The
Tour de France – currently underway – has long been regarded as one of
the most demanding endurance events in sporting history. But what does
that mean in physical terms for the athletes taking part?
Chris Abbiss, Edith Cowan University
The Tour de France – currently underway – has long been regarded as one of the most demanding endurance events in sporting history. But what does that mean in physical terms for the athletes taking part?
RELATED: Cycling Central
When it began in 1903, the Tour comprised 2,428km of racing over six days. Some 60 cyclists competed in that inaugural race, which was eventually won by amateur rider Maurice Garin in an impressive time of 94 hours and 33 minutes. While the structure of the Tour has changed somewhat since its inception, the unbelievably demanding nature of the event remains.
The Tour of today is conducted over 21 days with finishing athletes completing a total of 3,500km on some of France’s harshest roads. These roads include the long (around 200km) relatively flat early stages, which are designed specifically for sprinters and ridden at remarkably fast average speeds (around 45km/hr).
At the end of these stages, which can last for four-to-six hours, cyclists are required to overcome severe mental and physical fatigue in order to maintain speeds of more than 60km/hr for the last five-to-ten kilometres of racing, reaching speeds of 75-to-80km/hr at the finish line.
Those wishing to contend the sprint will attempt to conserve as much energy as possible throughout the stage in order to produce sufficient power (around 2,000 to 2,500 watts) required reach these speeds. (It’s worth pointing out that healthy men and women in other walks of life would struggle to produce more than 800W and 600W on a bike, respectively.)
Such high power outputs are needed to rapidly accelerate the cyclists against the high wind resistance – and would be sufficient to power a fridge, TV and most of the lights in a standard house.
The high altitude at the summit of these mountain passes (in the region of 2,000-2,500m) makes the speed the Tour cyclists ascend (around 20km/hr) even more impressive. The stage profiles video below should give an idea of the challenge facing riders on this front.
At such altitudes the reduced barometric pressure limits the ability to deliver sufficient oxygen to active tissue (muscles), compromising exercise capacity by as much as 10-to-15%.
Indeed, the top of the climbs in the Alps and Pyrenees are high enough that many sedentary unacclimatised onlookers may begin to experience symptoms of acute altitude sickness, including dizziness and shortness of breath.
Since such mountain stages are often extremely influential to the overall outcomes of the race, cyclists wishing to finish well in the general classification are required to stay with the leading riders during each relentless surge or attack.
The average power output cyclists apply to the pedals during their 30-to-60-minute ascent of mountain passes can be upwards of 450W (6.5W/kg). To put this in perspective, the average trained recreational cyclist may be able to hold this power output for a maximum of between 30 and 120 seconds.
Achieving such high calorie intake is obviously complicated by the high demands of racing and the large percentage of the day spent on the bike. Still, in order to avoid depleting energy stores, cyclists are required to consume carbohydrates at a rate of approximately 25-60 grammes an hour during racing.
Failure to consume sufficient macronutrients during – and in the evening following – racing will result in a progressive decline in exercise capacity and ultimately an inability to complete the Tour.
Despite consuming extremely high calorie diets, riders in the Tour will still experience significant lipid and protein breakdown throughout the three-week race.
The continuous and repetitive stress placed on the body during the Tour also increase injury and suppresses the immune system, increasing the athlete’s susceptibility to illness.
Regardless, the cyclists are required to wake up each morning for 21 days in July, put on their lycra and ride down to the starting line if they hope to finish one of the world’s toughest races on the Champs-Élysées in Paris.
Further reading:
By The Tour de France – currently underway – has long been regarded as one of the most demanding endurance events in sporting history. But what does that mean in physical terms for the athletes taking part?
RELATED: Cycling Central
When it began in 1903, the Tour comprised 2,428km of racing over six days. Some 60 cyclists competed in that inaugural race, which was eventually won by amateur rider Maurice Garin in an impressive time of 94 hours and 33 minutes. While the structure of the Tour has changed somewhat since its inception, the unbelievably demanding nature of the event remains.
The Tour of today is conducted over 21 days with finishing athletes completing a total of 3,500km on some of France’s harshest roads. These roads include the long (around 200km) relatively flat early stages, which are designed specifically for sprinters and ridden at remarkably fast average speeds (around 45km/hr).
At the end of these stages, which can last for four-to-six hours, cyclists are required to overcome severe mental and physical fatigue in order to maintain speeds of more than 60km/hr for the last five-to-ten kilometres of racing, reaching speeds of 75-to-80km/hr at the finish line.
Those wishing to contend the sprint will attempt to conserve as much energy as possible throughout the stage in order to produce sufficient power (around 2,000 to 2,500 watts) required reach these speeds. (It’s worth pointing out that healthy men and women in other walks of life would struggle to produce more than 800W and 600W on a bike, respectively.)
Such high power outputs are needed to rapidly accelerate the cyclists against the high wind resistance – and would be sufficient to power a fridge, TV and most of the lights in a standard house.
Climbing
Perhaps the more demanding stages within the tour are those that travel over some of Europe most gruelling mountain passes (known as “hors category” ascents). These mountains are often greater than 10km long, at an average gradient of 5-10%, requiring more than one hour of continuous climbing.The high altitude at the summit of these mountain passes (in the region of 2,000-2,500m) makes the speed the Tour cyclists ascend (around 20km/hr) even more impressive. The stage profiles video below should give an idea of the challenge facing riders on this front.
At such altitudes the reduced barometric pressure limits the ability to deliver sufficient oxygen to active tissue (muscles), compromising exercise capacity by as much as 10-to-15%.
Indeed, the top of the climbs in the Alps and Pyrenees are high enough that many sedentary unacclimatised onlookers may begin to experience symptoms of acute altitude sickness, including dizziness and shortness of breath.
Since such mountain stages are often extremely influential to the overall outcomes of the race, cyclists wishing to finish well in the general classification are required to stay with the leading riders during each relentless surge or attack.
The average power output cyclists apply to the pedals during their 30-to-60-minute ascent of mountain passes can be upwards of 450W (6.5W/kg). To put this in perspective, the average trained recreational cyclist may be able to hold this power output for a maximum of between 30 and 120 seconds.
Food
The extremely intense and long duration of the stages within the Tour de France require riders to consume an average of 23–25MJ/day (5,500-6,000 kcal), which is more than double the average daily calorie intake required by most people.Achieving such high calorie intake is obviously complicated by the high demands of racing and the large percentage of the day spent on the bike. Still, in order to avoid depleting energy stores, cyclists are required to consume carbohydrates at a rate of approximately 25-60 grammes an hour during racing.
Failure to consume sufficient macronutrients during – and in the evening following – racing will result in a progressive decline in exercise capacity and ultimately an inability to complete the Tour.
Despite consuming extremely high calorie diets, riders in the Tour will still experience significant lipid and protein breakdown throughout the three-week race.
Hormones
The physiological stress resulting from 21 days of racing begins to alter hormonal function, resulting in a decrease in resting cortisol and testosterone, a situation that’s typically only observed after months of intense training.The continuous and repetitive stress placed on the body during the Tour also increase injury and suppresses the immune system, increasing the athlete’s susceptibility to illness.
Regardless, the cyclists are required to wake up each morning for 21 days in July, put on their lycra and ride down to the starting line if they hope to finish one of the world’s toughest races on the Champs-Élysées in Paris.
Further reading:
- Le Tour de France is set to roll, so what makes a perfect bike wheel?
- High-end bikes for sale … but what are you really buying?
- Cadel Evans and other machines: the science of the Tour de France time trial
- Science of elite cycling: Tour de France (stage 1 to 11)
- Science of elite cycling: Tour de France (stage 12 to 21)
Re: Problem with {How demanding is the Tour de France?)))}
ReplyDeleteI was checking out your site today and noticed that there was one link that wasn’t working on this page:
http://doorstepskis.blogspot.com.ng/2012/07/how-demanding-is-tour-de-france.html
This page that you linked to don't seem to exist anymore:
http://mckinley.illinois.edu/handouts/macronutrients.htm
Please check the screenshot I have attached:http://i.imgur.com/dZ3NasN.png
If you need a replacement resource, I have a very similar post:
https://naturalhealthbag.com/what-are-macronutrients/
Hope that helps and keep up the awesome work with work at doorstepskis.