502 research outputs found
Novel Design and Analysis of Parallel Robotic Mechanisms
A parallel manipulator has several limbs that connect and actuate an end effector from the base. The design of parallel manipulators usually follows the process of prescribed task, design evaluation, and optimization. This dissertation focuses on interference-free designs of dynamically balanced manipulators and deployable manipulators of various degrees of freedom (DOFs).
1) Dynamic balancing is an approach to reduce shaking loads in motion by including balancing components. The shaking loads could cause noise and vibration. The balancing components may cause link interference and take more actuation energy. The 2-DOF (2-RR)R or 3-DOF (2-RR)R planar manipulator, and 3-DOF 3-RRS spatial manipulator are designed interference-free and with structural adaptive features. The structural adaptions and motion planning are discussed for energy minimization. A balanced 3-DOF (2-RR)R and a balanced 3-DOF 3-RRS could be combined for balanced 6-DOF motion.
2) Deployable feature in design allows a structure to be folded. The research in deployable parallel structures of non-configurable platform is rare. This feature is demanded, for example the outdoor solar tracking stand has non-configurable platform and may need to lie-flat on floor at stormy weathers to protect the structure. The 3-DOF 3-PRS and 3-DOF 3-RPS are re-designed to have deployable feature. The 6-DOF 3-[(2-RR)UU] and 5-DOF PRPU/2-[(2-RR)UU] are designed for deployable feature in higher DOFs. Several novel methods are developed for rapid workspace evaluation, link interference detection and stiffness evaluation.
The above robotic manipulators could be grouped as a robotic system that operates in a green way and works harmoniously with nature
Space Exploration Robotic Systems - Orbital Manipulation Mechanisms
In the future, orbital space robots will assist humans in space by constructing
and maintaining space modules and structures. Robotic manipulators will play
essential roles in orbital operations. This work is devoted to the implemented
designs of two different orbital manipulation mechanical grippers developed
in collaboration with Thales Alenia Space Italy and NASA Jet Propulsion
Laboratory – California Institute of Technology.
The consensus to a study phase for an IXV (Intermediate eXperimental
Vehicle) successor, a preoperational vehicle called SPACE RIDER (Space Rider
Reusable Integrated Demonstrator for European Return), has been recently
enlarged, as approved during last EU Ministerial Council. One of the main
project task consists in developing SPACE RIDER to conduct on orbit servicing
activity with no docking. SPACE RIDER would be provided with a robotic
manipulator system (arm and gripper) able to transfer cargos, such as scientific
payloads, from low Earth orbiting platforms to SPACE RIDER cargo bay.
The platform is a part of a space tug designed to move small satellites and
other payloads from Low Earth Orbit (LEO) to Geosynchronous Equatorial
Orbit (GEO) and viceversa. The assumed housing cargo bay requirements
in terms of volume (<100l) and mass (<50kg) combined with the required
overall arm dimensions (4m length), and mass of the cargo (5-30kg) force
to developing an innovative robotic manipulator with the task-oriented end
effector. It results in a seven degree-of-freedom arm to ensure a high degree
of dexterity and a dedicate end-effector designed to grasp the cargo interface.
The gripper concept developed consists in a multi-finger hand able to lock both
translational and rotational cargo degrees of freedom through an innovative
underactuation strategy to limit its mass and volume. A configuration study
on the cargo handle interface was performed together with some computer
aided design models and multibody analysis of the whole system to prove its feasibility. Finally, the concept of system control architecture, the test report
and the gripper structural analysis were defined.
In order to be able to accurately analyze a sample of Martian soil and to
determine if life was present on the red planet, a lot of mission concepts have
been formulating to reach Mars and to bring back a terrain sample. NASA
JPL has been studying such mission concepts for many years. This concept is
made up of three intermediate mission accomplishments. Mars 2020 is the first
mission envisioned to collect the terrain sample and to seal it in sample tubes.
These sealed sample tubes could be inserted in a spherical envelope named
Orbiting Sample (OS). A Mars Ascent Vehicle (MAV) is the notional rocket
designed to bring this sample off Mars, and a Rendezvous Orbiting Capture
System (ROCS) is the mission conceived to bring this sample back to Earth
through the Earth Entry Vehicle (EEV). MOSTT is the technical work study
to create new concepts able to capture and reorient an OS. This maneuver is
particularly important because we do not know an OS incoming orientation and
we need to be able to capture, to reorient it (2 rotational degrees of freedom),
and to retain an OS (3 translational degrees of freedom and 2 rotational ones).
Planetary protection requirements generate a need to enclose an OS in two shells
and to seal it through a process called Break-The-Chain (BTC). Considering
the EEV would return back to Earth, the tubes orientation and position have
to be known in detail to prevent any possible damage during the Earth hard
landing (acceleration of ∼1300g). Tests and analysis report that in order for the
hermetic seals of the sample tubes to survive the impact, they should be located
above an OS equator. Due to other system uncertainties an OS presents the
potential requirement to be properly reoriented before being inserted inside the
EEV. Planetary protection issues and landing safety are critical mission points
and provide potential strict requirements to MOSTT system configuration. This
task deals with the concept, design, and testbed realization of an innovative
electro-mechanical system to reorient an OS consistent with all the necessary
potential requirements. One of these electro-mechanical systems consists of a
controlled-motorized wiper that explores all an OS surface until it engages with
a pin on an OS surface and brings it to the final home location reorienting an
OS. This mechanism is expected to be robust to the incoming OS orientation
and to reorient it to the desired position using only one degree of freedom
rotational actuator
An Earth Orbiting Satellite Service and Repair Facility
A conceptual design was produced for the Geosynchronous Satellite Servicing Platform (GSSP), an orbital facility capable of repairing and servicing satellites in geosynchronous orbit. The GSSP is a man-tended platform, which consists of a habitation module, operations module, service bay and truss assembly. This design review includes an analysis of life support systems, thermal and power requirements, robotic and automated systems, control methods and navigation, and communications systems. The GSSP will utilize existing technology available at the time of construction, focusing mainly on modifying and integrating existing systems. The entire facility, along with two satellite retrieval vehicles (SRV), will be placed in geosynchronous orbit by the Advanced Launch System. The SRV will be used to ferry satellites to and from the GSSP. Technicians will be transferred from Earth to the GSSP and back in an Apollo-derived Crew Transfer Capsule (CTC). These missions will use advanced telerobotic equipment to inspect and service satellites. Four of these missions are tentatively scheduled per year. At this rate, the GSSP will service over 650 satelites during the projected 25 year lifespan
Earth Observatory Satellite (EOS) system definition study
An executive summary of a study on the Earth Observatory Satellite (EOS) was presented. It was concluded that the overall costs of space systems could be reduced significantly by the development of a modular shuttle compatible standard spacecraft, and the use of that spacecraft with the Shuttle Transportation System. It was also demonstrated that the development of the standard spacecraft is feasible, desirable, and cost effective if applied to a series of missions. The ability to initially retrieve, refurbish, and reuse the spacecraft and its payload, and ultimately to perform in-orbit servicing, would result in significant cost savings. A number of specific conclusions and recommendations were also suggested
Two designs for an orbital transfer vehicle
The Orbital Transfer Vehicle (OTV) and systems were researched in the following areas: avionics, crew systems, electrical power systems, environmental control/life support systems, navigation and orbital maneuvers, propulsion systems, reaction control systems (RCS), servicing systems, and structures
Conceptual design of a manned orbital transfer vehicle
With the advent of the manned space station, man now requires a spacecraft based on the space station with the ability to deploy, recover, and repair satellites quickly and economically. Such a craft would prolong and enhance the life and performance of many satellites. A basic design was developed for an orbital tansfer vehicle (OTV). The basic design criteria are discussed. The design of the OTV and systems were researched in the following areas: avionics, crew systems, electrical power systems, environmental control/life support systems, navigation and orbital maneuvers, propulsion systems, reaction control systems (RCS), servicing systems, and structures. The basic concepts in each of the areas are summarized
Pointing and control system enabling technology for future automated space missions
Future automated space missions present challenging opportunities in the pointing-and-control technology disciplines. The enabling pointing-and-control system technologies for missions from 1985 to the year 2000 were identified and assessed. A generic mission set including Earth orbiter, planetary, and other missions which predominantly drive the pointing-and-control requirements was selected for detailed evaluation. Technology candidates identified were prioritized as planning options for future NASA-OAST advanced development programs. The primary technology thrusts in each candidate program were cited, and advanced development programs in pointing-and-control were recommended for the FY 80 to FY 87 period, based on these technology thrusts
NASA Automated Rendezvous and Capture Review. A compilation of the abstracts
This document presents a compilation of abstracts of papers solicited for presentation at the NASA Automated Rendezvous and Capture Review held in Williamsburg, VA on November 19-21, 1991. Due to limitations on time and other considerations, not all abstracts could be presented during the review. The organizing committee determined however, that all abstracts merited availability to all participants and represented data and information reflecting state-of-the-art of this technology which should be captured in one document for future use and reference. The organizing committee appreciates the interest shown in the review and the response by the authors in submitting these abstracts
Design/cost tradeoff studies. Earth Observatory Satellite system definition study (EOS)
The results of design/cost tradeoff studies conducted during the Earth Observatory Satellite system definition studies are presented. The studies are concerned with the definition of a basic modular spacecraft capable of supporting a variety of operational and/or research and development missions, with the deployment either by conventional launch vehicles or by means of the space shuttle. The three levels investigated during the study are: (1) subsystem tradeoffs, (2) spacecraft tradeoffs, and (3) system tradeoffs. The range of requirements which the modular concept must span is discussed. The mechanical, thermal, power, data and electromagnetic compatibility aspects of modularity are analyzed. Other data are provided for the observatory design concept, the payloads, integration and test, the ground support equipment, and ground data management systems
Orbital assembly and maintenance study
The requirements, conceptual design, tradeoffs, procedures, and techniques for orbital assembly of the support structure of the microwave power transmission system and the radio astronomy telescope are described. Thermal and stress analyses, packaging, alignment, and subsystems requirements are included along with manned vs. automated and transportation tradeoffs. Technical and operational concepts for the manned and automated maintenance of satellites were investigated and further developed results are presented
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