A need exists for robotic systems and methods that more effectively operate an aperture closure between an aperture open state and an aperture closed state. Numerous embodiments of the present disclosure address the aforementioned limitations.
An exemplary force application system for placement on and removal from an actuable latch with a robotic arm includes a driving pad configured for attachment to the actuable latch, a force application mechanism configured to increase an input force to an amplified output force that is applied by the force application mechanism to the driving pad, and a frame for engagement by the robotic arm.
An exemplary method includes attaching, with a robotic arm, a force application tool to an actuable latch on a closure, where the force application tool includes a driving pad attached to the actuable latch, a force application mechanism operable to increase an input force to an amplified output force applied to the driving pad, applying the input force to the force application mechanism, moving the actuable latch to an unlocked position in response to the amplified output force, and moving the closure with the robotic arm to open a pathway.
An exemplary method of operating an aperture closure between an aperture open state and an aperture closed state includes (1) using a system of the present disclosure; (2) actuating the at least one gripper of the robotic arm to place the force amplifier on the latch of the closure; and (3) actuating the robotic arm to actuate the force amplifier to amplify a force, where the amplified force moves the latch and thereby facilitates the operating of the aperture closure of the enclosure between an aperture open state and an aperture closed state.
It is to be understood that both the foregoing general description and the following detailed description are illustrative and explanatory, and are not restrictive of the subject matter, as claimed. In this application, the use of the singular includes the plural, the word “a” or “an” means “at least one”, and the use of “or” means “and/or”, unless specifically stated otherwise. Furthermore, the use of the term “including”, as well as other forms, such as “includes” and “included”, is not limiting. Also, terms such as “element” or “component” encompass both elements or components comprising one unit and elements or components that include more than one unit unless specifically stated otherwise.
The section headings used herein are for organizational purposes and are not to be construed as limiting the subject matter described. All documents, or portions of documents, cited in this application, including, but not limited to, patents, patent applications, articles, books, and treatises, are hereby expressly incorporated herein by reference in their entirety for any purpose. In the event that one or more of the incorporated literature and similar materials define a term in a manner that contradicts the definition of that term in this application, this application controls.
Robotic systems have found applications in opening and closing numerous closures, such as doors. For instance, robotic systems that include unmanned ground vehicles (UGVs) and a robotic arm have been utilized to open and close doors in numerous places, such as factories.
However, robotic systems have limited capacities in opening and closing more complex closures due to their limited operational range, strength, and leverage. In particular, numerous factors affect a robotic system's ability to open and close closures. Such factors include: the environmental and physical conditions that affect the closure's opening and closing mechanism; temperature and pressure conditions that can cause a closure to expand, thereby leading to stronger applied pulling or pushing forces; and the complexity of the closure, including its size and functionality.
For instance, doors vary in design and function depending on their application. Some doors are mounted on hinges to be swung open while others are mounted on sliding rails. More sophisticated doors, such as revolving doors and airlock doors, take advantage of both sliding and pivoting mechanisms as well as multiple locking systems. While some doors utilize a simple mechanism of pivoting a handle, others may require multi-step processes. Additionally, many doors, such as pressurized doors and/or watertight ship doors, may be too tight for opening by a lightweight robotic system.
Many studies have focused on improving robotic systems in order to open different types of doors. However, such studies have primarily focused on investigating how to use robots to open home doors, which are lightweight and have simple structures. Opening a door with a knob lock requires appropriate end effector torque output to rotate the knob, which is a considerable simple task that only involves one degree of freedom (DOF) motion. Focus is also placed on torque control and finger pose control in opening a door with a knob lock.
Numerous studies have also focused on inverse kinematics for using robotic systems to open doors. In some cases, a robotic arm needs help from a UGV to open a door, and a UGV can provide an extra pull or push force to move the door. When opening the door, carrying out a curved movement sometimes requires simultaneous cooperation between the robotic arm and the UGV.
However, robotic systems with UGVs may not have sufficient leverage, strength, and torque output to open many enclosures. For instance, in order to open a watertight ship door, the first challenge is to generate enough torque to rotate a wheel to unlock the door. However, a standard robotic arm on a UGV would be unable to address the aforementioned challenge.
Studies have aimed to address the aforementioned challenges by focusing on modified robotic arm grippers in order to more effectively open and close doors. See, e.g., S. Kobayashi et al., “Development of a door opening system on rescue robot for search “umrs-2007”,” in Proc. of 2008 SICE Annual Conference. IEEE, 2008, pp. 2062-2065. However, such modified grippers affect the versatility of robotic arms for use in alternative applications. Furthermore, such modified grippers remain unable to open and close more complex enclosures, such as watertight ship doors.
As such, a need exists for robotic systems and methods that more effectively operate an aperture closure between an aperture open state and an aperture closed state. Numerous embodiments of the present disclosure address the aforementioned limitations.
An example of a system of the present disclosure is illustrated in
Force amplifier 18 is separate unit from robotic arm 12 and is functionally engageable with robotic arm 12, and selectively connectable by robotic arm 12 to actuatable latch 20 of an aperture closure 46. Force amplifier 18 is operational to be attached to latch 20 by robotic arm 12 and actuated by the robotic arm to amplify the input force 42 to an increased output force 44 to move latch 20 to an unlocked position and thereby facilitate operating closure 46 between an aperture open state and an aperture closed state. In an exemplary embodiment, force amplifier 18 is a tool that mechanically amplifies the input force.
In an embodiment, system 10 includes a support base 22 for supporting robotic arm 12 and force amplifier 18. In the illustration shown in
As illustrated in
Force amplifier 18 includes a driving pad or frame 38 that is connectable to latch 20. Pad 38 is rotationally stationary with ratchet wheel 28 to transfer the rotational output force to latch 20. Pad 38 may include teeth 48 (
An exemplary method, illustrated in
As will be understood by those with skill in the art with benefit of this disclosure, the system may be used to close and secure an aperture closure as well. For example, the robotic arm may be operated to move (swing or slide) the closure into a closed position blocking the aperture. The robotic arm may be operated to engage the force amplifier with a latch of the closure, for example a rotational latch. The robotic arm may be actuated to operate the latch from an unlatched position to a latched position for example by applying an arm force to the force amplifier which amplifies the arm force to an amplified force that is applied to the latch.
Robotic arms generally refer to mechanical devices with motor-powered joints that are able to utilize the motor-powered joints to move in desired directions. For instance, a robotic system can utilize robotic arms to operate exterior facilities and tools for a specific task. The methods and systems of the present disclosure can utilize various types of robotic arms.
For instance, in some embodiments, the robotic arms of the present disclosure include a gripper. In some embodiments, the gripper is operational to place a force amplifier on a latch and operate the force amplifier. In some embodiments, the gripper includes one or more grip fingers. In some embodiments, the gripper includes at least three grip fingers.
The robotic arms of the present disclosure can have various functions. For instance, in some embodiments, at least one gripper of a robotic arm may be utilized in accordance with the methods of the present disclosure to place a force amplifier on a latch of a closure. In some embodiments, the robotic arm may then be utilized to actuate the force amplifier to amplify a force that moves the latch and thereby facilitates the operating of the closure between an aperture open state and an aperture closed state.
In some embodiments, the methods of the present disclosure also include actuating the robotic arm of the system to remove a force amplifier from a latch of a closure. In some embodiments, the removal occurs after the operating of the closure between an aperture open state and an aperture closed state.
In some embodiments, the methods of the present disclosure include actuating the robotic arm to move the closure to open the enclosure. In some embodiments, the methods of the present disclosure also include moving the robotic system through the closure aperture.
Force amplifiers generally refer to devices that are operational to amplify a force. In some embodiments, the force to be amplified includes torque. In some embodiments, the force amplifier may be operational to amplify the torque.
In some embodiments, the force amplifier helps overcome a mechanical power output insufficiency of a robotic arm. In some embodiments, the force amplifier is operational to utilize a small force to generate a large torque.
The methods and systems of the present disclosure can utilize various types of force amplifiers. In some embodiments, the force amplifiers of the present disclosure represent system components that are separate from robotic arms. In some embodiments, the force amplifiers of the present disclosure are detachable from robotic arms. In some embodiments, the force amplifiers of the present disclosure are not embedded with robotic arms. In some embodiments, the force amplifiers of the present disclosure represent system components that function independently from robotic arms.
Due to being separate from robotic arms, the force amplifiers of the present disclosure can be utilized in accordance with the methods of the present disclosure without a need to modify existing robotic arms with force generation components. As such, the force amplifiers of the present disclosure can be operated by standard robotic arms that lack force generation components.
In some embodiments, the force amplifiers of the present disclosure are compact. For instance, in some embodiments, the force amplifiers of the present disclosure are in the form of a handheld device.
In some embodiments, the force amplifiers of the present disclosure are operational to move a latch in incremental turns. In some embodiments, the force amplifiers of the present disclosure are operational to divide a circular motion into multiple repetitive linear motions. In some embodiments, the force amplifiers of the present disclosure are operational to rotate a latch about a rotational axis.
In addition to a robotic arm and a force amplifier, the systems of the present disclosure may include additional components. For instance, in some embodiments, the systems of the present disclosure also include a support base that is operational for supporting the robotic arm and the force amplifier.
In some embodiments, the support base is operational for engaging a resisting surface in operational proximity to an enclosure. In some embodiments, the engagement of the support base with the resisting surface supports a reaction force in opposition to an amplified actuating force. In some embodiments, the reaction force further facilitates movement of the system at least one of prior to, during, subsequent to, and combinations thereof, within the operational proximity to the enclosure.
The support bases of the present disclosure may be in various forms. For instance, in some embodiments, the support bases of the present disclosure are in the form of a mobile platform. In some embodiments, the mobile platform is in the form of a remotely operated vehicle (ROV). In some embodiments, the remotely operated vehicle is in the form of an unmanned ground vehicle (UGV). In some embodiments, the remotely operated vehicle is in the form of an underwater vehicle.
The support bases of the present disclosure may have various components. For instance, in some embodiments, the support bases of the present disclosure also include one or more hydraulic lifts operational to adjust a height of the support base. In some embodiments, the support bases of the present disclosure include an electrical system for receiving remote control signals.
In some embodiments, the systems of the present disclosure may also include a user control interface. In some embodiments, the user control interface is operational to allow a user to remotely control the robotic arm.
Closures generally refer to a barrier member for closing an aperture and that is operable to be in an open state and a closed state. In some embodiments, the closures separate two spaces for the purpose of safety. In some embodiments, the closures require an operation to switch from an open state to a closed state.
For instance, in some embodiments, the closure includes a hatch. In some embodiments, the closure includes a valve. In some embodiments, the closure includes a door. In some embodiments, the closure is a pressurized barrier. In some embodiments, the closure is a watertight barrier. In some embodiments, the watertight barrier is a component of an underwater vessel, such as a submarine.
The closures of the present disclosure may also include various types of latches. For instance, in some embodiments, the latch is a rotatable wheel. In some embodiments, the latch comprises rotatable spokes. In some embodiments, the latch is a doorknob. In some embodiments, the latch includes a valve lever.
The systems and methods of the present disclosure may operate closures in various manners. For instance, in some embodiments where the closure is in an aperture open state, the methods and systems of the present disclosure may be utilized to place the closure in a closed state. In some embodiments where a closure is in an aperture closed state, the systems and methods of the present disclosure may be utilized to place the closure in an open state.
Recent offshore drilling activities have dramatically bloomed oil and gas production. Due to some extreme weathers, such as hurricanes, offshore oil platforms should be able to work under an unmanned operation mode. Applicant describes the development of a robotic system with an unmanned ground vehicle (UGV) component which can pick up a force amplifier tool, open a watertight ship door, and transition through the door with a remote control.
Given the watertight door's unique structure, Applicant designed door opening (unlocking) tools and a mobile platform to help the robotic arm complete the work. Applicant verified the possibility of the deploying the robotic system in the offshore oil industry and enhancing its adaptability.
After a door is opened, the second challenge is to transition through the door. The robotic system had a design requirement of crossing over a 9 cm high door threshold and turning within a compact space. The robotic system demonstrated a strong ability to overcome obstacles and achieve skid turning. With a wireless control system and high torque motor, the robotic system could carry the robotic arm and move freely. In opening the door, the robotic arm was first used to pick up and install the force application tool on to a door latch. Then the arm's orientation was manipulated to apply an input force to the force application (e.g., force amplification) tool, after which the tool was removed from the door latch. During the process, the robotic system was continuously maneuvered to help the robotic arm reach the best position.
The UGV component of the robotic system also provided extra help to drag and push when the robotic arm was performing another function. In the end, the UGV with the attached robotic arm made its way across the door threshold. This combined robot system was able to demonstrate the ability to open a quick-action watertight door without any human intervention.
With reference to
With the dog lock. the watertight door squeezes the rubber gasket and insulates the inside space from outside. The door's dimension is 0.8 m×1.6 m, with a mass of 400 kg. The torque needed to turn the wheel is 33 Nm, which was measured by a valve wrench and force gauge.
The frame has a 9 cm thread. To open the door, the wheel needed to be turned counterclockwise from the outside. As long as the dog and wedge were untouched, the door popped out slightly due to the rubber gasket's elasticity, allowing the door to be pulled open easier. The majority of torque is needed to overcome the friction between dog and wedge. Friction is strengthened from the elastic force as a consequence when squeezing the rubber gasket.
A major challenge to opening a watertight door with the robotic arm is the force limitation. The door's wheel was designed to enlarge the distance so that humans can operate using both hands with less force. However, the robotic arm's wrist and finger were driven by a separate actuator. The robotic arm's finger's force was insufficient to open the door.
Additionally, requiring the robotic arm to make a circular motion by manually controlling it is a challenge. Increasing the distance between the latch's rotational axis and the robotic arm was a key point to overcome force limitation. Devices were invented to work as a wrench to connect the door's wheel latch and the robotic arm. These force application tools can be stably attached to the wheel handle and can be rotated. Additionally, the devices enlarge the distance between the robotic arm and the wheel's rotating axis. Further, the devices are light and easy for the robotic arm to grasp.
In addition to the force limitation on the robotic arm, the door threshold presents challenges for a mobile platform. The robot in this trial needed to cross a 9 cm door threshold. Thus, the robotic system's structure has to be intelligently designed and qualified with sufficient power. Accordingly, the overall strategy included designing a door opening tool and a robotic system with a UGV.
A KINOVA Ultra lightweight robotic arm was nominated to handle the door opening. The robotic arm has 4 degrees of freedom (DOFs) and a three-finger gripper. The twist and finger has very limited load capacity. The first joint and second joint of the robotic arm is powered by a KA-75 motor, which has 30.5 Nm maximum torque. The robotic arm's total weight is 4.2 kg, and its maximum reach range is 0.75 m.
A requirement of the UGV was to cross over a 9 cm high obstacle carrying the robotic arm. The NASA's six wheeled rover concept was adopted to the original design using suspensions for the front wheels. Each tire was driven by a 30-rpm gear motor, which could output a maximum torque of 0.39 Nm. The mobile platform can climb over up to 0.15 m high obstacles with its 0.3 m diameter all-terrain tire and rover suspension. With parallel sets of wheels, the mobile platform can achieve skid steering by oppositely controlling the wheels on both sides.
The skid steering was an important ability to guarantee the mobile platform's maneuverability in a compact area. The ability also extends the robotic arm's reachability. The total weight of the mobile platform with a robotic arm was 7.2 kg.
The robotic arm was installed on the top of the platform (
Two different door opening tools were designed and fabricated to operate the door's latch (wheel). Both tools were equipped with a turning or driving pad 38. The exemplary turning pad has three teeth 48 that can be inserted between spokes 21 in the door's wheel 20, and the tool turns the wheel by pushing the spokes. The turning pad also provides a feasible base for the torque amplifying mechanism.
One force application tool uses gears, illustrated for example in
With reference to
Three gear sets were arranged with increasing diameter pitch to make sure the motion from a thin shaft could be transmitted smoothly to a large driving pad. Among these gears, the largest 6-64 gear was made of acrylic and cut by a Roland MDX540 milling machine. The input 24-15 gear was made of copper and purchased online. The other gears were 3D printed in PLA material by an Ultimaker 3 printer. All of the gears were designed by the Toolbox in SOLIDWORKS Education 2019.
In addition to the gear, a 20-mm aluminum frame 90 was built with linear rails bolted with aluminum connectors. Other frame parts were 3D printed by PLA material. A pair of IMT 6 suction cups 92 with a maximum 30 kg load per cup was installed at both ends of the frame to help secure the tool. Frame 90 may be used by the robotic arm to hold the force application tool place it on and remove it from the latch.
An exemplary wrench or ratchet and pawl type force amplifier tool is described with reference to
The first point may be addressed by adding magnets 94 (
Given that the latch wheel's effective turning angle is ranged from 15 to 45 degrees due to the clearance, the pawl mechanism can divide that large circular motion into multiple linear repetitions around a certain position. After a short linear motion drives the wheel to turn counterclockwise, the linear motion is reversed, and the spring can drag the pawl to the latter ratchet rim. Thus, the linear motion can turn the wheel counterclockwise again.
In
To further simplify the tool design, an alternative approach that directly used the robotic arm to push the wrench tool was implemented (
The whole door opening process includes 3 steps. The first step is to pick up and install the force amplifier tool. The robotic arm needs to pick up and firmly hold the force application tool. The challenge in this step is that the driving pad needs to be perpendicular to the wrist for easier installation. A large handle 66 (
The second step is to unlock the door and remove the tool. The robotic arm lifts the rod with the wrist. After unlocking, the gripper may grasp the tool's handle to detach it from the wheel handle.
The third step is to open the door and drive through. The gripper may grasp a small grip handle on the door, and the UGV gradually move back to pull the door and open the doorway. The UGV can pass through doorway and over the threshold.
Among these steps, unlocking the door posed the biggest challenge. The robot required a proper angle to exert force controlled. The robotic arm's posture with the wrench tool's position is described with reference to
The force applied on rod satisfied the relationship described by Equation 1.
M
0
=F
0
R
0
F
0
R
0 sec2(α0)=F1L0 Equation 1
In Equation 1, the rod's turning angle was ignored since it only swept within a very small range (
The force and moment on the first link of the robotic arm satisfied the condition illustrated in
M
1
−F
1
L
1 cos(α1)+½G1L1 cos(α1)≥0 Equation 2
In Equation 2, −F1 was considered as reaction force from rod to the first link. The α1 needed to be small in order to keep the best contact between the robotic arm and rod. The robotic arm had the best lift efficiency when α1=0, and Equation 2 was still held. Thus, the actuator in joint 1 was qualified for the task.
For the second link, a similar condition in Equation 3 was denoted.
F
2
=G
1
−F
1
M
2
−F
2
L
2 cos(α1)+½G2L2 cos(α2)≥0 Equation 3
The second link was longer than the first link, and so the α2 should be bounded to guarantee that the actuator in the second joint does not exceed the limit. Thus, the second link was denoted with Equation 4.
This result indicated the effective working space of the robotic arm. The result also proved that the robotic arm could generate enough lift force to unlock the door within a certain angle range.
The overall demonstration of the robotic system is described in
Without further elaboration, it is believed that one skilled in the art can, using the description herein, utilize the present disclosure to its fullest extent. The embodiments described herein are to be construed as illustrative and not as constraining the remainder of the disclosure in any way whatsoever. While the embodiments have been shown and described, many variations and modifications thereof can be made by one skilled in the art without departing from the spirit and teachings of the invention. Accordingly, the scope of protection is not limited by the description set out above but is only limited by the claims, including all equivalents of the subject matter of the claims. The disclosures of all patents, patent applications, and publications cited herein are hereby incorporated herein by reference, to the extent that they provide procedural or other details consistent with and supplementary to those set forth herein.
The present application claims the benefit of U.S. Provisional Patent Application No. 63/166,090, filed on Mar. 25, 2021. The entirety of the aforementioned application is incorporated herein by reference.
This invention was made with government support under Grant No. 582-15-57593 awarded by the Texas Commission on Environmental Quality Subsea Systems Institute. The government has certain rights in the invention.
Filing Document | Filing Date | Country | Kind |
---|---|---|---|
PCT/US2022/019720 | 3/10/2022 | WO |
Number | Date | Country | |
---|---|---|---|
63166090 | Mar 2021 | US |