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You want to get faster against the clock. You want to know if you spend X you will get Y time savings in return. Problem is, you’re bamboozled by a plethora of marketing hype and scientific data put out by companies who want you to buy their stuff, whether it be snazzy equipment or even time in a wind tunnel. Where do you start?


Let’s break it down into a simple question:

How much time can you save by going from your normal road bike and helmet to adding clip-on handlebar extensions to a full-on time trial bike with an aero helmet? That’s it. All other equipment (wheels, tyres, clothing) stays the same.

The answer is quantifiable but finding it is another matter. You need to know what you’re doing, and most of us don’t. Luckily there are people called engineers in the cycling world whose job it is to find the answers to these questions.

We were given the opportunity to spend a day with Specialized’s young aerodynamicist Mark Cote at the A2 Wind Tunnel and Lowe’s Motor Speedway in North Carolina. It’s NASCAR heartland here, and they put a lot of money into aerodynamic testing facilities.

The A2 Wind Tunnel, the smaller brother to the AeroDYN tunnel, is used to test small vehicles and bicycles. It’s one of the cheapest in the US at $390 per hour (compared to $800/hr for the San Diego tunnel) and the tunnel managers Mike Giraud and Dave Salazar know exactly what they’re doing when it comes to bikes. Plus they can compare wind tunnel data to on road data by using the nearby Lowe’s Motor Speedway, a 2.3km banked NASCAR oval.

For the test, Mark enlisted the help of Nathan O’Neill, eight time Australian time trial champion who has raced for European and US pro teams for the past eight years. He’s coming off a 15 month ban (expires November 12, 2008) after testing positive for the appetite suppressant Phentermine, which bizarrely is legal out of competition but illegal in competition. But his experience as a wind tunnel subject, time trialist and of course his availability makes him an ideal test rider.

How it’s done

Wind tunnel measurement is currently considered the gold standard of bicycle aerodynamic testing. For best results, you need the rider on the bike to be able to hold their position stable while pedalling.

You can test the bike alone, but it makes more sense to have someone on it, because the overall shape will be completely different. You also need to test over a range of yaw angles (wind direction relative to the rider’s direction) to account for crosswinds, because aerodynamics are significantly affected by wind direction.

The downside of doing this in a tunnel is that you can’t account for handling in a crosswind, because the bike is fixed to a set of rollers.

Testing outdoors is useful because it’s closer to real world conditions. That said, it’s time consuming and you still need to control as many variables as possible.

Even if you have a smooth flat track and precise measuring equipment, like the SRM cranks and mobile weather station that we had, too much wind will give you large errors, even greater than what you are trying to measure.

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Lowe’s Motor Speedway, North Carolina, USA

Jeff Jones/BikeRadar.com

The control bike with the mobile weather station

The 70 watt benchmark

In late July, Cote and his team did a series of tests comparing a standard road bike (Specialized Tarmac SL2 with HED Bastogne wheels) to a full time trial bike (Specialized Transition with HED3 Trispoke wheels and a Specialized TT3 aero helmet).

They compared wind tunnel data with track testing at the Lowe’s Speedway and the Asheville velodrome, which consisted of several 10 mile and 1km time trials at a constant speed of 40km/h.

They were lucky to have near ideal conditions for the outdoor tests, which kept the measurement errors down to around two percent of total power. The corresponding errors in the wind tunnel are under one percent. From doing this, they found the outdoor testing validated the wind tunnel testing, but did not replicate it.

They also found that outdoors there was a 60-70 watt saving at 40km/h between the normal road bike setup, which required 280-290W at this speed, and the full time trial setup ( 220W). That worked out at between 22-24 percent in aerodynamic savings.

To put it another way, it was nine seconds per kilometre, 2’14 per 10 miles (16.1km), 5’33 per 40km, and 24’58 over 180.2km, the distance of the bike leg in an Ironman triathlon. Or another way, if you can ride a road bike at 40km/h and switch to a time trial bike and helmet, you can do over 44km/h.

In the controlled environment of the wind tunnel, the savings were greater: between 32-42 percent, depending on yaw angle. These are aero savings only. About 70 percent of total power goes towards aero, so 70 percent of 32-42 percent = 22-29 percent of total power. This almost exactly matches the 22-24 percent from the track.

Also, the bigger the crosswind, the better off you are on a time trial bike because of the sail affect. Of course, you’ve got to be able to keep the thing upright…

Drilling down

So how do we break down that 70 watt saving? How much is position, how much is the bike, how much is the helmet and how much is the wheels? That was the purpose of this test, although we didn’t actually test different wheel configurations, so we were looking at 60 watts worth of savings.

Mark Cote decided on five protocols:

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Tarmac SL2 road bike | S-Works road helmet | drop bars

Jeff Jones/BikeRadar.com

Tarmac SL2 road bike | S-Works road helmet | clip-on aero bars

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Tarmac SL2 road bike| TT2 helmet | clip-on aero bars

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Transition time trial bike | S-Works road helmet | aero bars

Jeff Jones/BikeRadar.com

Transition time trial bike | TT2 helmet | aero bars

For each one, we used the same wheels (Roval) and tyres, and Nathan rode in a short sleeved skinsuit with arm warmers and full finger gloves, but no shoe covers. The mass of the bike + rider was 83kg.

All five setups were tested over two laps (4.6km) of the Lowe’s Motor Speedway at as close to 40km/h as we could get. The tests were repeated in the wind tunnel later that day.

During each test, Mike Giraud acted as a control, riding his bike around the circuit at 32km/h, with a wind probe attached to the front of his bike that could measure wind speed and direction. The probe looked like it could double as a harpoon, but luckily there were no whales on the circuit.

It was a clear, sunny November morning but the conditions weren’t quite ideal at the Speedway. While we could account for the changes in temperature and humidity, the wind affected things a little.

Speedway data

Setup Estimated Ave CdA (m^2) Speed (km/h) Power (W) Tarmac SL2 | road helmet | drop bars 0.310 40.10 306.6 Tarmac SL2 | road helmet | clip-on aero bars 0.267 40.27 268.6 Tarmac SL2 | TT2 helmet | clip-on aero bars 0.256 40.38 261.0 Transition | road helmet | aero bars 0.265 40.17 262.9 Transition | TT2 helmet | aero bars 0.230 40.05 229.0

[CdA = Coefficient of drag x frontal area]

On the plus side, the trends were accurate and there was still that big 77W (25 percent) difference between the road bike and the full TT setup. And it looked as though position would account for about half of that. But as for deciding how much the bike was worth relative to the aero helmet, it was tough.

This appeared to be because of an unreliable data point, as the time trial bike plus road helmet should have required about 240W rather than 263W at 40km/h. We suspected this was because of an SRM calibration error, rather than the wind on the track, but at the time of publication this was a known unknown.

Wind tunnel testing

Mark was happier once we got into the wind tunnel. Nice repeatable data that did make sense and gelled with his considerable testing experience. The testing was done at yaw angles of 0 and 10 degrees in 48.3km/h (30mph) wind, which was extrapolated back to 40km/h.

Wind tunnel data

Setup Wind Tunnel 0 CdA (m^2) Speed (km/h) at 278W Power req’d at 40km/h (W)* Tarmac SL2 | road helmet | drop bars 0.3019 40.00 278.3 Tarmac SL2 | road helmet | clip-on aero bars 0.2662 41.65 248.9 Tarmac SL2 | TT2 helmet | clip-on aero bars 0.2547 42.25 239.5 Transition | road helmet | aero bars 0.2427 42.90 229.6 Transition | TT2 helmet | aero bars 0.2323 43.50 221.0

[*The power req’d at 40km/h is aero power only, hence it’s significantly lower than the power measured out on the track. On the other hand, the CdAs outdoors and in the wind tunnel are closely matched. This is more what we’re interested in.]

The nice thing about this set of protocols is that there are two separate ways of comparing bikes and helmets. The difference between the Specialized road helmet and the TT2 was 8.6W or 9.4W, depending on which set of protocols we chose.

The difference between the Specialized Tarmac SL2 with clip-ons and the Transition was 18.5W or 19.3W. Finally, the difference between a road frame and one with a set of clip-ons on it was a whopping 29.4 watts. This difference is due to rider position (in the drops vs. in the aero bars).

That’s 60 watts accounted for in savings. The July tests showed 70 watts, but the wheels were also changed in that one so we can guesstimate that HED 3 Trispokes will save an extra 10 watts over Hed Bastogne wheels.

Since there were other differences (wore a TT3 in July vs a TT2 this time, and a skinsuit vs road wheels) we have to be careful in making this conclusion. But if it is made, it also shows that the Roval wheels tested about the same as the trispokes and the Roval wheels saved about the same 10 watts the trispokes did.

Finally, to put it in perspective, we can list the wattage savings per unit cost.

Cost $/watts saved at 40km/h Clip-on bars $100-1200 $3.30-$40 Aero helmet $75-230 $8.30-25.50 Time trial bike $1000-10,000+ $50-500 Aero wheels $600-$8000 $60-800

How much is it worth? That’s for you to decide.

Notes:

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