scholarly journals The development of an advanced composite structure using evolutionary design methods

2009 ◽  
Author(s):  
◽  
David Van Wyk
Keyword(s):  
Composite Materials ◽  
Composite Structure ◽  
Composite Structures ◽  
Empirical Method ◽  
Optimum Shape ◽  
Evolutionary Design ◽  
Structural Optimisation ◽  
Design For Manufacture ◽  
Advanced Composite ◽  
Evolutionary Optimisation

The development of an evolutionary optimisation method and its application to the design of an advanced composite structure is discussed in this study. Composite materials are increasingly being used in various fields, and so optimisation of such structures would be advantageous. From among the various methods available, one particular method, known as Evolutionary Structural Optimisation (ESO), is shown here. ESO is an empirical method, based on the concept of removing and adding material from a structure, in order to create an optimum shape. The objective of the research is to create an ESO method, utilising MSC.Patran/Nastran, to optimise composite structures. The creation of the ESO algorithm is shown, and the results of the development of the ESO algorithm are presented. A tailfin of an aircraft was used as an application example. The aim was to reduce weight and create an optimised design for manufacture. The criterion for the analyses undertaken was stress based. Two models of the tailfin are used to demonstrate the effectiveness of the developed ESO algorithm. The results of this research are presented in the study.

The Design of Advanced Composite Structures Using Evolutionary Design Methods

2006 ◽  
Author(s):  
David van Wyk ◽  
David Jonson
Keyword(s):  
Composite Structures ◽  
Empirical Method ◽  
Optimum Shape ◽  
Shell Elements ◽  
Advanced Composite ◽  
3D Elements ◽  
Evolutionary Optimisation ◽  
Total Analysis ◽  
Orthotropic Properties ◽  
Multiple Load

The development of an evolutionary optimisation method and its application to the design of an advanced composite structure is discussed. Composite materials are increasingly being used in various fields, and so optimisation of such structures would be advantageous. From among the various methods available, one particular method, known as Evolutionary Structural Optimisation (ESO), is shown here. ESO is an empirical method, based on the concept of removing and adding material from a structure, in order to create an optimum shape. Much work has been done on ESO by various researchers. V. Young, G.P Steven, Y.M. Xie and O.M. Querin extended the basic ESO algorithm to the addition of elements and multiple load cases. S. Savas, M. Ulker, and M.P. Saka utilised ESO to create structures with a uniform stress distribution. Both ESO algorithms were applied to isotropic structures. The basic principle of ESO is to remove material from the model, based on certain criteria, stress being typical. The method can also add material back, where it may become necessary to reinforce the structure, which may happen when excessive material is removed. The model undergoes an iterative process of analysis and modification, the cycle continuing until certain conditions are met, ranging from weight reduction to stress limits. The objective of the current research is to create an ESO method, utilising MSC.Patran/Nastran, to optimise composite structures. The final algorithm created is simple, in order to improve efficiency and reduce total analysis runtimes. The algorithm modifies the properties of the element, rather than removing it from the structure completely. This ensures that the connectivity of the elements remains intact. Elements are selected for removal or addition based on a driving criterion. The composite structures are modelled as a core and shell. The core consists of 3D elements with orthotropic properties, and the skin is represented by non-removable 2D shell elements. These shell elements bear the loads and boundary conditions. They also keep the external shape of the model, which is important for aerodynamic structures. The models were run through the ESO algorithm until the final optimised structure remained. A tailfin of an aircraft was used as an application example. The aim was to reduce weight and create an optimised design for manufacture. The criterion for the analyses undertaken was stress based. The results of this research are presented in the paper.

Development of Aerospace Composite Structures Through Vacuum-Enhanced Resin Transfer Moulding Technology (VERTMTy)

2018 ◽  
pp. 99-111
Author(s):  
Raghu Raja Pandiyan Kuppusamy
Keyword(s):  
Composite Materials ◽  
Composite Structures ◽  
Polymer Matrix Composites ◽  
Wide Spectrum ◽  
Low Cost ◽  
Matrix Composites ◽  
Resin Transfer Moulding ◽  
Advanced Composite ◽  
Advanced Composite Materials ◽  
Transfer Moulding

Quality products with low cost manufacturing routes are the major objectives for the product development in any application. The current statement is evident for polymer-matrix composites, particularly in high end applications such as aerospace and mass transit structures. These applications require advanced composite materials tailored to meet the property demands posted by dynamic load conditions, and hence, the use of wide spectrum of constituents and architectures are vital to cater the needs. Consequently, the development of novel composite materials with the permutations of ingredients leads to the innovative processing techniques. To address the gap in the manufacturing with economical processing routes of thick sectioned advanced composite parts showing superior properties at different wall sections, an innovative composite manufacturing technology coupling resin transfer moulding (RTM) processing and vacuum applications, namely vacuum enhanced resin transfer moulding technology (VERTMTy), is conceptualized, proposed, and developed.

scholarly journals A Study of Drive Shaft Assembly

2015 ◽  
Vol 1 (1) ◽  
Author(s):  
Deepak Pushpad
Keyword(s):  
Composite Materials ◽  
Weight Reduction ◽  
Composite Structures ◽  
Drive Shaft ◽  
Material Technology ◽  
Metallic Structures ◽  
Specific Strength ◽  
Advanced Composite ◽  
Advanced Composite Materials ◽  
Analysis Package

The weight reduction of the driveshaft can have a certain role in the general weight reduction of the vehicle and is a highly desirable destination. Substituting composite structures for conventional metallic structures has many advantages because of higher specific stiffness and durability of composite materials. The advanced composite materials such as graphite, carbon, Kevlar and Glass with suitable resins are widely practiced because of their high specific strength and high specific modulus. Advanced composite materials seem ideally suited for long, power driver shaft applications. The automotive industry is exploiting composite material technology for structural component construction in order to obtain the reduction of the weight without a reduction in vehicle quality and dependability. It is known that energy conservation is one of the most important objectives in vehicle design and reduction of weight is one of the most efficient steps to get this effect. In reality, on that point is about a direct proportion between the weight of a vehicle and its fuel use, especially in city driving. This task is an analysis performed on drive shaft with different composite materials and concludes that the utilization of composite materials for drive shaft would induce less amount of stress which additionally reduces the weight of the vehicle. CATIA is the modelling package used to model the drive shaft arrangement and ANSYS is the analysis package used to carry out analysis.

An Approach to Enhancement of Conductivity in Composite Material Using Nanotechnology

2006 ◽  
Author(s):  
Vivian T. Dang ◽  
Russ Maguire ◽  
Robab Safa-Bakhsh
Keyword(s):  
Composite Material ◽  
Composite Materials ◽  
Composite Structure ◽  
Composite Structures ◽  
Test Methods ◽  
Commercial Aircraft ◽  
Nano Technology ◽  
Novel Approaches ◽  
Non Destructive ◽  
Potential Integration

This review documents possible developments using Nano technology to enhance electromagnetic effects (EME) and identifies the potential integration on the composite structures for the next generation composite commercial aircraft. First, developments using Nano technology as a source to enhance the EME of the composite will be discussed. These developments include computational modeling of Nano-filled composites to predict certain properties and behaviors of Nano-enhanced materials, test methods for non-destructive examination of Nano-modified materials, and other novel approaches to resolve the challenges of increasing conductivity in composite materials. Next, the details of the potential impacts of using Nano technology for increasing conductivity will be outlined. Finally, the implementation of a Nano-enhanced material on the composite structure will be described.

scholarly journals Advanced composite structure combining Ultra high performance concrete with normal reinforced concrete

2019 ◽  
Vol 278 ◽  
pp. 03004
Author(s):  
Xiangguo Wu
Keyword(s):  
Reinforced Concrete ◽  
Material Properties ◽  
Composite Structure ◽  
Composite Structures ◽  
High Performance ◽  
High Performance Concrete ◽  
Raw Materials ◽  
Constitutive Relations ◽  
Ultra High Performance Concrete ◽  
Advanced Composite

Ultra high performance concrete (UHPC), one of the newest cementitious composites, demonstrates superior ductility with high strength and durability, which has gained the attention of researchers and engineers since it was successfully developed. Considering its superior ductility and durability, UHPC is a good alternative material for forming a advanced composite structure with normal reinforced concrete (RC) or prestressed concrete. The material properties are critical for its application in composite structures, so in this chapter, material properties of UHPC, such as constitute raw materials, mechanical properties, durability and several constitutive relations from several standards are firstly introduced. The basic concepts of advanced UHPC-RC composite structures, such as UHPC-RC composite beam, composite column, composite wall, etc, are introduced finally.

Fabrication of Composite Materials from Fibrous Precursors Using Paper Making Procedures

1990 ◽  
Vol 197 ◽  
Author(s):  
J. N. Zabasajja ◽  
Soonho Ahn ◽  
Tony Wu ◽  
A. Krishnagopalan ◽  
B. J. Tatarchuk
Keyword(s):  
Composite Materials ◽  
Composite Structure ◽  
Composite Structures ◽  
Structural Integrity ◽  
High Energy ◽  
High Energy Density ◽  
Kinetic Measurements ◽  
Paper Making ◽  
Bonded Composite ◽  
Sinter Bonding

ABSTRACTNovel composite materials have been fabricated from fibrous precursors using paper making procedures. Small metal fibers (2 μm in diameter) and carbon fiber bundles (20 μm in diameter) were combined with cellulose (as the binding agent) into an interwoven paper preform. The composite paper preform was then sintered at high temperatures in a controlled atmosphere, subsequently removing the cellulose and forming a sinter-bonded composite structure. The sinter bonding of the metal locked the metal fibers and provided high mechanical flexibility and structural integrity to the resulting composite structure. The composite structures were characterized using scanning electron microscopy, electrochemical and kinetic measurements. The optimization of these structures for high energy density applications was demonstrated through these measurements.

scholarly journals METHODS OF MODELING OF COMPOSITE MATERIALS AND COMPOSITE STRUCTURES ON «LIRA-SAPR»

2017 ◽  
Vol 1 (48) ◽  
pp. 129-137
Author(s):  
M. S. Barabash ◽  
I. V. Genzerskyi ◽  
А. V. Pikul А.V. ◽  
О. Yu Bashynska
Keyword(s):  
Numerical Modeling ◽  
Composite Material ◽  
Composite Materials ◽  
Composite Structure ◽  
Software Package ◽  
Composite Structures ◽  
Frame Structure ◽  
Structural Reinforcement ◽  
Modeling Process ◽  
Metal Casing

This paper provides detailed suggestions for the process of structural reinforcement modeling by composite materials on the software package «LIRA-SAPR». It also provides the implementation of bearing capacity checks for reinforced elements on the program called «ESPRI». The article offers an algorithm for calculation of  the construction objects in case of design situation changing, considering the modeling of the composite structure reinforcement. It considered the modeling process of reinforcement of structures using classical methods, such as using of metal casing. It also investigated a numerical modeling example of the frame structure reinforcement, with the selection and verification of the composite material.

scholarly journals SELECTION AND OPTIMIZATION OF FUSELAGE COMPONENTS FOR MODERN AIRPLANES

2019 ◽  
pp. 12-20
Author(s):  
Ihor Andriyovych Makarov ◽  
Sergey Romualdovich Ignatovich
Keyword(s):  
Titanium Alloys ◽  
Primary Structure ◽  
Composite Structure ◽  
Composite Structures ◽  
Advanced Materials ◽  
Advanced Composite ◽  
Advantages And Disadvantages ◽  
Treatment Techniques ◽  
Critical Components ◽  
Work Done

Nowadays the level of development of airplane materials shows the tendency of usage of advanced composite structures. However, these materials have plenty of advantages and disadvantages, the most crucial is the ability to absorb water from the environment and because of this layers of composite structures disbonded and consequently became useless. This issue demonstrates the limitation of usage of advanced composite structures. Despite this fact application of conventional materials (such as Aluminum or Titanium alloys) are limited by the weight of structure and manufacturability. In given article question of optimization for choosing of the airplane, the material is considered. The necessity to maintain equilibrium between minimal weight and appropriate strength pushes designers to develop new advanced materials, mechanical properties of which satisfy strict criteria of strength, despite lightweight of the material.  The goal of this research elaborating work is to estimate the necessity of usage of advanced composite structures vs well known conventional materials.  It was researched sizing and optimization of choosing of structural materials for the primary structure. On top of this, properties and peculiarities of conventional materials (such as Aluminum and Titanium alloys) and advanced composite structure. It was demonstrated that the usage of conventional materials for primary structure has a significant advantage in comparison with advanced composite structures. Additionally, manufacturability and maintainability of materials were discussed in the given article. As a result, the application of conventional materials for primary airplane structure is the most suitable way for the design of modern airplanes. Today, the structural designer no longer chooses a material solely based on its strength qualities, but on its proven ability to withstand minor damage in service without endangering the safety of the aircraft. The residual strength after damage, described as the toughness, is now uppermost in the engineer’s mind when he chooses alloys for airframes. Damage caused by fatigue is the main factor because it is difficult to detect and can disastrously weaken the strength of critical components. So whereas about a decade ago aluminum alloys looked as if they had reached a technical plateau, engineers have now been able to clarify their needs as a result of the work done on fracture mechanics, and metallurgists have changed their composition and treatment techniques to meet the new toughness requirements. The best option to consider the usage of both advanced composite structure (for secondary structures) and conventional material (for primary structures).

Residual Strength of Composites during and after Fire Exposure

1993 ◽  
Vol 11 (3) ◽  
pp. 255-270 ◽  
Author(s):  
U. Sorathia ◽  
C. Beck ◽  
T. Dapp
Keyword(s):  
Composite Materials ◽  
Residual Strength ◽  
Composite Structures ◽  
Damage Control ◽  
Structural Performance ◽  
Fire Exposure ◽  
Advanced Composite ◽  
Advanced Composite Materials ◽  
Flammability Characteristics ◽  
Relationship Of

The flammability characteristics of conventional and advanced composite materials have been extensively studied within the DOD. However, the structural performance of composite materials, the residual strength of composite structures, and the consequences of composite usage on ship sur vivability and damage control during and after fire have not yet been fully assessed. Residual flexural strength retained (%RSR) after exposure to 25 kW/m2 for a duration of 20 minutes (ASTM E-662) for selected conventional and advanced composite materials is presented. A methodology is presented for the assess ment of the residual strength of composite materials during fire exposure by inter-relationship of mechanical property, temperature, thickness and time.

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