Your search keyword '"racing car"' showing total 93 results

1. Computational Study on the Diffuser of Formula Racing Car

Author

Hassaan, Md., Dewivedi, Satyam, Khurshid, Hammad, Warsi, Gulam Hasnain, Alam, Mansha, Rahim, Abdur, Chaari, Fakher, Series Editor, Gherardini, Francesco, Series Editor, Ivanov, Vitalii, Series Editor, Cavas-Martínez, Francisco, Editorial Board Member, di Mare, Francesca, Editorial Board Member, Haddar, Mohamed, Editorial Board Member, Kwon, Young W., Editorial Board Member, Trojanowska, Justyna, Editorial Board Member, Xu, Jinyang, Editorial Board Member, Shukla, Anoop Kumar, editor, Sharma, Bhupendra Prakash, editor, Arabkoohsar, Ahmad, editor, and Kumar, Pradeep, editor

Published

2023

2. The Effect of Vibrations from Racing Cars on the Human Body in FORMULA STUDENT Races.

Author

Itu, Calin and Sorin, Vlase

Subjects

HUMAN body, HUMAN beings, SCHOOL contests, FINITE element method

Abstract

Featured Application: The results obtained in the study were used by the designers of the racing car with which the Transilvania University of Brașov participated in the Student Formula competitions. During car races, strong vibrations appear in the chassis of the vehicle, due to the high power created by the engine which are then transmitted and, therefore, affect the driver's condition. The study of these vibrations is a subject frequently addressed by researchers, analyzing the influence of different parameters on the forces to which the pilot's body or certain sensitive body parts are subjected. In this paper, we analyze the particular case of a racing car made to meet safety requirements in the event of an accident. For the analysis of the forced vibrations induced by the running track, the finite element method was used. This method proved to be a useful and stable modeling and analysis method, validated by practical applications. A standard-equipped racing car with a mannequin inside was studied. Once the natural frequencies of the structure were determined, the response of some points of the mannequin's body to the movement caused by the running track or the engine was analyzed. Modeling and discretization were performed using well-known classical procedures. The obtained results revealed the parameters that can negatively influence the body of the mannequin which were communicated to the design team. The conclusion of this study is a racing car that was successfully used in Formula Student competitions. [ABSTRACT FROM AUTHOR]

Published

2023

3. 基于经验迁移的赛车学习预测控制研究.

Author

程相超, 黄景涛, and 宋书中

Subjects

MODEL car racing, RACING automobiles, COORDINATE transformations, TRAFFIC violations, AUTOMOBILE travel

Abstract

Copyright of Control Theory & Applications / Kongzhi Lilun Yu Yinyong is the property of Editorial Department of Control Theory & Applications and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2023

4. The Effect of Vibrations from Racing Cars on the Human Body in FORMULA STUDENT Races

Author

Calin Itu and Vlase Sorin

Subjects

racing car, eigenvalues, eigenmodes, Formula Student, chassis, forced vibration, Technology, Engineering (General). Civil engineering (General), TA1-2040, Biology (General), QH301-705.5, Physics, QC1-999, Chemistry, QD1-999

Abstract

During car races, strong vibrations appear in the chassis of the vehicle, due to the high power created by the engine which are then transmitted and, therefore, affect the driver’s condition. The study of these vibrations is a subject frequently addressed by researchers, analyzing the influence of different parameters on the forces to which the pilot’s body or certain sensitive body parts are subjected. In this paper, we analyze the particular case of a racing car made to meet safety requirements in the event of an accident. For the analysis of the forced vibrations induced by the running track, the finite element method was used. This method proved to be a useful and stable modeling and analysis method, validated by practical applications. A standard-equipped racing car with a mannequin inside was studied. Once the natural frequencies of the structure were determined, the response of some points of the mannequin’s body to the movement caused by the running track or the engine was analyzed. Modeling and discretization were performed using well-known classical procedures. The obtained results revealed the parameters that can negatively influence the body of the mannequin which were communicated to the design team. The conclusion of this study is a racing car that was successfully used in Formula Student competitions.

Published

2023

5. Flow and Thermal Analysis of a Racing Car Braking System.

Author

Cravero, Carlo and Marsano, Davide

Subjects

*BRAKE systems, *RACING automobiles, *AUTOMOBILE brakes, *THERMAL analysis, *FORMULA One automobiles, *HEAT transfer

Abstract

The braking system of a racing car is one of the main design challenges. The flow around and inside the wheel of an F1 car with all braking system components is analyzed in order to evaluate the heat transfer after a braking event. Very few studies have been published on this topic, mainly due to the high confidentiality level in the racing car sector. In the present work, using an actual geometry of an early 2000s F1 car, the braking system is simulated using a CFD approach. The boundary conditions for the wheel and brake system are taken from the simulation of a vehicle model with a front wing. Different heat transfer phenomena are progressively added to the model in order to understand their effects, including thermal convection only, radiation and conjugate heat transfer. Two different vehicle velocities are simulated to quantify and compare the heat removal after a braking event. The different heat transfer mechanisms have dramatic effects on the prediction of the brake cooling results, and these are quantified in order to understand the limitations of the simplified approaches. Finally, the influence of the ambient pressure at two different altitudes on the heat transfer from a braking event is studied. [ABSTRACT FROM AUTHOR]

Published

2022

6. COMPUTATIONAL AND EXPERIMENTAL STUDY OF THE STRENGTH OF A COMPOSITE DRIVE SHAFT

Author

Aleksandr BOLSHIKH

Subjects

composite materials, drive shafts, filament winding, racing car, Transportation engineering, TA1001-1280

Abstract

This computational and experimental work is dedicated to the development of promising designs of vehicle drive shafts made of polymer composite materials. This paper analyzes the existing models of drive shaftsof“Formula Student” class vehicles and substantiates the use of a carbon-fiber drive shaft with titanium tips. A manufacturing technology for such a product is also presented.Evaluation of structure performance under the action of ultimate loads was carried out by the finite element method. Prototypes of composite drive shafts were produced for further laboratoryand fieldtests. The author proposed a new design of composite drive shafts and a method for calculating the strength of the proposed design;the results were verified by bench laboratory and field tests. From the results ofthis work, conclusions about the performance of the developed structures and their applicability to racing cars were drawn.

Published

2021

7. Nonlinear Interval Optimization of Asymmetric Damper Parameters for a Racing Car.

Author

Chai, Tian, Han, Xu, Liu, Jie, Zhou, Bing, Lei, Fei, and Li, Fan

Subjects

INTERVAL analysis, TAYLOR'S series, AUTOMOBILES, RACING automobiles

Abstract

Uncertainties in parameters can affect racing car performance. In this study, a nonlinear interval suspension damping optimization method is proposed to improve the road holding of a racing car. To evaluate the dynamic responses of racing cars under a random road input and a bump input with interval uncertain parameters, a quarter car model with a two-stage asymmetric damper is established. Then, a quadratic approximation model with second derivative terms is developed by second-order Taylor series expansion and dimension reduction to calculate the nonlinear dynamic response of the vehicle. Interval analysis of the objective function and constraints is carried out using interval arithmetic to eliminate nesting optimization and make the optimization efficient. The results show that the proposed optimization method can improve road holding performance, effectively suppress the fluctuation range of the road holding performance evaluation index, and ensure the robustness of the design scheme. [ABSTRACT FROM AUTHOR]

Published

2021

8. Design and Fabrication of Go Kart

Author

Gupta, S.P., Srivastava, Chitranshu, Kumar, Hemant, Swaroop, Aadi, and Yadav, Subham Singh

Published

2019

9. CALCULATION OF THE STABILITY FLAT SHAPE BENDING OF THE RACING CAR FRAME STRUCTURAL ELEMENTS IN THE CIRCULAR ARCHES FORM.

Author

Orobey, V., Lymarenko, O., Bazhanova, A., Khamray, V., and Ponomarenko, A.

Subjects

RACING automobiles, STRUCTURAL frames, BOUNDARY value problems, LINEAR differential equations, STRUCTURAL stability, CIRCLE, APARTMENTS

Abstract

To increase the strength and rigidity of the characteristics, the articulated elements of structural racing cars have a large ratio of axial moments of inertia of the cross sections. The method of solving boundary value problems of stability of the flat form of bending of racing car structural elements in the form of circular arches with sections having several axes of symmetry is obtained. In Formula Class cars, these elements are most responsible for the safety of the pilot. The system of integration of two differential equations of stability of the specified constructive elements of a car racing frame in the form of circular arches or curvilinear cores is executed in work. The numerical-analytical method of limiting elements developed by Professor V.F. Orobey was used for the research. The article presents two variants of systems of fundamental orthonormal functions for differential equations of stability of circular arches with constant coefficients obtained during research. The problem of stability of structural elements of racing cars on the geometry corresponding to circular arches is solved by a numerical method acquiring rapid development; the method has theoretically proved exact decisions. The equation obtained in the course of research is applicable to the solution of very complex problems of stability of various structures containing rods delineated along the arc of a circle. The equations can be used to solve very complex problems of stability of various structures containing rods drawn along the arc of a circle. Such structural elements are used in many designs of industrial engineering. [ABSTRACT FROM AUTHOR]

Published

2021

10. Flow and Thermal Analysis of a Racing Car Braking System

Author

Carlo Cravero and Davide Marsano

Subjects

CFD, racing car, braking system, aerodynamics, conjugate heat transfer, Technology

Abstract

The braking system of a racing car is one of the main design challenges. The flow around and inside the wheel of an F1 car with all braking system components is analyzed in order to evaluate the heat transfer after a braking event. Very few studies have been published on this topic, mainly due to the high confidentiality level in the racing car sector. In the present work, using an actual geometry of an early 2000s F1 car, the braking system is simulated using a CFD approach. The boundary conditions for the wheel and brake system are taken from the simulation of a vehicle model with a front wing. Different heat transfer phenomena are progressively added to the model in order to understand their effects, including thermal convection only, radiation and conjugate heat transfer. Two different vehicle velocities are simulated to quantify and compare the heat removal after a braking event. The different heat transfer mechanisms have dramatic effects on the prediction of the brake cooling results, and these are quantified in order to understand the limitations of the simplified approaches. Finally, the influence of the ambient pressure at two different altitudes on the heat transfer from a braking event is studied.

Published

2022

11. COMPUTATIONAL AND EXPERIMENTAL STUDY OF THE STRENGTH OF A COMPOSITE DRIVE SHAFT.

Author

BOLSHIKH, Aleksandr

Subjects

*DRIVE shafts, *FINITE element method, *COMPOSITE materials, *MOTOR vehicle driving

Abstract

This computational and experimental work is dedicated to the development of promising designs of vehicle drive shafts made of polymer composite materials. This paper analyzes the existing models of drive shafts of "Formula Student" class vehicles and substantiates the use of a carbon-fiber drive shaft with titanium tips. A manufacturing technology for such a product is also presented. Evaluation of structure performance under the action of ultimate loads was carried out by the finite element method. Prototypes of composite drive shafts were produced for further laboratory and field tests. The author proposed a new design of composite drive shafts and a method for calculating the strength of the proposed design; the results were verified by bench laboratory and field tests. From the results of this work, conclusions about the performance of the developed structures and their applicability to racing cars were drawn. [ABSTRACT FROM AUTHOR]

Published

2021

12. 分布式驱动电动方程式赛车扭矩分配策略.

Author

周增城, 彭育辉, and 钟龙飞

Abstract

Copyright of Journal of Fuzhou University is the property of Journal of Fuzhou University, Editorial Department and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2020

13. The Influence of Front Wing Pressure Distribution on Wheel Wake Aerodynamics of a F1 Car

Author

Daniel Martins, João Correia, and André Silva

Subjects

Formula One, racing car, front wing, wheel, transient, CFD, Technology

Abstract

The present study focuses on investigating the aerodynamic interaction between a three-element wing and wheel in ground effect, following the Formula One regulation change set for 2022, among which is the simplification of the front wing. This was accomplished by conducting a three-dimensional computational fluid dynamics analysis, using a Detached-Eddy Simulation approach, on a simplified one-quarter model of a Formula One racing car. The main goal was to examine how changing the front wing pressure distribution, by changing the incidence of the second flap, affected the wheel wake. The flow investigation indicated that the wheel wake is influenced by the flap configuration, which is mainly due to the fact that different flap configurations produce different upwash flow fields, leading to a variation of the separation point on top of the tire. As the separation point moves rearwards, the downwash generated in the central region (for a vertical plane) of the wheel wake increases incrementally, leading to a resultant wake that is shorter and further apart. The force investigation showed that the proximity between the region of instability (i.e., vortex breakdown) and the wing’s trailing edge influences the behavior of the transient oscillations, regarding the forces acting on the wing: detecting higher drag force fluctuations, when compared to downforce fluctuations.

Published

2021

14. Aerodynamic Effect of the Gurney Flap on the Front Wing of a F1 Car and Flow Interactions with Car Components

Author

Mattia Basso, Carlo Cravero, and Davide Marsano

Subjects

racing car, front wing, gurney flap, CFD, Technology

Abstract

The design of a racing car needs several aerodynamic design steps in order to achieve high performance. Each component has an aerodynamic interaction with the others and high performance requires a good match between them. The front wing is undoubtedly one of the main components to determine car performance with a strong interaction with the downstream components. The Gurney Flap (GF) is a small appendix perpendicular to the pressure side of the front wing at the trailing edge that can dramatically improve the front wing performance. In the literature, the performance of a GF on a single profile is well documented, while in this paper the GF mounted on the front wing of a racing car has been investigated and the interactions through the 3D flow structures are discussed. The global drag and downforce performance on the main components of the vehicle have been examined by comparing the cases with and without a GF. The GF increases the downforce by about 24% compared to a limited increase in the drag force. A fluid dynamic analysis has been carried out to understand the physical mechanisms of the flow interaction induced to the other components. The GF, in fact, enhances the ground effect, by redistributing the flow that interacts differently with the other components i.e., the wheel zone.

Published

2021

15. Comprehensive View on Racing Car Upright Design and Manufacturing

Author

Marek Hunar, Lukas Jancar, David Krzikalla, David Kaprinay, and David Srnicek

Subjects

topology optimization, upright, 3D printing, additive manufacturing, formula student, racing car, Mathematics, QA1-939

Abstract

This paper deals with the design of an upright using a topological optimization. This type of optimization is a relatively young and rapidly evolving area of computational mechanics that seeks to make multiple material savings that cannot be achieved by conventional methods. The optimized upright was utilized in a fully functional prototype of the student formula within the Formula Student competition. The main objective of the optimization was to meet the requirements of the physical properties, weight, stiffness, and strength of the upright. The initial model of the upright was iteratively optimized using topological optimization and a finite element static analysis to obtain the final model. Using the finite element analysis, its behavior in operation within individual load cases was predicted. Symmetry was used to mirror the finished model to obtain the opposite upright of the other side of the car. Finally, the topologically optimized upright was compared with an upright made by conventional methods.

Published

2020

16. Development of Real-Time Condition Check Systems for Racing Cars Using WCDMA

Author

Song, Min-Seop, Baek, Sung-Hyun, Jang, Jong-Wook, Jung, Hoe-Kyung, editor, Kim, Jung Tae, editor, Sahama, Tony, editor, and Yang, Chung-Huang, editor

Published

2013

17. Calculation of mechanical characteristics and stress-strain state of suspension elements of a racing car

Subjects

гоночный болид, car suspension, формула студент, кинематика подвески, suspension kinematics, simulation of car dynamics, подвеска автомобиля, racing car, formula student, моделирование гоночного автомобиля

Abstract

В данной работе изложена сущность Ð¿Ð¾Ð´Ñ Ð¾Ð´Ð° к проектированию подвески гоночного болида и анализу ее Ð¼ÐµÑ Ð°Ð½Ð¸Ñ‡ÐµÑÐºÐ¸Ñ ÑÐ²Ð¾Ð¹ÑÑ‚Ð² и напряженно-деформированного состояния. Объектом исследования являлся модель гоночного болида и отдельные его узлы. Задачи, которые решались в Ñ Ð¾Ð´Ðµ работы:Проведение моделирования Ð´Ð¸Ð½Ð°Ð¼Ð¸Ñ‡ÐµÑÐºÐ¸Ñ Ð¸ÑÐ¿Ñ‹Ñ‚Ð°Ð½Ð¸Ð¹ с помощью программного пакета ADAMS. Выполнение прочностного расчета и анализа усталостного поведения элементов подвески в программном пакете ANSYS. Изучение Ñ‚ÐµÑ Ð½Ð¾Ð»Ð¾Ð³Ð¸Ð¸ по созданию математической модели шины на основе ÑÐ¼Ð¿Ð¸Ñ€Ð¸Ñ‡ÐµÑÐºÐ¸Ñ Ð´Ð°Ð½Ð½Ñ‹Ñ .В качестве Ð¸ÑÑ Ð¾Ð´Ð½Ñ‹Ñ Ð´Ð°Ð½Ð½Ñ‹Ñ Ð´Ð»Ñ проведения исследований, были использованы результаты испытания шин, Ð¸ÑÑ Ð¾Ð´Ð½Ð°Ñ модель объекта, а также требуемые Ñ Ð°Ñ€Ð°ÐºÑ‚ÐµÑ€Ð¸ÑÑ‚Ð¸ÐºÐ¸ элементов, Ð½ÐµÐ¾Ð±Ñ Ð¾Ð´Ð¸Ð¼Ñ‹Ðµ для анализов.Для решения Ð¿Ð¾ÑÑ‚Ð°Ð²Ð»ÐµÐ½Ð½Ñ‹Ñ Ð·Ð°Ð´Ð°Ñ‡ были использованы: метод конечно-элементного моделирования, а также методы решения задач нелинейной динамики для параметрической модели.В результате была получена модель объекта, с улучшенными по сравнению с Ð¸ÑÑ Ð¾Ð´Ð½Ð¾Ð¹ версией Ñ Ð°Ñ€Ð°ÐºÑ‚ÐµÑ€Ð¸ÑÑ‚Ð¸ÐºÐ°Ð¼Ð¸, а также подтверждена ее работоспособность и пригодность для участия в ÑÐ¾Ñ€ÐµÐ²Ð½Ð¾Ð²Ð°Ð½Ð¸ÑÑ .Â, In the given work the essence of the approach to the design of the suspension of a racing car and the analysis of its mechanical properties and stress-strain state. The object of the study was a racing car and its individual components.Tasks that were solved during development:Simulation of dynamic tests using the ADAMS software package.Performing strength calculation and analysis of the fatigue behavior of suspension elements in the ANSYS software package.Study of technology for creating a mathematical model of a tire based on empirical data.As the initial data for the research, the tire test results, the initial model of the object and required characteristics of the elements necessary for the analyses were used.To solve the tasks, the method of finite element analysis was used, as well as methods for solving nonlinear dynamics problems for a parametric model.As a result, a model of the object was obtained, with improved characteristics compared to the original version, and its operability and suitability for participation in competitions was confirmed.

Published

2022

18. Aerodynamics of a rear wing on racing cars with DRS (Drag Reduction System)

Author

Lidón Madrigal, Pablo

Subjects

Lift, Túnel de viento, Airfoil, Racing car, Aerodinámica, Rear wing, Downforce, Efecto suelo, Flujo, FIA, Aerodynamics, Resistencia, Fluid mechanics, Coche competición, Aerodyamic efficiency, Flow, Perfil, Sustentación, Drag, Eficiencia aerodinámica, MAQUINAS Y MOTORES TERMICOS, Ground effect, DRS, Grado en Ingeniería Aeroespacial-Grau en Enginyeria Aeroespacial, Mecánica fluidos, CFD, Wind tunnel, Alerón

Abstract

[ES] El objetivo del presente trabajo es el diseño y análisis aerodinámico de alerones traseros con sistema DRS (Drag Reduction System) en diferentes posiciones. El primero de ellos diseñado con perfiles NACA y el segundo con perfiles propios de coches de competición en la Formula 1. El estudio comprenderá un análisis teórico mediante simulación de flujo CFD junto con su justificación experimental en el túnel de viento. Además, se estudiará la influencia del mismo en diferentes circuitos de competición para argumentar su implementación., [EN] The aim of this project is the design and aerodynamics of rear wings with DRS (Drag Reduction System) in different positions. The first of them is designed with NACA profiles from F1 cars. The study will compile a theoretical analysis through a CFD simulation flow with its experimental justification in the wind tunnel. What it¿s more, the influence of it in different competition circuits to arise its implementation will be studied.

Published

2022

19. AERODYNAMIC IMPROVEMENT OF KhADI 33 RACING CAR RADIATOR COMPARTMENT

Author

A. Avershyn

Subjects

Racing car, Radiator compartment, Aerodynamic characteristics, Motor vehicles. Aeronautics. Astronautics, TL1-4050

Abstract

Aerodynamic characteristics of radiator compartment of KhADI 33 racing car on the basis of the decision of the interfaced problem of internal and external aerodynamics are numerically investigated. The rational variant of radiator compartment which is characterized by high throughput and low level of non-uniformity of speed field at the input is offered.

Published

2011

20. Suspension Kinematics Study of the “Formula SAE” Sports Car.

Author

Chepkasov, S., Markin, G., and Akulova, A.

Subjects

AUTOMOBILE springs & suspension design & construction, KINEMATICS, SPORTS cars, MATHEMATICAL models, AUTOMOBILE springs & suspension equipment

Abstract

In this article the design of the suspension of a sports car with the class “FORMULA SAE” is considered. A suspension double wishbone is taken as the basis. The main requirements to the characteristics of the suspension of the car of this class are formulated. Calculated suspension scheme is adduced. The mathematical model for determining the position of the suspension depending on the angle of the upper arm has been drawn up. The analysis and the choice of the geometric parameters of the suspension of a sports car with the class «FORMULA SAE» were carried out. [ABSTRACT FROM AUTHOR]

Published

2016

21. Aerodynamic characteristics of a wing-and-flap configuration in ground effect and yaw.

Author

Roberts, Luke S., Correia, Joao, Finnis, Mark V., and Knowles, Kevin

Subjects

WIND tunnel testing, COMPUTATIONAL fluid dynamics, RACING automobiles -- Aerodynamics

Abstract

The influence of the yaw angle on a model representative of a monoposto racing car’s front wing and nose section operating in close proximity to the ground is discussed. The yawed condition is representative of a car operating in a crosswind or with side-slip while cornering. Because of the need for downforce in corners rather than on a straight, it is standard practice to test a racing car at various orientations of yaw, pitch and roll quasi-statically. Wind tunnel testing with a 50%-scale model at a unit Reynolds number of 1.69 × 106 was used to investigate the forces and the surface flow structures. The results were then used to validate simulations with the three-equation k–kL–ω transitional turbulence model to observe the surface pressures and the wake structures. It was found that a change in the surface pressure caused asymmetric loading of the wing, the strengthening or inhibiting of vortices depending on their rotational sense and an overall reduction in both the downforce and the drag of the wing; all these were amplified as the yaw angle was increased or the ground clearance reduced. The fundamental aerodynamic flow features of a racing car’s front wing operating at yaw are established. [ABSTRACT FROM AUTHOR]

Published

2016

22. Diseño e implementación de un sistema electrónico para el control del balance aerodinámico en un coche de competición

Author

Alcañiz Fillol, Miguel, Masot Peris, Rafael, Universitat Politècnica de València. Departamento de Ingeniería Electrónica - Departament d'Enginyeria Electrònica, Universitat Politècnica de València. Escuela Técnica Superior de Ingeniería del Diseño - Escola Tècnica Superior d'Enginyeria del Disseny, Roldán Caselles, Guillermo, Alcañiz Fillol, Miguel, Masot Peris, Rafael, Universitat Politècnica de València. Departamento de Ingeniería Electrónica - Departament d'Enginyeria Electrònica, Universitat Politècnica de València. Escuela Técnica Superior de Ingeniería del Diseño - Escola Tècnica Superior d'Enginyeria del Disseny, and Roldán Caselles, Guillermo

Abstract

[ES] El presente trabajo se centra en el diseño y la implementación de un sistema de control para el balance aerodinámico de un vehículo de competición en la categoría de Formula SAE, desarrollado en la Universidad Politécnica de Valencia, durante la temporada 2020-2021, el FSUPV-08. El objetivo es el diseño del sistema electrónico y la correspondiente placa de circuito impreso (PCB). Este sistema se integrará en la red electrónica del vehículo y controlará los flaps principales del alerón delantero mediante dos servomotores. Este trabajo se basa en simulaciones aerodinámicas previas, desarrolladas en CFD mediante la herramienta de ANSYS. Dichas simulaciones han permitido determinar, en función de la velocidad del vehículo, los ángulos de ataque variables en los flaps principales del alerón delantero, con el fin de mejorar su comportamiento dinámico. El circuito electrónico incorporará un microcontrolador ARM Cortex-M4 de 32 bits que, en base a los resultados de la simulación y el sensado de la velocidad del vehículo, establecerá la posición de los servomotores mediante señales moduladas por anchura de pulso (PWM).

Published

2021

23. Formula-SAE Racing Car: Experimental and Numerical Analysis of the External Aerodynamics.

Author

Mariani, Francesco, Poggiani, Claudio, Risi, Francesco, and Scappaticci, Lorenzo

Abstract

The present work aims to improve the external fluid-dynamics of the first prototype of the Formula-SAE (Society of Automotive Engineers) race car of the University of Perugia. In the first phase, the study concentrates its attention on the nose of the prototype; the latter has been tested in the wind tunnel of the Department of Industrial Engineering of the University of Perugia and the acquired experimental data have been used to calibrate the models used in the CFD/3D analysis. At the same time, with the goal of decreasing the vehicle's resistance and to increase its down-force, a comparative numerical analysis was performed. The results obtained by the simulation of the complete original prototype (model A ), are compared with those obtained from the model B , obtained redesigning some particulars of the model A or adding some appropriate aerodynamic elements such as: front wing, headrest, rear engine hood and aerodynamic extractor. The presented results show a remarkable improvement of the parameters above mentioned. For clarity, the model A is the one that participated at the international competition of Varano ( Parma- Italy ), 2013. [ABSTRACT FROM AUTHOR]

Published

2015

24. Diseño del sistema de control e información de un coche de FSAE

Author

Montalva Subirats, José Miguel, Universitat Politècnica de València. Departamento de Ingeniería de la Construcción y de Proyectos de Ingeniería Civil - Departament d'Enginyeria de la Construcció i de Projectes d'Enginyeria Civil, Universitat Politècnica de València. Escuela Técnica Superior de Ingenieros Industriales - Escola Tècnica Superior d'Enginyers Industrials, Fuster Llamazares, Teresa, Montalva Subirats, José Miguel, Universitat Politècnica de València. Departamento de Ingeniería de la Construcción y de Proyectos de Ingeniería Civil - Departament d'Enginyeria de la Construcció i de Projectes d'Enginyeria Civil, Universitat Politècnica de València. Escuela Técnica Superior de Ingenieros Industriales - Escola Tècnica Superior d'Enginyers Industrials, and Fuster Llamazares, Teresa

Abstract

[ES] El objetivo del trabajo a realizar es diseñar el sistema de control y de información de un coche eléctrico de Formula Student. El equipo de la escula se ha formado este año y el coche va a presentarse en la clase 2 de FSUK de 2018, como prototipo. Este proyecto se encarga de recoger los datos necesarios para conocer el estado del coche por medio de sensores y de tratarlos con microcontroladores con dos objetivos; almacenar información para poder estudiarla posteriormente y comunicarse con el controlador del motor, dándole los parámetros necesarios para que ajuste la comanda del motor a los requerimientos del piloto., [EN] The main goal of this work is to design of the control and information system of a Formula Studing electric racing car. The school team is brand new and the car will compete in the 2018 FSUK class II, as a prototype. This project is responsible of getting the relevant data to know the state of the car through sensors and treat the data with microcontrollers with to objectives; to store the data so and after race analysis can be done and to comunicate with the motor controller, sending him the necessary data so it can adjust the motor performace to the driver requirements.

Published

2020

25. Aerodynamic simulations of different surface structures of a monoposto (Formula Student)

Author

Hinterecker, Markus

Subjects

Heckflügel, Rennfahrzeug, Racing car, Downforce, Frontflügel, Strömungsablösung, Vortex generators, Aerodynamics, Golfballoberfläche, Vortex-Generatoren, Strömungslehre, Fluid mechanics, CFD-Simulation, Monoposto, Os.Car Racing, Flow separation, Grenzschicht, Abtriebskraft, FH Campus Vienna, Boundary layer, Rearwing, Flow resistance, Frontwing, FH Campus Wien, Strömungswiderstand, Aerodynamik, Golfball-surface

Abstract

Diese Arbeit beschäftigt sich mit der Konzeption, Konstruktion und Simulation verschiedener Oberflächenstrukturen oder Oberflächenmodifikationen von mehreren aerodynamisch relevanten Bauteilen des Rennwagens CR120, welcher von dem Formula Student Team der FH Campus Wien entwickelt und gefertigt wird. Zu Beginn werden die strömungsmechanischen Grundlagen erläutert und genauer beschrieben. Ebenso wird ein Einblick in die Grenzschichttheorie geschaffen, so dass ein Überblick möglich wird, inwiefern Modifikationen der Oberfläche von Aerodynamikkomponenten die Strömungseigenschaften des Bauteils und des gesamten Fahrzeugs verbessern könnten. Im Zuge dieser ersten Kapitel konnten bereits zwei vielversprechende Oberflächenstrukturen definiert werden, welche im Zuge der Arbeit weiter untersucht wurden. Hierfür wurden diese Veränderungen an den zu untersuchenden Baugruppen konstruktiv angebracht und daraufhin standardisierten Strömungssimulationen unterzogen. Ebenso wurden Referenzsimulationen von den unveränderten Baugruppen hergestellt, um einen quantitativen Vergleich zwischen den modifizierten und nicht modifizierten Baugruppen herstellen zu können. Somit konnte eine genaue Aussage getroffen werden, inwiefern diese Modifikationen das Strömungsverhalten der zu betrachtenden Baugruppen beeinflussen und ob diese in welcher Form am realen Fahrzeug appliziert werden könnten. This thesis focuses on the conception, design and simulation of different surface structures or surface modifications of various aerodynamically relevant components of the racing car CR120, which is developed and manufactured by the Formula Student Team of the FH Campus Wien. At the beginning, the fluid mechanical basics are explained and described in detail. Also, an insight into the boundary layer theory is created so that an overview can be created to what extent these surface modifications of aerodynamic components could improve the flow characteristics of the vehicle. In the process of researching of these topics, two promising surface structures could already be defined, which were to be further investigated during the thesis. To further investigate these structures, they were applied to the assemblies of the race car and then subjected to standardized flow simulations. Reference simulations of the unmodified assemblies were also carried out to enable a quantitative comparison to be made between the modified and unmodified assemblies. This enabled a precise statement to be made on the extent to which these modifications influence the flow behaviour of the assemblies and as to which way they could be applied to the real vehicle.

Published

2021

26. Design and thermal assessment of a high performance electric motor for racing applications

Author

Davide Barater, N. Matteazzi, L. Fazzini, Giovanni Franceschini, N. Rossi, G. L. Petti, and Stefano Nuzzo

Subjects

Electric motor, Engineering, PM motor, Launched, Racing car, 02 engineering and technology, Propulsion, 01 natural sciences, Automotive engineering, Propulsion system, Hardware_GENERAL, Propulsion motor, 0103 physical sciences, Thermal, 0202 electrical engineering, electronic engineering, information engineering, Brushless motor, Formula SAE, Championship, 010302 applied physics, business.industry, 020208 electrical & electronic engineering, Carbon footprint, business, Engineering design process

Abstract

Recently, an increasing attention in electric and hybrid vehicles is taking place. In order to raise awareness and technical knowledge on vehicles with reduced carbon footprint, several electric car competitions have been launched. Formula SAE is one of these, where talented students from different universities around the globe compete to design a fully electric racing car. This requires the development of high power density drives, with accurate electromagnetic and thermal analyses.This paper presents the design process and the thermal assessment of a high-performance electric motor intended for a FSAE racing car. The starting requirements for the electromagnetic and thermal designs are based on realistic available data from previous competitions and championship regulations.

Published

2021

27. Comprehensive view on racing car upright design and manufacturing

Author

Lukas Jancar, Marek Hunar, David Kaprinay, David Krzikalla, and David Srnicek

Subjects

0209 industrial biotechnology, Physics and Astronomy (miscellaneous), Computer science, General Mathematics, Formula Student, Physics::Medical Physics, ComputingMethodologies_IMAGEPROCESSINGANDCOMPUTERVISION, 3D printing, 02 engineering and technology, formula student, Physics::Popular Physics, 020901 industrial engineering & automation, Control theory, Computational mechanics, 0202 electrical engineering, electronic engineering, information engineering, Computer Science (miscellaneous), medicine, upright, racing car, topology optimization, Quantitative Biology::Neurons and Cognition, business.industry, lcsh:Mathematics, Topology optimization, Stiffness, Static analysis, lcsh:QA1-939, Finite element method, Symmetry (physics), Chemistry (miscellaneous), selective laser melting, 020201 artificial intelligence & image processing, medicine.symptom, aluminum alloy, business, additive manufacturing

Abstract

This paper deals with the design of an upright using a topological optimization. This type of optimization is a relatively young and rapidly evolving area of computational mechanics that seeks to make multiple material savings that cannot be achieved by conventional methods. The optimized upright was utilized in a fully functional prototype of the student formula within the Formula Student competition. The main objective of the optimization was to meet the requirements of the physical properties, weight, stiffness, and strength of the upright. The initial model of the upright was iteratively optimized using topological optimization and a finite element static analysis to obtain the final model. Using the finite element analysis, its behavior in operation within individual load cases was predicted. Symmetry was used to mirror the finished model to obtain the opposite upright of the other side of the car. Finally, the topologically optimized upright was compared with an upright made by conventional methods. Web of Science 12 6 art. no. 1020

Published

2020

28. The Influence of Front Wing Pressure Distribution on Wheel Wake Aerodynamics of a F1 Car

Author

André Silva, Daniel de Guarçoni Martins, João R. Correia, and uBibliorum

Subjects

Technology, Control and Optimization, 020209 energy, Racing car, Energy Engineering and Power Technology, 02 engineering and technology, Wake, Front wing, Ground effect (aerodynamics), transient, 0203 mechanical engineering, Separation points, 0202 electrical engineering, electronic engineering, information engineering, Formula One, Trailing edge, wheel, racing car, Electrical and Electronic Engineering, Engineering (miscellaneous), front wing, Detached eddy simulations, Wing, Vortex breakdown, Wakes, Transient, Renewable Energy, Sustainability and the Environment, CFD, Mechanics, Pressure distribution, Downforce, Drag, Vortex, Downwash, 020303 mechanical engineering & transports, Ground effect, Aerodynamic interactions, Wheel, Geology, Energy (miscellaneous)

Abstract

The present study focuses on investigating the aerodynamic interaction between a three-element wing and wheel in ground effect, following the Formula One regulation change set for 2022, among which is the simplification of the front wing. This was accomplished by conducting a three-dimensional computational fluid dynamics analysis, using a Detached-Eddy Simulation approach, on a simplified one-quarter model of a Formula One racing car. The main goal was to examine how changing the front wing pressure distribution, by changing the incidence of the second flap, affected the wheel wake. The flow investigation indicated that the wheel wake is influenced by the flap configuration, which is mainly due to the fact that different flap configurations produce different upwash flow fields, leading to a variation of the separation point on top of the tire. As the separation point moves rearwards, the downwash generated in the central region (for a vertical plane) of the wheel wake increases incrementally, leading to a resultant wake that is shorter and further apart. The force investigation showed that the proximity between the region of instability (i.e., vortex breakdown) and the wing’s trailing edge influences the behavior of the transient oscillations, regarding the forces acting on the wing: detecting higher drag force fluctuations, when compared to downforce fluctuations., Fundação para a Ciência e a Tecnologia

Published

2021

29. Investigation of fraudulent arson involving a racing car.

Author

Jones, M.

Published

2002

30. Development of a Planetary Reduction Gear for an In-Wheel Motor of an Electric Racing Car

Author

Kondakov, S.V., Larin, A.Ye., and Ulanov, A.G.

Subjects

calculation, 3D model, расчёт, Формула Студент SAE, 3D-модель, wheel motor, planetary reduction gear, electric car, УДК 629.113, планетарный редуктор, электромобиль, racing car, болид, мотор-колесо, Formula Student SAE

Abstract

Кондаков Сергей Владимирович, доктор технических наук, профессор кафедры «Колёсные и гусеничные машины», Южно-Уральский государственный университет, г. Челябинск, kondakovsv@susu.ac.ru. Ларин Алексей Евгеньевич, студент кафедры «Колёсные и гусеничные машины», ЮжноУральский государственный университет, г. Челябинск, rusfederation174@mail.ru. Уланов Александр Григорьевич, кандидат технических наук, доцент кафедры «Колёсные и гусеничные машины», Южно-Уральский государственный университет, г. Челябинск, ulanovag@susu.ac.ru. S.V. Kondakov, kondakovsv@susu.ac.ru, A.Ye. Larin, rusfederation174@mail.ru, A.G. Ulanov, ulanovag@susu.ac.ru South Ural State University, Chelyabinsk, Russian Federation В рамках студенческого проекта по разработке электрического болида в ЮжноУральском государственном университете в соответствии с техническим заданием был спроектирован планетарный редуктор будущего мотор-колеса. Этому предшествовали анализ и компоновка узла, разработка его кинематической схемы и составление уравнений кинематической связи. Тягово-динамический расчёт автомобиля показал, что передаточное число согласующего редуктора данного узла с учётом устанавливаемого электродвигателя должно быть равно 10. В итоге были определены числа зубьев зубчатых колес и их геометрические параметры, построена 3Б-модель планетарного редуктора. В качестве тяговых двигателей планируется использовать электрические машины комбинированного возбуждения. Предлагаемая электрическая машина имеет обращённое исполнение, что позволит в заданных габаритах получить максимальную электромагнитную мощность и хорошие удельные показатели. Вышеперечисленные показатели в нашем случае имеют очень важное значение, так как использование в приводе мотор-колес существенно увеличивает неподрессоренную массу электроболида, а это в свою очередь неизбежно скажется на его выходных характеристиках. При этом были учтены конструктивные особенности выбранного синхронного индукционного электродвигателя и все нюансы компоновки колёсно-ступичного узла, в том числе и габаритно-массовые, соблюдены условия соосности, соседства и сборки. В заключение была дана оценка коэффициента полезного действия планетарного редуктора проектируемого мотор-колеса. В настоящее время в студенческом конструкторском бюро Автотракторного факультета готовится сборочный чертеж спроектированного редуктора и его деталировка, а также дальнейшая передача пакета документов в производство. Макетный образец электрического болида планируется изготовить осенью 2019 года. Поставленные задачи более чем амбициозные. Within the student project on the electric car development, a planetary reduction gear for the future in-wheel motor was designed at South Ural State University in accordance with technical specifications. This was preceded by the analysis and layout of the unit, the development of its kinematic scheme, and the derivation of kinematic link equations. The car tractive and dynamic calculation showed that the reduction ratio of this unit matching gear, taking into account the installed electric motor, must be equal to 10. As a result, the teeth number of gear wheels and their geometrical parameters were determined and a 3D model of the planetary reducer was built. The constructive features of the selected synchronous induction motor and all the wheel-hub assembly peculiarities, including weight and dimensions, were taken into account. All the conditions of coaxiality, neighborhood and assembly were fulfilled. In conclusion, the efficiency of the planetary reduction gear for the in-wheel motor being designed was evaluated. At present, the designed reducer assembly drawing and its detailing, as well as documentation release for implementation, are in progress in the student design department of the Automobile and Tractor Faculty. Production of an electric car prototype model is technically challenging task which is planned to be implemented in the autumn of 2019.

Published

2019

31. Study on Input/Output Characteristics Calculation Method of Bell Crank Type Suspension by Three Dimensional Kinematics of Mechanism Theory

Subjects

Bell Crank, Pushrod, Suspension, Link Geometry, Vehicle Dynamics, Racing Car, Mechanism, Shock Absorber, Spring

Published

2016

32. The Influence of Front Wing Pressure Distribution on Wheel Wake Aerodynamics of a F1 Car.

Author

Martins, Daniel, Correia, João, and Silva, André

Subjects

*FORMULA One automobiles, *AERODYNAMICS, *COMPUTATIONAL fluid dynamics, *FLUTTER (Aerodynamics), *DRAG force, *RACING automobiles, *WHEELS

Abstract

The present study focuses on investigating the aerodynamic interaction between a three-element wing and wheel in ground effect, following the Formula One regulation change set for 2022, among which is the simplification of the front wing. This was accomplished by conducting a three-dimensional computational fluid dynamics analysis, using a Detached-Eddy Simulation approach, on a simplified one-quarter model of a Formula One racing car. The main goal was to examine how changing the front wing pressure distribution, by changing the incidence of the second flap, affected the wheel wake. The flow investigation indicated that the wheel wake is influenced by the flap configuration, which is mainly due to the fact that different flap configurations produce different upwash flow fields, leading to a variation of the separation point on top of the tire. As the separation point moves rearwards, the downwash generated in the central region (for a vertical plane) of the wheel wake increases incrementally, leading to a resultant wake that is shorter and further apart. The force investigation showed that the proximity between the region of instability (i.e., vortex breakdown) and the wing's trailing edge influences the behavior of the transient oscillations, regarding the forces acting on the wing: detecting higher drag force fluctuations, when compared to downforce fluctuations. [ABSTRACT FROM AUTHOR]

Published

2021

33. Diseño del sistema de control e información de un coche de FSAE

Author

Fuster Llamazares, Teresa

Subjects

Information sytem, INGENIERIA DE LA CONSTRUCCION, Sistema de control e información, Formula Student Electric, Racing car, FSAE, Control system, FSUK, Grado en Ingeniería en Tecnologías Industriales-Grau en Enginyeria en Tecnologies Industrials

Abstract

[ES] El objetivo del trabajo a realizar es diseñar el sistema de control y de información de un coche eléctrico de Formula Student. El equipo de la escula se ha formado este año y el coche va a presentarse en la clase 2 de FSUK de 2018, como prototipo. Este proyecto se encarga de recoger los datos necesarios para conocer el estado del coche por medio de sensores y de tratarlos con microcontroladores con dos objetivos; almacenar información para poder estudiarla posteriormente y comunicarse con el controlador del motor, dándole los parámetros necesarios para que ajuste la comanda del motor a los requerimientos del piloto., [EN] The main goal of this work is to design of the control and information system of a Formula Studing electric racing car. The school team is brand new and the car will compete in the 2018 FSUK class II, as a prototype. This project is responsible of getting the relevant data to know the state of the car through sensors and treat the data with microcontrollers with to objectives; to store the data so and after race analysis can be done and to comunicate with the motor controller, sending him the necessary data so it can adjust the motor performace to the driver requirements.

Published

2018

34. Aerodynamic Effect of the Gurney Flap on the Front Wing of a F1 Car and Flow Interactions with Car Components.

Author

Basso, Mattia, Cravero, Carlo, Marsano, Davide, and Barata, Jorge M. M.

Subjects

*AUTOMOBILES, *RACING automobiles, *DRAG force, *FORMULA One automobiles, *AIRPLANE wings

Abstract

The design of a racing car needs several aerodynamic design steps in order to achieve high performance. Each component has an aerodynamic interaction with the others and high performance requires a good match between them. The front wing is undoubtedly one of the main components to determine car performance with a strong interaction with the downstream components. The Gurney Flap (GF) is a small appendix perpendicular to the pressure side of the front wing at the trailing edge that can dramatically improve the front wing performance. In the literature, the performance of a GF on a single profile is well documented, while in this paper the GF mounted on the front wing of a racing car has been investigated and the interactions through the 3D flow structures are discussed. The global drag and downforce performance on the main components of the vehicle have been examined by comparing the cases with and without a GF. The GF increases the downforce by about 24% compared to a limited increase in the drag force. A fluid dynamic analysis has been carried out to understand the physical mechanisms of the flow interaction induced to the other components. The GF, in fact, enhances the ground effect, by redistributing the flow that interacts differently with the other components i.e., the wheel zone. [ABSTRACT FROM AUTHOR]

Published

2021

35. 小型レーシングカーの操舵力特性の改善

Subjects

Steering effort, Suspension, Racing car, Geometry, Steering, Vehicle dynamics, ComputingMilieux_MISCELLANEOUS

Abstract

Generally, in small-type racing cars, it is difficult to balance the vehicle dynamics capability and the steering effort characteristics because of the restriction of the vehicle specifications. By analyzing steering effort using a simple steering model and a mechanism analysis that uses 3D-CAD etc. on the vehicle with the double wishbone type suspension and the R&P type steering system, the researchers clarify a method that can coexist making the suspension/steering geometry the target characteristics and achieving the decrease of steering effort.

Published

2015

36. Analysis on Spring and Damper Characteristics of Suspension with Bell Crank Mechanism

Subjects

Bell Crank, Pushrod, Suspension, Link Geometry, Vehicle Dynamics, Racing Car, Mechanism, Shock Absorber, Spring

Abstract

The spring and damper characteristics of suspension systems have the key role for the maneuverability and stability as well as the riding comfort performance of a vehicle. Using a double wishbone type suspension with bell crank and pushrod as a model, this paper introduces a method for calculating suspension spring, shock absorber, anti-roll bar and pitting damper geometries using expressions derived directly from the kinematics of mechanism theory. Next, the authors derive expressions such as link lever ratio, spring constant converted into wheel center location, and roll stiffness by using the linear approximation functions obtained based on these calculation results and the balance equations of power derived from a dynamic model that simplifies bell crank surroundings. Finally, the authors clarify the relativity of these suspension characteristics and the geometries.

Published

2015

37. Comprehensive View on Racing Car Upright Design and Manufacturing.

Author

Hunar, Marek, Jancar, Lukas, Krzikalla, David, Kaprinay, David, and Srnicek, David

Subjects

*RACING automobiles, *FINITE element method, *COMPUTATIONAL mechanics, *SCHOOL contests, *TRUCK manufacturing

Abstract

This paper deals with the design of an upright using a topological optimization. This type of optimization is a relatively young and rapidly evolving area of computational mechanics that seeks to make multiple material savings that cannot be achieved by conventional methods. The optimized upright was utilized in a fully functional prototype of the student formula within the Formula Student competition. The main objective of the optimization was to meet the requirements of the physical properties, weight, stiffness, and strength of the upright. The initial model of the upright was iteratively optimized using topological optimization and a finite element static analysis to obtain the final model. Using the finite element analysis, its behavior in operation within individual load cases was predicted. Symmetry was used to mirror the finished model to obtain the opposite upright of the other side of the car. Finally, the topologically optimized upright was compared with an upright made by conventional methods. [ABSTRACT FROM AUTHOR]

Published

2020

38. Analiza in izdelava aerodinamike dirkalnika

Author

Štrakl, Mitja, Kolar, Jernej, Selič, Sanja, Marič, Rok, Zagoranski, Jure, Hedl, Vid Dominik, Brdnik, Rene, Fridman, Robert, Pongračič, Klemen, Markovič, Rok, Vrečko, Igor, and Ravnik, Jure

Subjects

aerodinamika, dirkalna vozila, racing car, udc:629.371.23:533.6, športni avtomobili, aerodynamics

Published

2015

39. Formula-SAE Racing Car: Experimental and Numerical Analysis of the External Aerodynamics

Author

Lorenzo Scappaticci, Francesco Mariani, Francesco Risi, and Claudio Poggiani

Subjects

Engineering, business.industry, Numerical analysis, formula SAE, Automotive industry, wind tunnel, Experimental data, Mechanical engineering, Aerodynamics, Computational fluid dynamics, drag force, Formula SAE, Energy(all), CFD, lift force, racing car, Drag, business, Wind tunnel

Abstract

The present work aims to improve the external fluid-dynamics of the first prototype of the Formula-SAE (Society of Automotive Engineers) race car of the University of Perugia. In the first phase, the study concentrates its attention on the nose of the prototype; the latter has been tested in the wind tunnel of the Department of Industrial Engineering of the University of Perugia and the acquired experimental data have been used to calibrate the models used in the CFD/3D analysis. At the same time, with the goal of decreasing the vehicle's resistance and to increase its down-force, a comparative numerical analysis was performed. The results obtained by the simulation of the complete original prototype (model A ), are compared with those obtained from the model B , obtained redesigning some particulars of the model A or adding some appropriate aerodynamic elements such as: front wing, headrest, rear engine hood and aerodynamic extractor. The presented results show a remarkable improvement of the parameters above mentioned. For clarity, the model A is the one that participated at the international competition of Varano ( Parma- Italy ), 2013.

Published

2015

40. Studies on the Tokai University System of Lean Burn Engine and a Racing Car for Le Mans

Subjects

Gasoline engine, Fast burn, Multi point ignition, Lean burn engine, Racing car, Homogeneous mixture, Le Mans, Racing engine

Published

2002

41. SAFETY PARAMETERS AND TECHNICAL PROPERTIES OF A RACE CAR IN THE EXCEPTIONAL CIRCUMSTANCES

Author

Divjak, Gregor and Šraml, Matjaž

Subjects

varnostni faktorji, dirkalno vozilo, technical characteristics, organizacija, organization, izračuni, udc:656.017:796.71(043.2), safety factors, racer, tehnične lastnosti, jump, calculations, skok, racing car, dirkač

Abstract

Diplomsko nalogo smo razdelili na tri dele. V prvem delu bomo preverili potrebna pooblastila in dovoljenja za izvedbo športnega dogodka, kjer bi postavili nov svetovni rekord. V tehnično-varnostnem delu bomo pogledali tehnične lastnosti reli vozila in rampe. V računskem delu bomo preverili izračune, ali je pravzaprav sploh možno še izboljšati trenutni rekord. Ugotovili smo, da je v Sloveniji možno izvesti takšen dogodek z vsemi potrebnimi dovoljenji in pooblastili. Izračuni so pokazali, da je možna izboljšava trenutnega rekorda, žal pa takšnega projekta ne moremo izpeljati samo, saj nimamo dovolj finančnih sredstev. The thesis was divided into three parts. In the first part, we verify the necessary authorizations and permits for the execution of a sporting event, where a new world record would be made. In the technical-safety section, we will look at the technical characteristics of rally vehicles and ramps. In the calculation part, we verify the calculations, if it is actually even possible to further improve the current record. We found that in Slovenia, it is possible to carry out such an event with all the necessary permits and authorizations. Calculations have shown that the potential improvement of the current record is possible, but unfortunately such a project can not be carried out only because we do not have sufficient financial resources.

Published

2014

42. Dynamics Performance Analysis with an Electric Powered Racing Car

Subjects

Electric Vehicle, Energy Efficiency, Racing Car, Dynamic Performance

Published

1997

43. Build your own racing car

Author

Verdult, E.

Subjects

racing car, drawing

Published

2013

44. Build your own racing car

Subjects

racing car, drawing

Published

2013

45. The DUT racing team; design, produce and race your own car

Subjects

racing car

Abstract

The DUT Racing Team consists of a group of sixty students that will design and produce a racing car for the Formula Student competition in the period of one academic year. Within the team there is a great variety of people, all from different faculties, nationalities and age. In addition there is an association of former members that ensures the continuity of the project. This make the DUT Racing Team the largest and oldest student project at the TU delft

Published

2011

46. The DUT racing team; design, produce and race your own car

Author

Kortenhorst, J.

Subjects

racing car

Abstract

The DUT Racing Team consists of a group of sixty students that will design and produce a racing car for the Formula Student competition in the period of one academic year. Within the team there is a great variety of people, all from different faculties, nationalities and age. In addition there is an association of former members that ensures the continuity of the project. This make the DUT Racing Team the largest and oldest student project at the TU delft

Published

2011

47. Build your own racing car

Author

Verdult, E. (author) and Verdult, E. (author)

Abstract

Delft University of Technology

Published

2013

48. Krmilni mehanizem malega dirkalnika : diplomska naloga univerzitetnega študijskega programa

Author

Vesenjak, Matej and Pehan, Stanislav

Subjects

motorna vozila, motor vehicles, krmilni mehanizen, steering mechanism, design, krmilna geometrija, racing car, udc:629.1-482:62-514.5, konstruiranje, steering geometry, dirkalnik

Published

2007

49. The DUT racing team; design, produce and race your own car

Author

Kortenhorst, J. (author) and Kortenhorst, J. (author)

Abstract

The DUT Racing Team consists of a group of sixty students that will design and produce a racing car for the Formula Student competition in the period of one academic year. Within the team there is a great variety of people, all from different faculties, nationalities and age. In addition there is an association of former members that ensures the continuity of the project. This make the DUT Racing Team the largest and oldest student project at the TU delft, Aerospace Engineering

Published

2011

50. Suspension System Testing and Tuning with the Use of a Four-Post Rig

Author

Marco Gadola, Danilo Cambiaghi, and David Vetturi

Subjects

Engineering, business.industry, seven poster, ride, vehicle dynamics, vehicle testing, Racing car, simulation, four poster, road simulator, Automotive engineering, testing, Vehicle dynamics, suspension, measurements, Suspension (vehicle), business

Published

2004