Добірка наукової літератури з теми "Hypersonic Transportation Systems"

This paper aims to provide technical insights on the aerodynamic characterization activities performed in the field of the H2020 STRATOFLY project, for the Mach 8 waverider reference configuration. Considering the complexity of the configuration to be analyzed at conceptual/preliminary design stage, a build-up approach has been adopted. The complexity of the aerodynamic model increases incrementally, from the clean external configuration up to the complete configuration, including propulsion systems elements and flight control surfaces. At each step, the aerodynamic analysis is complemented with detailed mission analysis, in which the different versions of the aerodynamic databases are used as input for the trajectory simulation. eventually, once the contribution to the aerodynamic characterization of flight control surfaces is evaluated, stability and trim analysis is carried out. The comparison of the results obtained through the different mission analysis campaigns clearly shows that the accuracy of aerodynamic characterization may determine the feasibility or unfeasibility of a mission concept.

This report assesses the performance characteristics of a ramjet compression system in the application of a hypersonic vehicle. The vehicle is required to be self-powered and perform a complete flight profile using a combination of turbojet, ramjet and scramjet propulsion systems. The ramjet has been designed to operate between Mach 2.5 to Mach 5 conditions, allowing for start-up of the scramjet engine. Multiple designs, including varying ramp configurations and turbo-ramjet combinations, were investigated to evaluate their merits and limitations. Challenges arose with attempting to maintain sufficient pressure recoveries and favourable flow characteristics into the ramjet combustor. The results provide an engine inlet design capable of propelling the vehicle between the turbojet and scramjet phase of flight, allowing for the completion of its mission profile. Compromises in the design, however, had to be made in order to allow for optimisation of other propulsion systems including the scramjet nozzle and aerodynamics of the vehicle; it was concluded that these compromises were justified as the vehicle uses the ramjet engine for a minority of the flight profile as it transitions between low supersonic to hypersonic conditions.

Purpose This paper aims to propose a methodology for a safety and reliability assessment for the conceptual and preliminary design of very complex and disrupting innovative systems like trans-atmospheric vehicles. The proposed methodology differs from existing ones because it does not rely on statistical data at aircraft-level but exploits the statistical population at components-level only. For the sake of clarity, the paper provides some preliminary results of the application of the methodology at system level. The example deals with the safety and reliability assessment of a very complex propulsion system aimed at guaranteeing vertical take-off and landing capabilities of a suborbital vehicle. Design/methodology/approach The proposed methodology is strongly based on a systems engineering approach. It exploits safety and reliability assessment analyses which have already been developed in both aeronautical and space engineering domains, but it combines them in an innovative way to overcome the lack of statistics at aircraft level. The methodology consists of two different steps: a qualitative top-down process, allowing a functional and physical decomposition of the transportation system and a following quantitative bottom-up approach, which provides the estimation of system-level reliability and safety characteristics starting from the statistical estimation of the components’ characteristics. Findings The paper presents a new methodology for the preliminary reliability and safety assessment of innovative transportation systems, such as hypersonic transportation systems. The envisaged methodology will overcome the poorness of statistical data that is usually affecting the conceptual design of breakthrough systems. Research limitations/implications The paper shows the application of the articulated methodology to a limited case study. A complete example of application of the methodology to estimate safety and reliability characteristics at vehicle level will be provided in feature works. Practical implications The methodology has been proposed to be exploited in international research activities in the field of hypersonic transportation systems. Furthermore, a massive application of this approach would allow to create a database for the generation and the update of semi-empirical models focused on high-level estimations of reliability, availability, maintainability and safety (RAMS) characteristics. Moreover, the proposed safety assessment has been conceived to be fully integrated within a typical conceptual design process. Originality/value The existing literature about safety and reliability assessment at the early design stages proposes pure statistical approaches which are usually not applicable to highly innovative products, where the statistical population is not existing, for example, in the case of trans-atmospheric vehicles. This paper describes how to overcome this problem, through the exploitation of statistical data at components-level only through the combination of these data to estimate RAMS characteristics at aircraft-level thanks to functional analysis, concept of operations and typical safety assessment tools, like functional hazard analysis, failure mode and effect analysis, reliability block diagram and fault tree analysis.

Purpose This paper aims to present an aerothermodynamic analysis of a new concept of a small hypersonic airplane. Aerodynamics characteristics for different flow conditions encountered during the missions are analyzed. The effects of elevons deflection for pitch control and of the presence of engines on aerodynamic performances are also investigated for different flight conditions. The effects of boundary layer laminar–turbulent transition on aerodynamic heating are studied to preliminarily identify proper materials that can sustain the hypersonic phase. Design/methodology/approach Aerodynamic characteristics are predicted by means of the semi-empirical aerodynamic prediction code Missile DATCOM and computational fluid dynamics simulations. Computational fluid dynamics analysis is also performed to investigate aerodynamic heating phenomenon. Findings Major discrepancies between the results offered by the two methods have been registered in transonic regime, whereas in subsonic and super-hypersonic conditions, Missile DATCOM confirms to be a suitable tool for preliminary design steps. The results of the analysis show that for the identification of the materials that can sustain the hypersonic phase, the turbulent solution must be taken into account. Carbon fiber reinforced ceramics composite materials seem particularly well suited for the nose, wing and vertical tail leasing edges and control surfaces, while titanium alloys could be used for the rest of the vehicle surface. Originality/value This new concept of vehicle is designed both for point-to-point medium range hypersonic transportation and long duration suborbital space tourism missions, by integrating available technologies developed for aeronautical and space systems.

Several well-established best practices and reliable tools have been developed along the years to support aircraft conceptual and preliminary design. In this context, one of the most widely used tool is the Matching Chart (MC), a graphical representation of the different performance requirements (curves representing the thrust-to-weight ratio (T/W) requirement as function of the wing loading (W/S)) for each mission phase. The exploitation of this tool allows the identification of a feasible design space as well as the definition of a reference vehicle configuration in terms of maximum thrust, maximum take-off weight, and wing surface since the very beginning of the design process. Although the tool was originally developed for conventional aircraft, several extensions and updates of the mathematical models have been proposed over the years to widen its application to innovative configurations. Following this trend, this paper presents a further evolution of the MC model to support the conceptual design of high-speed transportation systems, encompassing supersonic and hypersonic flight vehicles. At this purpose, this paper reports and discusses the updates of the methodology laying behind the generation of the MC for high-speed transportation. Eventually, the results of the validation of the updated methodology and tool are reported, using as case study, the STRATOFLY MR3 vehicle configuration, a Mach 8 antipodal civil transportation system, currently under development within the H2020 STRATOFLY project.

Aerothermodynamic heating is one of the primary challenges faced in progressing towards reliable hypersonic transportation. In the present study, the transpiration cooling method applied to the thermal protection system of re-entry vehicles is investigated. The complexity in analysing the incoming heat flux for re-entry lies not only in the extreme conditions of the flow but also in the fact that the coolant flow through the porous medium needs to be treated appropriately. While the re-entering spacecraft passes through various flow regimes, the peak conditions are faced only near continuum regime. Focusing on these conditions, traditional computational fluid dynamics techniques are used to model transpiration cooling for re-entry vehicles. In the current work, the open source CFD framework OpenFOAM is used to couple two different solvers iteratively and then analyse the thermal response for flow speed conditions typical of re-entry vehicles. Independent computations are performed using the explicit, loosely coupled procedure for high speed argon flow over a 2D axi-symmetrical cylindrical vehicle. The results presented indicate distinct heat flux drop along the surface of the cylindrical vehicle as a function of parameters such as coolant pressure and wall temperature.

The scope of this research is to investigate the design process, and develop methodologies appropriate to the conceptual level designs of hypersonic vehicles; the Space Launcher and the Hypersonic Transport. Currently most large airframe manufacturers are focusing on developing more efficient, cheaper, greener aircraft designs. On the contrary to this trend, since the late 1930s, there is variable intensity, but continuous interest in hypersonic vehicles. Both classes of hypersonic vehicles can deliver capabilities beyond the current state of the art. The ability in itself, to drastically reduce travelling time, could justify the existence of a Hypersonic Transport for applications such as emergency response, time critical business trips, not to mention military applications. Since the recent retirement of the Space Shuttle, all space launches are dependent on expendable launch vehicles, which are inherently high cost and low reliability vehicles. Compared to this contemporary space access technology, Space Launchers offer a significant advantage: they can reach, operate in and return from orbit without expending the vehicle. These days there is definite renewed interest in hypersonic vehicle technology. This thesis explores the design process as a whole, and focuses on the special area of aircraft design. Past, current and future methodologies and trends are discussed, along with the role of computer aided design in modern aircraft conceptual design. The hypersonic vehicle design process is examined in detail. Each of the essential design areas appropriate at conceptual level are investigated; common and state of the art methodologies are discussed. With the explored methodologies, example results are generated, strengths and shortcomings are highlighted. Where appropriate the results are compared to available data, to validate the methodology on a moduleby- module basis. In addition to the piecewise verification, the design process as a whole is demonstrated. An instance of SSTO Space Launcher conceptual design was generated using the GENUS aircraft design environment. Using GENUS it can be concluded that the methodology is adequate to generate a conceptual level hypersonic vehicle design. The limitations of a SSTO design were identified and the relevance and limits of using airbreather engines explored. Potential for future research and focus areas were identified for the key areas of propulsion and structures. The approach for effective use of the design methodology and the GENUS design environment is explained in detail. This critical appraisal and demonstration of methodology is the basis of the quasi-validation of the methodology as a whole.

This Ph.D. Thesis aims at suggesting a proper integrated and multidisciplinary design methodology to improve the current conceptual and preliminary design phases of breakthrough innovative aerospace products. The methodology, based on a Systems Engineering approach, is presented together with an envisaged toolchain, consisting of both commercial and ad-hoc developed software, integrated in a Model-Based Systems Engineering perspective. In addition, for the sake of clarity and for validation purposes, a specific case study has been selected and developed all along the document. The reference case-study is inspired to a real pre-feasibility study in which the research group of Politecnico di Torino, which the author of this Thesis belongs to, has been involved. The project aims at developing a suborbital vehicle able to perform parabolic flights for both scientific and touristic purposes. This kind of initiatives paves the way for the future hypersonic vehicles, because it allows to crucial enabling technologies to be tested and validated in relevant environment but with lower performances’ requirements. The Thesis is articulated in seven Chapters with an introduction and conclusion sections and in each Chapter a balanced mix between theoretical investigation, mathematical model development, tool selection or development and application to the selected case study is guaranteed. This document starts reporting the major reasons why an innovative design methodology should be envisaged to deal with the increasing level of complexity in the aerospace domain. In particular, in the first Chapter, a brief overview of existing or underdevelopment initiatives related to hypersonic is reported, together with the description of the different types of mission in which the new hypersonic vehicles will be exploited. Moreover, the major issues related to the infrastructures required to operate these transportation systems are summarized. As far as operations are concerned, a short section makes the readers aware of the current under-development regulatory framework. Then, the integrated multidisciplinary design methodology is presented starting from the very high level analyses up to the sizing of the different components of the transportation system. All along the document, crucial role is played by requirements, whose management can allow a complete traceability of the different design characteristics during the overall product life-cycle. Furthermore, proper algorithms allowing to move from purely qualitative to quantitative trade-offs, are presented, with a noticeable advantage in terms of traceability and reproducibility. Eventually, further improvements of both the tool-chain and the reference case studies are envisaged for future developments.

Αντικείμενο της παρούσας διδακτορικής διατριβής αποτελεί η θεωρητική και υπολογιστική προσομοίωση της πτήσης ατμοσφαιρικής καθόδου υψηλών ταχυτήτων, με ιδιαίτερη έμφαση στις υπερυπερηχητικές ταχύτητες και την αεροδυναμική και θερμοδυναμική ανάλυσή της. Η μεθοδολογία που ακολουθείται έχει ως κύριο σκοπό την πρόβλεψη του ίχνους επιστροφής υπερυπερηχητικών οχημάτων στη Γη, με δεδομένο οι ταχύτητες πτήσης να φτάνουν τα 15000 m/s (αριθμός Mach ~ 40) και οι θερμοκρασίες ανακοπής τους 15000 Κ. Στην εργασία αυτή ακολουθείται μεθοδολογική προσέγγιση και συστηματική βιβλιογραφική έρευνα στον επιστημονικοτεχνικό τομέα της αεροδυναμικής υπερθέρμανσης, που υφίστανται Υπερυπερηχητικά Οχήματα (Υ/Ο), κατά την πτήση τους στην ατμόσφαιρα. Η ανάλυση της υπερυπερηχητικής ροής, των θερμικών φορτίων και οι μέθοδοι θερμοθωράκισης των Υ/Ο αναπτύσσονται τις τελευταίες δεκαετίες και εξελίσσονται συνεχώς, αλλά μέχρι και σήμερα (2008), προκύπτουν αστοχίες, κυρίως κατά την επανείσοδό τους στην ατμόσφαιρα από το διάστημα. Για την προσομοίωση της υπερυπερηχητικής πτήσης καθόδου στην ατμόσφαιρα γίνεται μελέτη και ανάλυση των θερμοχημικών ιδιοτήτων και παραμέτρων, οι οποίες χαρακτηρίζουν τα ροϊκά πεδία στις υψηλές ταχύτητες και υψηλές θερμοκρασίες. Ο προσδιορισμός των μεταβαλλόμενων ροϊκών συνθηκών, των θερμοδυναμικών ιδιοτήτων και μεγεθών μεταφοράς θα συμβάλλει στις θεωρίες μοντελοποίησης και υπολογισμού της υψηλής θερμικής καταπόνησης, της σύστασης του υπέρθερμου αέρα και της υψηλής θερμοκρασίας του στην εξωτερική επιφάνεια του θερμομονωτικού τοιχώματος οχημάτων υψηλών ταχυτήτων, κατά την πτήση τους στην ατμόσφαιρα της Γης. Στα πλαίσια αυτά αναπτύσσονται υπολογιστικοί αλγόριθμοι προσομοίωσης και επιτυχούς πρόβλεψης του ατμοσφαιρικού ίχνους καθόδου οχημάτων υπερυπερηχητικής μεταφοράς. Τα βασικά αεροδυναμικά χαρακτηριστικά των ανωστικών οχημάτων στις υψηλές ταχύτητες υπολογίζονται με κατάλληλη προσαρμογή της κλασσικής Νευτώνειας Ροής στις υψηλές ταχύτητες και επιβεβαιώνονται με πειραματικά δεδομένα αεροδυναμικών μετρήσεων σε αεροσήραγγες υψηλών ταχυτήτων της NASA. Επιπλέον στη διατριβή ενσωματώνονται μοντέλα προσομοίωσης των ιδιοτήτων συμπεριφοράς του υπέρθερμου αέρα ως πραγματικού αερίου σε συνθήκες θερμοδυναμικής ισορροπίας σε ακραίες ροϊκές συνθήκες (υψηλές ταχύτητες, υψηλές πιέσεις και χαμηλές πυκνότητες). Πιο συγκεκριμένα γίνεται ανάλυση της μεταβαλλόμενης σύστασης και των ιδιοτήτων του αέρα (θερμοδυναμικά μεγέθη και μεγέθη μεταφοράς) στις πολύ υψηλές θερμοκρασίες του υπέρθερμου ροϊκού πεδίου. Η μελέτη αυτή θα οδηγήσει στην εξαγωγή ενός νέου μοντέλου υπολογισμού της μεταφερόμενης θερμικής ροής στην περιοχή ανακοπής υπερυπερηχητικών οχημάτων, το οποίο επιβεβαιώνεται τόσο με διεθνώς αναγνωρισμένα θερμικά μοντέλα (όπως αυτό των Fay-Riddell) όσο και με υπολογιστικές προσομοιώσεις άλλων ερευνητών. Η μεθοδολογία που ακολουθείται θα αποτελέσει τη βάση για την εξαγωγή ενός νέου θεωρητικού μοντέλου υπολογισμού της θερμοκρασίας του αέρα στην επιφάνεια του θερμοθώρακα του υπερυπερηχητικού οχήματος. Η αποτελεσματικότητα της προτεινόμενης μεθοδολογίας, με το συνδυασμό κινηματικής και αεροθερμοδυναμικής ανάλυσης σε ενιαίο υπολογιστικό αλγόριθμο, αποδεικνύεται και ενισχύεται μέσω της εφαρμογής των ανωτέρω μοντέλων προσομοίωσης σε βαλλιστικό (διαστημικός θαλαμίσκος Απόλλων) και ανωστικό (Σύστημα Διαστημικής Μεταφοράς, γνωστό ως Διαστημικό Λεωφορείο Space Shuttle) υπερυπερηχητικό όχημα. Τα αποτελέσματα της προτεινόμενης μεθόδου συγκρίνονται, αξιολογούνται και πιστοποιούνται με παρόμοια από διεθνώς αναγνωρισμένα υπολογιστικά συστήματα και πειραματικά δεδομένα μετρήσεων σε υπερυπερηχητικές αεροσήραγγες οχημάτων υψηλών ταχυτήτων. Μέσα στις επόμενες δεκαετίες, η εξέλιξη των υπερυπερηχητικών συστημάτων μεταφοράς θα είναι ραγδαία και ιδιαίτερα ελκυστική από τεχνολογικής πλευράς με ελπιδοφόρα μηνύματα για "γήϊνες" μετακινήσεις με υψηλές ταχύτητες σε σύντομους χρόνους, αλλά και πιθανές μετοικήσεις ανθρώπων-αστροναυτών σε άλλους πλανήτες του ηλιακού συστήματος. Έτσι η παρούσα διδακτορική διατριβή, αξιοποιώντας τις προόδους που έχουν συντελεστεί τα τελευταία χρόνια, εκτιμάται ότι συμβάλλει ουσιαστικά στο ακόμα υπό εξέλιξη – για τα ελληνικά δεδομένα πρωτόγνωρο – επιστημονικό πεδίο της Υπερυπερηχητικής Αεροθερμοδυναμικής, και στην ανάπτυξη μεθοδολογίας για τον αεροθερμοδυναμικό σχεδιασμό υπερυπερηχητικών οχημάτων. Το προτεινόμενο σύνθετο μοντέλο κινηματικής και θερμοδυναμικής υπολογιστικής ανάλυσης και η μεθοδολογία που ακολουθείται έχει ισχύ και εφαρμογή στην πλειονότητα των περιπτώσεων των υπερυπερηχητικών πτήσεων στη γήινη και, με κατάλληλες προσαρμογές, σε οποιαδήποτε πλανητική ατμόσφαιρα. Βεβαίως, η προτεινόμενη μεθοδολογία έχει περιθώρια εξέλιξης και ανάπτυξης, προκειμένου να βελτιωθεί η απόδοσή της με την εισαγωγή και νέων στοιχείων, αλλά και να διευρυνθεί το φάσμα των δυνατών εφαρμογών της.
The object of the present doctoral thesis constitutes the theoretical and calculating simulation of high-speed atmospheric flightmotion, with particular emphasis in hypersonic speeds and aerodynamic and thermodynamic analysis. The methodology that is followed has as main aim the prediction of return flight trace of hypersonic vehicles in Earth’s ground, assuming the speeds of flight to reach the 15000 m/s (Mach number ~ 40) and stagnation temperatures the 15000 K. In this work are followed methodological approach and systematic bibliographic research in the scientific field of aerodynamic overheating that suffers Hypersonic Vehicles(H/V) at their flight in Earth’s atmosphere. The analysis of hypersonic flow, thermal loads and new methods for thermal protection systems of H/V are developed the last decades and are evolved continuously, but until today (2008) resulting failures mainly at their reentry in atmosphere from the interval. For the simulation of the atmospheric hypersonic flight motion become study and analysis of thermodynamic properties and parameters, that characterize the flow fields in high speeds and high temperatures. The determination of altered flow conditions, thermodynamic properties and transport magnitudes will contribute in the theories of modelling and high thermal strain calculations, in the constitution of overheating air and it’s high temperature determination in the external surface of heat insulation wall of high-speed vehicles at their flight in Earth’s atmosphere. In this work are developed calculating algorithms of simulation for the successful prediction of atmospheric flight motion of hypersonic transport vehicles. The basic aerodynamic characteristics of lifting vehicles in high speeds are calculated with suitable adaptation of classic Newtonian Flow in high speeds and are confirmed with experimental data of aerodynamic measurements in high speed wind-tunnels of NASA. Moreover in this thesis are incorporated models for the simulation of properties of overheating air behaviour as real gas in thermodynamic balance in extreme flow conditions (high speeds, high pressures and low densities). Particularly becomes analysis of the altered constitution and properties of air (thermodynamic magnitudes and transport magnitudes) in very high temperatures on hypersonic flow field. This study will lead to the export of a new model for the transported thermal stagnation region calculations of hypersonic vehicles, which is confirmed so much with internationally recognized thermal models (as that of Fay-Riddell) and with calculating simulations of other researchers. The methodology that is followed will constitute the base for the export of a new theoretical model for high temperature air calculations in thermal protection systems surface of hypersonic vehicles. The effectiveness of proposed methodology, with the combination kinematic and aerothermodynamics analysis in united calculating algorithm, is proved and confirmed via the application of above simulation models on ballistic (Apollo Command Module) and lifting (Space Transportation System, known as Space Shuttle) hypersonic vehicles. The results of proposed method are compared, evaluated and certified with similarly by internationally recognized calculating systems and experimental data of measurements in hypersonic wind-tunnels for high speed vehicles. In the next decades, the development of hypersonic transportation systems will be rapid and particularly attractive from technological side with hopeful messages for “earthy” transfers with high speeds in short times, but also likely persons-astronaut missions in other planets of solar system. Thus the present doctoral thesis, developing the progress that has taken place in the past few years, is appreciated that it contributes substantially in still under development - for the Greek data unusual - scientific field of Hypersonic Aerothermodynamics, and in the growth of methodology for the aerothermodynamic construction of hypersonic vehicles. The proposed complex model of kinematic and thermodynamic calculating analysis and it’s methodology that is followed have influence and application in the majority of cases of hypersonic flights in earthy and, with properly adaptations, in anyone planetary atmosphere. Of course, the proposed methodology has margins of development and growth in order to improve her efficiency with the import of also new elements and also extended the spectrum of her possible applications.