Carpets and floor coverings

The body engineer has a choice of materials, ranging

from carpeting of the Wilton type for prestige

vehicles, through polyamide and polypropylene

moulded needle felts, to rubber flooring for economy

versions. The main requirements of flooring are

wear resistance, colour fastness to light and water,

and adequate strength to enable the customer to

remove the flooring from the car without it suffering

damage. The method of manufacture of pile carpets

varies: in some cases the pile is bonded to hessian

backing; in other cases it is woven simultaneously

Table 4.12Undersealing and protection materials used in vehicle body repair work

Type Base material Application

Coatings for underbodies, Bitumen/rubber Coating for underbodies, wheel arches, new and repaired

spray type parts. Also a corrosion protection for vehicle underbodies

against elements such as moisture, road salt, road stone

chippings. Good adhesion, and durable at extreme

temperatures. Applied with a spray pistol

Rubber/resin Suitable for underbodies, wheel arches, front and rear

aprons, sills, new parts, repair sheets. Can be painted over

and has high abrasion resistance. Applied with a spray pistol

Wax Suitable for underbodies, touching up and subsequent

treatment of all protective coatings

Polymer wax Long-term corrosion protection even when thinly applied.

Has good flowing properties

Small-scale repair Rubber/bitumen Brushable coating, suitable for underbody and wheel arches.

application (brushable) High abrasion resistance and good sound deadening

properties

Road stone chip repair Synthetic/dispersion Good protection against stone chips and corrosion.

material Particularly suitable for front and rear aprons, sills, spoilers,

wheel arches

Metals and non-metals used in vehicle bodies 147

into the backing and then anchored in position with

either a rubber coating on the back surface or a vinyl

coating. Quality is normally controlled by characteristics

such as number of rows of tufts of pile per unit

length, height and weight of the free pile, overall

weight of the carpet, strength as determined by a

tensile test in both the warp and weft directions,

together with adhesion of pile if applicable. Rubber

flooring generally has a vinyl coating to provide

colour.

Leather (hide)

Large numbers of motor vehicle users all over the

world continue to specify hide upholstery when the

option is available, and will gladly pay the extra

cost involved for a material which defies complete

simulation. Great advances have been made in the

development of suitable substitutes, and the best of

the plasticized materials are to many people quite

undistinguishable by eye from leather. The unique

character of leather lies in its microstructure, the

like of which is not obtained in any manmade material.

Under a microscope leather can be seen to consist

of the hairy epidermis and under that the

corium, or bulk of the hide, this being the basis of

the leather as we know it. By virtue of the millions

of minute air spaces between the fibres and bundles

of fibres, leather is able to ‘breathe’. To the motorist

this means that leather does not get hot and uncomfortable

in warm weather or cold and inflexible in

winter, and although permeable to water vapour it

offers sufficient resistance if it is exposed to normal

liquids. It is also strongly resistant to soiling, and

when it does get dirty the dirt can usually be

removed fairly easily without special materials.

Unlike some plasticized materials, leather does not

appear to attract dirt and dust as a result of static

electricity. Many people, moreover, regard the distinctive

smell of leather as an asset, and this defies

imitation by manufacturers of substitute materials.

However, natural hide has to go through many complex

processes before it attains the form familiar to

the upholsterer trimmer or motorist.

Fabrics for interior trim

Vinyl coated fabrics are now well established as

trim material. Their vast superiority over the linseed

oil coatings, and later the nitrocellulose coatings, of

yesteryear are almost forgotten in the march of

progress. Vinyl coatings are now sufficiently familiar

for their merits to be taken for granted; nevertheless

they continue to provide a material which

for durability, uniformity and appearance at a reasonable

cost so far remains unsurpassed. The resin

polyvinyl chloride, the main ingredient of the coating,

became available in commercial quantities in

the early 1930s, and now a coating based on

polyvinyl chloride (PVC) is used for seating material

in this country. Although by tradition PVC is

produced with a simulated leather appearance, on

the Continent and particularly in the USA it is

widely used with fancy embosses, and patterns. An

extremely wide range of qualities is available, and

in recent years there has been an effort to achieve

some degree of rationalization. Additional qualities

are necessary for tilt covers, headlinings and hoods

for convertibles; the material for hooding convertibles

must be resistant to mildew, to shrinkage and

to wicking, this last term relating to the absorption

of water on the inside surface of the cloth from the

bottom edge of the hood. The characteristics necessary

to provide serviceability over the life of the

vehicle are the strength of the material under tension

and under tearing conditions; adhesion of the

coating to the backing cloth; resistance to flexing,

and resistance to cracking at low temperatures; low

friction, to enable the owner to slide on the seat;

colour fastness, soiling resistance and, of course,

wear resistance. In the case of the breathable

leathercloth, the air permeability of the fabric has to

be controlled.

Modern trends

The interior furnishing of a car is gaining in importance

within the automotive trade. In response stylists

are endeavouring to upgrade and soften the

interior, using fabrics with the appearance and feel

of textiles to appeal visually and functionally. This

has manifested itself in all areas of the car, including

the boot, seating, carpets, door trims and headliner

cover fabrics. In all four areas of fabric use in

car interiors (seating, door and side panels, bolsters

and headliners) fabrics are gaining ground against

exposed plastics. Both polyamide and polyester are

giving designers new scope for attractive colours

and variation in seating upholstery and in panels,

while fully meeting light fastness and other performance

standards.

148Repair of Vehicle Bodies

4.12 Plastics

Development

Celluloid might well qualify for the honour of being

the first plastic, though its inventor, Alexander

Parkes, was certainly not aware of that fact. He

made it around 1860 and patented his method for

making it in 1865. An American, John Hyatt, found

a way of solving the technical problems which

plagued Parkes, and he set up business in 1870 to

sell the same sort of material. He called it Celluloid

to indicate its raw material, cellulose.

In 1920 a German chemist, Hermann Staudinger,

put forward a theory about the chemical nature of a

whole group of substances, natural and synthetic.

He called them macromolecules; today we call

them polymers. His theory not only explained the

nature of plastics, but also indicated the ways in

which they could be made. It provided the foundation

for the world of plastics as we know it.

Polymerization

The raw materials for plastics production are natural

products such as cellulose, coal, oil, natural gas and

salt. In every case they are compounds of carbon (C)

and hydrogen (H). Oxygen (O), nitrogen (N),

chlorine (Cl) and sulphur (S) may also be present.

Oil, together with natural gas, is the most important

raw material for plastics production.

The term plastics in the broadest sense encompasses

(a) organic materials which are based on

(b) polymers which are produced by (c) the conversion

of natural products or by synthesis from primary

chemicals coming from oil, natural gas or coal.

The basic building blocks of plastics are monomers.

These are simple chemicals that can link together to

form long chains or polymers. The type of monomer

used and the way it polymerizes, or links together,

give a plastic its individual characteristics. Some

monomers form simple linear chains. In polyethylene,

for example, a typical chain of 50 000 ethylene

links is only about 0.02 mm long. Other monomers

form chains with side branches. Under certain circumstances,

the individual chains can link up with

each other to form a three-dimensional or crosslinked

structure with even greater strength and stability.

Cross-linking can be caused either chemically or

by irradiating the polymer.

To get the advantages of two different plastics,

two different monomers can be combined in a

copolymer. By combining the monomers in different

proportions and by different methods, a vast range

of different properties can be achieved (see Tables

4.13 and 4.14). The properties of plastics can also be

enhanced by mixing in other materials, such as

graphite or molybdenum disulphide (for lubrication),

glass fibre or carbon fibre (for stiffness), plasticizers

(to increase flexibility) and a range of other

additives (to make them resistant to heat and light).