The present disclosure is directed to cargo handling systems and, more specifically, to a cargo transport system including a pallet loader with sliding forklift and anti-tip system.
Movement of materials and equipment is a significant and important component of any supply and distribution chain. Materials and equipment are routinely required to be transported many times throughout their life cycle. As such, many transport systems have been developed to help efficiently move items (referred to generally as “cargo” herein) through various different modes of transportation, including transport by road vehicles, rail vehicles, aircraft, and watercraft. For example, forklifts are commonly used in cargo and material transport, such as exemplary forklift 100 and 200 illustrated in
Various aspects of the present disclosure provide a cargo transport system that provides the ability to move cargo in an autonomous or semi-autonomous manner, using a relatively compact lift vehicle capable of lifting relatively heavy objects in a variety of situations. In some aspects, the cargo transport system is designed to operate autonomously or remotely to move cargo between desired locations. The system may navigate over rough terrain while carrying heavy loads through the use of a track-based propulsion system, although wheel-based systems may also be used. The system, in some aspects, provides a cargo loading system, dunnage detection, cross-decking capability, cargo stacking capability, autonomous navigation, tip detection and prevention, or any combinations thereof. In some examples, a fork assembly may be coupled with a mast and movable in a vertical direction relative to the mast. Further, the mast may be coupled with a platform or deck and movable in a horizontal direction relative to the platform. In some cases, the fork assembly may be lowered below a top plane of the platform when the mast is at a forward location relative to the platform to be in position to lift cargo that is resting at a ground (or other surface) level. In some cases, an anti-tip system may include one or more supports coupled with the platform and movable to be in front of the platform (e.g., by rotating or extending a support arm away from the platform, etc.) when the mast is located at the forward location relative to the platform. In some cases the anti-tip system may include one or more pressure sensors that may be used, alone or in conjunction with tip sensors or pressure sensors associated with a propulsion system (e.g., tracks or wheels), for load and stability monitoring when lifting and moving cargo.
Thus, in accordance with various aspects discussed herein, the cargo transport system provides a forklift-type vehicle that is designed to autonomously carry especially heavy and/or bulky loads across a wide range of terrain. Similar to a traditional forklift, the system is designed to manipulate (pick up, transport, and drop off) palletized cargo, or other cargo that is capable of being moved with a forklift, using traditional forklift tines. In some cases, the vehicle may be configured to transport military aircraft cargo packed on pallets across airfields, but is compatible with numerous other types of cargo and environments as well. In some aspects, the cargo transport system has autonomous functions that include identifying cargo located on dunnage on the ground, properly positioning the vehicle relative to the cargo on the ground, picking up the cargo, autonomously transporting cargo across a wide range of terrain, and delivering it either by cross-decking or placement on the ground. The cargo transport system may also be capable of autonomously driving into cargo aircraft with cargo aboard the vehicle, so that both may be flown to a new destination. The cargo transport system may also perform the reverse of these activities to unload aircraft as well.
In some aspects, a method for cargo transport is provided in which a cargo transport system having a suite of sensors may detect cargo that is to be moved. In some cases, the cargo detection may be based on optical sensors, radar, ultrasonic sensors, rangefinders, LIDAR, or any combinations thereof. In some cases, the cargo may be located on dunnage (e.g., integrated dunnage on a pallet or separate dunnage that is located beneath the cargo or a pallet), and the suite of sensors may detect a location of the dunnage. In some cases, one or more sensors located on one or more forks of the cargo transport system may detect a location of the end of the respective fork relative to the dunnage and cargo, and may provide the information to a controller to allow for proper placement of the forks relative to the cargo. In some cases, cargo characteristics may be preconfigured at the controller, such as dimensions and weight of the cargo, which may be used to determine the proper placement of the forks relative to the cargo. In other cases, sensed characteristics of the cargo and dunnage may be used to determine the proper placement of the forks relative to the cargo. The controller may receive information from the sensor suite, position the forks relative to the cargo, and lift the cargo for transport. With the cargo lifted, the controller may engage a propulsion system to move the cargo transport system to a desired destination for the cargo. In some cases, the controller may use waypoints to move the cargo. In some cases, the controller may use inputs from the sensor suite to identify a transport path for the cargo autonomously (e.g., without preset waypoints). In other cases, the controller may provide information from the sensor suite to a remote location (e.g., remote controller or operator), and may receive commands for movement from the remote location. In some cases, the sensor suite may provide pressure or sensed weight information from one or more locations on the system to the controller, that may be used to adjust a location of the forks, adjust an anti-tip system, adjust one or more suspension characteristics of the propulsion system, trigger a warning to an operator, or any combinations thereof. In some cases, the cargo may be lifted and moved onto a top platform of the cargo transport system, and the cargo transport system and cargo may be transported together.
The foregoing has outlined rather broadly the features and technical advantages of examples according to the disclosure in order that the detailed description that follows may be better understood. Additional features and advantages will be described hereinafter. The conception and specific examples disclosed may be readily utilized as a basis for modifying or designing other structures for carrying out the same purposes of the present disclosure. Such equivalent constructions do not depart from the spirit and scope of the appended claims. Features which are believed to be characteristic of the concepts disclosed herein, both as to their organization and method of operation, together with associated advantages will be better understood from the following description when considered in connection with the accompanying figures. Each of the figures is provided for the purpose of illustration and description only, and not as a definition of the limits of the claims.
This description provides examples, and is not intended to limit the scope, applicability or configuration of the invention. Rather, the ensuing description will provide those skilled in the art with an enabling description for implementing embodiments of the invention. Various changes may be made in the function and arrangement of elements. Thus, various implementations of techniques and components as discussed herein may omit, substitute, or add various procedures or components as appropriate. For instance, aspects and elements described with respect to certain examples may be combined in various other examples. It should also be appreciated that the following systems, devices, and components may individually or collectively be components of a larger system, wherein other procedures may take precedence over or otherwise modify their application.
Various examples disclosed herein provide a cargo transport system that is self-propelled and interacts with one or more control systems. The cargo transport system of various aspects is a self-propelled cargo transport system vehicle (e.g., using an electric motor, internal combustion engine, fuel cell, or any combinations thereof) that is designed to move cargo in various different settings autonomously, semi-autonomously, or teleoperatively (e.g., by remote control). In some cases, the cargo transport system may use hydraulic propulsion with a hybrid electric and gasoline or diesel engine providing power to a hydraulic system. In some cases, the cargo transport system may use an all-electric propulsion system in which one or more electric motors are powered by a rechargeable battery, an on-board generator, or combinations thereof. In some cases, the cargo transport system maintains compatibility with one or more different military cargo transports (e.g., aircraft, ship, vehicle, etc.) such as, for example, current military CH-53 and V-22 aircraft. In other examples, the system may be compatible other aircraft such as military C-17, C-130, or Boeing 747 aircraft, or may be compatible with commercial Boeing 737, 747, 757, or 767 aircraft, Airbus A300 aircraft, or McDonnell Douglas MD-11-type aircraft. Further, the cargo transport system may be compatible with ground-based transports (e.g., cargo trucks, trailers, shipping containers, etc.) or maritime-based transports (e.g., military or commercial maritime vessels). Such systems provide a compact vehicle with an advanced ability to autonomously or semi-autonomously move cargo in congested, dynamic, environments of warehouses, aircraft decks, outdoor settings, landing zones, airports, and the like, with relatively little operator involvement.
As mentioned above, various aspects are described herein with respect to specific mechanical designs compatible with current military cargo transports. However, as will be readily apparent to those of skill in the art, the cargo transport system as discussed herein may be used in numerous other commercial, industrial, and military settings having different cargo handling specifications. In some cases, the cargo transport system utilizes a tracked propulsion system to provide vehicle motion in space constrained environments that may be unimproved to provide off-road capable cargo transport in unimproved environments, in addition to supporting the ability to load/unload cargo aircraft. The system, in some examples, may be used in a variety of situations that require moving heavy loads, such as delivery of cargo to remote locations, for transportation of supplies (water, food, etc.), or for construction to move around heavy building components, to name but a few examples. Further, the cargo transport system may also provide the ability to navigate indoor or outdoor environments, or both. For example, the cargo transport system may provide for autonomous or semi-autonomous movement of cargo through indoor/outdoor thresholds of warehouses, and autonomous or semi-autonomous movement of cargo between disparate warehouse buildings.
To operate autonomously and safely, the cargo transport system of various aspects utilizes a suite of sensors to detect its surroundings to include detection of obstacles (to include people, vehicles, boxes, walls, etc.), perform collision avoidance of obstacles, and determine its location indoors, outdoors, and within a cargo transport. Such sensors may include, for example, positioning sensors, Global Positioning System (GPS) sensors, inertial measurement units (IMUs), proximity detectors, cameras, stereographic imaging sensors, ultrasonic sensors, 3D flash LIDAR systems, LIDAR systems, and 3D Time of Flight (TOF) cameras, to name a few. As used herein, the term dense 3D sensor units may be used to refer to units that may provide data that may be used for 3D sensing around a cargo system, such as stereographic imaging sensors, ultrasonic sensors, 3D flash LIDAR, LIDAR, radar, and cameras coupled with image processing and recognition, for example. Further, aspects discussed herein may also have cargo detection and identification sensors, such as sensors (e.g., optical, radar, and ultrasonic sensors or rangefinders, etc.) that are located at the tip of each fork and/or adjacent to a mast that may be used to detect fork and vehicle location relative to cargo or dunnage.
With reference now to
While various examples illustrated and discussed herein show four tracked propulsion units 310, in some cases, the system may be constructed with only two propulsion units if desired, with more than four propulsion units, with wheels rather than tracks (with some or all of the wheels or tracks powered). Cargo 505 may be palletized cargo such as illustrated in
As shown in
Each propulsion unit 310, in some examples, may include a motor, suspension, a hydraulic system used to propel, raise, and lower the chassis, and a controller to control operation of the unit. In some examples, each propulsion unit may include a suspension spring (e.g., one or more coil springs, leaf springs, torsion springs, or any combinations thereof) for shock absorption and a hydraulic cylinder to provide height manipulation. In some examples, the system uses motor controllers (e.g., CANopen controllers) to communicate between each propulsion unit controller and a master computing system. The motors in some examples may be driven by a fully hydraulic system, or electrically using a battery system (e.g., a 48 V rechargeable battery system) and/or generator (e.g., internal combustion engine, fuel cell, photovoltaic system, etc.). The controller at each propulsion unit may respond to speed and torque commands from the master computing system or master controller and power the drive motors responsive to the commands. The propulsion units 310 may be mounted to the side or the bottom of the chassis using bolts, and each propulsion unit 310 may include an emergency stop button. In some examples, one or more of the propulsion units 310 may include sensors for use in control operations, such as positioning sensors, rotational sensors, speed sensors, encoders, and the like.
At 1215, optionally, the vehicle may identify dunnage associated with the cargo. In some cases, LIDAR and optical inputs may be used to sense dunnage under palletized cargo with sufficient accuracy to enable the vehicle to autonomously pick-up cargo off of the dunnage. In some cases, sensors may be placed at the end of the forklift tines to locate the dunnage underneath pallets (e.g., distance rangefinders, optical sensors, etc.). Further, in some cases, the vehicle may also detect dunnage without cargo with sufficient accuracy to be able to autonomously drop cargo off on the dunnage in unloading operations. Additionally, in cases where a pallet has integrated dunnage (e.g., a standard cargo wooden pallet), or in cases where a container has integrated lift points (e.g., for fork placement at the top, bottom, or sides of the container), the vehicle may detect proper locations for placement of the fork tines. At 1220, the vehicle may determine routing and fork placement to lift cargo. At 1225, the vehicle may be positioned to approach the cargo and pick up the cargo. When dropping off the cargo, the vehicle may autonomously drive to the desired location and lower the cargo or otherwise place the cargo at the desired location. In some cases, such as illustrated in
As discussed herein, a cargo transport system may perform a number of functions that provide for efficient handling and movement of cargo, including sensing cargo with varying shape, size, and positioning to enable autonomous manipulation of cargo. The system may also sense an aircraft (or other cargo drop-off points) with sufficient accuracy to determine whether it is in the cross-decking configuration (for loading and unloading cargo only) or in the ramped position for driving into the aircraft. This ensures that the vehicle does not perform the wrong behavior and damage the aircraft or other cargo moving devices.
Vehicle height—which may be calculated with actuator position sensors, and/or using downward pointing LIDAR systems;
Motor speed—which may be calculated using encoders on the motor and/or freewheel;
Track angle—which may be calculated with data from one or more tilt sensors on the track of each propulsion unit, and/or through the use of encoders on a track bearing;
Vehicle orientation—which may be calculated based on data from tilt sensors, a GPS, and/or an IMU;
Vehicle speed—which may be calculated based on data from a ground speed sensor and/or encoders associated with each propulsion unit. In some examples, GPS data may also provide vehicle speed, and LIDAR also may provide speed data as well;
Vehicle location—which may be calculated based on GPS data and/or any of the other data as discussed above (and/or data from one or more other positioning systems);
Ramp detection of an aircraft or vehicle ramp—which may be calculated based on LIDAR data to detect ramp edges, and/or other imaging components such as cameras or time of flight cameras;
Collision detection—which may be determined based on LIDAR detection data, sonar, or cameras (time of flight cameras may also provide distance data to prevent collisions).
It should be noted that the systems and devices discussed above are intended merely to be examples. It must be stressed that various embodiments may omit, substitute, or add various procedures or components as appropriate. For instance, it should be appreciated that, in alternative embodiments, features described with respect to certain embodiments may be combined in various other embodiments. Different aspects and elements of the embodiments may be combined in a similar manner. Also, it should be emphasized that technology evolves and, thus, many of the elements are exemplary in nature and should not be interpreted to limit the scope of the invention.
Specific details are given in the description to provide a thorough understanding of the embodiments. However, it will be understood by one of ordinary skill in the art that the embodiments may be practiced without these specific details. For example, well-known circuits, structures, and techniques have been shown without unnecessary detail in order to avoid obscuring the embodiments.
Having described several embodiments, it will be recognized by those of skill in the art that various modifications, alternative constructions, and equivalents may be used without departing from the spirit of the invention. For example, the above elements may merely be a component of a larger system, wherein other rules may take precedence over or otherwise modify the application of the invention. Also, a number of steps may be undertaken before, during, or after the above elements are considered. Accordingly, the above description should not be taken as limiting the scope of the invention.
The present Application claims priority to U.S. Provisional Patent Application No. 63/192,926 by Wehner et al., entitled “CARGO TRANSPORT SYSTEM,” filed May 25, 2021 and assigned to the assignee hereof, the entire disclosure of which is incorporated herein by reference.
This invention was made with Government support under SBIR Contract Numbers M67854-19-P-6619 and M67854-19-P-6619 P00001; contracted through the United States Marine Corps. The Government may have certain rights to this invention.
Number | Date | Country | |
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63192926 | May 2021 | US |