Your search keyword '"Khanh V. Trinh"' showing total 21 results

1. From Natural Language Requirements to the Verification of Programmable Logic Controllers: Integrating FRET into PLCverif.

Author

Zsófia ádám, Ignacio D. Lopez-Miguel, Anastasia Mavridou, Thomas Pressburger, Marcin Bes, Enrique Blanco Viñuela, Andreas Katis, Jean-Charles Tournier, Khanh V. Trinh, and Borja Fernández Adiego

Published

2023

2. Automated Verification of Programmable Logic Controller Programs Against Structured Natural Language Requirements

Author

Zsófia Ádám, Ignacio D Lopez-Miguel, Anastasia Mavridou, Thomas Pressburger, Martin Bes, Enrique Blanco Vinuela, Andreas Katis, Jean-Charles Tournier, Khanh V Trinh, and Borja Fernandez Adiego

Subjects

Computer Programming and Software

Abstract

PLCverif is an actively developed project at CERN, enabling the formal verification of Programmable Logic Controller (PLC) programs in critical systems. In this paper, we present our work on improving the formal requirements specification experience in PLCverif through the use of natural language. To this end, we integrate NASA’s FRET, a formal requirement elicitation and authoring tool, into PLCverif. FRET is used to specify formal requirements in structured natural language, which automatically translates into temporal logic formulae. FRET’s output is then directly used by PLCverif for verification purposes. We discuss practical challenges that PLCverif users face when authoring requirements and the FRET features that help alleviate these problems. We present the new requirement formalization workflow and report our experience using it on two critical CERN case studies.

Published

2023

3. Flight Control with Optimal Control Allocation Incorporating Structural Load Feedback.

Author

Susan A. Frost, Marc Bodson, John J. Burken, Christine V. Jutte, Brian R. Taylor, and Khanh V. Trinh

Published

2015

4. Elastic Shape Morphing of Ultralight Structures by Programmable Assembly

Author

Martynas Lendraitis, Christine Gregg, Joseph H. Kim, Greenfield Trinh, Kenneth C. Cheung, Sean Shan-Min Swei, Khanh V Trinh, Olivia Formoso, Benjamin Jenett, Nick B. Cramer, and Daniel Cellucci

Subjects

Materials science, Mechanical engineering, 02 engineering and technology, 01 natural sciences, Article, Ultralight material, 0103 physical sciences, medicine, General Materials Science, Electrical and Electronic Engineering, Civil and Structural Engineering, Wind tunnel, 010302 applied physics, business.industry, Stiffness, Modular design, Conformable matrix, 021001 nanoscience & nanotechnology, Condensed Matter Physics, Aeroelasticity, Atomic and Molecular Physics, and Optics, Morphing, Mechanics of Materials, Signal Processing, Deformation (engineering), medicine.symptom, 0210 nano-technology, business

Abstract

Ultralight materials present an opportunity to dramatically increase the efficiency of load-bearing aerostructures. To date, however, these ultralight materials have generally been confined to the laboratory bench-top, due to dimensional constraints of the manufacturing processes. We show a programmable material system applied as a large-scale, ultralight, and conformable aeroelastic structure. The use of a modular, lattice-based, ultralight material results in stiffness typical of an elastomer (2.6 MPa) at a mass density typical of an aerogel (5.6 [Formula: see text]). This, combined with a building block based manufacturing and configuration strategy, enables the rapid realization of new adaptive structures and mechanisms. The heterogeneous design with programmable anisotropy allows for enhanced elastic and global shape deformation in response to external loading, making it useful for tuned fluid-structure interaction. We demonstrate an example application experiment using two building block types for the primary structure of a 4.27m wingspan aircraft, where we spatially program elastic shape morphing to increase aerodynamic efficiency and improve roll control authority, demonstrated with full-scale wind tunnel testing.

Published

2021

5. Flight Control with Optimal Control Allocation Incorporating Structural Load Feedback

Author

Brian R. Taylor, Christine V. Jutte, John J. Burken, Khanh V. Trinh, Susan A. Frost, and Marc Bodson

Subjects

Engineering, business.industry, Feed forward, Aerospace Engineering, ComputerApplications_COMPUTERSINOTHERSYSTEMS, Control engineering, Flight control surfaces, Avionics, Optimal control, Computer Science Applications, Structural load, Flight dynamics, Control theory, Control system, Electrical and Electronic Engineering, business, Change control

Abstract

Advances in sensors and avionics computation power suggest real-time structural load measurements could be used in flight control systems for improved safety and performance. A conventional transport flight control system determines the moments necessary to meet the pilot’s command while rejecting disturbances and maintaining stability of the aircraft. Control allocation is the problem of converting these desired moments into control effector commands. In this paper, a framework is proposed to incorporate real-time structural load feedback and structural load constraints in the control allocator. Constrained optimal control allocation can be used to achieve desired moments without exceeding specified limits on monitored load points. Furthermore, certain criteria can be minimized, such as loads on certain parts of the aircraft. Flight safety issues can be addressed by using system health monitoring information to change control allocation constraints during flight. The framework to incorporate structural l...

Published

2015

6. Optimization for Load Alleviation of Truss-Braced Wing Aircraft With Variable Camber Continuous Trailing Edge Flap

Author

Eric B. Ting, Nhan T. Nguyen, Khanh V. Trinh, and Sonia Lebofsky

Subjects

Variable (computer science), Wing, business.industry, Computer science, Camber (ship), Trailing edge, Truss, Structural engineering, business

Published

2015

7. Aeroelastic Modeling and Drag Optimization of Flexible Wing Aircraft with Variable Camber Continuous Trailing Edge Flap

Author

Sonia Lebofsky, Eric B. Ting, Nhan T. Nguyen, and Khanh V. Trinh

Subjects

Wing, Drag, Computer science, business.industry, Wing twist, Camber (aerodynamics), Constrained optimization, Trailing edge, Aerodynamics, Aerospace engineering, business, Aeroelasticity, ComputingMethodologies_COMPUTERGRAPHICS

Abstract

This paper contains the development and optimization of an aeroelastic model of a flexible wing aircraft. The aircraft model is based on the NASA Generic Transport Model (GTM), with the wing structures of the model incorporating a novel aerodynamic control surface known as a Variable Camber Continuous Trailing Edge Flap (VCCTEF). The aeroelastic structural framework developed for the GTM model is implemented using finiteelement analysis. Aerodynamic modeling conducted using the vortex-lattice method is coupled with the structural framework through a geometry generation tool to form the static aeroelastic model. Constrained optimization using a surrogate function and sequence of approximations (SOA) optimization is conducted to tailor the wing twist for the aircraft’s design cruise flight condition. Further optimization is then conducted on the VCCTEF settings for drag reduction at off-design cruise flight conditions. The results demonstrate the potential of utilizing the novel control surface on aircraft for wing shaping control to improve aerodynamic efficiency.

Published

2014

8. Flight Dynamic Modeling and Stability Analysis of Flexible Wing Generic Transport Aircraft

Author

Daniel Nguyen, Eric B. Ting, Khanh V. Trinh, and Nhan T. Nguyen

Subjects

Reduced frequency, Aerodynamic force, Wing, Computer science, Camber (aerodynamics), Deflection (engineering), Control theory, business.industry, Trailing edge, Aerodynamics, Aerospace engineering, Aeroelasticity, business

Abstract

This paper presents a coupled vortex-lattice flight dynamic model with an aeroelastic finite-element model to predict dynamic characteristics of a flexible wing transport aircraft. The aircraft model is based on NASA Generic Transport Model (GTM) with representative mass and stiffness properties to achieve a wing tip deflection about twice that of a conventional transport aircraft (10% versus 5%). This flexible wing transport aircraft is referred to as an Elastically Shaped Aircraft Concept (ESAC) which is equipped with a new aerodynamic control surface for active wing shaping control for drag reduction. This aerodynamic surface is referred to as a Variable Camber Continuous Trailing Edge Flap (VCCTEF). A vortex-lattice aerodynamic model of the ESAC is developed for coupling with the aeroelastic finite-element model via an automated geometry generation tool. This coupled model is used to compute static and dynamic aeroelastic solutions. The deflection information from the finite-element model and the vortex-lattice model is used to compute unsteady contributions to the aerodynamic force and moment coefficients which are used for the flight dynamic model. Two different methods for a state-space formulation for coupled aeroelastic-flight dynamics are considered to address the dependency on the reduced frequency parameter. The first method is to formulate the equations of motion which are dependent on the exact Theodorsen’s unsteady aerodynamic model. The second method is to approximate the Theodorsen’s complex-valued function as a second-order transfer function proposed by R. T. Jones. This approximation eliminates the reduced frequency dependency, but also results into two additional states for each of the structural deflection state. Both methods will be described in the study. A vehicle stability analysis will be conducted to assess the effect of aeroelasticity on rigid-body aircraft modes.

Published

2014

9. Static Aeroelastic and Longitudinal Trim Model of Flexible Wing Aircraft Using Finite-Element Vortex-Lattice Coupled Solution

Author

Nhan T. Nguyen, Eric B. Ting, and Khanh V. Trinh

Subjects

Engineering, Wing, ComputingMethodologies_SIMULATIONANDMODELING, Structural mechanics, business.industry, Longitudinal static stability, Stiffness, Aerodynamics, Structural engineering, Aeroelasticity, Finite element method, Trim, medicine, Aerospace engineering, medicine.symptom, business, ComputingMethodologies_COMPUTERGRAPHICS

Abstract

This paper presents a static aeroelastic model and longitudinal trim model for the analysis of a flexible wing transport aircraft. The static aeroelastic model is built using a structural model based on finite-element modeling and coupled to an aerodynamic model that uses vortex-lattice solution. An automatic geometry generation tool is used to close the loop between the structural and aerodynamic models. The aeroelastic model is extended for the development of a three degree-of-freedom longitudinal trim model for an aircraft with flexible wings. The resulting flexible aircraft longitudinal trim model is used to simultaneously compute the static aeroelastic shape for the aircraft model and the longitudinal state inputs to maintain an aircraft trim state. The framework is applied to an aircraft model based on the NASA Generic Transport Model (GTM) with wing structures allowed to flexibly deformed referred to as the Elastically Shaped Aircraft Concept (ESAC). The ESAC wing mass and stiffness properties are based on a baseline "stiff" values representative of current generation transport aircraft.

Published

2014

10. Flutter Analysis of Mission-Adaptive Wing with Variable Camber Continuous Trailing Edge Flap

Author

Nhan T. Nguyen, Daniel Nguyen, Khanh V. Trinh, and Eric B. Ting

Subjects

Aerodynamic force, Wing, Computer science, business.industry, Camber (aerodynamics), Trailing edge, Flutter, Aerodynamics, Structural engineering, Flight control surfaces, business, Aeroelasticity

Abstract

This paper presents an aeroelastic method for predicting flutter characteristics of a flexible wing transport aircraft. The aircraft model is based on NASA Generic Transport Model (GTM) with representative mass and stiffness properties to achieve a wing tip deflection about twice that of a conventional transport aircraft (10% versus 5%). This flexible wing transport aircraft is referred to as an Elastically Shaped Aircraft Concept (ESAC) which is equipped with a new type of aerodynamic control surfaces for active wing shaping control for drag reduction. This aerodynamic surface is referred to as a Variable Camber Continuous Trailing Edge Flap (VCCTEF). A vortex-lattice aerodynamic model is developed for coupling with the aeroelastic finite-element model via an automated geometry generation tool. This coupled model is used to compute static aeroelastic deflections and flutter solutions. The deflection information from the finite-element model is used to compute unsteady aerodynamic contributions to the aerodynamic force and moment coefficients. A flutter analysis is conducted to estimate the flutter boundary of the GTM and ESAC. A sensitivity analysis is also studied to examine the effect of relaxed stiffness on the flutter boundary.

Published

2014

11. A Preliminary Study for Optimal Longitudinal-Mode Flight Control through Distributed Aeroelastic Shaping

Author

Eric B. Ting, Corey A. Ippolito, Khanh V. Trinh, and Nhan T. Nguyen

Subjects

Vehicle dynamics, Wing twist, Computer science, Control theory, Drag, Airframe, Trailing edge, Control engineering, Aerodynamics, Aeroelasticity, ComputingMethodologies_COMPUTERGRAPHICS

Abstract

The emergence of advanced lightweight materials is resulting in a new generation of lighter, flexible, more-efficient airframes that are enabling concepts for active aeroelastic wing-shape control to achieve greater flight efficiency and increased safety margins. These elastically shaped aircraft concepts require non-traditional methods for large-scale multiobjective flight control that simultaneously seek to gain aerodynamic efficiency in terms of drag reduction while performing traditional command-tracking tasks as part of a complete guidance and navigation solution. This paper presents results from a preliminary study of a notional multi-objective control law for an aeroelastic flexible-wing aircraft controlled through distributed continuous leading and trailing edge control surface actuators. This preliminary study develops and analyzes a multi-objective control law derived from optimal linear quadratic methods on a longitudinal vehicle dynamics model with coupled aeroelastic dynamics. The controller tracks commanded attack-angle while minimizing drag and controlling wing twist and bend. This paper presents an overview of the elastic aircraft concept, outlines the coupled vehicle model, presents the preliminary control law formulation and implementation, presents results from simulation, provides analysis, and concludes by identifying possible future areas for research.

Published

2014

12. Static Aeroelastic Scaling and Analysis of a Sub-Scale Flexible Wing Wind Tunnel Model

Author

Sonia Lebofsky, Khanh V. Trinh, Nhan T. Nguyen, and Eric B. Ting

Subjects

Wing, Scale (ratio), business.industry, Wing configuration, Stiffness, Structural engineering, Condensed Matter::Mesoscopic Systems and Quantum Hall Effect, Aeroelasticity, Deflection (engineering), Physics::Space Physics, medicine, Astrophysics::Solar and Stellar Astrophysics, medicine.symptom, business, Scaling, Physics::Atmospheric and Oceanic Physics, Geology, Wind tunnel

Abstract

This paper presents an approach to the development of a scaled wind tunnel model for static aeroelastic similarity with a full-scale wing model. The full-scale aircraft model is based on the NASA Generic Transport Model (GTM) with flexible wing structures referred to as the Elastically Shaped Aircraft Concept (ESAC). The baseline stiffness of the ESAC wing represents a conventionally stiff wing model. Static aeroelastic scaling is conducted on the stiff wing configuration to develop the wind tunnel model, but additional tailoring is also conducted such that the wind tunnel model achieves a 10% wing tip deflection at the wind tunnel test condition. An aeroelastic scaling procedure and analysis is conducted, and a sub-scale flexible wind tunnel model based on the full-scale's undeformed jig-shape is developed. Optimization of the flexible wind tunnel model's undeflected twist along the span, or pre-twist or wash-out, is then conducted for the design test condition. The resulting wind tunnel model is an aeroelastic model designed for the wind tunnel test condition.

Published

2014

13. Coupled Vortex-Lattice Flight Dynamic Model with Aeroelastic Finite-Element Model of Flexible Wing Transport Aircraft with Variable Camber Continuous Trailing Edge Flap for Drag Reduction

Author

Tung Dao, Eric B. Ting, Khanh V. Trinh, Nhan T. Nguyen, and Daniel Nguyen

Subjects

Aerodynamic force, Aircraft flight mechanics, Engineering, Elevator, Wing twist, business.industry, Camber (aerodynamics), Trailing edge, Spoileron, Structural engineering, Aerospace engineering, business, Aeroelasticity

Abstract

This paper presents a coupled vortex-lattice flight dynamic model with an aeroelastic finite-element model to predict dynamic characteristics of a flexible wing transport aircraft. The aircraft model is based on NASA Generic Transport Model (GTM) with representative mass and stiffness properties to achieve a wing tip deflection about twice that of a conventional transport aircraft (10% versus 5%). This flexible wing transport aircraft is referred to as an Elastically Shaped Aircraft Concept (ESAC) which is equipped with a Variable Camber Continuous Trailing Edge Flap (VCCTEF) system for active wing shaping control for drag reduction. A vortex-lattice aerodynamic model of the ESAC is developed and is coupled with an aeroelastic finite-element model via an automated geometry modeler. This coupled model is used to compute static and dynamic aeroelastic solutions. The deflection information from the finite-element model and the vortex-lattice model is used to compute unsteady contributions to the aerodynamic force and moment coefficients. A coupled aeroelastic-longitudinal flight dynamic model is developed by coupling the finite-element model with the rigid-body flight dynamic model of the GTM.

Published

2013

14. Initial Assessment of a Variable-Camber Continuous Trailing-Edge Flap System for Drag-Reduction of Non-Flexible Aircraft in Steady-State Cruise Condition

Author

Eric B. Ting, Corey A. Ippolito, Khanh V. Trinh, Joseph J. Totah, and Nhan T. Nguyen

Subjects

Takeoff and landing, Drag, Camber (aerodynamics), Computer science, Control system, Trailing edge, Flight control surfaces, Aeroelasticity, Marine engineering, Nonlinear programming

Abstract

In this paper, we describe an initial optimization study of a Variable-Camber Continuous Trailing-Edge Flap (VCCTEF) system. The VCCTEF provides a light-weight control system for aircraft with long flexible wings, providing efficient high-lift capability for takeoff and landing, and greater efficiency with reduced drag at cruising flight by considering the effects of aeroelastic wing deformations in the control law. The VCCTEF system is comprised of a large number of distributed and individually-actuatable control surfaces that are constrained in movement relative to neighboring surfaces, and are non-trivially coupled through structural aeroelastic dynamics. Minimzation of drag results in a constrained, coupled, nonlinear optimization over a high-dimension search space. In this paper, we describe the modeling, analysis, and optimization of the VCCTEF system control inputs for minimum drag in cruise. The purpose of this initial study is to quantify the expected benefits of the system concept. The scope of this analysis is limited to consideration of a rigid wing without structural flexibility in a steady-state cruise condition at various fuel weights. For analysis, we developed an optimization engine that couples geometric synthesis with vortex-lattice analysis to automate the optimization procedure. In this paper, we present and describe the VCCTEF system concept, optimization approach and tools, run-time performance, and results of the optimization at 20%, 50%, and 80% fuel load. This initial limited-scope study finds the VCCTEF system can potentially gain nearly 10% reduction in cruise drag, provides greater drag savings at lower operating weight, and efficiency is negatively impacted by the severity of relative constraints between control surfaces.

Published

2013

15. A Mission Adaptive Variable Camber Flap Control System to Optimize High Lift and Cruise Lift to Drag Ratios of Future N+3 Transport Aircraft

Author

James Urnes, Nhan T. Nguyen, Khanh V. Trinh, Joseph J. Totah, Eric B. Ting, and Corey A. Ippolito

Subjects

Lift-to-drag ratio, Wing, business.industry, Camber (aerodynamics), Drag, Wing twist, Computer science, Aerodynamic drag, Flapping, Takeoff, Aerospace engineering, business, Marine engineering

Abstract

Boeing and NASA are conducting a joint study program to design a wing flap system that will provide mission-adaptive lift and drag performance for future transport aircraft having light-weight, flexible wings. This Variable Camber Continuous Trailing Edge Flap (VCCTEF) system offers a lighter-weight lift control system having two performance objectives: (1) an efficient high lift capability for take-off and landing, and (2) reduction in cruise drag through control of the twist shape of the flexible wing. This control system during cruise will command varying flap settings along the span of the wing in order to establish an optimum wing twist for the current gross weight and cruise flight condition, and continue to change the wing twist as the aircraft changes gross weight and cruise conditions for each mission segment. Design weight of the flap control system is being minimized through use of light-weight shape memory alloy (SMA) actuation augmented with electric actuators. The VCCTEF program is developing better lift and drag performance of flexible wing transports with the further benefits of lighter-weight actuation and less drag using the variable camber shape of the flap.

Published

2013

16. Elastically Shaped Wing Optimization and Aircraft Concept for Improved Cruise Efficiency

Author

Kevin Reynolds, Khanh V. Trinh, Nhan T. Nguyen, James Kless, James Urnes, and Michael J. Aftosmis

Subjects

Lift-to-drag ratio, Engineering, Wing, Lift-induced drag, business.industry, Wing twist, Drag, Trailing edge, Flight control surfaces, Aerodynamics, Aerospace engineering, business

Abstract

This paper presents the findings of a study conducted tn 2010 by the NASA Innovation Fund Award project entitled "Elastically Shaped Future Air Vehicle Concept". The study presents three themes in support of meeting national and global aviation challenges of reducing fuel burn for present and future aviation systems. The first theme addresses the drag reduction goal through innovative vehicle configurations via non-planar wing optimization. Two wing candidate concepts have been identified from the wing optimization: a drooped wing shape and an inflected wing shape. The drooped wing shape is a truly biologically inspired wing concept that mimics a seagull wing and could achieve about 5% to 6% drag reduction, which is aerodynamically significant. From a practical perspective, this concept would require new radical changes to the current aircraft development capabilities for new vehicles with futuristic-looking wings such as this concept. The inflected wing concepts could achieve between 3% to 4% drag reduction. While the drag reduction benefit may be less, the inflected-wing concept could have a near-term impact since this concept could be developed within the current aircraft development capabilities. The second theme addresses the drag reduction goal through a new concept of elastic wing shaping control. By aeroelastically tailoring the wing shape with active control to maintain optimal aerodynamics, a significant drag reduction benefit could be realized. A significant reduction in fuel burn for long-range cruise from elastic wing shaping control could be realized. To realize the potential of the elastic wing shaping control concept, the third theme emerges that addresses the drag reduction goal through a new aerodynamic control effector called a variable camber continuous trailing edge flap. Conventional aerodynamic control surfaces are discrete independent surfaces that cause geometric discontinuities at the trailing edge region. These discontinuities promote vorticities which result in drag rises as well as noise sources. The variable camber trailing edge flap concept could provide a substantial drag reduction benefit over a conventional discrete flap system. Aerodynamic simulations show a drag reduction of over 50% could be achieved with the flap concept over a conventional discrete flap system.

Published

2013

17. Coupled Aeroelastic Vortex Lattice Modeling of Flexible Aircraft

Author

Khanh V. Trinh, Susan A. Frost, Nhan T. Nguyen, and Kevin Reynolds

Subjects

Engineering, Wing, ComputingMethodologies_SIMULATIONANDMODELING, business.industry, Computation, Aerodynamics, Aeroelasticity, Vortex, Iterated function, Deflection (engineering), Lattice (order), Aerospace engineering, business, Physics::Atmospheric and Oceanic Physics, ComputingMethodologies_COMPUTERGRAPHICS

Abstract

This paper presents a recently developed computational tool for aeroelastic analysis of aircraft performance. The computational tool couples a vortex-lattice code, Vorview, with an aeroelastic model that computes wing structural deflections under a combined coupled bending-torsion motion. The aeroelastic model of the wing structure is based on a one-dimensional structural dynamic theory using steady state aerodynamics assumption. An automated aircraft geometry modeler is developed to generate a deformed aircraft geometry based on the structural deflection aeroelastic analysis. The computation is iterated until the solution converges within a specified error tolerance. This computational tool is capable to predict both steady state aerodynamics as well as aeroelastically induced unsteady aerodynamics. Simulations are conducted for a generic transport aircraft to demonstrate the capability of the computational tool.

Published

2011

18. Application of Structural Load Feedback in Flight Control

Author

Khanh V. Trinh, Christine V. Jutte, Marc Bodson, Susan A. Frost, Brian R. Taylor, and John J. Burken

Subjects

Engineering, business.industry, Control (management), ComputerApplications_COMPUTERSINOTHERSYSTEMS, Control engineering, Avionics, Optimal control, Allocator, Flight dynamics, Structural load, Control theory, Control system, business, Change control

Abstract

Advances in sensors and avionics computation power suggest real-time structural load measurements could be used in flight control systems for improved safety and performance. A convention transport flight control system determines the moments necessary to meet the pilot’s command, while rejecting disturbances and maintaining stability of the aircraft. Control allocation is the problem of converting these desired moments into control effector commands. In this paper, a framework is proposed to incorporate real-time structural load feedback and structural load constraints in the control allocator. Constrained optimal control allocation can be used to achieve desired moments without exceeding specified limits on monitored load points. Furthermore, certain criteria can be minimized, such as loads on certain parts of the aircraft. Flight safety issues could be addressed by using system health monitoring information to change control allocation constraints during flight. The framework to incorporate structural loads in the flight control system and an optimal control allocation algorithm will be described and then demonstrated on a nonlinear simulation of a generic transport aircraft with flight dynamics and static structural loads.

Published

2011

19. Integrating Systems Health Management with Adaptive Controls for a Utility-scale Wind Turbine

Author

Kai Goebel, Mark J. Balas, Khanh V. Trinh, Susan A. Frost, and Alan M. Frost

Subjects

Engineering, Adaptive control, Wind power, Turbine blade, business.industry, Reliability (computer networking), Condition monitoring, ComputerApplications_COMPUTERSINOTHERSYSTEMS, computer.software_genre, Turbine, law.invention, Reliability engineering, Cost reduction, law, Systems management, business, computer

Abstract

Increasing turbine up-time and reducing maintenance costs are key technology drivers for wind turbine operators. Components within wind turbines are subject to considerable stresses due to unpredictable environmental conditions resulting from rapidly changing local dynamics. Systems health management has the aim to assess the state-of-health of components within a wind turbine, to estimate remaining life, and to aid in autonomous decision-making to minimize damage. Advanced adaptive controls can provide the mechanism to enable optimized operations that also provide the enabling technology for Systems Health Management goals. The work reported herein explores the integration of condition monitoring of wind turbine blades with contingency management and adaptive controls. Results are demonstrated using a high fidelity simulator of a utility-scale wind turbine.

Published

2011

20. A Framework for Optimal Control Allocation with Structural Load Constraints

Author

John J. Burken, Khanh V. Trinh, Marc Bodson, Brian R. Taylor, Christine V. Jutte, and Susan A. Frost

Subjects

Engineering, Structural load, Proof of concept, business.industry, Control theory, Control system, Lookup table, Control (management), Flight control surfaces, business, Optimal control, Flight simulator

Abstract

Conventional aircraft generally employ mixing algorithms or lookup tables to determine control surface deflections needed to achieve moments commanded by the flight control system. Control allocation is the problem of converting desired moments into control effector commands. Next generation aircraft may have many multipurpose, redundant control surfaces, adding considerable complexity to the control allocation problem. These issues can be addressed with optimal control allocation. Most optimal control allocation algorithms have control surface position and rate constraints. However, these constraints are insufficient to ensure that the aircraft's structural load limits will not be exceeded by commanded surface deflections. In this paper, a framework is proposed to enable a flight control system with optimal control allocation to incorporate real-time structural load feedback and structural load constraints. A proof of concept simulation that demonstrates the framework in a simulation of a generic transport aircraft is presented.

Published

2010

21. Elastic shape morphing of ultralight structures by programmable assembly.

Author

Nicholas B Cramer, Daniel W Cellucci, Olivia B Formoso, Christine E Gregg, Benjamin E Jenett, Joseph H Kim, Martynas Lendraitis, Sean S Swei, Greenfield T Trinh, Khanh V Trinh, and Kenneth C Cheung

Abstract

Ultralight materials present an opportunity to dramatically increase the efficiency of load-bearing aerostructures. To date, however, these ultralight materials have generally been confined to the laboratory bench-top, due to dimensional constraints of the manufacturing processes. We show a programmable material system applied as a large-scale, ultralight, and conformable aeroelastic structure. The use of a modular, lattice-based, ultralight material results in stiffness typical of an elastomer (2.6 MPa) at a mass density typical of an aerogel . This, combined with a building block based manufacturing and configuration strategy, enables the rapid realization of new adaptive structures and mechanisms. The heterogeneous design with programmable anisotropy allows for enhanced elastic and global shape deformation in response to external loading, making it useful for tuned fluid-structure interaction. We demonstrate an example application experiment using two building block types for the primary structure of a 4.27 m wingspan aircraft, where we spatially program elastic shape morphing to increase aerodynamic efficiency and improve roll control authority, demonstrated with full-scale wind tunnel testing. [ABSTRACT FROM AUTHOR]

Published

2019