 51 of the tool changer 47 are coupled when in use and uncoupled when not in use. For example, manipulator 29 can be equipped with an ATI Robotic Tool Changer. The various types of auxiliary tools 41 with which the service vehicle 27 can be equipped are discussed in detail below. The manipulator can also concurrently support multiple auxiliary tools 41.
    [0123] [00123] In an alternative embodiment (Figure 11), a service station 53 is equipped with a power supply 35, at least one controller 31 in the form of a CPU with programmable logic, at least one manipulator 29, storage compartments 39 and auxiliary tools 41 for use in conjunction with manipulator 29. Service station 53 is similar in many ways to service vehicle 27 with many of the same benefits and purposes. The following discussion focuses on the differences and does not repeat all the similarities that apply to service station 53. A mining excavator 1 is brought to service station 53 and located close enough to handler 29 for handler 29 to be able to reach the wear members 15 in the bucket 3. As with the service vehicle 27, the service station 53 can be equipped with rails (not shown) for the manipulator 29 to slide over, forwards and backwards. Manipulator 29 and auxiliary tools 41 at service station 53 can be powered from a number of power sources 35. For example, manipulator 29 and auxiliary tools 41 can be powered by a generator, batteries or powered by a system existing power supply. Service station 53 is preferably located in a convenient location for working tools on the ground to approach and for operators to have access. However, the service station may be located in the field and may include a mobile base such as a trailer to be moved to different locations.
    [0124] [00124] Once the service vehicle 27 is in position in relation to the digging bucket 3 or the digging bucket 3 is in position in relation to the service station 53, the type of wear members 15 in the bucket 3 are identified . The wear members 15 in the bucket 3 can be identified by an operator who manually enters the information in the controller 31. The operator can enter a specific identifier related to the excavation equipment 1, and the controller 31 uses the identifier to refer to a bank of wear member data 15 on the identified excavation equipment 1.
    [0125] [00125] In an alternative mode, an operator or manipulator 29 may have an auxiliary tool to pull information from a database regarding the state of the wear parts. The database can be accessed by a coding element 55 located on the excavation equipment 1, preferably in a protected area. The coding element 55 can, for example, be located at the rear of bucket 3 (Figure 12) or on the earth working machine that operates the bucket (not shown). The coding element can be, for example, an RFID, barcode, or QR code. In an alternative mode not shown, the auxiliary tool can pull information from a mobile data collection device. The coded mechanism 55 or database can store, for example, the bucket serial number, the bucket capacity, the machine the bucket is installed on, the bucket part number and type of wear members 15 currently installed in bucket 3. Data is then entered into controller 31. Controller 31 with an external Programmable Logic Controller (PLC) (not shown) or an external PC (not shown) can perform a check to ensure wear members 15 to be installed are compatible with bucket 3.
    [0126] [00126] In yet another alternative mode, controller 31 can pull the type of wear members 15 currently installed in bucket 3 from a bucket health monitoring unit (not shown). The bucket health monitoring unit can be a system that monitors and stores the current wear characteristics of each wear member 15 in bucket 3 and gives an alert when a wear member 15 is close to being spent passing a wear profile. minimal wear to wear member 15. The alert can be sent wirelessly to equipment operators and wireless devices when wear members 15 on digging equipment 1 need maintenance. In order to determine the minimum wear profile of each wear member 15 in the bucket, the health monitoring unit can refer to a database with various wear profiles for various types of wear members 15. Various aspects of the unit Bucket health monitoring can be, for example, performed by the Tooth Wear Monitoring System marketed by Motion Metrics or similar bucket health monitoring units or from a mobile data collection device.
    [0127] [00127] In addition, to assist in determining which type of wear members 15 are currently installed in bucket 3, the bucket health monitoring system may also be able to communicate other information to tool 25. Communication between the bucket health monitoring system and tool 25 can be wireless or via a cable. The bucket health monitoring system can report, for example, the specific wear member (s) 15 that is (are) worn out so that the wear member (s) wear 15 must be replaced before the next maintenance window. The bucket health monitoring system can assist the tool in providing a response to the tool during the installation and removal process. For example, the bucket health monitoring system can provide information from its sensors (for example, cameras, accelerometers) to assist the tool in locating and securing the worn out part and installing a new wear part in the base of the excavation equipment.
    [0128] [00128] In an alternative mode, the tool can communicate with the bucket health monitoring system database or another separate database to record information about the installation and the removal process. The tool can communicate with, for example, at least one of: i) the time and date that the wear parts were removed and replaced, ii) how long it took to replace the wear parts, iii) the machine on which the wear parts wear were installed, iv) type of wear parts replaced and installed, v) torque required to remove a gripping mechanism that maintains the wear part on earth moving equipment, vi) torque used to install the gripping mechanism to maintain the wear part in the earthmoving equipment and vii) the geographic location from where the wear parts were replaced.
    [0129] [00129] If mining excavator 1 is not equipped with a bucket health monitoring unit, an operator can view the current wear characteristics of each of the wear members 15 and manually insert into the controller 31 which wear members 15 need replacement. Controller 31, for example, a CPU, an external wireless, or an external PC, can also transmit information to wireless devices for which wear members 15 are being replaced. If none of the wear members 15 need to be replaced, the controller 31 can be programmed not to continue the removal and installation process.
    [0130] [00130] If one or more wear members 15 need replacement, controller 31 can determine the location of wear member 15 with respect to handler 29. Bucket 3 and service vehicle 27 or service station 53 can be equipped with sensors so that the orientation and location of the wear parts can be determined independently of the orientation of the wear parts to the ground. The sensors can be active or passive sensors and can be, for example, receivers, transmitters and digital sensors. Bucket 3 can have receivers, transmitters and digital sensors permanently installed in bucket 3 or the sensors can be positioned in bucket 3 by an operator prior to the removal and installation process. For example, bucket 3 can have at least one GPS receiver 57 and service vehicle 27 or service station 53 can also have at least three GPS receivers 57 (Figure 13). Additional digital sensors, for example, an inclinometer unit 59 and / or a compass 61, can be located on a bucket surface with a calibrated starting angle so that controller 31 can determine the orientation and location of bucket 3 in relation to the vehicle service 27 or service station 53. The initial calibrated angle can be, for example, a flat surface of bucket 3 (for example, when bucket 3 is at rest at ground level). Controller 31 can have a bucket and wear member geometry database to assist in locating wear members 15 in bucket 3. Controller 31 can determine where to maneuver manipulator 29 based on bucket 3 tilt angle, at the locations of the service vehicle 27 and bucket 3 determined from the GPS receivers 57 and at the location of the wear member 15 determined from the bucket and wear member geometry database. In another embodiment, both bucket 3 and service vehicle 27 or service station 53 may have electromagnetic wave receivers and / or transmitters, mechanical wave receivers and / or transmitters, or laser receivers and / or transmitters instead of GPS receivers 57. Electromagnetic waves may, for example, have a longer wavelength than the visible spectrum (for example, infrared, microwave, or radio frequency). Mechanical waves can, for example, have a wavelength in the ultrasonic spectrum. The receivers and transmitters can be similar to those used in the Nikon iGPS system or the iTrack’s Local Positioning System.
    [0131] [00131] In an alternative modality (Figures 27a and 27b), the location of the wear member in space in relation to the manipulator can be determined with the use of a camera 32, vision recognition software and bucket geometry / wear member . For example, the manipulator can be equipped with one or more cameras 32 and the controller, (for example, a CPU, an external PLC or an external PC) can be equipped with vision recognition software. The manipulator can be rotated, rotated or maneuvered up, down or in a circle until the vision recognition software identifies the excavation equipment, bucket or wear member. Once the vision recognition software identifies the excavation equipment, bucket or wear member, the controller can determine the orientation and location of the bucket. The manipulator can then be maneuvered closer to the bucket or wear member until the vision recognition software identifies a unique feature in the bucket or wear member. The unique feature can be, for example, unique cast surfaces, a uniquely designed welded plate or a unique hard-coated pattern. The singular resource should preferably be located in a place where it does not wear out completely. The singular feature should preferably have a pattern on the wear member or bucket so that the controller can determine the direction in which the bucket or wear member is oriented. The manipulator can be directed to the singular feature and an initial position in the bucket or wear member could be established. Based on the established starting position and bucket / limb wear geometry, the manipulator can be maneuvered to various positions required to remove and / or install bucket members.
    [0132] [00132] In an alternative embodiment, the location of the wear member 15 in the space in relation to the manipulator 29 can be entered by an operator using a user input device (i.e., a controller 31) to maneuver the manipulator 29 for a specific position on the wear member 15. In this example, controller 31 is a user input device such as, for example, a joystick or wearable user interface (not shown). Alternatively, an operator can physically guide (for example, with his hands) the manipulator 29. For example, the operator can maneuver the manipulator 29 so that the manipulator 29 is directly over the gripping mechanism 21 between the wear member 15 and the base 13 in the excavation equipment 1 so that the controller 31 is programmed with the location and orientation of the wear member 15 in relation to the manipulator. The operator is preferably remote, that is, located at a safe distance away from the wear member 15 and the manipulator. If the operator is located in a position where he cannot physically see the wear member 15, the manipulator 29 and service vehicle 27 or service station 53 can be equipped with cameras 32 (Figures 27a and 27b) to assist in maneuvering visually the manipulator 29 for the worn wear member 15. The user input device can also have tactile, visual or audible responses to provide information from the manipulator 29. The response, for example, can be a vibration, a light visible or audible sound. The answer, for example, can be given to an operator when the manipulator touches an object.
    [0133] [00133] To ensure that wear member 15 does not disengage prematurely from excavation equipment 1, bucket 3 can be tilted upward so that wear member 15 is at an angle so that gravity keeps the worn member 15 in place at the base 13. An inclinometer unit 59 located on a bucket surface with a calibrated starting angle. The bucket surface can be, for example, a flat surface of bucket 3 (for example, when bucket 3 is at rest at ground level). The inclinometer unit 59 can wirelessly transmit to the controller 31 the current orientation of bucket 3 so that controller 31 can determine when bucket 3 is in a safe orientation so that gravity keeps the worn member 15 in place after the mechanism grip 21 to be removed (Figures 14 and 15). Alternatively, a light or other audio, visual or tactile response (not shown) can indicate to the operator when bucket 3 is in a safe orientation to continue the removal process.
    [0134] [00134] In an alternative embodiment, an auxiliary tool, preferably in the form of a multi-arm tool 191, can hold the wear member on two or more sides of the wear member 15 (Figures 27a and 27b). In the illustrated example, the auxiliary tool 191 has three arms, an arm 191a which contacts the bottom of the wear member 15 and two arms 191b and 191c which contact the sides of the wear member 15, although the multi-arm tool 191 can be provided with more than three arms or less than three arms. In addition, the multi-arm tool 191 can grab any two opposing surfaces on the wear member (for example, the arms can grab the top and bottom of the wear member, the arms can grab the sides of the wear member and the top of the member wear, or the arms can grab the top and bottom and sides of the wear member). Each arm 191a to 191c can be opened and closed so that the side arms 191b and 191c move from side to side and move closer and further apart and the bottom arm 191a moves up and down. The arms can be moved by means of a motor or can be moved hydraulically. The arms 191a to 191c are spaced apart far enough that, when the arms are in the open position, the wear member fits within the opening provided by the arms and, likewise, they are spaced close enough to each other so that when the wear member is inside the opening, the arms contact and fully engage the wear member. Each arm 191a to 191c may additionally have an adjustable surface 193 for contacting the wear member 15. The adjustable surface 193 allows arms 191a to 191c to better contact the varied surfaces of the wear member. In addition, the adjustable surface 193 allows the arms 191a to 191c to better contact a worn wear member.
    [0135] [00135] In a preferred embodiment, the multi-arm tool 191 is combined with a second auxiliary tool in the form of a removal tool 195 to create a combined tool 197 that both holds the wear member 15 and can remove the gripping mechanism from wear member 15. This operation can also be performed by a single auxiliary tool with multiple skills. In the illustrated embodiment, the removal tool 195 is provided with an adjustment mechanism 199 that only adjusts the position of the removal tool 195 without adjusting the overall position of the manipulator 29 (i.e., the manipulator has fine control). Although the adjustment mechanism 199 is shown only in the embodiment shown in Figures 27a and 27b, the adjustment mechanism 199 can be applied to any of the various auxiliary tools 41 used in the removal and installation process. The adjustment mechanism 199 provides the removal tool 199 with two or more degrees of freedom so that the removal tool 195 can move from side to side and up and down without adjusting the position of the arm manipulator 29. The removal tool removal 195 is shown to have a hexagonal tool 201, although other tools are possible, to remove the gripping mechanism. The combination of the multi-arm tool 191 with the removal tool 195 allows a tool 197 to be used to remove the worn wear member and to install the new wear member. An auxiliary tool in the form of a combined tool 197 can combine any of the various auxiliary tools 41 that secure the wear member and any of the various auxiliary tools 41 that remove and install the gripping mechanism from the wear member. In addition, the auxiliary tool as a combined tool 197 can combine more than two auxiliary tools (for example, the combined tool can have an auxiliary tool for holding the wear member, an auxiliary tool for removing fines and an auxiliary tool for removing the gripping mechanism).
    [0136] [00136] In an alternative embodiment, a magnetic band 63 can secure the wear member to the base (Figure 16). Magnetic strap 63 can be made of at least one air-driven permanent magnet 65. At least one air-driven permanent magnet 65 can be attached to the worn wear member 15 and another air-activated permanent magnet 65 can be attached to base 13 and both the air-activated permanent magnets 65 can be attached to each other, for example, with a metal strap 67. The magnetic strap 63 can be applied manually or can be applied with the manipulator 29. The air-activated permanent magnets 65 can be attached , for example, be Optimag Pneumatic Lifting Magnets, SAV 531.03 NEO-AIR 500 magnets, SCHUNK Lifting Magnets MHM-P or similar commercially available permanent air-driven magnets.
    [0137] [00137] In yet another alternative modality, two (or more) 29 manipulators (not shown) can be used. A first manipulator can be used to secure wear member 15 to prevent falling and a second manipulator can be used to disengage wear member 15 from the excavator (not shown). The first handler can use a tool such as a permanent air driven magnet 65 to secure the wear member 15 (Figure 17). The controller 31 directs the manipulator 29 and the air-activated permanent magnet 65 to the programmed location X just above the wear member 15. Then, the manipulator 29 and the air-activated permanent magnet 65 can be further directed towards the member of wear 15 until the force response in the manipulator 29 registers a peak of force. The air-activated permanent magnet 65 can then be engaged to secure the wear member 15.
    [0138] [00138] In an alternative embodiment, a cartridge 69 can be used to secure the wear member 15 (Figures 18e and 18f). The cartridge 69 has a top wall 71, a bottom wall 73 and two opposite side walls (75, 79) that extend between the top wall 71 and the bottom wall 73. The guides or locators 81 on the inner surface 83 of the cartridge 69 can assist in the proper positioning of the wear member 15 within the cartridge 69. The locators can be an additional piece attached to one of the walls or the locator can be an integral part of one of the walls. The locators can be sensors that indicate when the wear member is properly positioned inside the cartridge. The locators 81 can be on the inner surface 83 of the top wall 71, the bottom wall 73, the first side wall 75, the second side wall 77 or a combination thereof. In addition, for the cartridge 69 to be able to accommodate a worn wear member 15 for removal, storage and shipping; cartridge 69 can also be used to house new wear members 15 for shipping, storage and installation (Figures 18a to 18d). However, the cartridge can be used only to accommodate worn wear members or can be used only to accommodate new wear members. The uniform shape of cartridge 69 allows wear member 15 to be stored and dispatched more easily. Locators 81 can be, for example, hollow so that studs 80 can be inserted into locators 81. Studs 80 can have a resilient member so that studs can be pushed further into the locators when studs 80 engage the wear member 15. In an alternative embodiment not shown, locators 81 can be resilient so that locators engage the wear member as the wear member is inserted into the cartridge. For example, the locator can be a cutout of a part of one of the walls of the cartridge so that the cutout creates a flap that extends into the cavity of the cartridge to engage the wear member (not shown). The worn-out member 15 may be a welded prisoner, or otherwise imprisoned 85, to prisoners 80 and / or locators 81 for additional support, but this is not a requirement and prisoners or locators may be sufficient to retain the member of wear in position. Stud weld 85 can be carried out by an operator or can be carried out using the manipulator 29. The walls 71, 73, 75, and 79 of cartridge 69 can be provided with at least one clamping mechanism 87 to secure the cartridge 69 to a lifting device. The fixing mechanism can, for example, be a lifting eye, a permanent magnet driven by air or one or more holes, for example, in the side walls 75, 79. The lifting device, for example, can be a crane or manipulator 29. In an alternative embodiment, the earthmoving equipment can be brought into cartridge 69. The walls 71, 73, 75, and 79 of cartridge 69 can have an opening 91 for the gripping mechanism 21 to enter the limb. wear 15 and the base 13 is accessible once the cartridge 69 is installed in the wear member 15. The clamping mechanism 87 can also be used to lift the cartridge 69, to rotate the cartridge 69, to pull the cartridge 69 or to push the cartridge 69. A clamping mechanism 87 that can be lifted, pulled or pushed allows a wear member 15 stuck inside the cartridge 69 to be installed and removed from the base 13 while it is attached to the handler 29. The cartridge 69 in combination with mec clamping mechanism 87 can eliminate the need for a lifting eye on the wear member 15. The elimination of the lifting eye on the wear member 15 can minimize the manufacturing waste of the wear members 15. In an alternative embodiment, at least one securing mechanism 87 is provided for securing cartridge 69 and at least one additional securing mechanism 87 is provided for lifting, pulling and pushing.
    [0139] [00139] Multiple cartridges 69 and new wear members 15 can be housed, stored, dispatched and transported in a storage compartment 39 from the moment the wear members 15 leave the manufacture to the time the wear members 15 are installed in the excavation equipment 1. Multiple cartridges 69 and worn wear members 15 can be housed, stored, dispatched and transported in a storage compartment 39 from the moment the wear members 15 are removed from the excavation equipment 1 at the time when the wear members 15 are reformed, recovered or destroyed. In an alternative embodiment, cartridges 69 can be positioned inside a storage compartment 39 in a magazine formation so that when a cartridge is taken out of the storage compartment the remaining cartridges slide to a new location so that a new one cartridge is ready for removal from storage compartment 69 (Figures 10a and 10b). Since a cartridge 69 is used to remove a worn wear member 15, the cartridge 69 with worn wear member 15 can be positioned back in the same storage compartment 39 or can be positioned in a different storage compartment 39 ( Figure 10C).
    [0140] [00140] Alternatively, a manipulator with a first arm to secure the wear member 15 to prevent falling and a second arm to disengage the wear member 15 from the excavator can be used (not shown). The first arm can use a multi-jaw claw 95 to secure the wear member 15 to the manipulator (Figures 19a to 19d). The multi-jaw claw 95 can have two outer arms 97 opposite each other. Each outer arm 97 has a wedge 99 that extends from an inner surface 101 and along the rear surface 103 of each arm 97. Each outer arm 97 has an inner wedge 105 that can slide along the inner surface 101. One cavity 107 extends between outer arm 97 and inner wedge 105. A sliding mechanism 109 is inserted into each cavity 107. The sliding mechanism can be, for example, a screw, a pneumatic cylinder, or a hydraulic cylinder. Each outer arm 97 is attached to a support 111 that extends between each opposite outer arm 97. A cavity 113 extends from an outer arm 97 through the support 111 and through the other outer arm 97. A sliding mechanism 109 is inserted into the cavity 113 so that the opposing arms are able to slide together and apart. To fix the multi-jaw clamp 95 to a wear member 15 the manipulator 29 slides the outer arms 97 apart from each other and the manipulator 29 slides the inner wedges 105 away from the rear surface 103. The manipulator positions the multi-claw 95 over the wear member 15 and slide the opposite outer arms 97 together so that each rear surface 103 and each wedge 99 fits between the wear member 15 and the base 13. In that position each rear surface 103 adjoins the base 13 and the wedge 99 is contiguous to the wear member. The manipulator 29 then slides each inner wedge 105 towards the rear surface 103 until the inner wedges 105 are contiguous with the front end 19 of the wear member 15. The wear member 15 is now secured and ready for the gripping mechanism 21 for be removed from the wear member 15.
    [0141] [00141] If mining excavator 1 is used in an environment that creates fines that accumulate between the wear member 15 and the base 13 and the area surrounding the gripping mechanism 21, an auxiliary tool 41 to dislodge the fines can be used. The auxiliary tool can be used manually by an operator or can be used with the manipulator 29. For example, a common tool currently used in the mining industry to remove fines can be used. The common tool can be, for example, a pneumatic needle hammer (not shown) or it can be a pressure wash system. For example, a nozzle 121 can be provided for a pressure washing system 123 that attaches to the manipulator 29 (Figure 20a). The pressure wash system 123 is shown to have a nozzle 121, but it can have more than one nozzle 121. The pressure wash system 123 can use a cleaning agent such as air with or without suspended abrasive grains or water to remove the fines. In an alternative embodiment, the pressure washing system 123 may use a ring nozzle 122 with many inwardly facing holes 124 around the ring to deliver the cleaning agent (Figure 20b). The ring spout 122 creates a cleaning agent blade around the wear member 15. The ring can be provided with a gripping accessory 130 to secure the ring to a tool changer 47 (Figure 8). The manipulator 29 can move the ring nozzle 122 along the longitudinal geometric axis of the wear member 15. In an alternative embodiment, the pressure washing system 123 can use a frame 126 with a sliding conveyor 128 mounted on the frame 126 (Figure 20c). The sliding conveyor must be able to slide back and forth along the frame 126 as the cleaning agent is spread from the nozzle 121 on the sliding conveyor 128. The frame 126 can be provided with a gripping accessory (not shown) similar to the gripping accessory 130 used with the ring nozzle 122 in Figure 20b. The manipulator can move the frame 126 along the longitudinal geometric axis of the wear member 15.
    [0142] [00142] In an alternative embodiment, a vibrator 125 can be used to remove the fines from the wear member 15. For example, the manipulator 29 can be used to lower a vibrator 125 against the worn wear member 15 with a winch 127 (Figure 21). Vibrator 125 is insulated so that vibrations do not cause damage to the manipulator 29. In alternative modes not shown, the tool may not have a winch 127 and the vibrator 125 can be isolated from the manipulator 29, for example, with a pneumatic system or a rubber balloon to ensure that vibrations do not damage the manipulator 29. Vibrator 125 can be a commercially available CDX Explosion Proof Electric Vibrator or similar vibrators. At least one permanent air-driven magnet 65 can be mounted on vibrator 125 with a rotating support 129. The permanent air-driven magnet 65 can be an Optimag Pneumatic Lifting Magnet, SAV 531.03 NEO-AIR 500, SCHUNK Lifting Magnet MHM-P or commercially available similar air-powered permanent magnet. The pivoting support 129 allows the air-driven permanent magnet 65 to be oriented towards the outer surface of the wear members 15.
    [0143] [00143] To disengage the gripping mechanism 21 between the wear member 15 and the base 13, the manipulator 29 can use an auxiliary tool 41 to fix a handling member or part 131 to the lock 21. For example, the manipulator 29 and an auxiliary tool 41 for securing the handling member 131 to the lock 21 is directed to a programmed location just above the wear member 15. The programmed location can be entered manually via the user input device as explained above, or it can be determined by receivers and bucket geometry as set out above. Then the manipulator 29 is further directed towards the wear member 15 along the geometric axis of the lock 21 until the force response in the manipulator 29 registers a peak of force indicating that the auxiliary tool 41 is touching the wear lock 21 The auxiliary tool 41 then fixes the handling part 131 to the lock 21. Fixing a part to the lock 21 allows the manipulator 29 not to require precise alignment with the lock 21 for removal. The handling part can have a variety of different shapes and can be, for example, a cylindrical stud, a grooved stud with a ring groove, a T-shaped stud, an L-shaped stud or a blade stud. The manipulator 29 can switch to another auxiliary tool 41 to remove the lock. The auxiliary tool 41 for fixing the piece 131 can be, for example, a stud welder 133, and the auxiliary tool 41 for removing the lock 21 can be, for example, a pneumatic or hydraulic wrench 135 that matches the shape of the stud 131 (Figures 22a and 22b). The handling member 131 can also be fixed mechanically. In the example given, lock 21 has a threaded pin that can be released by turning the pin with the pneumatic or hydraulic wrench. Other attachments or auxiliary tools could be used for other types of locks. The manipulator 29 can switch to another auxiliary tool 41 and return to the programmed location of the part or stud 131 to grab the stud 131 and discard the lock 21 in a discard compartment 137 located on the service vehicle 27 or service station 53.
    [0144] [00144] In an alternative mode, an auxiliary tool 41 that corresponds to the opening shape of the lock 22 can be attached to the manipulator 29. The force control on the manipulator 29 and an algorithm can be used to find the opening 22 in the lock 21. For example, the manipulator 29 and a hexagonal tool 139, which corresponds to the shape of the lock opening 22, can be directed to a programmed location X just above the wear member 15 (Figure 23). The programmed location X can be entered manually using a user input device or can be determined using receivers and bucket geometry as explained above. Then the manipulator 29 is further directed towards the wear member 15 along the geometric axis of the lock 21 until the force response in the manipulator 29 registers a peak of force indicating that the hexagonal tool 139 is touching the wear member 15. The manipulator 29 continues to move in a variable pattern, generally circular in a plane normal to a longitudinal geometric axis of the lock 21 until the force falls, which indicates that the hexagonal tool 139 is at least partially in alignment with the lock opening 22. Manipulator 29 can rotate hexagonal tool 139 to assist in aligning hexagonal tool 139 within lock opening 22. Manipulator 29 continues to move in a variable pattern, usually circular in a plane normal to the geometric axis longitudinal lock 21 until the force drops again which indicates that the hexagonal tool 139 is aligned in addition to the lock opening 22. Manipulator 29 continues this p until the hexagonal tool 139 is in complete alignment with the opening of the lock 22. The manipulator 29 rotates the hexagonal tool 139 in order to remove the lock 21 from the opening 20. If the lock 21 cannot be kept inside the wear member 15 in a release position, manipulator 29 can switch to another auxiliary tool 41 such as a suction cup (not shown) or a permanent air-driven magnet 65 (Figure 17) to grasp latch 21 for disposal. The suction cup or permanent magnet driven by air 65 is directed to the programmed location X just above the lock 21. Then the manipulator 29 is further directed towards the wear member 15 until the force response in the manipulator 29 registers a peak force . The suction cup or permanent magnet driven by air 65 is then engaged to catch the latch 21 for disposal of the latch 21 in a disposal compartment 137 located in the service vehicle 27 or in the service station 53.
    [0145] [00145] In yet another alternative, the manipulator 29 can use an auxiliary tool 41 to cut the lock 21. The lock 21 can be completely cut or only the parts of the lock 21 can be cut. Cutter 141 can be moved by manipulator 29 so that cutter 141 cuts an inverse frustoconical path 142 so that only latch 21 and wear member 15 are cut (Figures 24 and 25a to 25d). The base 13 remains uncut so that the base 13 does not need to be replaced. In an alternative embodiment only lock 21 is cut. The reverse frustoconic movement path can, for example, converge in a key slot void 140 of the base 13. The cutter 141 can be an electric air-torch, a water jet or laser cutter. If the entire latch 21 is not cut, manipulator 29 can switch to another auxiliary tool 41, for example, a suction cup (not shown) or a magnet 65 (Figure 17), to remove and discard latch 21 in a disposal compartment 137 located on service vehicle 27 or service station 53. Other auxiliary tools for removing other types of retainers or locks can also be used.
    [0146] [00146] To disengage the worn wear member 15 from the base 13 the manipulator 29 can first use an auxiliary tool 41 to attach at least one handling piece 131 to the worn wear member 15. For example, the manipulator 29 and a auxiliary tool 41 for attaching 131 to the wear member 15 is directed to a programmed location just above the wear member 15. The programmed location can be entered manually via a user input device or can be determined via receivers and bucket geometry as explained above. Then the manipulator 29 is further directed towards the wear member 15 until the force response in the manipulator 29 registers a peak of force indicating that the auxiliary tool 41 is touching the wear member 15. The auxiliary tool 41 then remains at least one piece 131 to the wear member 15. The auxiliary tool 41 can attach a piece 131 to each side of the wear member (Figure 22c). The auxiliary tool 41, for example, can be a prisoner welder 133 (Figure 22a). The handling member can also be mechanically attached to the wear member such as by a clamp inserted in the lock opening or by a lock component (e.g., an expansion clamp as marketed by the Pascal Corporation of Itami, Hyogo, Japan). The manipulator 29 can then switch to another auxiliary tool 41 and return to the programmed location of the new part (s) or stud (s) 131 to grab the stud (s) 131. The manipulator 29 must pull the prisoner (s) 131 along a longitudinal geometric axis of the base 13 to pull the worn wear member 15 out of the base 13. In an alternative embodiment, the auxiliary tool 41 can also fix handling parts 131 to base 13 (not shown). Fixing the pieces 131 to the base 13 allows the auxiliary tool 41 to leverage against the new pieces 131 in the base 13 and the wear member 15 to pull the wear member 15 out of the base 13. The handler 29 must then discard the member worn out wear 15 in a disposal compartment 137 located in service vehicle 27 or in service station 53. The disposed wear compartment 137 may have accessories or jigs (not shown) to support worn wear member 15 so that the parts are kept in a fixed location.
    [0147] [00147] In an alternative embodiment, the worn wear member 15 can be disengaged from the base 13 by the manipulator 29 who pulls the cartridge 69 or the multi-jaw claw 95 along the longitudinal geometric axis of the base 13.
    [0148] [00148] In an alternative embodiment, the worn wear member 15 can initially be disengaged from the base 13 with the use of a vibrator 125. Vibrator 125 can be similar to vibrator 125 discussed above to remove fines (Figure 21 ). After the initial separation, the manipulator 29 can switch to another auxiliary tool 41, for example, an air-driven permanent magnet 65 similar to the air-driven permanent magnet 65 used to grab the latch for disposal (Figure 17). The air-activated permanent magnet 65 is directed to the programmed location X just above the wear member 15. Then the manipulator 29 is further directed towards the wear member 15 until the force response in the manipulator 29 registers a peak force. . The air driven permanent magnet 65 is then engaged to catch the worn wear member 15. The manipulator 29 pulls the air driven permanent magnet 65 and the wear member 15 along the longitudinal geometric axis of the base 13 to remove the worn wear member 15 of base 13 for disposal of wear member 15 in a disposal compartment 137 located on service vehicle 27 or service station 53.
    [0149] [00149] Once the worn wear member 15 has been removed from the base 13, the fines on the base 13 may have to be removed before installing a new wear member 15. There are several auxiliary tools for removing fines and the tools can be used manually by an operator or can be used with manipulator 29. For example, a common tool currently used in the mining industry to remove fines can be used. The common tool can be, for example, a pneumatic needle hammer (not shown) or it can be a pressure washing system 123 or a vibrator 125 as previously discussed (Figures 20a, 20b, 20c and 21).
    [0150] [00150] Each new wear member 15 (that is, the wear member to be installed, whether new or partially used) is located in a specific location in the storage compartments or pallet 39. Each new wear member 15 it is located on an accessory or template 45 in a fixed orientation (Figures 9 and 10). In an alternative embodiment, each new wear member 15 can be located in a cartridge 69 in a specific fixed orientation and position on pallet 39. Each pallet 39 is located in a specific fixed location in relation to the manipulator 29. When the base 13 is ready for a new wear member 15 to be installed the controller 31 can use the programmed location of the pallet 39 and the programmed location of the new wear member 15 on the pallet to maneuver the manipulator 29 to the new wear member 15. In one embodiment Alternatively, an operator can use a controller in the form of a user input device (not shown) to maneuver the manipulator 29 to the new wear member 15.
    [0151] [00151] The manipulator 29 can use an auxiliary tool 41 to rigidly grasp the new wear member 15. The auxiliary tool 41 can be, for example, a custom tool 165 that rigidly grips a lifting eye 169 on the wear member 15 ( Figures 26a and 26b). The custom tool 165 may, for example, consist of a U 167 screw which is threaded 181 at both ends and is passed laterally through a lifting eye 169 on the wear member 15, a double wedge block 171 with side flanges 173 and holes 175 that align with screw U 167, and two nuts 177 to be threaded at the ends of screw U 167. The double wedge block 171 is positioned over screw U so that the ends of screw U 167 enter holes 175 on the double wedge block 171. Nuts 177 are threaded at the ends of screw U 167 to tighten the double wedge block 171 against the lifting eye 169. Once the nuts 177 have been fully tightened, the custom tool 165 eliminates movement side and forwards / backwards of the wear member 15 while lifting, orienting and positioning the wear member 15. The double wedge block 171 may have a surface 179 for attaching a tool changer amenta 47 (Figure 8) so that the custom tool 165 can be used with a handler 29. In an alternative embodiment (not shown), a sandwich clamping mechanism in combination with articulated tripod stabilizing feet can be used to grip rigidly the wear member 15. The articulated feet can, for example, use pneumatic, hydraulic or electric cylinders.
    [0152] [00152] With the new wear member 15 rigidly attached to the manipulator 29 the controller 31 maneuvers the new wear member 15 back to the programmed location of the base 13. Due to the fact that * the manipulator 29 catches the wear member 15 in a fixed orientation and due to the fact that * the customized tool keeps the wear member 15 in a fixed orientation the controller 31 can orient the wear member 15 to fit the base 13. The manipulator 29 pushes the new wear member 15 towards to the base 13. To ensure that the wear member 15 is fully seated on the base 13 the controller 31 compares the current location of the lock opening 22 on the new wear member 15 with the location of programmed removal of the lock 21 on the worn wear member 15. In an alternative mode, a visual check is performed. Visual verification can be performed by an operator or can be performed by a 2D view camera (not shown). Cameras (not shown) can be located on handler 29 to assist the operator in visual verification.
    [0153] [00153] In an alternative embodiment, the manipulator 29 can grasp the clamping mechanism 87 on the cartridge 69 to lift the cartridge 69 from the pallet. Since the wear member 15 has a fixed orientation inside the cartridge 69 and the cartridge 69 has a fixed orientation and location on the pallet 39 the controller 31 can rotate and orient the cartridge 69 and the wear member 15 inside the cartridge 69 to fit on the base 13. While the manipulator 29 is attached to the clamping mechanism 87, the manipulator 29 pushes the new wear member 15 towards the base 13 until the wear member 15 is fully seated on the base 13. Spring pins 82 can be installed on the guides or locators 81 inside the cartridge 69 (Figure 18b). The elastic pins 82 can engage detectors on the new wear member 15 to hold the wear member 15 on the cartridge 69. The elastic pins 82 engage the wear member 15 until the gripping mechanism 21 is in place between the wear member 12 and the base 13 and, from that point, the spring pins 82 are released and the new wear member 15 is disengaged from the cartridge 69.
    [0154] [00154] Once the new wear member 15 is fully seated on the base 13 the controller 31 locates the new gripping mechanism 21. The controller 31 can be programmed with the type of wear member 15 being installed and can be programmed with the geometry of the new wear member 15. Based on the programmed geometry of the wear member 15, the manipulator 29 can determine where the gripping mechanism 21 needs to be located on the wear member 15. If the new gripping mechanism 21 is integrated to the wear member 15 the controller 31 maneuvers the manipulator 29 to the appropriate location on the wear member 15. If the gripping mechanism 21 is not integrated with the wear member 15, the controller 31 manages the manipulator 29 into the service compartment 39 The gripping mechanism 21, like the wear member 15, can be located on pallet 39 at a fixed location and orientation. In an alternative embodiment, an operator can use a user input device (not shown) to maneuver the manipulator 29 to the gripping mechanism 21.
    [0155] [00155] To engage the gripping mechanism 21 between the wear member 15 and the base 13, an auxiliary tool 41 that corresponds to the shape of the lock opening 22 can be attached to the manipulator 29. For example, as discussed above, control of force on the manipulator 29 and an algorithm can be used to place the hexagonal tool 139 in the opening of the lock 22 (Figure 23). Once the hexagonal tool 139 is fully seated in the opening of the lock 22 the hexagonal tool rotates the lock to fully attach the wear member 15 to the base 13. In the present example, the hexagonal tool 139 can be used to drive the lock 21 in. opening of latch 22 to hold latch 21 in a clamping position to secure the tip to the base. In a wear member with an integrated lock, the lock can be in a location determined by the controller and still keep the wear member in the base.
    [0156] [00156] Controller 31 can be equipped with error handling features. For example, if the base 13 in bucket 3 moves between the removal and installation process, the manipulator 29 is equipped with a force response so that if the force response finds a force in a location that the manipulator or controller CPU 31 does not expect to find a force, manipulator 29 returns to a starting position. An operator can reinsert the location of base 13 to controller 31 using a user input device (not shown) to maneuver manipulator 29 to a specific position on base 13. In an alternative embodiment, controller 31 can relearn the location of base 13 with the use of receivers, transmitters and digital sensors in bucket 3 and service vehicle 27 or service station 53 as previously discussed.
    [0157] [00157] The above disclosure describes specific examples of a process for removing and installing wear parts. The process includes different aspects or features of the invention. Resources in one mode can be used with resources in another mode. The examples presented and the combination of resources revealed are not intended to be limiting in the sense that they have to be used together.
    权利要求:
    Claims (15)
    [0001]
    Tool (25) for removing a wear member (15) attached to an earth work equipment operating in a mine, the earth work equipment including a base (13), a wear member (15) mounted on the base ( 13), and a retainer (21) to hold the wear member (15) on the base (13), the tool (25) comprising at least one auxiliary tool (41) for maintaining the wear member (15) mounted on the ground working equipment, and for releasing the retainer (21), at least one manipulator (29) that movably supports at least one auxiliary tool (41), in which the at least one manipulator (29) and at least one auxiliary tool (41) cooperate to remove the limb from wear (15) from ground work equipment, and a controller (31) for directing the movements of at least one auxiliary tool (41) and at least one manipulator (29), characterized by the fact that a movable base to support and have the ability to move at least one auxiliary tool (41) and the manipulator (29) to different locations within the mine, including from a first location away from the mining equipment. ground work with the wear member (15) to a second suitable location for replacing the wear member (15).
    [0002]
    Tool (25) according to claim 1, characterized by the fact that the mobile base is a service vehicle (27) steerable to a desired location to remove the wear member (15) from the work equipment on the ground .
    [0003]
    Tool (25) according to claim 1, characterized by the fact that the mobile base is a mobile service station (53) that can be moved to a desired location to remove the wear member (15) from the equipment on the land.
    [0004]
    Tool (25), according to any of the preceding claims, characterized by the fact that it includes a database to provide the controller (31) with information about at least one of: i) the work equipment on the ground, ii) the wear members (15) on the ground work equipment and iii) the wear members (15) that need replacement.
    [0005]
    Tool (25) according to any one of the preceding claims, characterized by the fact that it includes an input device for receiving data in relation to the work equipment on the ground to be used by the controller (31).
    [0006]
    Tool (25), according to claim 5, characterized by the fact that the input device receives information from a wear part monitoring unit in the ground working equipment.
    [0007]
    Tool (25) according to any one of the preceding claims, characterized in that it includes at least one sensor to determine a location and orientation of the wear member (15) to be removed.
    [0008]
    Tool (25) according to any one of the preceding claims, characterized in that the at least one auxiliary tool (41) uses a multi-jaw gripper (95) to hold the wear member (15).
    [0009]
    Tool (25) according to any one of the preceding claims, characterized by the fact that the controller (31) operates at least one auxiliary tool (41) to secure a handling part (131) to the retainer (21) and with the handling part (131) releases the retainer (21).
    [0010]
    Tool (25) according to any one of the preceding claims, characterized in that the controller (31) operates at least one auxiliary tool (41) to unscrew at least a portion of the retainer (21) to release the retainer ( 21).
    [0011]
    Tool (25) according to any one of the preceding claims, characterized in that the at least one auxiliary tool (41) includes a nozzle (121) for spraying pressurized fluid to remove fines from the retainer (21).
    [0012]
    Tool (25) according to any of the preceding claims, characterized by the fact that the controller (31) operates at least one manipulator (29) and at least one auxiliary tool (41) to maintain and install a member of replacement wear (15) on ground work equipment where the removed wear member (15) was mounted.
    [0013]
    Tool (25), according to any of the preceding claims, characterized by the fact that the controller (31) operates in programmable logic to automate, at least partially, the use of the tool (25).
    [0014]
    Tool (25) according to any one of the preceding claims, characterized by the fact that the controller (31) is operated at least partially manually by a remote user.
    [0015]
    Tool, according to claim 14, characterized by the fact that the controller (31) includes a joystick operated by a remote user.
    类似技术:
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    同族专利:
    公开号 | 公开日
    JOP20200120A1|2017-06-16|
    TW201525244A|2015-07-01|
    AU2014240371A1|2015-05-07|
    JP2020125685A|2020-08-20|
    AU2018264149B2|2020-09-10|
    EP3060372A4|2017-11-29|
    AR098123A1|2016-05-04|
    AU2018264149A1|2018-12-06|
    PE20160700A1|2016-07-28|
    US11015324B2|2021-05-25|
    TWI683944B|2020-02-01|
    AU2014240371B2|2018-07-12|
    PE20210073A1|2021-01-11|
    BR112016008626A8|2020-03-17|
    AU2020210254B2|2021-12-09|
    AU2021202483A1|2021-05-20|
    JP6925482B2|2021-08-25|
    AU2020210254A1|2020-08-20|
    PE20210074A1|2021-01-11|
    EP3060372A1|2016-08-31|
    US20150107075A1|2015-04-23|
    PE20210621A1|2021-03-23|
    JO3590B1|2020-07-05|
    JP2016536489A|2016-11-24|
    TW201908572A|2019-03-01|
    WO2015061232A1|2015-04-30|
    AU2018232959A1|2018-10-11|
    JP6590799B2|2019-10-16|
    JP2019124118A|2019-07-25|
    TWI647359B|2019-01-11|
    US20210372092A1|2021-12-02|
    CA2928485A1|2015-04-30|
    JP6709306B2|2020-06-10|
    AU2018232959B2|2020-04-02|
    CL2016000945A1|2016-11-11|
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    法律状态:
    2020-03-31| B06U| Preliminary requirement: requests with searches performed by other patent offices: procedure suspended [chapter 6.21 patent gazette]|
    2020-11-10| B25A| Requested transfer of rights approved|Owner name: ESCO GROUP LLC (US) |
    2020-12-08| B09A| Decision: intention to grant [chapter 9.1 patent gazette]|
    2021-02-17| B16A| Patent or certificate of addition of invention granted [chapter 16.1 patent gazette]|Free format text: PRAZO DE VALIDADE: 20 (VINTE) ANOS CONTADOS A PARTIR DE 20/10/2014, OBSERVADAS AS CONDICOES LEGAIS. |
    优先权:
    申请号 | 申请日 | 专利标题
    US201361893833P| true| 2013-10-21|2013-10-21|
    US61/893,833|2013-10-21|
    PCT/US2014/061425|WO2015061232A1|2013-10-21|2014-10-20|Wear assembly removal and installation|
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