These days nearly all mid and low-cost front-wheel drives use torsion beam rear suspension. A torsion beam suspension integrates both an anti-roll bar and the suspension arms – but what if you want to have a stiffer anti-roll function? Then it gets interesting…
Torsion Beam Rear Suspensions
In plan, a torsion beam suspension is usually shaped like a slightly odd-looking ‘H’.
Here is the view looking down on a torsion beam suspension. The green rectangles are the tyres. The purple blocks are pivot points attached to the body and the black lines are the suspension members. The thick blue line is the transverse torsion beam that is welded to each of the trailing arms.
Imagine both wheels pass over a single upwards bump – like a speed hump. Both wheels move upwards as the trailing arms rotate around their forward pivots. As the wheels move upwards, so does the torsion beam that links them.
Now imagine that only one wheel passes over an upwards bump - the other wheel just continues rolling long. (For the one-wheel bump think of a brick on the road!) This time only one trailing arm pivots around its forward point as the single wheel rises. But what happens to the torsion beam? If one wheel rises and the other does not, the torsion beam must bend (to accommodate the different heights to which the trailing arms have risen) and it must also twist (because a turning moment occurs).
The torsion beam is able to accommodate these movements because it is appropriately shaped from the correct steel grade to allow it to flex in both bending and torsion.
Let’s explore torsion (twist) in more detail. Here we’ve redesigned the suspension, with the torsion beam closer to the pivots. Now over one-wheel bumps the torsion beam twists more than it bends.
Now let’s move the torsion bar component down to the axle line. This time, when a single wheel passes over a bump, the beam is subject to more bending than twisting.
So the further the beam is positioned away from the pivot points, the greater the bending of the beam that occurs in one-wheel bumps.
So what’s this got to do with body roll?
First let’s start off with an imaginary suspension design that causes both wheels to always compress the springs by the same amount. So in this design, both back wheels must rise by the same amount, even if only one wheel is passing over a bump.
Think about that for a moment and you can see that such a car could not have any body roll! So why couldn’t a car with this suspension have body roll? That’s because normally when a car rolls, one spring is compressed and the other is extended – and in this mysterious suspension design, both spring movements are always the same.
Therefore, the more than you can configure a suspension system so that the left and right wheels always move up/down by the same amount, the less body roll that will occur when cornering.
And that’s just what an anti-roll bar tries to do – connect the action of the springs. Let’s take a look.
Anti-roll bars (sometimes called sway or stabiliser bars) reduce body roll. They do this by linking the two sides of the car – either at the front or at the rear.
Taking the case of a rear sway bar, the roll of the car is resisted by the torsional (twisting) action of the sway bar that attempts to compress the inside rear spring as much as the outside rear spring. In other words, a sway bar is effectively an extra torsional spring that connects the left and right wheels together – in this case, at the back of the car.
Anti-Roll Bars and Torsion Beam Rear Axles
So let’s get back to the torsion beam rear axle design. In this design the beam acts like a torsion bar. In other words, with torsion beam rear suspension designs, the anti-roll bar is built right in!
If the torsion bar was mega-strong in torsion, both rear wheels would always rise and fall together – therefore there’d be no body roll. But the reason that the torsion beam is designed to allow some twist is the same reason that you don’t fit too strong an anti-roll bar to other suspension designs – the stiffer the anti-roll, the less independent the suspension becomes.
If the suspension on each side of the car is linked so that it is no longer independent, as one wheel goes up over a bump, so will the one on the other side of the car. So when you’re cornering and the outside wheel passes over a bump, the inside wheel will also be lifted. The outcome is that the back of the car will skip sideways. (Too stiff an anti-roll action can also have other negative consequences – see the box later on this page that deals specifically with front-wheel drives.)
So in a torsion beam suspension, the torsion beam acts like an anti-roll bar – and the closer it is positioned to the pivots, the more torsion it undergoes and so the greater the influence it has on resisting roll.
Torsion Beam Designs
In most cases, the torsion beam is made from an open ‘U’ or ‘V’ section of rolled steel, with the opening facing the front or back of the car. Such a design has little torsional stiffness – although since these beams are made from thick gauge material, they still provide some torsional resistance.
Many car designers leave the set-up like this but others add a hollow or solid steel bar that runs inside the torsion beam, linking the two trailing arms and giving the beam greater torsional resistance. In this type of suspension system, this round bar or tube is the anti-roll bar. In this diagram it’s coloured green (and here is called a stabiliser bar.)
Why Increase the Anti-Roll Bar Rate?
Anti-roll bars can make an enormous improvement to how a car handles. Purists will suggest that anti-roll bar tweaking should be the last step in a handling package that includes upgraded springs, dampers (shocks), bushes, etc - but if you’re on a budget, increasing anti-roll bar stiffness can be an excellent first step.
It’s vital to realise that tweaking anti-roll bar stiffness is less about reducing body roll and more about determining which end of the car is handling more of the cornering forces.
Take a front-wheel drive that feels like it’s leaning all its cornering weight on the front outside wheel. Get on the power and it understeers (ie the front runs wide). Get off the power and all it does is stop understeering!
But by increasing the rear roll stiffness (eg by fitting a bigger rear anti-roll bar) the cornering weight distribution on the front wheels becomes more even, allowing them to better get their power down and so reducing power-understeer. Such an anti-roll bar also makes the back end work harder. Lift-off the throttle and the back can drift into oversteer, giving you throttle control of both understeer (power-on) and oversteer (power-off).
So for most front-wheel drives, increasing rear roll stiffness provides an immediate and noticeable improvement in handling balance.
The story thus far….
Let’s see where we’ve come in the analysis of torsion beam rear suspension systems in front-wheel drives.
- In one-wheel bumps and when the car rolls, the torsion beam is subject to bending and torsion. Sometimes an added internal bar is used from the factory to improve the torsional resistance of the beam. The total torsional resistance of the beam acts as the rear anti-roll bar.
- During body roll, the wheel on one side compresses its spring and the wheel on the other side extends its spring. In any suspension system, the more similar that the springs can be made to behave in extension and compression, the less body roll that will occur when cornering.
- Reducing body roll by adding a rear anti-roll bar (or by changing the torsional stiffness of the beam) will improve the front/rear cornering balance. However, going too far can have some adverse effects.
That’s enough to chew over: next issue we’ll explore the different ways of upgrading rear roll stiffness on FWD cars with rear torsion beam suspension, and show you how with one approach you can achieve a great DIY outcome for under AUD$50!