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aerodynamic considerations

Aerodynamic Considerations

Aerodynamic factors, considered carefully, can improve many aspects of a vehicle. Some key aerodynamic considerations have been summarised here.

[(vi) refers to Road Vehicle Aerodynamic Design by R.H. Barnard]

With an object moving through a fluid, the wake is extremely significant. When considering family vehicles, the nature of the vehicle’s rear, in three dimensions, can make the difference between a low or a high coefficient of drag (Cd).

Improvements at the front can be made by ensuring the ‘front end is made as a smooth, continuous curve originating from the line of the front bumper’. On normal two and three box shapes, drag is often caused by high pressure just upstream of the front windscreen, ‘often with a separation bubble of recirculating air at the base of the screen’. The magnitude of this effect depends upon the windscreen ‘rake angle’. Making the screen more raked (ie. not as upright) ‘tends to reduce the pressure at the base of the screen, and to lower the drag’. However, much of this improvement arrives because a more sloped screen means a softer angle at the top where it meets the roof, keeping flow attached. Similar results can be achieved through a suitably curved roof.

Design in plan as well as profile, is significant. ‘Curving the windscreen in plan view modifies the flow patterns considerably … which reduces the extent and intensity of high pressure.’

The A-post is also an issue: ‘A strong outward cross-flow can occur towards the edges of the windscreen, tending to produce separated vortices around the A-posts.’ These effects can be minimised by smoothing the form of the A-post and increasing the curvature of both the A-post and the screen. Smoothing the transition from the body to door mirror is also significant as it can otherwise be a major source of drag and wind noise.

At the rear of vehicles, the ideal format is a long and gradual slope. As this is not practical, it has been found that ‘raising and/or lengthening the boot generally reduces the drag”.

Results of research state that drag due to rear slope angle will be at its ‘peak at 30º and minimum at around 10º’.

Increasing the curvature of the roofline will also reduce the drag coefficient. Benefits are gained by bringing the roof line down at the front and rear. Simply ‘bulging the roofline up’ however, may cause such an increase in frontal area that any gains may be negated.

In plan view, rounding corners and ‘all forward facing elements’ will reduce drag. Increases in curvature of the entire vehicle in plan will usually decrease drag provided that frontal area is not increased. ‘Tapering the rear in plan view’, usually from the rear wheel arch backwards, ‘can produce a significant reduction in drag’. Under the vehicle, a smooth surface is desirable as it can reduce both vehicle drag and surface friction drag. ‘For a body in moderate proximity to the ground, the ideal shape would have some curvature on the underside.’

In (vi), the author lists the following significant areas for thought when attempting to design a typical car (not a sports car or commercial vehicle):

  • Smooth unbroken contours with favourable pressure gradients as far back as practical should be used.
  • Strongly unfavourable pressure gradients at the rear should be avoided; some taper and rear end rounding should be used.
  • The form should produce negligible lift.

A If a hatchback configuration is required, the backlight angle should not be in the region of 30º, and if a notchback (saloon) is to be used, the effective slope angle (ie. the angle of a direct line between the roof and the highest, most rearward point) should also not be in the region of 30º.

  • The underbody should be as smooth and continuous as possible, and should sweep up slightly at the rear,
  • There should be no sharp angles (except where it is necessary to avoid cross-wind instability).
  • The front end should start at a low stagnation line, and curve up in a continuous line.
  • The front screen should be raked as much as is practical.
  • All body panels should have a minimal gap.
  • Glazing should be flush with the surface as much as possible.
  • All details such as door handles should be smoothly integrated within the contours.
  • Excrescences should be avoided as far as possible; windscreen wipers should park out of the airflow.
  • Minor items such as wheel trims and wing mirrors should be optimised using wind-tunnel testing.
  • The cooling system needs to be designed for low drag.

Although aerodynamic concerns are not as strong in this vehicle as they may be in a sports car, for example, the basic principles outlined here should be observed throughout the design process. Energy efficiency can be improved with low drag and low levels of wind noise improve passenger comfort.




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Plastics

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Car Design Online > Production > Materials > Plastics

Plastics

Plastics are the most commonly used type of polymer. Plastics include a very wide range of materials that can be used for everything from body panels to bonding metal. Below is a chart designed to make it easier to understand this group of materials. The list is not absolute but covers the principle automotive plastics.

Material Type Properties Uses Commercial Names
ABS

(Acrylonitrile Butadiene Styrene)
Thermoplastic Very strong and tough; good resistance to heat deformation; good electrical properties. Bumpers, dashboards, interior door panels; generally used because of its resistance to wear and tear and good deformation properties. Abson, Delta, Cycolac, Denka, Magnum, Novodur, Terluran, Toyolac
Acrylics

(poly-methylmethacrylate)
Thermoplastic Average mechanical properties but excellent for transmitting light with good resistance to weathering. Transparent features; previously used for dashboard lighting. Can be used with a light source to create interesting surfaces in low light.
Fluorocarbons

(PTFE / TFE)
Thermoplastic Very low coefficient of friction; very good electrical properies; chemically inert under virtually all conditions. Can be used up to 260ºC High-temp electronic components; anti-adhesive coatings; anti-corrosive seals; bearings. Used generally to keep surfaces protected, clean and smooth.


Polyamides

(nylons)
Thermoplastic Strong and tough; resistant to abrasion; low coeffiecient of friction; absorbs water and several other liquids. Bushes and light-loaded gears and bearings.


Polycarbonates Thermoplastic Transparent; low water absorption; ductile; good resistance to impact; average chemical resistance. Headlight lenses, non-shatter sports car windows. Hardness is insufficient for daily use for windows on production vehicles (surface deterioration).


Polyethylene

(PE)
Thermoplastic Low strength, poor resistance to weathering; low coefficient of friction; electrically insulating. Battery parts; not substantial enough for most automotive applications.
Polypropylene

(PP)
Thermoplastic Cheap; good fatigue strength and electrical properties; chemically inert; poor UV resistance; resistant to heat distortion. Bumpers
Polystyrene Thermoplastic Interior trim; cheap alternative for low demand transparent applications (eg. interior light lenses).
Vinyls

(usually Polyvinylchloride – PVC)
Thermoplastic
Polyester (PET / PETE) Thermoplastic

Epoxies Thermoset
Phenolics Thermoset
Polyesters Thermoset








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Materials

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Materials

This section looks at some of the key materials that are and can be used in the production of road going vehicles.

Topics

Polymers

Metals Composites


Recycling (Design for) Biodegrading

Key Materials in Brief

GRP – Glass Reinforced Polymer, also known as Glass Fibre

GRP is a low volume material. It is not suitable for mass production and is used most commonly in bespoke circumstances, such as hand built sports cars, kit cars and bus and train fascias. GRP is made using a manual layering technique; glass fibres are padded into layers of polymer in a mould. The polymer sets with an aerobic reaction, which means the mould is invariably tied up for a longer period of time than mass production would allow. The end result is a strong form that can be painted using cellulose paints in a traditonal way. Using a coloured gel-coat (the outermost layer), it is possible to pre-colour a component.

Pros:

Components can be formed relatively quickly with low-tooling time and cost. When using a disposable mould, complex shapes can be formed. GRP does not corrode.

Cons:

Only practical for low volume production. Production and preparation requires suitable safety precautions. Gel coat colouring is subject to colour fade. Poor performance impact, GRP is brittle and shatters rather than deforms like many common polymers.

Mild Steel

Mild steel is the most common material in use in the car industry. Despite the in-roads made by aluminium and polymers, steel still offers great value in mass production and more simpler production processes than its rivals. Improved galvanising and painting techniques mean that steel is holding more ground than ever before in terms of corrosion, one of its biggest problems. Steel is cheap to obtain by comparison to Aluminium and is readily available through recycling.

Pros:

Cheap, available and well understood. Mild steel can be prepared and processed using traditional tooling and responds well to standard joining processes such as spot and seam welding as well as bolting. Steel’s simplicity and ubiquity make it easy to repair.

Cons:

Steel requires good preparation to ensure it does not corrode in the presence of air and water, especially in cold climates where salt is also present on roads. Steel is heavier than its immediate rivals and adds to vehicle weight; this affects fuel consumption and to a lesser extent momentum (in impact) and handling.

Aluminium

Aluminium is hailed by Audi as a suitable material for all elements of a vehicle’s body. Whilst it can be used to save weight and resist corrosion, it does have its own concerns. Firstly, slightly more complex TIG welding processes need to be used in production (and repair) making it (currently) more costly than steel to work with. Where space-frame construction is employed, aluminium is often bonded with epoxy which creates strong bonds with good force distribution but is very difficult to repair.

Pros:

Aluminium is light and resistant to corrosion. Large weight savings can be made when using aluminium for the engine block.

Cons:

Aluminium is currently more expensive to manufacture with than steel. Corrosion can still take place if aluminium is placed on a less reactive metal or exposed to salt. Less well-established joining and bonding techniques can make aluminium awkward to repair.

Polypropylene

Polypropylene, or PP, is commonly used in bumper construction and is increasingly proposed as an alternative to metal bodywork. PP offers great elastic and plastic deformation characteristics compared to metals – making it ideal for use in impact. A combination of hard skin and softer foam PP has been flagged as a good alternative to traditional bonnets (hoods) where pedestrian impact is a consideration. Polypropylene is a thermoplastic which means it can be heated and melted for recycling, making it more attractive to manufacturers responding to European Vehicle End-of-Life Directives. Once considerable down-side of this material is its rate of expansion and contraction in response to heat. Current tolerances in car shut lines cannot be sustained with PP as during the summer panels will expand more than metals and will shrink more than metals in winter.









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Materials

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Materials



This section looks at some of the key materials that are and can be used in the production of road going vehicles.

Topics

Polymers

Metals Composites

General



Resources

GE Plastics

DuPont








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Fibres / Fibers

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Car Design Online > Production > Materials > Fibres

Fibres / Fibers

Fibre polymers can be drawn into filaments of a length at least 100 times greater than the diameter. Fibres are typically used for textiles and are used extensively in automotive interior applications. Additionally aramid fibres are used in composite materials.



More information on carbon fibre.



Fibres have commonly been sourced from mineral supply but are increasingly being obtained from natural sources. This offers particular benefits when considering vehicle end-of-life requirements and reliance on oil.


Fibres in the Automotive Industry

Fibres are used in cars and other vehicles for a wide range of purposes from component manufacture to passenger safety.

Fibres

Carpeting/Flooring

Mats

Trim

Headliners


Aramid Fibres

Belts / hosing

Fibre optic & electromechanical cables

Gaskets

Friction linings (eg. brake pads / clutch plates)

Adhesives

Sealants

Resources



Natural Fibres in Automotive Applications

Plastic Optical Fibres in Cars









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Carbon Fibre / Carbon Fiber

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Car Design Online > Production > Materials > Carbon Fibre

Carbon Fibre / Carbon Fiber



Carbon fibre is a composite material made from embedding fibres of carbon in epoxy resin. The process, in its simplest form involves laminating layers of fibres (usually as matting) with epoxy before curing.

Carbon fibre has many particular advantages in weight and performance but is held back by expensive fabrication, repair and recycling processes. The beauty of carbon fibre is that it can be fabricated in such a way that directional performance (in terms of response to force applied) can be manipulated to give the best possible results in virtually every circumstance. Whilst a material such as steel will have desirable performance when subjected to forces in certain ways or from certain directions, weaknesses will remain. The ability to arrange fibres to suit the particular forces affecting a component mean more areas of weakness can be eliminated.



Carbon fibre is expensive to use for several key reasons:

  • The raw materials are complicated and thus costly to produce.
  • There is a relatively high level of wastage.
  • Automated manufacture is difficult as most of the performance benefits come from the way components are built by hand to best suit force-distribution across a component.
  • Fabrication and curing mean product cycle times and demand on resources are high.


Despite the significant production costs, carbon fibre is an extremely appealing material for high-performance applications where cost restrictions are not so tight. It is commonly stated that carbon fibre can offer the same tensile strength as steel for just 25% of the weight. This is subject to careful design and fabrication to ensure the best possible performance across a component.



In order to reduce costs, increase rates of production and produce more consistent results, some new processes are being introduced. In the Mercedes-Mclaren SLR this envolves producing blanks, moulds and utilising processes from the textile industry to weave fibres to create accurate, ready made elements.


"The longitudinal members of the front body structure consist of a central cross member and the encircling moulded part or internal web. The cross member comprises several layers of carbon fibre stitched together by a machine. After the form has been cut to shape, the web blank is inserted into a braided polystyrene core. This core element is clamped into a specially developed braiding machine that produces the longitudinal member from 25,000 ultra-fine carbon filaments that are unwound simultaneously from 48 reels. This process allows the fibres to be braided around the core at a precisely defined angle to create the desired contour. Several layers are overlapped in certain areas, depending on the thickness required." – Mercedes McLaren
Images courtesy & © DaimlerChrysler



Performance in Impact

Relatively little is known about carbon fibre in crash situations. Material failure is difficult to model due to the complex nature of its composition and the variance in its construction when produced by hand. Failure is non-elastic and very different to standard automotive metals. Reinforcements are used to modify the characteristics of components to improve strength or elastic deformation characteristics. The Mercedes Mclaren SLR uses a roof made of a carbon fibre foam sandwich to improve crash-worthiness.









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Automotive Manufacturing Processes

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Automotive Manufacturing Processes



Modern manufacturing and assembly processes, whilst highly refined and advanced, are still based in principle on the production-line pioneered by Ford for the Model T in the early years of vehicle mass production. Contemporary systems are fast, precise and now not only actuated by robots, they are increasingly setup and configured by computer.





Pressing



Body-in-White Assembly (BIW)

Following delivery of parts from the press shop the vehicle is assembled from the inside-out.

– Assembly of various modules, typically joined by cramping and spot welding.

Painting

Electro-coating

Drying

Base coat

Top coat

Drying unit

Conveyor to assembly

Final Assembly

Trim (including interior modules)

Powertrain

End of line detail assembly

Testing and inspection

Resources

World Auto Steel – covering all aspects of car production with steel.








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Automotive Production

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Automotive Production



Welcome to the automotive section of Car Design Online. This area addresses the demands and requirements of design for manufacture and covers key considerations such as materials, processes and production feasibility.







Materials

A look at some of the key materials used in automotive production including staples such as steel and more advanced composites such as carbon fibre.

Manufacturing Processes

From body-in-white to road-going vehicle, this section looks at the processes used in automotive manufacturing.



Global Production Figures

Car sales/production figures by manufacturer




The Mercedes SLR McLaren uses the latest carbon fibre technology

Resources

Siemens Automotive Production Portal

The Welding Institute








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Global Car Production

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Car Design Online > Production > Global Car Production Figures

Global Car Production



Listed here are the global sales figures for many well-known manufacturers. Whether a company’s information is listed here or not is a reflection of the ease of access to the necessary data, rather than any other consideration. We will endeavour to expand this section to include a greater number of companies in the future.



Figures are listed specifically for the trading name of the manufacturer without including its dependencies or subsidiaries (unless otherwise stated). See the footnotes for details of manufacturing groups and joint results.




Manufacturer 2002 2003 2004
Audi Brand Group 2 1,191,000 1,217,000
Aston Martin
Bentley
BMW Cars 913,225 928,151
BMW Group 1,057,344 1,104,916
BMW Motorcycles§ 92,599 92,962
Buick 6 432,017 336,788
Cadillac 6 199,748 216,090
Chevrolet 6 2,642,786 2,655,777
Chrysler Group 4 2,820,000 2,640,000
DaimlerChrysler Group 4,300,000
Fiat
Ford (Worldwide) 6,973,000 6,720,000
GM Cars (US) 2,063,875 1,960,682
GM Trucks (US) 2,790,140 2,795,721
Holden 9 178,392 175,412
Honda
Hummer 7 19,581 35,259
Jaguar
Jaguar (US) 61,204 54,655
Land Rover
Land Rover (US) 40,987 39,035
Lincoln 150,057
Mazda 8 936,371 1,068,400
Mercedes-Benz Group 5 1,232,300 1,216,900
Mini 144,119 176,465
Nissan 2,693,737 2,957,757
Oldsmobile 6 155,113 125,897
Opel
Pontiac 6 516,832 475,615
Renault (passenger cars) 1,902,322 1,896,128
Renault Group 1 2,404,889 2,389,022
Saab 120,831 131,706
Saab (US) 47,914
Saturn 6 280,248 271,157
Smart
Volkswagen 3 3,539,000 3,549,000
Volvo 406,112 415,046


1 – incorporates Dacia, Renault Samsung and Renault light commercial vehicles.

2 – Audi brand group incorporates Audi, Seat and Lamborghini.

3 – Volkswagen brand group incorporates VW passenger cars, Skoda, Bentley and Bugatti.

4 – Chrysler Group incorporates Chrysler, Dodge and Jeep brands.

5 – The Mercedes Car Group includes Mercedes-Benz, Maybach, smart, Mercedes-Benz AMG and Mercedes-Benz McLaren

6 – Part of GM Car (US)

7 – Part of GM Truck (US)

8 – Refers to ‘Key global Markets’ (Japan, the US, Canada, Europe, China, Australia, Thailand, New Zealand, Singapore, Taiwan, Hong Kong, Israel, Saudi Arabia, South Africa, Colombia, Chile, Venezuela and Puerto Rico)

9 – Passenger cars and light trucks








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