DOCSLIB.ORG

Design of Formula One Racing Car

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
Design of Formula One Racing Car International Journal of Engineering Research & Technology (IJERT) ISSN: 2278-0181 Vol. 4 Issue 04, April-2015 Design of Formula One Racing Car Triya Nanalal Vadgama Mr. Arpit Patel, Student Assistant Professor Department of Aeronautical Engineering Department of Aeronautical Engineering Sardar Vallabhbhai Patel Institute of Technology, Vasad Sardar Vallabhbhai Patel Institute of Technology, Vasad Gujarat Technological University, Ahmedabad, India Gujarat Technological University, Ahmedabad, India Dr. Dipali Thakkar, Head & Professor Department of Aeronautical Engineering Sardar Vallabhbhai Patel Institute of Technology, Vasad Gujarat Technological University, Ahmedabad, India Abstract- A modern Formula One (F1) Racing Car has almost as affect the airflow, and placing a badge on a crucial element much in common with an aircraft as it does with an ordinary could produce a two-to-three percent difference in air road car. Aerodynamics has become a key to success in the sport pressure. Disrupted air flow can cause turbulence, which will and teams spend millions of dollars on research and produce drag to slow the car. F1 cars often have small development in the field each year for improving performance. 'winglets' before the rear wing, which 'clean up' complex air The aerodynamic designer has two primary concerns : i. the creation of downforce, to help push the car’s tyres flow in order to maximize down force. The scope of this onto the track and improve cornering forces, project includes : ii. to minimise the drag that occurs due to turbulence and i. Designing of F1 three-dimensional CAD model acts to slow down the car. using CATIA V5 R21 software. In this project, a Formula One race car will be designed using the CAD software CATIA V5R20. All the dimensions are based The CAD model will be rectified before simulating it. The on the standards laid down by the FIA (Fédération corrections are necessary to ensure an accurate representation Internationale de l'Automobile). The car design will be of the aerodynamic geometry of the car. These will be done enhanced to streamline the flow over the car. Various parts that in three steps: will be designed include the wheels, front and rear airfoils, front and rear wings, car body chassis, among other subassemblies. A i. Assembling missing components, driver will also be placed in a typical driving position inside the ii. Redesigning lost parts or parts that were missing, car. iii. Resizing components with accurate dimensions and features. Keywords- Formula One race car, Airfoil, Aerodynamics, Body chassis, driver. The internal geometry, such as the engine and transaxle, will I. INTRODUCTION not be included as the primary focus of this project is external flow. As such, the internal parts will be removed from the On the surface, automobile racing appears simply as a CAD model. popular sport. But in reality, racing serves as a proving ground for new technology and a battlefield for the giants of A. Formula One Background History automobile industry. Although human factors are frequently The Formula One (F1) World Championship is the publicized as the reason behind the success or failure of one highest class of single-seat auto racing in the world. It is racing team or another, engine power, tire adhesion, chassis sanctioned by the FIA (Fédération Internationale de design, and recently, aerodynamics probably play a very l'Automobile). Formula One cars can reach speeds upto 330 important role in winning this technology race. km/h. The FIA controls and regulates all the sizes and dimensions of Formula One car. These strict regulations led One of the most important aspects of Formula One (F1) to similarly-dimensioned cars. A typical car will be 463cm car design is aerodynamics. Creating down force, to hold the long, 180cm wide and 95cm high. car to the ground to improve cornering; and minimizing drag, which slows the car down are two primary concerns when Flexible bodywork, with the exception of the rear-wing, is designing the car. Modern F1 teams use expensive wind strictly prohibited. Moreover, any device, system or tunnels and computational fluid dynamics systems to analyze procedure which uses driver movement to alter the the effectiveness of an aerodynamic design for a car. In these aerodynamic characteristics of the car’s bodywork is strictly analyses, every surface of the car, including the driver's prohibited. Sections of bodywork, such as front wing end- helmet must be considered. Even an advertising sticker can IJERTV4IS040962 www.ijert.org` 702 (This work is licensed under a Creative Commons Attribution 4.0 International License.) International Journal of Engineering Research & Technology (IJERT) ISSN: 2278-0181 Vol. 4 Issue 04, April-2015 plates, are required to be sufficiently thick to prevent damage to tyres of other cars. B. Ferrari F10 Background The Ferrari F10 is built by Scuderia Ferrari Marlbolo. 1) Specifications : Chassis: Carbon fiber and honeycomb composite structure Gearbox: Ferrari 7-speed (+reverse) longitudinal gearbox Differential & gearbox: Limited slip differential, Semi-automatic sequential electronically controlled gearbox Brakes: Ventilated carbon fibre disc brakes Suspension: Independent suspension, push rod activated torsion springs, front and rear 2) Engine : Engine: type 056 Cylinders: V8 90° Cylinder Block: Cast Aluminium Fig. 3 Top View of F10 Number of Valves: 32, C. Aerodynamics Background Pneumatic Distribution Aerodynamics is a branch of dynamics concerned Total Displacement: 2398 Cm³ with studying the motion of air, particularly when it interacts Piston Bore: 98 Mm with a moving object. Aerodynamics is a subfield of fluid Weight: 95 Kg dynamics and gas dynamics, with much theory shared Injection: Magneti Marelli between them. It is often used synonymously with gas Digital Electronic Injection dynamics, with the difference being that gas dynamics Iginition: Magneti Marelli applies to all gases. Static Electronic Ignition Fuel: Shell V-Power Understanding the motion of air (often called a flow Lubricant: Shell Helix Ultra field) around an object enables the calculation of forces and moments acting on the object. Typical properties calculated 3) Dimensions : for a flow field include velocity, pressure, density and Wheelbase: 3050mm temperature as a function of position and time. By defining a Front Track: 1470mm control volume around the flow field, equations for the Rear Track: 1405mm conservation of mass, momentum, and energy can be defined Overall Length: 4545mm and used to solve for the properties. Overall Height: 959mm Overall Width: 1796mm Aerodynamics has become key to success in the Overall Weight: 600kg, Formula One sport and spends of millions of dollars on including driver and camera research and development in the field each year. The Wheels, Front And Rear: 13" aerodynamic design has two primary concerns. i. The creation of downforce to help push the car’s tires onto the track and improve the cornering force. ii. To minimizing the drag that caused by turbulence and act to slow the car down. The drag over a body can be minimized by streamlining it (smooth exterior surface). As a result, there will be potential improvements in fuel economy. [Fig.4 & 5] Fig. 1 Front View of F10 Fig. 4 Flow Over A Streamlined Body (Courtesy of Race Care Aerodynamics – By Joseph Katz) Fig. 2 Side View of F10 IJERTV4IS040962 www.ijert.org` 703 (This work is licensed under a Creative Commons Attribution 4.0 International License.) International Journal of Engineering Research & Technology (IJERT) ISSN: 2278-0181 Vol. 4 Issue 04, April-2015 Fig. 5 Aerodynamic Forces Fig. 8 Schematic description of the flow field over an open-wheel F1 race (Courtesy of Race Care Aerodynamics – By Joseph Katz) car. (Courtesy of Race Car Aerodynamics – By Joseph Katz) D. Selection of Airfoil NACA 4-series airfoils are the most widely used airfoils for Formula One race cars. The NACA four-digit wing sections define the profile by: i. First digit - maximum camber as percentage of the chord. ii. Second digit - the distance of maximum camber from the airfoil leading edge in tens of percentage of the chord. iii. Last two digits - maximum thickness of the airfoil as a percentage of the chord. Fig. 6 Schematic description of the “Ground Effect” that increases the aerodynamic lift of the wings when placed near the ground. 1) Front Wing Airfoil – NACA 4412 (Courtesy of Race Care Aerodynamics – By Joseph Katz) The Front Wing of a Formula One car creates about 25% of the total car’s downforce. This is one of the most widely used spoiler airfoil, but needs to be enhanced as per speed. Such a thicker airfoil is used to obtain the desired higher downforce from the front end of the car, at a given speed. Fig. 9 NAC A 4412 2) Rear Wing Airfoil – NACA 2408 Due to location of engine at the rear end of the car, more downforce is generated. Hence, to compensate for minimization of downforce from rear end, a thinner airfoil is Fig. 7 Schematic description of the effect of rear wing on the streamlines nearby a generic body. (Courtesy of Race Care Aerodynamics – By Joseph used. Thinner airfoil also helps to maintain the continuity of Katz) the flow without flow separation. Thus, NACA 2408 is employed at the rear end. An inverted airfoil to generate a negative lift force – Downforce. This leads to major improvements in race car performance, especially on tracks with numerous high-speed, unbanked turns. Aerodynamic downforce increases the tires’ cornering ability by increasing loads on the tires without Fig. 10 NACA 2408 increasing the vehicle’s weight. The result is increased cornering ability, with no weight penalty, which gives a reduction in lap times. IJERTV4IS040962 www.ijert.org` 704 (This work is licensed under a Creative Commons Attribution 4.0 International License.) International Journal of Engineering Research & Technology (IJERT) ISSN: 2278-0181 Vol. 4 Issue 04, April-2015 II. CAD (COMPUTER-AIDED DESIGN) MODEL DEVELOPMENT USING CATIA V5R20 A.
Load more

Recommended publications
  • Spare Parts EVOLUTION
    25702 FerrariA Enzort.Nr. 89154 25703 Ferrari Enzoitem no. 89154 25704 Williams F1 Team BMW FW24 Livery 2003 "No.3" 89157 25705 Williams F1 Team BMW FW24 Livery 2003 "No.4" 89157 Hinweise 25706 Ferrari F2002 V10 "No.1" 89159 Notes Änderungen und Irrtümer vorbehalten 1 - 44 status: Juni 2018 25707 Ferrari F2002 V10 "No.2" 89159 25708 Jaguar D-Type Mille Miglia 2001 ----- 25709 Jaguar D-Type SCCA '60 ----- 25710 Ferrari 166/212 MM, Mille Miglia '51 89162 89161 89163 89200 26362 26363 89107 --- 25711 Ferrari 166/212 MM, Mille Miglia '52 89162 89161 89163 89200 26362 26363 89107 --- Bezeichnung Description Übersicht - Ersatzteile / overview - spare parts EVOLUTION Kleinteile Accessories 89153 89155V 89200order- & 26362 26363 89107 --- Hinterachse 89153 89155 89200 26362Front & Rea 26363r axle 89107 --- 89185 90105 89200 26362 26363 89107 --- 89185 90105 89200 26362 26363 89107 --- 89158 89160 89206 26362 26363 89107 --- Reifen tires 89158 89160 89206 26362 26363 89107 --- 89196 89147 89200 26362 26363 89107 --- 89196 89147 89200 26362 26363 89107 --- Motor Schleifer contact brushes Leitkiel guide keel Spezialleitkiel guide keel for external tracks Platine ciruit board for upgrade DIGITAL 132 25713 FordA Mustangrt GT.N 350r. 89326 89190 89166 89200 26362 26363 89107 --- 25725 Ferrari 575 GTC Presentation Car item no. 89226 89207 25726 Ferrari 575 GTC JMB-Racing Estoril 2003 89247 89207 25727 Ferrari 512 BB LM NART 1979 89227Hin 89242weise 89218 89200 26362 26363 89107 --- Notes 25728 Ferrari 512 BB Beurlys LM 1979 89253 89242 89218 89200 26362
    [Show full text]
  • Formula 1 Race Car Performance Improvement by Optimization of the Aerodynamic Relationship Between the Front and Rear Wings
    The Pennsylvania State University The Graduate School College of Engineering FORMULA 1 RACE CAR PERFORMANCE IMPROVEMENT BY OPTIMIZATION OF THE AERODYNAMIC RELATIONSHIP BETWEEN THE FRONT AND REAR WINGS A Thesis in Aerospace Engineering by Unmukt Rajeev Bhatnagar © 2014 Unmukt Rajeev Bhatnagar Submitted in Partial Fulfillment of the Requirements for the Degree of Master of Science December 2014 The thesis of Unmukt R. Bhatnagar was reviewed and approved* by the following: Mark D. Maughmer Professor of Aerospace Engineering Thesis Adviser Sven Schmitz Assistant Professor of Aerospace Engineering George A. Lesieutre Professor of Aerospace Engineering Head of the Department of Aerospace Engineering *Signatures are on file in the Graduate School ii Abstract The sport of Formula 1 (F1) has been a proving ground for race fanatics and engineers for more than half a century. With every driver wanting to go faster and beat the previous best time, research and innovation in engineering of the car is really essential. Although higher speeds are the main criterion for determining the Formula 1 car’s aerodynamic setup, post the San Marino Grand Prix of 1994, the engineering research and development has also targeted for driver’s safety. The governing body of Formula 1, i.e. Fédération Internationale de l'Automobile (FIA) has made significant rule changes since this time, primarily targeting car safety and speed. Aerodynamic performance of a F1 car is currently one of the vital aspects of performance gain, as marginal gains are obtained due to engine and mechanical changes to the car. Thus, it has become the key to success in this sport, resulting in teams spending millions of dollars on research and development in this sector each year.
    [Show full text]
  • Davide Signed with Alpine F1 Team in January 2021 As
    ALPINE F1 TEAM PRESS PACK Already recognised for its records It is part of Groupe Renault’s Luca De Meo, CEO Groupe That’s the beauty of racing as In September 2020, Luca De Meo, and successes in endurance strategy to clearly position Renault: “It is a true joy to see a works team in Formula 1. announced the creation of Alpine F1 Team, and rallying, the Alpine name each of its brands. For Alpine, the powerful, vibrant Alpine We will compete against the naturally finds its place in the this is a key step to accelerate name on a Formula One car. biggest names, for spectacular a renaissance of Groupe Renault’s F1 team, high standards, prestige and the development and influence New colours, new managing car races made and followed one of F1’s most historic and successful. performance of Formula 1. The of the brand. Renault remains team, ambitious plans: it’s a new by cheering enthusiasts. I can’t Alpine brand, a symbol of sporting an integral part of the team, beginning, building on a 40-year wait for the season to start.” prowess, elegance and agility, with the hybrid power unit history. We’ll combine Alpine’s will be designated to the chassis retaining its Renault E-Tech values of authenticity, elegance and pay tribute to the expertise moniker and unique expertise and audacity with our in-house that gave birth to the A110. in hybrid powertrains. engineering & chassis expertise. ALPINE F1 TEAM | PRESS PACK | 2021 Alpine Today and Tomorrow As part of Groupe Renault’s strategic plan ‘Renaulution’, Alpine unveiled its long-term plans to position the brand at the forefront of Groupe Renault’s innovation.
    [Show full text]
  • Stock List Updated 28/09/2021
    1:43 Formula 1 - Stock List Updated 28/09/2021 Limited Price Model Year Description Manufacturer Manuf # Edition (AUD) F o r m u l a 1 , 2 a n d 3 Alfa Romeo 158 1950 Race car (25) (Oro Series) Brumm R036 35.00 Alfa Romeo 158 1950 L.Fagioli (12) 2nd Swiss GP Brumm S055 5000 40.00 Alfa Romeo 159 1951 Consalvo Sanesi (3) 6th British GP Minichamps 400511203 55.00 Alfa Romeo Ferrari C38 2019 K.Raikkonen (7) Bahrain GP Minichamps 447190007 222 135.00 Alfa Romeo Ferrari C39 2020 K.Raikkonen (7) Turkish GP Spark S6492 100.00 Alpha Tauri Honda AT01 2020 D.Kvyat (26) Austrian GP Minichamps 417200126 400 125.00 Alpha Tauri Honda AT01 2020 P.Gasly (10) 1st Italian GP Spark S6480 105.00 Alpha Tauri Honda AT01 2020 P.Gasly (10) 7th Austrian GP Spark S6468 100.00 Andrea Moda Judd S921 1992 P.McCathy (35) DNPQ Monaco GP Spark S3899 100.00 Arrows BMW A8 1986 M.Surer (17) Belgium GP "USF&G" Last F1 race Minichamps 400860017 75.00 Arrows Mugen FA13 1992 A.Suzuki (10) "Footwork" Onyx 146 25.00 Arrows Hart FA17 1996 R. Rosset (16) European GP Onyx 284 30.00 Arrows A20 1999 T.Takagi (15) show car Minichamps 430990084 25.00 Australian GP Event car 2001 Qantas AGP Event car Minichamps AC4010300 3000 40.00 Auto Union Tipo C 1936 R.Gemellate (6) Brumm R110 38.00 BAR Supertec 01 2000 J.Villeneuve test car Minichamps 430990120 40.00 BAR Honda 03 2001 J.Villeneuve (10) Minichamps 400010010 35.00 BAR Honda 005 2003 T.Sato collection (16) Japan GP standing driver Minichamps 518034316 35.00 BAR Honda 006 2004 J.
    [Show full text]
  • 2021 Formula 1 Technical Regulations
    2021 FORMULA 1 TECHNICAL REGULATIONS PUBLISHED ON 16 DECEMBER 2020 Issue 7 Convention: Black text: based on 2020 Technical Regulations – Issue 5 (19/06/2020) Pink text: changes for 2021 approved by the WMSC on 19/06/2020, 04/09/2020, 09/10/2020, 30/10/2020 and 16/12/2020 Green text: comments / not regulatory CONTENTS: Pages ARTICLE 1: DEFINITIONS 8 1.1 Formula One Car 1.2 Automobile 1.3 Land Vehicle 1.4 Bodywork 1.5 Wheel 1.6 Complete wheel 1.7 Automobile Make 1.8 Event 1.9 Weight 1.10 Cubic capacity 1.11 Pressure charging 1.12 Cockpit 1.13 Sprung suspension 1.14 Survival cell 1.15 Camera 1.16 Camera housing 1.17 Cockpit padding 1.18 Brake caliper 1.19 Electronically controlled 1.20 Open and closed sections 1.21 Power train 1.22 Power unit 1.23 Engine 1.24 Energy Recovery System (ERS) 1.25 Motor Generator Unit - Kinetic (MGU-K) 2021 Formula 1 Technical Regulations 1 16 December 2020 © 2020 Fédération Internationale de l’Automobile Issue 7 1.26 Motor Generator Unit - Heat (MGU-H) 1.27 Energy Store (ES) 1.28 Compressor inlet 1.29 Compressor outlet 1.30 Combustion chamber 1.31 Fuel injector 1.32 Auxiliary Oil Tank (AOT) 1.33 Engine exhaust system 1.34 Turbocharger (TC) 1.35 In-cylinder pressure sensor 1.36 High pressure Fuel pump 1.37 Fuel Flow meter 1.38 Ignition Coil 1.39 Ancillaries 1.40 Engine Plenum 1.41 ES cells 1.42 DC-DC Converter 1.43 Power Unit Control Electronics (PU-CE) 1.44 Valve Stem ARTICLE 2: GENERAL PRINCIPLES 13 2.1 Role of the FIA 2.2 Applicable regulations and amendments to the regulations 2.3 Dangerous construction 2.4
    [Show full text]
  • Formula Uno Auto Collection 2015 Periodicita': Settimanale
    FORMULA UNO AUTO COLLECTION 2015 PERIODICITA': SETTIMANALE PREZZO 1A USCITA€ 3,99 PREZZO 2A USCITA € 8,99 PREZZO USCITE SUCCESSIVE € 12,99 NUMERO USCITE PREVISTE: 200* *L’Editore si riserva la facoltà di variare il numero delle uscite periodiche complessive, nonché di modificare l’ordine e la sequenza delle singole uscite, comunicando con adeguato anticipo gli eventuali cambiamenti che saranno apportati al piano dell’opera. N° USCITA DATA EDICOLA Pilota Vettura 1 30/03/15 AYRTON SENNA McLAREN MP 4/4 - 1989 2 17/04/15 NIKI LAUDA FERRARI 312 T2 -1977 3 04/05/15 FERNANDO ALONSO RENAULT R25 -2005 4 18/05/15 LEWIS HAMILTON McLAREN MP 4/23 - 2008 5 01/06/15 EMERSON FITTIPALDI LOTUS 72 D - 1972 6 15/06/15 MICHAEL SCHUMACHER FERRARI F2001 - 2001 7 29/06/15 NELSON PIQUET BRABHAM BT 49 - 1981 8 13/07/15 ALAIN PROST WILLIAMS FW 15 C - 1993 9 27/07/15 AYRTON SENNA TOLEMAN TG 184 -1984 10 10/08/15 CARLOS PACE BRABHAM BT 44 B -1975 11 27/08/15 MICHAEL SCHUMACHER JORDAN 191 -1991 12 10/09/15 NIGEL MANSELL WILLIAMS FW 14B -1992 13 24/09/15 LEWIS HAMILTON MERCEDES F1 W05 - 2014 14 15/10/15 JENSON BUTTON BRAWN GP 01 -2009 15 29/10/15 SEBASTIAN VETTEL RED BULL RB9 - 2013 16 12/11/15 CLAY REGAZZONI FERRARI 312 B3 - 1975 17 26/11/15 MICHAEL SCHUMACHER BENETTON B 194 -1994 18 10/12/15 MICHAEL SCHUMACHER FERRARI F2002 -2002 19 24/12/15 VITTORIO BRAMBILLA MARCH 751 -1975 20 07/01/16 AYRTON SENNA McLAREN MP 4/8 -1993 21 21/01/16 SEBASTIAN VETTEL TORO ROSSO STR 3 -2008 22 04/02/16 JACKIE STEWART TYRRELL 006 - 1973 23 18/02/16 KIMI RAIKKONEN FERRARI F2007 -2007
    [Show full text]
  • Formula One Race Strategy Mclaren Racing Limited Sports Technology Mclaren Is a Registered Trademark of Mclaren Racing Limited
    Formula One Race Strategy McLaren Racing Limited Sports Technology McLaren is a registered trademark of McLaren Racing Limited INTRODUCTION We will solve this problem in three steps as follows: Step 1: How long will it take to reach the first pit stop? From the scenario, we have the following information: Fuel Consumption C = 3 kg/lap How much slower our lap E = 0.03 sec/ time is for every kg of fuel on (lap kg) board (also called the “weight effect”) Time to complete a lap with 1 t1 = 100.045 lap of fuel on board sec Figure 1: A Vodafone McLaren Mercedes driven by Lewis Hamilton Using this, we can calculate how much slower the McLaren Racing, the company behind Vodafone car goes for every lap’s worth of fuel we have on McLaren Mercedes, operates in the highly board. We call this the Fuel Laps Weight Effect competitive and technological environment of (W ) and this is calculated as follows: Formula One. McLaren Racing comprises a W = Fuel Laps Weight Effect multitude of administrative and engineering = Fuel Consumptio n ´ Weight Effect departments, ranging from vehicle design and aerodynamics, to materials science and the paint = 3 ´ 0.03 = 0 .0 9 sec/(lap lap of fuel) shop. As one of the most successful teams in the The extra time taken to complete a lap when we history of Formula One, McLaren has won more have fuel on board can be calculated as follows: Grand Prix than any other Constructor since it Extra time taken to complete lap due to fuel on board entered the sport in 1966.
    [Show full text]
  • Red Bull Racing 1:23.619 1:21.773 1:20.981 2 S
    2017 FIA Formula One™ World Championship FORMULA 1 GRAN PREMIO DE ESPAÑA PIRELLI 2017 12 – 14 May 2017 TABLE OF CONTENTS Time Schedule FORMULA 1 GRAN PREMIO DE ESPAÑA PIRELLI 2017 Welcome to Circuit de Barcelona-Catalunya The Circuit de Barcelona-Catalunya in detail Recommendations to get to Circuit de Barcelona-Catalunya Media Centre Operation Formula One Press Conference Schedule 2011/2016 Spanish Grand Prix results Media Contacts FORMULA 1 GRAN PREMIO DE ESPAÑA PIRELLI 2017 Officials 2017 Circuit de Barcelona-Catalunya Race Calendar 2017 FIA Formula One World Championship™ Calendar 2017 FIA Formula One World Championship™ Entry list 2017 FIA Formula One World Championship™ Classification Drivers and Teams Statistics 2017 FIA Formula One World Championship™: Australia, China, Bahrain and Russia Appendix The Formula One Spanish Grand Prix 1913-2016 Circuit general map, grandstands and giant screens Red Zones map TIME SCHEDULE THURSDAY, 11th May 13.00 Gates and Ticket Offices Opening 16.00 - 18.30 Formula One Pit Lane Walk (with 3-day or Sunday ticket) 18:00-18:30 Go Karting Karting driver demo meet & greet F1 Drivers FRIDAY, 12th May 08.00 Gates and Ticket Offices Opening 10.00 - 11.30 Formula One 1st Practice Session 12.00 - 12.45 FIA Formula 2 Practice Session 14.00 - 15.30 Formula One 2nd Practice Session 15.55 - 16.25 FIA Formula 2 Qualifying Session 16.45 - 17.30 GP3 Series Practice Session 17.50 - 18.35 Porsche Mobil 1 Supercup Practice Session SATURDAY, 13th May 08.00 Gates and Ticket Offices Opening 09.45 - 10.15 GP3 Series Qualifying
    [Show full text]
  • Investigation of Turbulence Created by Formula One™ Cars with the Aid of Numerical Fluid Dynamics and Optimization of Overtaking Potential
    Investigation of Turbulence Created by Formula One™ Cars with the Aid of Numerical Fluid Dynamics and Optimization of Overtaking Potential Milad Mafi Competence Centre, transtec AG, Tübingen, Germany Summary Formula One™ is the most successful racing series in the world. And with over 25 million television viewers per race it attracts many prominent sponsors who have invested over a billion euros in it, making them indispensable for Formula One™’s survival. In the last ten years the numbers of overtaking maneuvers in Formula One™ races have become rarer and rarer – changes in position now take place in the pit stop or as a result of defective parts. This has caused races to be less eventful, as reflected in falling TV viewing figures. Many sponsors have withdrawn their support and, should this trend continue, it would mean the end of Formula One™. The reason for the decreasing number of overtaking maneuvers, which were quite common in the nineteen-eighties, can be found in the aerodynamics of Formula One™ racing cars: During the age of turbo motors road holding, in racing jargon “grip” which is produced by the tires, the aerodynamics created down force resulting in extra grip. Like the tires, the proper functioning of which is restricted to a certain temperature range, the aerodynamics of a racing car depends on several factors, including the intensity of air turbulence. Laminar air flow is the basis for the efficient functioning of the wings and bodywork. The aerodynamics of modern Formula One™ cars produces a down force of roughly 25000 N, which corresponds to a gravitational force of 2.5 metric tons.
    [Show full text]
  • The Aerodynamics of a Formula One Car Front Cascade Wing During
    Journal of Advanced Research in Fluid Mechanics and Thermal Sciences 53, Issue 1 (2019) 53-60 Journal of Advanced Research in Fluid Mechanics and Thermal Sciences Journal homepage: www.akademiabaru.com/arfmts.html ISSN: 2289-7879 Aerodynamics of a Formula One Car Front Cascade Wing Open Access during Cornering Ahmed T. Raheem1, Azwan Sapit1,*, Akmal Nizam Mohammed2 1 Faculty of Mechanical & Manufacturing Engineering, Universiti Tun Hussein Onn Malaysia, 86400 Parit Raja, Batu Pahat, Johor, Malaysia 2 Centre for Energy and Industrial Environment Studies, Universiti Tun Hussein Onn Malaysia, 86400 Parit Raja, Batu Pahat, Johor, Malaysia ARTICLE INFO ABSTRACT Article history: The design for the aerodynamics of front wing based on cornering angle of a Formula- Received 10 October 2018 One car plays an important role on the car's performance. The cascade elements above Received in revised form 21 November 2018 the main front wing is enhanced with new and the deep winglets that manage the Accepted 5 December 2018 airflow for the rest of the car. The front wing cascades are attached with end plates at Available online 8 January 2019 the extremities of the front wing to reduce turbulence. However, when the car turns, the airflow behaviour on these cascades wings changes significantly. This paper presents the aerodynamic characteristics resulting from the cornering forces subjected on Formula One styled cascade wings. The study attempts to predict the down-force and drag-force acting on the front wing under the effect of airflow change in this area. In order to investigate the airflow behaviour, computational fluid dynamics (specifically the ANSYS software) was used to simulate selected cases with specific surface definitions and boundary conditions defined in a 3D domain.
    [Show full text]
  • Tires by Brand Revision Date : 2/24/2013
    Tires By Brand Revision Date : 2/24/2013 Part Alternate Part Manufacturer Application - Rear tires unless otherwise specified Number Numbers M16 / Artin American Thunder Stockers M16X Porsche & Mercedes DTM (Older Version) IG4101 NASCAR (Older Version) IG4102 Lamborghini / Lola / Saleen (Older Version) IG4103 M19 / Auto Art Ford Mustang GT / Mustang FR500C M19X Mitsubishi Lancer / Subaru Impreza WRC (fronts or rears) IG4201 Auto Art Lamborghini Murcialago (roadster & coupe) / Lamborghini IG4202 Gallardo (rears) Auto Art Lamborghini Murcialago (roadster & coupe) / Lamborghini IG4203 Gallardo (fronts) Audi R10 / Pescarolo / Peugeot 908 HDi FAP / Porsche Spyder / M37 / Avant Slot IG2007 Kremer Porsche K8 Spyder / Mirage GR8 M37X BRM All 1/24 Kit Cars IG3101 M07 / Carrera 1/32 Chevrolet Camaro 2007 Concept Car M07X M08 / 1/32 IMSA & LeMans 1/32 Audi R10 M08X M14 / 1/32 Porsche RS Spyder / AMG-Mercedes DTM / Porsche GT3 RSR M14X M17 / 1/32 Chevrolet Corvette C6R (non Spinner Wheels) M17X 1/32 (GTO / Charger 500 / Mustang GT / Corvette C6R) - ALL With M20 / "Spinner" Wheels / '41 Willys Coupe Leadsled M20X M22 / 1/32 Peugeot 908 RSR / Dodge Charger SRT8 Super Stocker M22X M24 / 1/32 Mustang GT (non Spinner Wheels) M24X M30 / 1/32 Porsche 917-30 Can Am M30X M31 / 1/32 Ferrari 599XX / Ferrari 458 Italia M31X M32 / 1/32 McLaren M20 Can Am M32X M40 / 1/32 Mercedes-Benz SLR McLaren GT / Mercedes SLS AMG M40X M41 / 1/32 Porsche GT3 RSR M41X M43 / 1/32 Audi R8 LMS M43X M44 / 1/32 BMW Z4 M44X M47 / 1/32 Red Bull / McLaren Mercedes MP4-25 / Ferrari F10
    [Show full text]
  • Who's Driving What 2019.Xlsx
    First Name Surname Who They Are What They're Driving/Riding Rauno Aaltonen Former World rally Championship competitor, known as "The Rally Professor" Mini Cooper on the Forest Rally Stage Jonny Adam Three-time British GT Champion, Le Mans class winner Aston Martin GTE Giacomo Agostini 15-time Motorcycle Grand Prix World Champion MV Agusta Rene Arnoux Formula 1 race winner Ferrari 126, Renault RS10 and Ferrari supercars Richard Attwood 1970 Le Mans 24hr winner, finished 2nd at 1968 Monaco Grand Prix Le Mans-winning Porsche 917 Rubens Barichello 11-time Grand Prix winner Brawn BGP-001 Sylvain Barrier Two-time FIM Superstock 1000 Cup champion and current BSB rider Ducati Panigale V4R Franco Battaini Former Grand Prix motorcycle racer Ducati Desmosidici X2 Derek Bell Five-time Le Mans 24hr winner, three-time Daytona 24hr winner, two-time World Sportscar Champion Abarth 3000 V8 Prototyp, Ferrari 365 GTB/4 Daytona, Abarth 2000 Sport SE01, Porsche 909 Bergspyder, P Steve Biagioni "Baggsy" - Professional Drifter, 2009 British Champion Nissan GT-R in The Arena Miki Biasion Two-time World Rally Champion Lancia Delta S4 Frank Biela Five-time Le Mans 24hr winner, 1991 DTM champion and 1996 BTCC champion Audi 200 Quattro Trans-Am Ben & Tom Birchall 2017 Sidecar World Champions and Isle of Man TT lap record holders TT sidecar Ken Block Legendary gymkhana driver, professional rally and rallycross driver Hoonitruck and Ford RS Cossie Stig Blomqvist 1984 World Rally Champion Audi Quattro A2 Valtteri Bottas Five-time Grand Prix winner and current Mercedes
    [Show full text]