Smart intelligent aircraft structure

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The term "smart structures" is commonly used for structures which have the ability to adapt to environmental conditions according to the design requirements. As a rule, the adjustments are designed and performed in order to increase the efficiency or safety of the structure. Combining "smart structures" with the "sophistication" achieved in materials science, information technology, measurement science, sensors, actuators, signal processing, nanotechnology, cybernetics, artificial intelligence, and biomimetics, [1] one can talk about Smart Intelligent Structures. In other words, structures which are able to sense their environment, self-diagnose their condition and adapt in such a way so as to make the design more useful and efficient.

Contents

The concept of Smart Intelligent Aircraft Structures offers significant improvements in aircraft total weight, manufacturing cost and, above all, operational cost by an integration of system tasks into the load carrying structure. [2] It also helps to improve the aircraft's life cycle and reduce its maintenance. [3] Individual morphing concepts also have the ability to decrease airframe generated noise and hence reduce the effect of air traffic noise near airports. Furthermore, cruise drag reductions have a positive effect on fuel consumption and required take-off fuel load.

Morphing structures

Fixed geometry wings are optimized for a single design point, identified through altitude, Mach number, weight, etc. Their development is always a compromise between design and off-design points, referred to a typical mission. This is emphasised for civil aircraft where flight profiles are almost standard. Nevertheless, it may occur to fly at high speeds and low altitude with light weight over a short stretch or to fly at low speeds and high altitude with maximum load for a longer range. The lift coefficient would then range between 0.08 and 0.4, [4] [5] with the aircraft experiencing up to 30% weight reduction as the fuel is consumed. [6] These changes could be compensated by wing camber variations, to pursue optimal geometry for any flight condition, thus improving aerodynamic and structural performance.

Existing aircraft cannot change shape without aerodynamic gaps, something that can be solved with Smart Intelligent Structures. By ensuring the detailed consideration of structural needs throughout the entire lifetime of an aircraft and focusing on the structural integration of needed past capabilities, Smart Intelligent Aircraft Structures will allow aircraft designers to seriously consider conformal morphing technologies. The reduced drag during take-off, cruise and landing for future and ecologically improved civil aircraft wings can be achieved through naturally laminar wing technology, by incorporating a gapless and deformable leading edge device with lift providing capability. Such a morphing structure typically consists of a flexible outer skin and an internal driving mechanism (Figure 1). Current aircraft designs already employ winglets aimed at increasing the cruise flight efficiency by induced drag reduction. Smart intelligent Structures propose a state of the art technology that incorporates a wingtip active trailing edge, which could be a means of reducing winglet and wing loads at key flight conditions.

Structural health monitoring

Another component of an "intelligent" aircraft structure is the ability to sense and diagnose potential threats to its structural integrity. This differs from conventional non-destructive testing (NDT) by the fact that Structural Health Monitoring (SHM) [7] uses sensors that are permanently bonded or embedded in the structure. Composite materials, which are highly susceptible to hidden internal flaws which may occur during manufacturing and processing of the material or while the structure is subjected to service loads, require a substantial amount of inspection and defect monitoring at regular intervals. Thus, the increasing use of composite materials for aircraft primary structure aircraft components increases substantially their life cycle cost. According to some estimates, over 25% of the life cycle cost of an aircraft or aerospace structure, which includes pre-production, production, and post-production costs, can be attributed to operation and support, involving inspection and maintenance. With sensing technology reducing in cost, size and weight, and sensor signal processing power continuously increasing, a variety of approaches have been developed allowing integration of such sensing options onto or into structural components.

Although available in principle, none of these SHM technologies have currently achieved a sufficient level of maturity such that SHM could be reliably applied to real engineering structures. A real reduction of life cycle costs related to maintenance and inspections can only be achieved by SHM systems designed as "fail-safe" components and included within a damage tolerance assessment scenario, able to reduce the inspection times (or their intervals) by investigating the structure quickly and reliably and avoiding the time-consuming disassembly of structural parts. [8]

Multifunctional materials

The advantages of carbon fibre reinforced polymers (CFRPs) over metallic materials in terms of specific stiffness and strength are well known. In the last few years, there has been a sharp increase in the demand for composite materials with integrated multifunctional capabilities for use in aeronautical structures.

However, a major drawback with CFRPs for primary structural applications is their low toughness and damage tolerance. Epoxy resins are brittle and have poor impact strength and resistance to crack propagation, resulting in unsatisfactory levels of robustness and reliability. This results in designs with large margins of safety and complex inspection operations. In addition, by increasing the relative fraction of composite components within new aircraft, challenges regarding electrical conductivity have arisen such as lightning strike protection, static discharge, electrical bonding and grounding, interference shielding and current return through the structure. These drawbacks can be solved by the use of emerging technologies such as nanocomposites, which combine mechanical, electrical and thermal properties. [9]

Nanoparticle reinforced resins have been found to offer two distinct advantages over current resin systems. [10] [11] [12] [13] [14] First of all, they are able to provide an increase in fracture toughness of up to 50% for older liquid resin infusion (LRI) resins and 30% in more advanced systems. Secondly, percolated nanoparticles drastically improve resin conductivity, turning it from a perfect isolator into a semiconductor. While improved damage tolerance properties could directly lead to structural weight savings, the exploitation of electrical properties could also enable a simpler, and hence cheaper, Electrical Structure Network (ESN).

Running research activities to implement the above technologies to aircraft

Developing these technologies for future A/C, there is currently (2011 – 2015) a running project, partially funded by the European Commission, called "SARISTU" (Smart Intelligent Aircraft Structures) with a total budget of €51,000,000. This initiative is coordinated by Airbus and brings together 64 partners from 16 European countries. [15] [16] SARISTU focuses on the cost reduction of air travel through a variety of individual applications as well as their combination. Specifically, the integration of different conformal morphing concepts in a laminar wing is intended to improve aircraft performance through a 6% drag reduction, with a positive effect on fuel consumption and required take-off fuel load. A side effect will be a decrease of up to 6 dB(A) of the airframe generated noise, thus reducing the impact of air traffic noise in the vicinity of airports. Recent calculations and Computational Fluid Dynamics Analysis indicate that the target is likely to be exceeded but will still need to be offset against a possible weight penalty.

Another expected outcome is to limit the integration cost of Structural Health Monitoring (SHM) systems by moving the system integration as far forward in the manufacturing chain as possible. In this manner, SHM integration becomes a feasible concept to enable in-service inspection cost reductions of up to 1%. Structural Health Monitoring related trials indicate that specific aircraft inspections may gain higher benefits than originally anticipated.

Finally, the incorporation of Carbon Nanotubes into aeronautical resins is expected to enable weight savings of up to 3% when compared to the unmodified skin/stringer/frame system, while a combination of technologies is expected to decrease Electrical Structure Network installation costs by up to 15%.

Related Research Articles

In materials science, a metal matrix composite (MMC) is a composite material with fibers or particles dispersed in a metallic matrix, such as copper, aluminum, or steel. The secondary phase is typically a ceramic or another metal. They are typically classified according to the type of reinforcement: short discontinuous fibers (whiskers), continuous fibers, or particulates. There is some overlap between MMCs and cermets, with the latter typically consisting of less than 20% metal by volume. When at least three materials are present, it is called a hybrid composite. MMCs can have much higher strength-to-weight ratios, stiffness, and ductility than traditional materials, so they are often used in demanding applications. MMCs typically have lower thermal and electrical conductivity and poor resistance to radiation, limiting their use in the very harshest environments.

Fiberglass or fibreglass is a common type of fiber-reinforced plastic using glass fiber. The fibers may be randomly arranged, flattened into a sheet called a chopped strand mat, or woven into glass cloth. The plastic matrix may be a thermoset polymer matrix—most often based on thermosetting polymers such as epoxy, polyester resin, or vinyl ester resin—or a thermoplastic.

<span class="mw-page-title-main">Thermosetting polymer</span> Polymer obtained by irreversibly hardening (curing) a resin

In materials science, a thermosetting polymer, often called a thermoset, is a polymer that is obtained by irreversibly hardening ("curing") a soft solid or viscous liquid prepolymer (resin). Curing is induced by heat or suitable radiation and may be promoted by high pressure or mixing with a catalyst. Heat is not necessarily applied externally, and is often generated by the reaction of the resin with a curing agent. Curing results in chemical reactions that create extensive cross-linking between polymer chains to produce an infusible and insoluble polymer network.

Fibre-reinforced plastic is a composite material made of a polymer matrix reinforced with fibres. The fibres are usually glass, carbon, aramid, or basalt. Rarely, other fibres such as paper, wood, boron, or asbestos have been used. The polymer is usually an epoxy, vinyl ester, or polyester thermosetting plastic, though phenol formaldehyde resins are still in use.

Structural health monitoring (SHM) involves the observation and analysis of a system over time using periodically sampled response measurements to monitor changes to the material and geometric properties of engineering structures such as bridges and buildings.

Nanotechnology is impacting the field of consumer goods, several products that incorporate nanomaterials are already in a variety of items; many of which people do not even realize contain nanoparticles, products with novel functions ranging from easy-to-clean to scratch-resistant. Examples of that car bumpers are made lighter, clothing is more stain repellant, sunscreen is more radiation resistant, synthetic bones are stronger, cell phone screens are lighter weight, glass packaging for drinks leads to a longer shelf-life, and balls for various sports are made more durable. Using nanotech, in the mid-term modern textiles will become "smart", through embedded "wearable electronics", such novel products have also a promising potential especially in the field of cosmetics, and has numerous potential applications in heavy industry. Nanotechnology is predicted to be a main driver of technology and business in this century and holds the promise of higher performance materials, intelligent systems and new production methods with significant impact for all aspects of society.

Composite gear housing refers to the use of composite materials to enclose the components of motor transmissions. Fiber reinforced composite materials are used primarily for weight reduction. Carbon fiber reinforced plastic material is commonly used in the aerospace and automotive industries.

Sheet moulding compound (SMC) or sheet moulding composite is a ready to mould glass-fibre reinforced polyester material primarily used in compression moulding. The sheet is provided in rolls weighing up to 1000 kg. Alternatively the resin and related materials may be mixed on site when a producer wants greater control over the chemistry and filler.

<span class="mw-page-title-main">Wind turbine design</span> Process of defining the form of wind turbine systems

Wind turbine design is the process of defining the form and configuration of a wind turbine to extract energy from the wind. An installation consists of the systems needed to capture the wind's energy, point the turbine into the wind, convert mechanical rotation into electrical power, and other systems to start, stop, and control the turbine.

<span class="mw-page-title-main">Honeycomb structure</span> Natural or man-made structures that have the geometry of a honeycomb

Honeycomb structures are natural or man-made structures that have the geometry of a honeycomb to allow the minimization of the amount of used material to reach minimal weight and minimal material cost. The geometry of honeycomb structures can vary widely but the common feature of all such structures is an array of hollow cells formed between thin vertical walls. The cells are often columnar and hexagonal in shape. A honeycomb-shaped structure provides a material with minimal density and relative high out-of-plane compression properties and out-of-plane shear properties.

Carbon fiber-reinforced polymers, carbon-fibre-reinforced polymers, carbon-fiber-reinforced plastics, carbon-fiber reinforced-thermoplastic, also known as carbon fiber, carbon composite, or just carbon, are extremely strong and light fiber-reinforced plastics that contain carbon fibers. CFRPs can be expensive to produce, but are commonly used wherever high strength-to-weight ratio and stiffness (rigidity) are required, such as aerospace, superstructures of ships, automotive, civil engineering, sports equipment, and an increasing number of consumer and technical applications.

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<span class="mw-page-title-main">Tailored fiber placement</span>

Tailored fiber placement (TFP) is a textile manufacturing technique based on the principle of sewing for a continuous placement of fibrous material for composite components. The fibrous material is fixed with an upper and lower stitching thread on a base material. Compared to other textile manufacturing processes fiber material can be placed near net-shape in curvilinear patterns upon a base material in order to create stress adapted composite parts.

<span class="mw-page-title-main">Clean Sky</span>

The Clean Sky Joint Undertaking (CSJU) is a public-private partnership between the European Commission and the European aeronautics industry that coordinates and funds research activities to deliver significantly quieter and more environmentally friendly aircraft. The CSJU manages the Clean Sky Programme (CS) and the Clean Sky 2 Programme (CS2), making it Europe's foremost aeronautical research body.

Composite repairs are performed on damaged laminate structures, fibre reinforced composites and other composite materials. The bonded composite repair reduces stresses in the damaged region and prevents cracks from opening or growing. Composite materials are used in a wide range of applications in aerospace, marine, automotive, surface transport and sports equipment markets. Damage to composite components is not always visible to the naked eye and the extent of damage is best determined for structural components by suitable Non Destructive Test (NDT) methods.

Microwave imaging is a science which has been evolved from older detecting/locating techniques in order to evaluate hidden or embedded objects in a structure using electromagnetic (EM) waves in microwave regime. Engineering and application oriented microwave imaging for non-destructive testing is called microwave testing, see below.

Carbon fiber testing is a set of various different tests that researchers use to characterize the properties of carbon fiber. The results for the testing are used to aid the manufacturer and developers decisions selecting and designing material composites, manufacturing processes and for ensured safety and integrity. Safety-critical carbon fiber components, such as structural parts in machines, vehicles, aircraft or architectural elements are subject to testing.

Structural batteries are multifunctional materials or structures, capable of acting as an electrochemical energy storage system while possessing mechanical integrity.

Adhesive bonding is a process by which two members of equal or dissimilar composition are joined. It is used in place of, or to complement other joining methods such mechanical fasting by the use nails, rivets, screws or bolts and many welding processes. The use of adhesives provides many advantages over welding and mechanical fastening in steel construction; however, many challenges still exist that have made the use of adhesives in structural steel components very limited.

References

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