Patent Application
20240011239
This disclosure relates to a bucket for moving ground. It also extends to a ground moving machine including the bucket. It also extends to a method of changing the size of a bucket and a method of refurbishing a bucket. This disclosure relates particularly but not exclusively to a bucket for a loader, and a wheeled loader having a bucket mounted on arms extending forward from the loader, e.g., a surface or above ground LHD loader. It will therefore be convenient to describe the invention hereinafter with reference to this example application. However, at the same time, it is to be clearly understood that the invention is capable of broader application. For example, it could be applied to other buckets and other ground moving machines.
In the specification and claims, the term “comprising” shall be understood to have a broad meaning similar to the term “including” and will be understood to imply the inclusion of a stated integer or step or group of integers or steps but not the exclusion of any other integer or step or group of integers or steps. This definition also applies to variations on the term “comprising” such as “comprise” and “comprises”.
In the specification and claims, the term “ground material” shall be interpreted broadly and shall be understood to include all broken material that comes from or is extracted from the ground including rock, sand, earth, and ore material.
Earth or ground moving machines have wide application in construction, mining and engineering industries. Such ground moving machines include excavators, bulldozers, and loaders.
These machines have a bucket which is used to gather ground material, move the ground material and then discharge it in a different location. For example, loaders are used in mining operations to transfer ground material from a muck pile or heap of broken rock material to a dump truck. The loose ground materials include rock, and minerals such as iron ore and coal.
One prior art bucket is integrally formed and has an upper region that interacts with a bucket handling arrangement and a lower region that receives and holds the ground material loaded into the bucket. The lower region of an earth or ground moving bucket is subjected to high levels of wear and tear during daily operation of the bucket. By contrast, the upper region is exposed to significantly lower levels of wear in use, and the lifetime of the bucket is therefore determined by the longevity of the lower load carrying region.
One of the limitations with these buckets is that when the lower region is damaged or worn, the entire bucket needs to be replaced even though the upper region is still in a serviceable condition when this occurs. There is substantial cost in replacing an entire bucket because of the high cost of fabricating the bucket and machining some of the formations on the bucket, e.g., the high tolerance formations that interact with an external bucket handling arrangement.
Additionally, when a bucket fails and needs to be replaced, an associated loader may be out of commission for some time, and this results in a loss of revenue. Accordingly, machine operators would like to replace a failed bucket as quickly as possible.
The reference to prior art in the background is not and should not be taken as an acknowledgment or any form of suggestion that the referenced prior art forms part of the common general knowledge in Australia or in any other country.
Applicant recognizes that it would be advantageous if at least some components of a bucket could be re-used if a bucket failed and required replacement. Yet further, Applicant recognizes it would be beneficial if a bucket could be refurbished quickly and easily if it was damaged, to limit the downtime of the machine on which the bucket was being used. Applicant also recognizes it would be beneficial if it was possible to change the size of a bucket and that this would help to optimize mining operations.
According to one aspect of the invention there is provided a bucket for a loader used in mining operations, the bucket comprising:
The handling section may include a mounting formation, and the load carrying section may include a complementary mounting formation interacting with said one mounting formation.
The load carrying section may be sized and configured to be received within the handling section with a small clearance. The upper wall of the handling section has two sides, and the sides of the upper wall may be positioned laterally outward of the side walls of the load carrying section.
The mounting formation may include locating elements on sides of the upper wall that locate the load carrying section on the handling section in a lateral direction.
The rear end of the upper wall of the handling section may slide over the rear end of the base wall outside of the base wall. The handling section may include locating formations, e.g., locating tabs on the upper wall, for locating the rear end of the base wall in position relative to the upper wall.
The fastening arrangement may comprise a primary side fastening arrangement fastening the side walls to the upper wall, and a secondary end fastening arrangement fastening the rear end of the upper wall to the base wall.
The primary side fastening arrangement may include a mechanical fastening arrangement comprising a pin on each side of the body operatively engaged with the side wall and the upper wall that supports the load carrying section on the handling section while permitting the handling section to pivot relative to the load carrying section. Each pin may be passed through aligned apertures formed in the side wall and upper wall respectively. The upper wall may include two spaced elements each defining a pin aperture therein and the side wall includes a further element defining a pin aperture therein, and the side wall may be sandwiched between the two spaced elements on the upper wall, with the pin being passed through all three apertures to support the load carrying section.
The secondary end fastening arrangement may include a plurality of mechanical fastening elements that fasten the rear end of the upper wall to the base wall.
The plurality of mechanical fastening elements may be spaced apart in a line from one side of the upper wall to the other adjacent to the rear end.
Instead of the fastening arrangement described above, the secondary end fastening arrangement includes at least one weld for welding the rear end of the upper wall to the base wall. The at least one weld may comprise two parallel extending weld lines that extend across the upper wall at the rear end. Yet further instead, the secondary end fastening arrangement may include a combination of welding and mechanical fastening elements.
Yet further, the primary side fastening arrangement may include at least one weld on each side of the upper wall for welding the upper wall to the side walls. The at least one weld may comprise two parallel extending weld lines that extend along each side wall welding the sides of the upper wall to the load carrying section.
The mouth may have a width extending from one side wall to the other side wall and a height extending from the base wall to the upper wall at the mouth, and the width of the mouth may be greater than the height of the mouth. The mouth may face forward, i.e., away from the rear end of the upper wall when the bucket is resting on a support surface and when the bucket is engaging rock material in use. The mouth does not face upwardly when it is resting on a support surface.
The width of the mouth may be at least 20% greater than the height of the mouth, preferably at least 50% greater than the height, and even more preferably at least 80% greater than the height.
The secondary end fastening arrangement may be a different arrangement to the primary side fastening arrangement, e.g., using different components or technique of fastening to the side fastening arrangement.
According to another aspect of the invention there is provided a method of changing the size of a bucket of a loader used in mining operations comprising a handling section that is connected to a separate load carrying section to form a fixed body defining a load carrying space and an open mouth through which material is received into and discharged from the load carrying space, the handling section including an upper wall that extends in a direction away from a front end adjacent the open mouth to a rear end, and the load carrying section including a base wall and two side walls projecting up from each side of the base wall, the method comprising:
The handling section may include a mounting formation and the load carrying section may include a complementary mounting formation interacting with said one mounting formation. Said complementary mounting formations of each of said one and other load carrying sections may be sized and configured so that they both fit on said one mounting formation on the handling section (and said one and other load carrying sections are interchangeable).
The one and other load carrying sections may be received within the handling section.
The bucket body may have a depth in a direction from the front end to the rear end of the upper wall, and changing the load carrying section may increase/decrease the depth of the bucket body to increase/decrease the volume of the load carrying space.
The bucket may include a fastening arrangement fastening the handling section to the load carrying section, and detaching said one load carrying section from the handling section may include removing the fastening arrangement.
Replacing said one load carrying section with another load carrying section may include attaching the handling section to said other load carrying section using the fastening arrangement.
The fastening arrangement may include a primary side fastening arrangement attaching the side walls to the upper wall of the handling section comprising mechanical fasteners, e.g., in the form of a pin on each side of the body.
The fastening arrangement may also include a secondary end fastening arrangement fixing the rear end of the upper wall to the base wall. The secondary end fastening arrangement may comprise a plurality of mechanical fasteners or at least one weld, or a combination of welds and mechanical fasteners, fastening the rear end of the upper wall to the base wall.
The bucket may include one or more of the optional features of the bucket defined in any preceding aspect of the invention.
According to yet another aspect of the invention there is provided a method of refurbishing a bucket comprising a handling section and a separate load carrying section fastened together by a fastening arrangement to form a fixed body defining a load carrying space and an open mouth through which material is received into and discharged from the load carrying space, the handling section including an upper wall that extends away from the open mouth to a rear end, and the load carrying section including a base wall and two side walls projecting up from each side of the base wall, the method comprising:
Said removing the fastening arrangement may include cutting or unfastening mechanical fasteners from the handling and load carrying sections.
Said fastening said other load carrying section to said one handling section with the fastening arrangement may include fastening the side walls to the upper wall with mechanical fasteners, and fastening the rear end of the upper wall to the base wall with mechanical fasteners.
Instead, said removing the fastening arrangement may include cutting welds fastening the handling and load carrying sections to each other.
Further, said fastening said other load carrying section to said one handling section may include welding the side walls to the upper wall, and welding the rear end of the upper wall to the base wall.
The bucket may include one or more of the optional features of the bucket defined in any preceding aspect of the invention.
According to yet another aspect of the invention there is provided a loader for use in mining operations comprising a front body section, and a rear body section that can articulate relative to the front body section to manoeuvre the loader in use, a pair of arms extending forward from the front body section, and a bucket mounted on the pair of arms as defined in any one of the preceding aspects of the invention.
The loader may include a hinge connection intermediate the front and rear body sections that enables them to pivot relative to each other.
The loader may have wheels on the front and rear body sections for travelling across the ground, and the rear body section may include an operator's cabin and a drive arrangement for the loader.
The loader may be a wheeled LHD loader used in above ground mining operations.
The bucket may include one or more of the optional features of the bucket defined in any preceding aspect of the invention.
A bucket and a machine that is a wheeled loader for use in surface mining operations in accordance with this disclosure may manifest itself in a variety of forms. It will be convenient to hereinafter describe several embodiments of the disclosure in detail with reference to the accompanying drawings. The purpose of providing this detailed description is to instruct persons having an interest in the subject matter of the invention how to carry the invention into practical effect. However, it is to be clearly understood that the specific nature of this detailed description does not supersede the generality of the preceding broad description. In the drawings:
In
The bucket 10 comprises broadly a handling section 12 that is rigidly connected to a separate load carrying section 16 by means of a fastening arrangement indicated generally by reference numeral 20 to form a fixed body. The handling and load carrying sections 12 and 16 define an interior load carrying space 22 having a volume and form a fixed open mouth 24 through which material is received into the load carrying space 22 and through which material is discharged from the load carrying space 22.
The handling section 12 includes an upper wall 30 that curves down in a direction away from the open mouth 24 along its length to a remote or rear end 32 that abuts the load carrying section 16. The curved upper wall has two sides 34 and 36 extending from the mouth 24 to the rear end 32.
The handling section 12 also includes a bucket handling formation 38 which is coupled to and interacts with an external bucket handling arrangement (not shown in
The load carrying section 16 includes a base wall 40 and two side walls 42 and 44 extending up from the base wall 40. The two side walls 42 and 44 have an upper edge 46 that abuts against the sides 34 and 36 of the upper wall 30. The base wall 40 has a front or mouth end 45 and a rear end 46 and two sides 47 and 48 extending between the mouth end 45 and rear end 46.
The fastening arrangement 20 in turn includes a primary side fastening arrangement 50 and a secondary end fastening arrangement 70. The primary side fastening arrangement 50 fastens each side of the handling section 12 to the associated side wall of the load carrying section 16. By comparison, the secondary end fastening arrangement 70 attaches the rear end 32 of the upper wall 30 of the handling section 12 to the rear end 46 of the base wall 40 of the section 16. The primary and secondary fastening arrangements 50 and 70 are different from each other and they will therefore be described separately in some detail below.
In the illustrated embodiment, each primary side fastening arrangement 50 comprises a primary fastener or pin 51 or 52, on each side of the body, extending through complementary aligned fastener apertures 54 or 56 in the handling and load carrying sections 12 and 16 respectively. The primary fasteners 51 and 52 are located adjacent to the open mouth 24 towards an upper end of the side walls 42 or 44. This secures the section 16 to the section 12 adjacent the mouth which is subject to a high load in use.
As shown in
The boss formation 140 on the handling section 12, for example, has two elements or walls that are spaced apart from each other, that each define a primary side fastening aperture 54 or 56 through which the fastening member 51 or 52 is passed. By contrast, the boss formation 142 on the load carrying section 16 has a single element or wall with its side fastening aperture that is received between or sandwiched between the two walls of the boss formation 140 of the handling section 12.
Additionally, the primary fasteners 51 and 52 are able to rotate to some extent within the primary side fastening apertures 54 and 56 and this enables the handling section 12 to pivot relative to the load carrying section 16. This enables the handling section 12 to be pivoted down into engagement with the load carrying section 16 during assembly of the bucket 10 as will be described in more detail below.
Each primary fastener 51 and 52 is a reusable pin having a diameter of about 40-150 mm (illustrated in
The plurality of secondary end fasteners 71 connect the upper wall 30 of the handling section 12 to the base wall 40 of the load carrying section 16. The secondary end fasteners 71 are arranged in a line from one side of the upper wall 30 (and base wall 40) to the other side, at the rear ends 46 and 32 thereof remote from the mouth 24. In the illustrated embodiment, the bucket 10 has about 16-24 end fasteners 71 securely fastening the base wall 40 to the upper wall 30. However, it must be understood that the number of fasteners 71 extending across the upper wall will depend in large measure on the size of the bucket and can therefore vary quite considerably for different sizes.
The secondary end fasteners 70 include complementary end fastener apertures 72 and 74 defined in respectively the upper wall 30 of the handling section 12 and the base wall 40 of the load carrying section 16. When the sections 12 and 16 are engaged to form a bucket 10, the corresponding secondary apertures 72 and 74 are aligned with each other and each secondary end fastener 71 is passed through an aligned pair of apertures 72, 74.
The handling section 12 includes a mounting formation and the load carrying section 16 has a complementary mounting formation that interacts with said one mounting formation by being received within said one mounting formation. The mounting formation includes a transverse flange 80 that depends down from both sides 34, 36 of the upper wall 30 perpendicular to the upper wall 30. The flange 80 on the left side of the bucket is clearly shown in
The transverse flange 80 extends down over its adjacent side wall 42 and provides mechanical support for the handling section 12 around the boss formations 140 and associated fastener apertures 54 and 56. It will be appreciated that a substantial load is applied through the pins 51, 52 to the handling section 12 around the apertures 54 and 56.
The walls or elements with their fastener apertures 54 or 56 in the handling and load carrying sections 12 and 16 (with the wall of the load carrying section sandwiched between the spaced walls of the handling section) help to position the load carrying section 16 accurately with respect to the handling section 12. In particular, these walls position the sections 12 and 16 correctly relative to each other in a direction of width.
The bucket 10 also includes locating tabs 90 on the handling section 12. These locating tabs 90 assist in locating a new load carrying section 16 in position within the existing handling section 12 particularly in a front to rear direction. In particular, the tabs help to locate the rear end of the base wall in position relative to the upper wall. In the illustrated embodiment, these locating tabs 90 comprise blocks or buttress formations welded onto the upper wall 30 that are spaced apart across the width of the upper wall 30 of the section 12. The bucket includes further tabs adjacent the sides of the handling section 12 for locating the side walls of the load carrying section 16 against the handling section 12.
During assembly of a bucket 10, the base wall 40 of the section 16 is received within the rear end 32 of the upper wall 30 of the section 12 and is displaced or slide across an inner surface of the upper wall 30 until the rear end 46 of the base wall 40 butts up against the locating tabs 90 on the handling section 12.
The locating tabs 90 are positioned such that when the rear end 46 of the base wall 40 abuts the formations 90, the sections 12 and 16 are aligned with each other in a front to rear direction. In this position, the secondary end fastener apertures 72 and 74, are also aligned with each other in a front to rear direction. Further, locating tabs towards the sides of the upper wall help to align the apertures 72 and 74 in a transverse direction.
The bucket further includes GET (ground engaging teeth) formations 110 extending around the open mouth 24 for enhancing the wear protection of this high wear region of the bucket 10. The GET formations 110 typically comprise discrete teeth that are individually mounted on the mouth end 45 of the base wall 40 of the load carrying section 16. The GET formations 110 may also include folded plates that are mounted over a leading edge of the side walls 42 and 44. The structure and function of GET formations 110 is known in the prior art and does not form part of the invention disclosed in this application. They will therefore not be disclosed in further detail in this detailed description.
Additionally, the bucket 10 includes deflector plates 120 mounted on an outer surface of each side wall 42, 44 of the load carrying section 16. The deflector plates 120 flare outward away from the side wall 42 or 44 in a direction away from the mouth 24. The deflector plates 120 function to deflect broken rock material away from the wheels of the loader vehicle in use. As these deflector plates 120 are known in prior art loaders, they will not be described in greater detail in this specification.
Further, the upper wall 30 of the handling section 16 has an arrangement of elongate slots 126 defined therein towards the mouth 24 or leading end thereof proximate to the mouth 24. These slots 126 in the upper wall 30 increase the visibility of the ground in front of the bucket 10 for a driver or operator of the loader. Once again, as these elongate slots 126 are known in the art they will not be described in further detail in this detailed description.
In use, a new bucket 10 of the type described above with reference to
The bucket 10 is exposed to a harsh environment in mining operations which subjects it to high wear. After a period of use, the load carrying section 16 will become worn and/or damaged to the point where the bucket 10 cannot perform its function and the section 16 needs to be replaced.
To do this, the bucket 10, and specifically the handling formation 38 of section 12, may be first detached or removed from the external bucket handling arrangement or arms of the loader to which it is fitted. This therefore basically removes the bucket from the loader on which it is mounted. This would typically be the case where a bucket is damaged and requires complete refurbishment.
Thereafter, the load carrying section 16 is separated or detached from the handling section 12 by releasing and/or removing the fasteners of the mechanical fastening arrangement 20. This involves firstly removing the secondary fasteners 71 extending along the width of the base wall 40. This is done manually by a technician using appropriate tools for the type of fasteners being used as the secondary fasteners. Where the fasteners 71 are nut and bolt fasteners, the nuts can be removed enabling the bolts to be withdrawn from their fastener apertures. Depending on their condition, the fasteners 71 are either re-used to fasten the new load carrying section or they are thrown away and replaced with new fasteners.
After the secondary fasteners 71 have been removed, the primary fasteners that are the pins 51 and 52 are removed from the primary side fastener openings 54, 56 in the boss formations 140, 142 of the handling and load carrying sections 12 and 16. This is done by removing the cap retainers 134 from the fastening members 51, 52 and then withdrawing the fasteners 51 and 52 from their side fastener apertures 54 and 56.
Once this has been done, the sections 12 and 16 are effectively detached, and the handling section 12 can be lifted off the old worn load carrying section 16 and replaced with a new load carrying section 16.
When assembling or mounting the new load carrying section 16 on the handling section 12, the various fastener apertures 54 and 56 and 72 and 74 need to be registered with each other, i.e., be aligned with each other. However, it is not a straightforward task to align or register all the associated fastener apertures with each other because the harsh operating environment causes some deformation of the bucket in use. In addition to wear of the load carrying section 16, the handling section 12 may also be deformed even though it has less contact with the rocks and other ground material than the load carrying section 16.
In a first step, the boss formations 142 on section 16 are received between the boss formations 140 on the section 12. This correctly positions the handling section 12 relative to the side walls 42, 44 of section 16 in a direction of width, i.e., extending from one side wall to the other side wall.
The primary side fastening members 51, 52 are then passed through their associated side fastener apertures 54, 56 in the sections 12 and 16 providing a basic attachment of the sections 12 and 16. The sections 12 and 16 are then aligned with each other in a transverse direction but can pivot relative to each other in a front to rear direction. That is, the primary side fastening members 51, 52 can rotate within the primary side fastening apertures 54, 56.
Thereafter, the sections 12 and 16 need to be brought into their assembly position in a front to rear direction. To do this, the handling section 12 is pivoted down into its assembly position on the load carrying section 16. The handling section 12 is correctly located in position when the rear end 46 of the base wall 40 of the load carrying section 16 butts up against the locating tabs 90 on the upper wall 30.
This action registers the associated pairs of secondary end fastener apertures 72 and 74 of two sections 12 and 16 in a front to rear direction. This enables the secondary end fasteners 71 to be inserted through the associated pairs of end apertures 72, 74 to secure the new section 16 to the existing section 12.
After this has been done, the bucket 10 is ready for use and can be operatively mounted on the external bucket handling arrangement of the loader.
An advantage of the embodiments illustrated in
The combination of primary side fastening arrangements and secondary end fastening arrangements helps to facilitate appropriate mechanical attachment and connection of the handling and load carrying sections with limited equipment. This embodiment helps to facilitate attachment of a new load carrying section to an existing handling section even if it has been deformed to some extent.
Further, the primary side fastening arrangement comprising the pins passed through the apertures on the sides of the sections 12 and 16 considerably simplifies the fastening arrangement and makes it more user friendly that prior techniques. Yet another advantage of the working embodiment in
While the process of swapping out load carrying sections can technically be performed in the field, more typically mine managers insist that it be done in a workshop for workplace safety reasons. In some applications where there is a simple swap out of load carrying sections, to change the load carrying volume of the bucket and no refurbishment is required, the bucket may remain operatively connected to the loader while the load carrying section is replaced.
One advantage of all illustrated embodiments of the bucket is that when a lower load carrying section of a bucket fails or is damaged, it can be removed and replaced with a new load carrying section. The handling section is re-used, and this is advantageous because the handling formation that interacts with the external controls is machined to a high tolerance and is expensive to manufacture.
Yet another advantage of all illustrated embodiments is that the handling section comprises a curved upper wall which extends rearward from the mouth to the load carrying section. Further, the load carrying section comprises a substantially planar base wall that matches the upper wall of the handling section and two substantially planar side walls extending up from the base that close off sides of the bucket. This basic structure assists with fabrication of the handling and load carrying sections.
Another advantage of all the described embodiments of a two-piece bucket is that a fabrication of separate handling and load carrying sections takes up less workshop space. Further, the separate sections are smaller and some ‘working at height’ risks are removed improving safety.
Related to this, the fabricated sections can be handled separately post manufacture which is easier because the sections are smaller than a combined bucket. A large bucket can be expensive to transport from its manufacturing site to a mine site and it can be cheaper and easier to transport two smaller components to site. By separately manufacturing the handling and load carrying sections, the sections can be packed more efficiently, e.g., ‘flat packed’ for shipping to the customer which reduces shipping costs. The difficulty of transporting large unitary buckets to remote customers in overseas countries adds significant cost and in some extreme cases can result in lost sales.
The bucket in
The handling section 12 has an engagement formation that comprises flanges 210 and 212 on the sides of the upper wall 30 that extend downward over complementary engagement formations on the load carrying section 16. In turn, the complementary engagement formations on the load carrying section 16 are formed by upper edge regions 216 and 218 of side walls 42 and 44 that extend up from the sides of the base wall 40. The side walls 42, 44 and particularly the upper edge regions 216 and 218 thereof, are received within the flanges 210 and 212 extending down from the upper wall 30. The flanges 210 and 212 are sized to receive the formations 216 and 218 therein with a small amount of clearance. That is, the load carrying section 16 is received within the handling section 12.
Further, the rear edge 32 of the upper wall 30 is positioned outside the base wall 40 of the section 16 (which is received within the upper wall), and the rear edge 46 of the base wall 40 is correctly located in position in a front to rear direction by locating formations 220 on the section 12.
In the
The section 12 is welded to the section 16 along each side 34 and 36 of the upper wall 30. As shown in
Further, the section 12 is welded to the section 16 along the rear end 32 of the upper wall 30. As shown in
In use, when an operator desires to replace an existing, e.g., worn, load carrying section 16 with a new load carrying section 16 they cut through the welds along the weld lines to detach or separate the section 16 from the section 12.
A new section 16 is then brought into position beneath the handling section 12 and the configurations of the sections 12, 16 with their complementary engagement formations 210, 212 and 216, 218 helps to locate them in a correct position relative to each other. The new section 16 is then welded to the existing handling section 12. This provides a bucket 10 with a new load carrying section 16 and a new working life.
Further, in another embodiment that is not illustrated in the drawings, the sections 12 and 16 of the new bucket 10 may be fastened to each other by means of a combination of mechanical fasteners and welds. For example, the side walls 42, 44 could be fastened to the upper wall 32 by mechanical fasteners like the primary side fasteners shown in
Instead, the side walls could be welded to the section 12 and the rear ends of the base wall and the upper wall could be fastened to each other by mechanical fasteners like the secondary fasteners shown in
Other than this design difference, the other dimensions of the bucket are basically the same as those on the bucket in
In use, a mine operator using the bucket shown in
In some situations, the bucket 10 may be able to remain operatively connected to the loader while the load carrying sections are swapped out. This is obviously advantageous for a mine operator because the sections can be swapped out more quickly with less downtime. Additionally, less manpower and equipment are required when the load carrying section can be replaced without removing the bucket from the loader.
An advantage of the embodiments described above with reference to
The embodiment in
One scenario where a mine operator desires to increase the bucket capacity is where a substantial amount of lighter overburden is required to be removed before the ore material can be reached and recovered. A larger bucket capacity will be preferred for removing overburden because the overburden is lighter and therefore a bigger volume of material can be carried in each bucket. This can be accomplished by swapping out a smaller load carrying section for a larger load carrying section in the manner described above.
In another scenario, a mining contractor may operate a fleet of wheel loaders which need to be relocated and deployed at another mine site, where the density of the ore being recovered is different. Alternatively, the density of an ore being recovered at a particular site may change and the contractor wants to adjust the bucket size in response to different material densities to optimize their mining operation. The interchangeability of different sized load carrying sections on a single size of handling section, makes the bucket more versatile and capable of being adapted to provide different load carrying volumes. Margins are often tight, and sub-optimum bucket sizes lead to inefficient loading and lost production. The contractors are paid per ton of material removed and therefore like to optimize their bucket size.
In another scenario, a customer may be working on a new mine site with limited information of the ore body and still be trying to establish an optimum load carrying volume of the bucket. In this situation, the properties of the ore and rock material to be handled are not precisely known until operations have been conducted for some time (long after the bucket has been fabricated). In this scenario, the bucket in
Related to this, a mining company may have multiple mining leases and its own fleet of wheel loaders for each lease, with the buckets sized to suit their specific operating conditions. However, when a lease expires, or is put on care and maintenance, or production is ramped up at other locations, loaders may need to be transferred between sites. The existing loaders may have bucket sizes that are sub-optimal for the new site and this feature enables the volume of the bucket to be changed to suit the current situation.
It will of course be realized that the above has been given only by way of illustrative example of the invention and that all such modifications and variations thereto, as would be apparent to persons skilled in the art, are deemed to fall within the broad scope and ambit of the invention as is herein set forth.
| Number | Date | Country | Kind |
|---|---|---|---|
| 2020903358 | Sep 2020 | AU | national |
| 2020904845 | Dec 2020 | AU | national |
| 2021221476 | Aug 2021 | AU | national |
| Filing Document | Filing Date | Country | Kind |
|---|---|---|---|
| PCT/AU2021/051080 | 9/17/2021 | WO |
