Patent Application
20220332236
This application incorporates by reference in its entirety, to the extent it is not inconsistent herewith, Australia Provisional Patent Application AUSN 2019902623 filed Jul. 24, 2020, titled LIGHTWEIGHT TRAY WITH PNEUMATIC CUSHIONING SYSTEM, Australia Provisional Patent Application AUSN 2019902624 filed Jul. 24, 2020, titled METHOD FOR CREATING AN ADHESIVE BOND USING AN ELASTOMERIC MATERIAL, and Australia Provisional Patent Application AUSN 2019902628 filed Jul. 24, 2020, titled METHOD FOR APPLYING A PROTECTIVE COATING TO A HAUL TRUCK TRAY.
The embodiments herein generally relate to a pneumatic cushioning system, and more particularly to an energy-dissipative pneumatic cushioning system for cushioning heavy loads, such as for passive and active airbag preparation and/or deployment in a haul truck.
The inventors of the inventions disclosed and claimed herein have recognized novel technical problems relating to haul truck component design, and have promulgated novel technical solutions to those problems, including improved haul truck tray design, improved tray support infrastructure, and improved cushioning elements to better support a tray. These improvements provide many benefits, including reduced overall truck weight, increased vehicle fuel efficiency, improved load capacity, reduced wear and tear, and better operational safety.
In view of the foregoing, embodiments herein provide an energy-dissipative pneumatic cushioning system for managing heavy loads, which are often measured in tons, as well as for counteracting high impact forces, for example those encountered during loading. In some embodiments, the energy-dissipative pneumatic cushioning system includes (a) one or more support members that extend beneath at least a portion of at least one pneumatic cushioning element; (b) at least one connector assembly operable to communicatively couple the at least one pneumatic cushioning element o a gas supply unit and optionally at least one gas reservoir; and (c) at least one tethering mechanism for limiting an extent of a separation between the one or more support members and the at least one pneumatic cushioning element or a structure above the at least one pneumatic cushioning element. The at least one gas reservoir is capable of accepting at least a portion of gas from the at least one pneumatic cushioning element under a force of a load. The at least one connector assembly is further operable to allow a return of at least a portion of the gas to the at least one pneumatic cushioning element upon reduction of at least a portion of a force of the load.
The embodiments herein mitigate the effects high-impact forces on a tray and truck during loading and provide a balancing function that enhances the stability of the haul truck dump tray during loading and transport. The claimed inventions further improving the structural integrity of the haul truck dump tray by dissipating kinetic energy during loading and transport, thereby reducing the amount of energy absorbed by other components of the truck, such as the tray and chassis. This in turn results in safer operation of the haul truck.
Further, the energy-dissipative pneumatic cushioning system may help to minimize lateral movement of the haul truck dump tray, e.g., side-to-side swaying of the haul truck dump tray through increased energy dissipation compared with standard load bearing and shock absorbing mechanisms.
Certain benefits of the energy-dissipative pneumatic cushioning system over conventional shock absorbing mechanisms are realized when the heavy equipment component, such as the haul truck dump tray, is made of a light-weight material. For some lightweight materials, such as haul truck dump trays made of composite materials, large instantaneous forces, such as those experienced during loading of a haul truck in the context of mining, induce large movements in the haul truck dump tray due to the tray's lower inertia compared to a heavier steel tray. By using an energy-dissipative pneumatic cushioning system in combination with lightweight heavy equipment components having some elasticity, the energy-dissipative pneumatic cushioning system can more effectively dampen any flexing of the haul truck dump tray resulting from instantaneous high-impact loads.
In some embodiments, the one or more support members include a pair of haul truck dump tray supports positioned between a haul truck chassis and a haul truck dump tray. The pair of haul truck dump tray supports may include two longitudinal steel support beams running from front to back, and substantially parallel with one or more wheels of the haul truck. The dimensions of the two longitudinal support beams may be modified in length and width to support the large number of special purpose haul trays used in mining, transportation, and construction.
The pair of haul truck dump tray supports may include a welded steel support unit. In some embodiments, the at least one pneumatic cushioning element includes a pair of elongated pneumatic cushioning elements positioned directly over and aligned with the pair of haul truck dump tray supports and extending substantially the length of the pair of haul truck dump tray supports.
The pair of elongated pneumatic cushioning elements may include one or more elongated elastic air compartments, e.g., one or more rubber air compartments. In some embodiments, the one or more elongated elastic air compartments may have a wall thickness of from about 3 mm to about 10 mm. In some embodiments, the one or more elongated elastic air compartments have a working pressure (i.e., not under load) of up to 20 bar. In some embodiments, the pneumatic cushioning elements may be comprised of at least one of a hyperelastic material or an elastic material.
In some embodiments, the at least one connector assembly includes at least one valve and at least one flange. The at least one connector assembly may be configured to accept air from the at least one gas supply unit. The at least one gas supply unit may include at least one air compressor.
In some embodiments, the at least one gas reservoir comprises a pair of elongated air tanks that are positioned parallel to the pair of elongated pneumatic cushioning elements. In some instances, the pair of elongated air tanks may be made from a metal such as steel, from a composite material, or from polyethylene or polypropylene to reduce the weight of the energy-dissipative pneumatic cushioning system. Polyethylene or polypropylene air tanks may have a greater impact resistance and superior resistance to rust, corrosion, and fuel additives relative to other tank materials. The pair of elongated air tanks may be connected to the pair of elongated pneumatic cushioning elements via at least one conduit or connector pipe. In some embodiments, the at least one conduit or connector pipe includes at least one of a metal, polyvinylchloride, or composite material pipe. The at least one conduit or connector pipe provides enhanced durability, configurability to the geometry of the support structure, and is extremely lightweight.
The at least one conduit or connector pipe may include a valve operable to functionally separate the pair of the elongated air tanks into non-linked (i.e., independent) individual compartments. The at least one tethering mechanism may include at least one of a strap (e.g., a composite material strap), a steel link, a slotted guide pin, a chain, or a cable. The at least one tethering mechanism may be joined at a first end to at least one of the one or more support members or at least one support member cross piece, and at a second end to an attachment point of a haul truck dump tray.
In some embodiments, the one or more elongated elastic air compartments present a pair of substantially fiat upper surfaces upon which a portion of the haul truck dump tray may rest, e.g., when the one or more elongated elastic air compartments are filled to at least one working pressure. In some embodiments, the at least one working pressure is maintained passively via gas flow between the at least one pneumatic cushioning element and the at least one gas reservoir in a load-dependent manner. In other embodiments, the working pressure may be maintained actively via a pneumatic system for controlling the pressure in the at least one pneumatic cushioning element in response to sensed loads over time (e.g., via pressure regulation using valves and an air compressor). In some embodiments, the at least one pneumatic cushioning element is capable of accepting, holding, and releasing a gas on demand.
The connector assembly may be adapted to release at least a portion of gas from the pneumatic cushioning element when a pressure inside the pneumatic cushioning element reaches a threshold value. In some embodiments, the pneumatic cushioning element is capable of managing transient pressures inside the pneumatic cushioning element of up to 20 bar. A material of the at least one pneumatic cushioning element may include at least one of polyurethane, rubber, nylon, woven nylon, polypropylene, polyethylene, olefin, PVC laminated and coated fabric, cloth-backed vinyl, thermoplastic films, ethyl vinyl acetate (EVA), thermoplastic polyurethane (TPU), thermoplastic elastomers (TPE), or other material deemed suitable to those of ordinary skill in the art.
In one aspect, a haul truck comprises a chassis and a haul truck dump tray assembly. For example, a subframe of the haul truck dump tray assembly may be pivotally attached to the chassis. As described above, the haul truck further may include a pneumatic system for supplying and controlling air flow to at least one pneumatic cushioning element, and the haul truck may include a pneumatic system for supplying air to, and controlling inflation of, the at least one pneumatic cushioning element.
In some embodiments, the energy-dissipative pneumatic cushioning system is operable to dissipate at least a portion of a force of weight from a structure above the energy-dissipative pneumatic cushioning system, and/or an opposing force pushing up from the support structure beneath the pneumatic cushioning system.
The energy-dissipative pneumatic cushioning system may use polyurethane material for the air compartments, which is lightweight and effectively protects the haul truck dump tray and the one or more support members from heavy loads during loading and transport when filled with gas. The energy-dissipative pneumatic cushioning system mitigates rolling and swaying of the haul truck dump tray, thereby improving safety, durability, and efficiency during loading and transport.
These and other aspects of the embodiments herein will be better appreciated and understood when considered in conjunction with the following description and the accompanying drawings. It should be understood, however, that the following descriptions, while indicating preferred embodiments and numerous specific details thereof, are given by way of illustration and not of limitation. Many changes and modifications may be made within the scope of the embodiments herein without departing from the spirit thereof, and the embodiments herein include all such modifications.
The embodiments herein will be better understood from the following detailed description with reference to the drawings, in which:
The embodiments herein and the various features and advantageous details thereof are explained more fully with reference to the non-limiting embodiments that are illustrated in the accompanying drawings and detailed in the following description. The examples used herein are intended merely to facilitate an understanding of ways in which the claimed inventions and embodiments herein may be practiced and to further enable those of skill in the art to practice the embodiments herein and the subject matter of the claims. Accordingly, the examples should not be construed as limiting the scope of the embodiments herein or the claims of this application.
As mentioned, there remains a need for better load management in haul trucks for improved safety, structural integrity, and efficiency during loading and transportation. Referring now to the drawings, and more particularly to
The load carrying assembly 104 may include one or more polyurethane adhesive joints in its construction for shear strength, tensile strength, energy dissipation, and/or durability. Load carrying assembly 104 may include a bed connector that connects with stabilization and tray support system 106. The bed connector may connect with stabilization and tray support system 106 using one or more bed connector assemblies. The one or more bed connector assemblies may include known mechanisms for connecting the haul truck dump tray 100 to a chassis, including any of chain links, pins, cams or other mechanism known to those of ordinary skill in the art; or components of a pivot sub-assembly, and/or a hoist portion. Cams may permit rotation of the haul truck dump tray 100 relative to a pivot point on the chassis of the haul truck 101.
The load carrying assembly 104 may include a polyurethane surface coating or a wear liner that provides resistance from abrasion, and surface wear and tear. The stabilization and tray support system 106 may include one or more support members 108 as a tray support structure. The tray support structure may also include at least one location for accepting a pivot mechanism connection and at least one location for accepting a hoisting mechanism connection. In some embodiments, the tray support structure includes one or more attachment points for outriggers that are configured to provide roll stabilization support by connecting one or more attachments on a side wall of the tray with one or more attachments on the tray support structure.
The one or more support members 108 may include a pair of haul truck dump tray supports that are positioned between a chassis of the haul truck 101 and the haul truck dump tray 100. The pair of haul truck dump tray supports may include two longitudinal support beams in a front of the tray to the rear of the tray orientation, and aligned with and substantially parallel to the left side wheels and the right side wheels of the haul truck 101, e.g., the support beams may extend over a length from the front to the rear of the haul truck dump tray 100. In some embodiments, the dimensions of the two longitudinal support beams may be modified in length and width to support the large number of special purpose haul truck dump trays used in mining, transportation, and construction. The pair of haul truck dump tray supports may be made of welded steel beams. The energy-dissipative pneumatic cushioning system 102 may dissipate at least a portion of the force from the tray support structure, or the load that is above the energy-dissipative pneumatic cushioning system 102, including from any load in the tray.
The one or more gas reservoirs 206A-N may store air or any other suitable gas under pressure. In some embodiments, the one or more gas reservoirs 206A-N are operably connected to a gas compressor, for example an air compressor. The one or more gas reservoirs 206A-N may be associated with a gas pump for maintaining a desired pressure, e.g., maintaining a nominally high or low pressure within the pneumatic shock absorption system depending on the weight of the load on the haul truck dump tray 100. The gas reservoir may accept at least a portion of gas from the one or more pneumatic cushioning elements 202A-N under a force of a load. The one or more gas reservoirs 206A-N may include a pair of elongated air tanks that are positioned parallel to the pair of elongated pneumatic cushioning elements. The pair of elongated air tanks may be made from polyethylene or polypropylene.
The one or more connector assemblies 208A-N are operable to communicatively couple the one or more pneumatic cushioning elements 202A-N and the one or more gas reservoirs 206A-N. The one or more connector assemblies 208A-N may allow a return of at least a portion of gas to the one or more pneumatic cushioning elements 202A-N on reduction of at least a portion of the force of the load on pneumatic cushioning elements 202A-N. The one or more connector assemblies 208A-N may be communicatively coupled to the one or more pneumatic cushioning elements 202A-N and the one or more gas reservoirs 206A-N. In some embodiments, the one or more connector assemblies 208A-N includes at least one valve and at least one flange. The one or more connector assemblies 208A-N may accept air from the one or more gas reservoirs 206A-N. The one or more connector assemblies 208A-N may also be configured to accept air from the gas supply unit. In some embodiments, the one or more gas reservoirs 206A-N is itself a gas supply unit. The gas supply unit may include at least one air compressor. The pair of elongated air tanks may be connected to the pair of elongated pneumatic cushioning elements via the one or more connector assemblies 208A-N. In some embodiments, the one or more connector assemblies 208A-N includes at least one conduit or connector pipe 204. The pair of elongated air tanks may be connected to the pair of elongated pneumatic cushioning elements via the at least one conduit or connector pipe 204. For example, the at least one conduit or connector pipe 204 may include a polyethylene pipe, a polypropylene pipe, or a polyvinylchloride pipe. In some embodiments, the at least one conduit or connector pipe 204 includes a valve that is operable to functionally separate the pair of elongated air tanks into non-linked individual (i.e., independent) compartments.
During loading of a tray, high-impact forces are common, placing extreme physical stresses on haul truck dump tray 100, the one or more support members 108, and/or the chassis of haul truck 101. Accordingly, energy-dissipative pneumatic cushioning system 102 that is filled with gas may absorb a portion of the energy of the high-impact forces via compression of gas and a concomitant increase in pressure within the one or more pneumatic cushioning elements 202A-N, and/or via release of gas into the one or more gas reservoirs 206A-N. In some embodiments, the energy-dissipative pneumatic cushioning system 102 is designed to maintain a dynamic equilibrium in which the one or more pneumatic cushioning elements 202A-N are kept at a substantially constant working pressure so that there is a capacity for additional gas compression and cushioning. Increased weight on the energy-dissipative pneumatic cushioning system 102, e.g., during loading of the haul truck dump tray 100, may supply a baseline net increasing force that increases the baseline pressure within the elongated compartment of the one or more pneumatic cushioning elements 202A-N. This increased pressure may be regulated by release of gas into the one or more gas reservoirs 206A-N.
The one or more connector assemblies 208A-N may release the excess pressure from the one or more pneumatic cushioning elements 202A-N to the one or more reservoirs 206A-N. The one or more gas reservoirs 206A-N may accept at least a portion of the gas from the one or more pneumatic cushioning elements 202A-N under the force of a load on the haul truck dump tray 100. In some embodiments, the one or more connector assemblies 208A-N reduce pressure in pneumatic cushioning elements 202A-N via release of gas when elevated pressure in the one or more pneumatic cushioning elements 202A-N exceeds the baseline pressure of the one or more pneumatic cushioning elements 202A-N. In some embodiments, the one or more connector assemblies 208A-N reduce pressure in the one or more pneumatic cushioning elements 202A-N via release of gas when elevated pressure in the one or more pneumatic cushioning elements 202A-N exceeds a threshold pressure of the one or more pneumatic cushioning elements 202A-N.
When gas from the one or more pneumatic cushioning elements 202A-N is released, any rebounding force of the one or more pneumatic cushioning elements 202A-N may be dampened and the haul truck dump tray 100 may settle stably on the one or more support members 108. In some embodiments, sequential increases in pressure within the one or more pneumatic cushioning elements 202A-N may trigger the one or more connector assemblies 208A-N to release gas into the one or more gas reservoirs 206A-N and thereby reduce the excess pressure from the haul truck dump tray 100 and, e.g., act to dissipate at least a portion of the energy of the impact of loading on the haul truck dump tray 100, the one or more support members 108, the chassis, and other components of the haul truck 101.
In some embodiments, the energy-dissipative pneumatic cushioning system 102 includes a pressure-regulating flange that maintains a working pressure within the elongated compartment of the one or more pneumatic cushioning elements 202A-N. The one or more pneumatic cushioning elements 202A-N may include a pair of elongated pneumatic cushioning elements that are positioned directly over a pair of haul truck dump tray supports, the pair of elongated pneumatic cushioning elements extending substantially the entire length of the pair of haul truck dump tray support members 108 and aligned with them. The pair of elongated pneumatic cushioning elements may include one or more elongated elastic air compartments. The pair of elongated elastic air compartments may have a wall thickness of from about 3 mm to about 10 mm. The pair of elongated elastic air compartments may include a working pressure (i.e., not under load) of up to 20 bar. The pair of elongated elastic air compartments may present a pair of substantially flat upper surfaces upon which a portion of the haul truck dump tray 100 rests when the pair of elongated elastic air compartments are filled to at least one working pressure. In some embodiments, the working pressure is maintained passively via gas flow between the one or more pneumatic cushioning elements 202A-N and the one or more gas reservoirs 206A-N in a load-dependent manner. The working pressure may be maintained actively via the pneumatic system for controlling the pressure in the one or more pneumatic cushioning elements 202A-N in response to the sensed loads over time (e.g., via pressure regulation using valves and an air compressor).
The energy-dissipative pneumatic cushioning system 102 may include at least one tethering mechanism for limiting an extent of a separation between the one or more support members 108 and the one or more pneumatic cushioning elements 202A-N or the tray support structure above the one or more pneumatic cushioning elements 202A-N. The at least one tethering mechanism may include any of a strap (e.g., a composite material strap), a steel link, a slotted guide pin, a chain, and/or a cable.
The one or more forward outriggers 302A-N and the one or more rear outriggers 304A-N provide roll stabilization support in the haul truck dump tray 100 by securing one or more points on the haul truck dump tray 100 to one or more points on the one or more support members 108A-N or chassis. The torque box 306 may include a hole that accepts at least one tethering mechanism for limiting the extent of the separation between the one or more support members 108A-N and the one or more pneumatic cushioning elements 202A-N or the tray support structure above the one or more pneumatic cushioning elements 202A-N. The rear frame assembly 308 also may include a hole that accepts at least one tethering mechanism for limiting the extent of separation between the one or more support members 108A-N and the one or more pneumatic cushioning elements 202A-N or the tray support structure above the one or more pneumatic cushioning elements 202A-N. In some embodiments, the one or more forward outriggers 302A-N and the one or more rear outriggers 304A-N may stabilize the side-to-side or lateral motion of the haul truck dump tray 100 via a connection between attachment points on the tray side walls and attachment points on, e.g., the support members 108A-N.
For example, during loading of the haul truck dump tray 100 or during transport, forces may push on one or more of the side walls of the haul truck dump tray 100, causing the haul truck dump tray 100 to tip laterally. In order to prevent the haul truck dump tray 100 from tipping over, the one or more forward outriggers 302A-N and the one or more rear outriggers 304A-N may anchor sides of the haul truck dump tray 100 to an out carriage or other point on a haul truck support structure (e.g., one or more support members 108A-N or the chassis), thereby providing an opposing force for stability. In some embodiments, the one or more forward outriggers 302A-N and the one or more rear outriggers 304A-N stabilize the haul truck dump tray 100 during uneven loading, which may favour one side of the haul truck dump tray 100 over the other side. The one or more forward outriggers 302A-N and the one or more rear outriggers 304A-N may also provide an opposing force for stability while hauling.
In some embodiments, the at least one tethering mechanism may include any of a strap (e.g., a composite material strap), a steel link, a slotted guide pin, a chain, and/or a cable. The at least one tethering mechanism may be joined at a first end to at least one of the one or more support members 108A-N or at least one support member cross piece, and at a second end to an attachment point of a haul truck dump tray 100.
The one or more rear outriggers 304A-N may include a chassis tray mount 314 for attaching the haul truck dump tray 100 to the chassis of the haul truck 101. In some embodiments, the chassis tray mount 314 is a pivot location for attaching the haul truck dump tray 100 to the chassis the haul truck 101. The one or more rear outriggers 304A-N may include a subframe of the haul truck dump tray 100 that is pivotally attached to the chassis of the haul truck 101. In some embodiments, the haul truck 101 includes a pneumatic system for supplying and controlling airflow to the one or more pneumatic cushioning elements 202A-N. The pneumatic system on the haul truck 101 may supply air to the one or more pneumatic cushioning elements 202A-N and control inflation and/or deflation of the one or more pneumatic cushioning elements 202A-N.
The foregoing description of the specific embodiments will so fully reveal the general nature of the embodiments herein that others can, by applying current knowledge, readily modify and/or adapt for various applications such specific embodiments without departing from the generic concept, and, therefore, such adaptations and modifications should and are intended to be comprehended within the meaning and range of equivalents of the disclosed embodiments. It is to be understood that the phraseology or terminology employed herein is for the purpose of description and not of limitation. Therefore, while the embodiments herein have been described in terms of preferred embodiments, those skilled in the art will recognize that the embodiments herein can be practiced with modification within the scope of the appended claims.
| Number | Date | Country | Kind |
|---|---|---|---|
| 2019902625 | Jul 2019 | AU | national |
PRIORITY CLAIM AND CROSS-REFERENCE TO RELATED APPLICATIONS This application is a National Phase of PCT/AU2020/050758 filed Jul. 24, 2020, which claims benefit of and priority to Australia, Provisional Patent Application AUSN 2019902625 filed Jul. 24, 2020, titled ENERGY-DISSIPATIVE PNEUMATIC CUSHIONING SYSTEM, and is hereby incorporated by reference in its entirety, to the extent it is not inconsistent herewith.
| Filing Document | Filing Date | Country | Kind |
|---|---|---|---|
| PCT/AU2020/050758 | 7/24/2020 | WO |
