The quest for ever-greater fuel efficiency is driving auto manufacturers to extreme lengths to reduce the weight of their vehicles. Aluminum, carbon fiber and fiberglass are all being used to help meet stringent emissions standards. In its search for "enlightenment," Audi has announced it will introduce glass fiber-reinforced polymer (GFRP) springs in its vehicles before the end of the year.
The core of the spring is made up of fiberglass strands, impregnated with epoxy resin and twisted together. Audi then uses a machine to wrap additional strands of fiberglass around the core and cures the unit in an oven. The strands are wrapped across each other at a 45-degree angle, to allow the load to be equally distributed across the whole spring.
So what benefits do the GFRP springs hold over steel? To start with, they don't corrode, even after damage by stone chips, and they're not impacted by wheel washing chemicals. In areas with snowy, salted roads, there are huge potential benefits to ditching steel for fiberglass.
Another key advantage over traditional steel springs is weight. In an upper mid-size car, Audi claims each individual spring weighs almost 2.7 kg (6 lbs), whereas its GFRP units weigh just 1.6 kg (3.5 lb). This adds up to a saving of around 40 percent. While a saving of 4.4 kg (9.8 lb) may seem insignificant, every gram saved contributes to lower emissions and a better driving experience.
Speaking of driving experience, Audi also claims the GFRP springs can be "precisely tuned" for the task at hand, be that ride comfort or a sporty feel, which allows the benefits to be felt across its whole range of cars. To top the whole package off, and in keeping with the low-emissions benefit of weight saving, the GFRP springs take less energy to produce than traditional units.
Audi plans to debut the springs on an "upper mid-size car" (presumably its A6 or A7) by the end of 2014.
Source: Audi
I haven't heard of disproportionate problems with the fiberglass leaf springs.
Whilst a road spring failure is not necessarily too dangerous because the car will be able to proceed by riding on the bump stops, a failure could cause an accident, which in turn could cause fatalities. As for reliability, it will be tested exhaustively, both on a rig and on a pavé circuit with a considerable number of kerb strikes thrown in for good measure. There will also be a lot of whole vehicle testing in all sorts of climates and road conditions.
Considering the reduction in unsprung weight and what that means for ride comfort, I imagine that this is only the first of a range of components to be manufactured using this material.
Amongst other vehicles, Chevrolet Corvettes have had them for years and my wife's Nissan Serena has one.
However, all the examples I have seen have been leaf springs - a sadly underrated configuration that can save a huge amount of space and height.
For springs Composite have a natural dampening and quite steel does at 30% of the weight.
And proves there is no reason not to build an all composite car chassis/body at 50% of the weight with 2x's the strength in cost effective medium tech composites, not CF which is mostly costly hype.
Dziks, I can't believe you are in the industry making statements like that as I've been doing these in high tech racing boats, etc for 45 yrs now, not new at all.
I also have a 2x's stronger than steel at 50% of the weight body/chassis that also proves you are not correct.