The Secret Life of Machines (1988) s02e02 Episode Script
The Internal Combustion Engine
[Door opens, footsteps.]
[Jazzy music: 'The Russians Are Coming' - Val Bennett.]
[rattly engine revs several times.]
Tim: It's hard to imagine the modern world without the internal combustion engine it's used to drive such a vast variety of machines, including, of course, the car.
[engine stops.]
It was the engine that made the whole idea of the car possible.
The principle on which it works is really quite simple: It's really just like a canon, the explosive fuel forcing out whatever's inside the barrel.
This is actually a firework mortar And it forces out this cylindircal shell, and the explosive fuel is the gunpowder in the bottom.
Put it in here [strikes match.]
[fuse fizzles.]
[BANG-Whoompf!.]
[whistling of shell.]
The internal combustion engine is really just the same, except it has a captive piston, instead of the shell, and it uses an explosive vapour instead of the gunpowder.
Athough the idea's very simple, it hasn't been easy to tame the violent energy of all these explosions, thousands of times a minute.
In this programme, I'm going to look at this wild, unlikely contraption, and also at its fuel.
Almost all internal combustion engines use a fuel based on crude oil.
This naturally seeps out of the ground in places, and has been known about since ancient times.
It had a variety of uses, but not as a fuel.
[bubbling of oil well.]
It's mentioned several times in the Bible: Noah was instructed by God, to use it for waterproofing his ark.
[thunder.]
[distant shouting of ark-builders.]
It was only in the 19th century that oil's potential as a fuel was realised, and people started drilling and refining it.
One of the products of the refining was a volatile gas-oil, or petrol.
The petrol was at first regarded as a completely useless byproduct; its vapour was so dangerously inflammable.
But it was also realised that it was an enormously potent source of energy.
We can show this with this modified firework mortar This obviously isn't an experiment to do at home, but if Rex puts a teaspoonful of gunpowder down the mortar [tapping of spoon.]
And, er, using the lager can as the projectile [can rattles down tube.]
[fuse fizzles.]
[dull pop.]
Hehehe, ohdear.
Well, it's not very powerful.
Ah, well now we're going to compare this with the, er, a teaspoon full of petrol, we'll see how far that goes This time we're igniting it with a spark plug in the side.
[spoon taps on tube.]
[can rattles down tube.]
[muffled bang.]
You can see what an enormous amount of energy there is in the petrol.
[splash.]
Although it's hard to believe, this isn't actually an explosion.
It's just a very rapid combustion; a vary rapid fire.
The early internal combustion engines were often called explosion engines, though, and I think it's really a much more appropriate name.
The great attraction of the explosion engine, is the enormous power it has for its size and weight.
This is the smallest engine we could find, complete with fuel tank behind; used for model aeroplanes.
[loud mosquito-like buzzing.]
Even this has enough power to pull Rex round at quite a speed, though it takes a bit of time to get the momentum.
[engine buzzes loudly.]
The power of a modern car engine is quite awesome - even a basic one is rated at about 60 horsepower.
That's literally equivilant to the power of 60 horses.
[buzzing fades out.]
[bang!.]
The first successful explosion engine was built by an inventor called Etienne Lenoir in 1859.
He simply threw away the boiler of a steam engine, and modified it so it would ignite the piped gas supplied for lighting.
Unfortunately the violence of the explosions tended to damage the piston and valves.
And it was much less efficient than the original steam engine.
Lenior: Ooph! [mutters in French.]
[Bang!.]
Lenoir: Arrgh! [passers-by abuse Lenoir in French.]
Tim: However his engine inspired other inventors, including a German wholesale grocery salesman called Nicolaus Otto.
[puffinging of gas-engine.]
Lenoir: Herr Otto! [Bang!.]
Otto: Ooogh! [horse neighs.]
[puffing of engine.]
Tim: Otto came up with an engine which was much more efficient.
His engines were immediately successful, and he sold over 35,000 to power factories and workshops.
One of the first Otto engines to be built in britain was the 1895 Hornsby-Ackroyd.
[roar of burner.]
It all still looks very like a steam engine, but it runs on paraffin; another product of refining crude oil.
It first has to be heated to make it an inflammable vapour.
[Hiss!.]
It's a two-man job to start it, and it never goes round faster than 100 times a minute.
[Puff-puff-puff of vapour through valves.]
What's going on inside is that first the vapour is sucked into the cylinder then it's compressed, ignited, and finally the exhaust gasses are pushed out.
[click of valves.]
[puff of ignition.]
This sequence suck, squash, bang, blow is called the four-stroke cycle.
Otto's big improvement was squashing the vapour up before igniting it, which gave the engine much more power.
Although, from the outside, a modern car engine looks completely different, and it's obviously got more than one cylinder, inside it's really quite similar.
If you start turning it over The piston goes in and out.
the crankshaft goes round and round And this is the exhaust valve, with the strong spring keeping it closed, and the cam pushing it open.
The other valve, the inlet valve, is tucked away behind on this engine.
The rusty space around the edge is full of water; essential for cooling the heat of the explosions.
All these fundamental features have remained unchanged.
[puffing.]
Otto's engines were much too large and clumsy for a car.
But one of his employees, called Gottleib Daimler, developed a much smaller engine in 1883.
This ran much faster, and used the volatile petrol as the fuel.
It produced nearly as much power as Otto's, but weighed 10 times less.
Daimler's high-speed engine finally made the idea of a car practical.
And it was quickly realised that cars could do some quite remarkable things.
The early engines did still have their drawbacks, though.
This is a 1902 Wolsey, owned by Jack Howes.
Under the bonnet the bonnet really just contains the enormous cooling system and radiator the engine's tucked away right underneath.
It's not entirely easy to operate, there are 20 operations you have to do before you can start it.
Where do you start? Jack: First thing I do is to connect the battery, then I turn on the petrol tap.
And just give the carburettor a touch to draw the petrol through.
[bonnet clicks shut.]
My next operation after that is to turn on the 12 oilers for the total-loss oiling system.
Now the most important job of all: Having inserted the starting-handle as you can see in the side of the engine, is to put it on half-compression.
Otherwise there's a great risk of breaking your wrist.
Turn on the switch, adjust the throttle and ignition controls.
[click-click-click-buzzzt click-click-click-buzzzt.]
[Clunk! click-click-click-buzzzt.]
[click-click-click-buzzzt.]
[click-click-click.
click-click-click-click-click.]
[clicking speeds up as he increases compression.]
Jack: (inaudible over engine) [loud rattly engine noise.]
Tim: It's not just tricky to get it going: The two leavers controlling fuel and ignition have to be skillfully adjusted as you drive along.
One false move, and the thing stalls.
Also the engine's very inefficient by today's standards, only doing about 12MPG And the total-loss oiling system leaves a trail of oil along the ground wherever it goes.
[honk.
.
honk.
.
honk.]
Engines haven't changed radically since this time.
But their design has been continuously refined.
Arguably the biggest single improvement has been in the oil and how the engine puts it to use.
An engine wouldn't last for long without oil.
The oil's fed through holes in the castings to all the bearings.
There's actually an enormous amount of oil being pumped round all the time.
I can show you this if I knock a hole in the oil filter this may be a bit messy [rattly idle.]
[tapping of hammer.]
[engine noise.]
The oil doesn't just lubricate, but it gets all black and filthy like this because it's also a detergent.
It cleans up the deposits left by the exploding gasses.
Before this detergent was added in the 1940s, you had to strip down the engine and clean everything out, or decoke it, every few thousand miles.
Now you just have to change the oil and the filter.
I'm going to turn it off, actually.
Whoops! [engine stops.]
[Tim laughs.]
Many of the improvements in oil, and petrol, have been made possible by the ever-more-sophisticated refining of the crude oil.
Today, almost everything the refinery produces can be used by the car industry.
Besides petrol and oil, it provides the chemicals which are the basis of plastics, paints and synthetic rubbers.
And even the bitumen that the roads are made of.
[Uplifting music.]
Voiceover: Gasoline! The liquid power to run millions of automobiles everywhere! Yet how many know what happens to the gas after it is poured into the gas tank? Or realise the care that motor car engineers have taken to give each drop an equal chance to do its duty.
Gasoline is powerful.
But each drop can give a 100% account of himself only when he finds the most efficiently designed gasoline system, to help him along his journey.
For a successful life, every drop of gasoline depends entirely on what happens to him after he gets in the swim.
First the fuel has to be mixed with air.
The air comes in through the large air filter on the top of the engine.
And it's mixed with the fuel inside the carburetor.
It's easiest to see the principle of the carburetor with this model.
We've used the vaccum cleaner to represent the engine, because it's sucking in air all the time.
It simply sucks the fuel up and up this little tube, and mixes it with the air in here.
Here we're going to use red ink instead of petrol so you can see it more clearly.
[vaccum cleaner starts up.]
Petrol by itself isn't explosive.
Only the mixture of petrol vapour and oxygen from the air.
You can see the petrol being sucked in, looking down a real carburetor.
[vaccum cleaner off.]
Unfortunately real engines need different concentrations of fuel for different conditions.
Starting, idling, accellerating, etc.
That's why the 1902 Wolsey had the mixture lever on the steering wheel.
Modern carburetors make all these adjustments automatically, but this is why they're so fiendishly complicated.
Today a completely different system, fuel injection, is becoming more common.
[whine of fuel pump, clicking of injectors.]
It's basically simple; there's just a row of electric valves, one for each cylinder, that squirt a bit of petrol into each inlet.
[roar of flame.]
The precise length of time the valve opens, controlled by a computer, varies the amount of fuel injected very accurately.
Once the fuel and air's been sucked into the cylinder and squashed up, it's ignited.
A spark's created by a high voltage jumping across a gap in the spark plug.
The high voltage itself is created by the coil connected to the battery.
Engines don't like getting wet, because water provides an easier path for the electricity than jumping across the gap which I think I can show you [squirting.]
put the spark out.
Fortunately though, you can often get the spark back again simply with a water-repelling oil.
[squirt.
squirtWoomph!.]
[quiet sparking noise.]
Although the ignition should be started by the spark, petrol's a complicated mixture of chemicals some of which are quite unstable.
These can ignite spontaneously under heat and pressure, causing a sort of uneven explosion, called detonation or knock.
As engines have become more powerful over the years, knock has become more of a problem.
It can be overcome, either by damping the unstable compounds with lead additives, or in lead-free petrol, by refining the unstable compounds out.
The other option, used in diesel engines, is to refine the fuel less, and to compress it more.
The more the fuel's squashed up in the cylinder, the hotter it gets.
It can get so hot that it ignites spontaneously without any spark.
We've blocked the bottom of this cylinder up completely and cut a hole in it Um and if I put a bit of fuel in the side here And bash the piston down with a hammer It should ignite [BANG!.]
If I blow out the burnt gasses, there may be enough fuel left to make it work a second time.
[compressed air.]
[smaller bang.]
It was a vicorian cigar lighter working ont his principle, that inspired Rudolph Diesel to design his first engine in the 1890s.
[clock ticking.]
Diesel believed that more compression would make his engine much more efficient.
Diesel: The vision I have, of a better future machines will free mankind from the slavery of work! Tim: The higher compression made the engine more dangerous, and a prototype nearly killed him.
[BANG!.]
Diesel: What! Nearly killed me! Men: Oh, oh, oh Jah! JAH! Tim: By 1895 though, Diesel had an design which ran on cheap fuel and was twice as efficient as any other engine of its time.
Diesel became a millionaire from his invention, and invested very badly, quickly getting heavily into debt.
And decided he couldn't carry on.
Diesel: Ah! Mein gott! I cannot pay this.
In May 1913, he set off on a night ferry to Britain.
Diesel: I go! Goodbye! [splash!.]
Tim: He was never seen again.
[Engine noise.]
Today, the diesel engine has been greatly improved, and it's now fitted in many cars.
This contraption, which Rex and I built for a TV series a few years ago, is diesel-powered.
The engine, from a Volkswagen Golf car, hardly looks any different from a petrol one.
However, as Diesel orignally thought, the higer compression does make the engine more efficient, and do more miles to the gallon.
Here, as well as powering the vehicle, the engine's also powering a hydraulic lift.
[engine running.]
[fairly quiet engine noise.]
The most dramatic change to both diesel and petrol engines in the last 10 years, has been the addition of sophisticated electronics.
Rex: This modern car engine, compared to the early ones, is horrendously complicated.
For example, there's two computers on board.
One controls the electronic fuel injection, another one controls the cruise control.
Even thought the engine is much more complicated, this makes the most of every drop of fuel and gives greater fuel economy and power.
Although the complex electronics would be impossible to repair by the roadside, I've driven 80,000 miles in it, and even with my poor maintenance, it's never even failed once.
Tim: The engine's improved enormously since 1900.
It starts at the flick of a switch [engine turns over, starts and idles.]
It's incredibly powerful [engine revs.]
And it's really very reliable.
But it's still far from perfect.
Despite it's power, it's really very wasteful.
4/5 of the energy released by the petrol is simply lost as heat through the radiator, or the exhaust.
And the exhaust gasses themselves, pose even worse problems There's an awful lot of them [revs engine.]
The average car releases four times its own weight in exhaust gasses during its life.
And it's all pretty horrid stuff! [engine revs.]
This wasn't such a problem when there weren't so many cars around.
[uplifting music.]
Voiceover: If we are to realise in full the motor car's vast potential for good, we must use it and care for it wisely.
The motor car has been the key to open new horizons.
Not for the few, but for all.
And all of us share the responsibility of safeguarding the benefits it has brought.
If we plan for the future, if we look ahead to clear all obstacles and roadblocks, if we recognise the importance of this great individual freedom of movement, the motor car will be the key to our ever-widening horizons of tomorrow.
[music ends triumphantly.]
# Oh beautiful, for spacious skies, # For amber waves of grain, # For purple mountain majesties, [coughs.]
# Above the fruited plain, [coughs.]
# America, [cough-cough.]
# America, [coughs.]
# God shed his grace on thee, Voiceover: If you want sing about America, you'd better sure you have the breath to sing with! [singing and coughing continues.]
We've been fighting air pollution, but it's time to fight harder.
Help us.
It's a beautiful country [coughs.]
let's not all get choked up about it! # sea! # In an attempt to clean up the exhaust gasses, catalytic converters are gradually becoming compulsory all over the world.
Child: Oh! Oh Dad! Dad, Dad, it smells all funny! Oh Dad! Dad stop! [sqeaks to a halt.]
Tim: Recent reports from America suggest in practice, catalysts may only remove 30% of the poisonous gasses, bacause the engine needs carfeul maintenance for them to work properly.
AA man: Don't worry sir, trouble with the catalytic? Very common these days I'll just adjust this screw, and then that'll be alright.
Tim: Even when they do work perfectly, they only convert the gasses to carbon dioxide, the greenhouse gas.
Child: Dad it's getting awfully hot.
I'm boiled Dad! [bubbling.]
Man: Nothing for it, we'll have to go electric, it's the only way to be really green Tim: Electric cars aren't perfect either, the electricity to charge their batteries just transfers a lot of the pollution to the power stations.
I don't think there's any such thing as a completely green car.
[electric motor whine.]
The engine's really a victim of its own success.
Despite its disgusting exhaust, it's such a reliable and potent source of power, it's made the car, and all sorts of other machines, completely indispensable.
It's so central to our modern way of life, that there's almost something rather religious about it.
[Starts engine.]
[engine fast-idles.]
[Jazzy music: 'Take 5' - Dave Brubeck.]
[Jazzy music: 'The Russians Are Coming' - Val Bennett.]
[rattly engine revs several times.]
Tim: It's hard to imagine the modern world without the internal combustion engine it's used to drive such a vast variety of machines, including, of course, the car.
[engine stops.]
It was the engine that made the whole idea of the car possible.
The principle on which it works is really quite simple: It's really just like a canon, the explosive fuel forcing out whatever's inside the barrel.
This is actually a firework mortar And it forces out this cylindircal shell, and the explosive fuel is the gunpowder in the bottom.
Put it in here [strikes match.]
[fuse fizzles.]
[BANG-Whoompf!.]
[whistling of shell.]
The internal combustion engine is really just the same, except it has a captive piston, instead of the shell, and it uses an explosive vapour instead of the gunpowder.
Athough the idea's very simple, it hasn't been easy to tame the violent energy of all these explosions, thousands of times a minute.
In this programme, I'm going to look at this wild, unlikely contraption, and also at its fuel.
Almost all internal combustion engines use a fuel based on crude oil.
This naturally seeps out of the ground in places, and has been known about since ancient times.
It had a variety of uses, but not as a fuel.
[bubbling of oil well.]
It's mentioned several times in the Bible: Noah was instructed by God, to use it for waterproofing his ark.
[thunder.]
[distant shouting of ark-builders.]
It was only in the 19th century that oil's potential as a fuel was realised, and people started drilling and refining it.
One of the products of the refining was a volatile gas-oil, or petrol.
The petrol was at first regarded as a completely useless byproduct; its vapour was so dangerously inflammable.
But it was also realised that it was an enormously potent source of energy.
We can show this with this modified firework mortar This obviously isn't an experiment to do at home, but if Rex puts a teaspoonful of gunpowder down the mortar [tapping of spoon.]
And, er, using the lager can as the projectile [can rattles down tube.]
[fuse fizzles.]
[dull pop.]
Hehehe, ohdear.
Well, it's not very powerful.
Ah, well now we're going to compare this with the, er, a teaspoon full of petrol, we'll see how far that goes This time we're igniting it with a spark plug in the side.
[spoon taps on tube.]
[can rattles down tube.]
[muffled bang.]
You can see what an enormous amount of energy there is in the petrol.
[splash.]
Although it's hard to believe, this isn't actually an explosion.
It's just a very rapid combustion; a vary rapid fire.
The early internal combustion engines were often called explosion engines, though, and I think it's really a much more appropriate name.
The great attraction of the explosion engine, is the enormous power it has for its size and weight.
This is the smallest engine we could find, complete with fuel tank behind; used for model aeroplanes.
[loud mosquito-like buzzing.]
Even this has enough power to pull Rex round at quite a speed, though it takes a bit of time to get the momentum.
[engine buzzes loudly.]
The power of a modern car engine is quite awesome - even a basic one is rated at about 60 horsepower.
That's literally equivilant to the power of 60 horses.
[buzzing fades out.]
[bang!.]
The first successful explosion engine was built by an inventor called Etienne Lenoir in 1859.
He simply threw away the boiler of a steam engine, and modified it so it would ignite the piped gas supplied for lighting.
Unfortunately the violence of the explosions tended to damage the piston and valves.
And it was much less efficient than the original steam engine.
Lenior: Ooph! [mutters in French.]
[Bang!.]
Lenoir: Arrgh! [passers-by abuse Lenoir in French.]
Tim: However his engine inspired other inventors, including a German wholesale grocery salesman called Nicolaus Otto.
[puffinging of gas-engine.]
Lenoir: Herr Otto! [Bang!.]
Otto: Ooogh! [horse neighs.]
[puffing of engine.]
Tim: Otto came up with an engine which was much more efficient.
His engines were immediately successful, and he sold over 35,000 to power factories and workshops.
One of the first Otto engines to be built in britain was the 1895 Hornsby-Ackroyd.
[roar of burner.]
It all still looks very like a steam engine, but it runs on paraffin; another product of refining crude oil.
It first has to be heated to make it an inflammable vapour.
[Hiss!.]
It's a two-man job to start it, and it never goes round faster than 100 times a minute.
[Puff-puff-puff of vapour through valves.]
What's going on inside is that first the vapour is sucked into the cylinder then it's compressed, ignited, and finally the exhaust gasses are pushed out.
[click of valves.]
[puff of ignition.]
This sequence suck, squash, bang, blow is called the four-stroke cycle.
Otto's big improvement was squashing the vapour up before igniting it, which gave the engine much more power.
Although, from the outside, a modern car engine looks completely different, and it's obviously got more than one cylinder, inside it's really quite similar.
If you start turning it over The piston goes in and out.
the crankshaft goes round and round And this is the exhaust valve, with the strong spring keeping it closed, and the cam pushing it open.
The other valve, the inlet valve, is tucked away behind on this engine.
The rusty space around the edge is full of water; essential for cooling the heat of the explosions.
All these fundamental features have remained unchanged.
[puffing.]
Otto's engines were much too large and clumsy for a car.
But one of his employees, called Gottleib Daimler, developed a much smaller engine in 1883.
This ran much faster, and used the volatile petrol as the fuel.
It produced nearly as much power as Otto's, but weighed 10 times less.
Daimler's high-speed engine finally made the idea of a car practical.
And it was quickly realised that cars could do some quite remarkable things.
The early engines did still have their drawbacks, though.
This is a 1902 Wolsey, owned by Jack Howes.
Under the bonnet the bonnet really just contains the enormous cooling system and radiator the engine's tucked away right underneath.
It's not entirely easy to operate, there are 20 operations you have to do before you can start it.
Where do you start? Jack: First thing I do is to connect the battery, then I turn on the petrol tap.
And just give the carburettor a touch to draw the petrol through.
[bonnet clicks shut.]
My next operation after that is to turn on the 12 oilers for the total-loss oiling system.
Now the most important job of all: Having inserted the starting-handle as you can see in the side of the engine, is to put it on half-compression.
Otherwise there's a great risk of breaking your wrist.
Turn on the switch, adjust the throttle and ignition controls.
[click-click-click-buzzzt click-click-click-buzzzt.]
[Clunk! click-click-click-buzzzt.]
[click-click-click-buzzzt.]
[click-click-click.
click-click-click-click-click.]
[clicking speeds up as he increases compression.]
Jack: (inaudible over engine) [loud rattly engine noise.]
Tim: It's not just tricky to get it going: The two leavers controlling fuel and ignition have to be skillfully adjusted as you drive along.
One false move, and the thing stalls.
Also the engine's very inefficient by today's standards, only doing about 12MPG And the total-loss oiling system leaves a trail of oil along the ground wherever it goes.
[honk.
.
honk.
.
honk.]
Engines haven't changed radically since this time.
But their design has been continuously refined.
Arguably the biggest single improvement has been in the oil and how the engine puts it to use.
An engine wouldn't last for long without oil.
The oil's fed through holes in the castings to all the bearings.
There's actually an enormous amount of oil being pumped round all the time.
I can show you this if I knock a hole in the oil filter this may be a bit messy [rattly idle.]
[tapping of hammer.]
[engine noise.]
The oil doesn't just lubricate, but it gets all black and filthy like this because it's also a detergent.
It cleans up the deposits left by the exploding gasses.
Before this detergent was added in the 1940s, you had to strip down the engine and clean everything out, or decoke it, every few thousand miles.
Now you just have to change the oil and the filter.
I'm going to turn it off, actually.
Whoops! [engine stops.]
[Tim laughs.]
Many of the improvements in oil, and petrol, have been made possible by the ever-more-sophisticated refining of the crude oil.
Today, almost everything the refinery produces can be used by the car industry.
Besides petrol and oil, it provides the chemicals which are the basis of plastics, paints and synthetic rubbers.
And even the bitumen that the roads are made of.
[Uplifting music.]
Voiceover: Gasoline! The liquid power to run millions of automobiles everywhere! Yet how many know what happens to the gas after it is poured into the gas tank? Or realise the care that motor car engineers have taken to give each drop an equal chance to do its duty.
Gasoline is powerful.
But each drop can give a 100% account of himself only when he finds the most efficiently designed gasoline system, to help him along his journey.
For a successful life, every drop of gasoline depends entirely on what happens to him after he gets in the swim.
First the fuel has to be mixed with air.
The air comes in through the large air filter on the top of the engine.
And it's mixed with the fuel inside the carburetor.
It's easiest to see the principle of the carburetor with this model.
We've used the vaccum cleaner to represent the engine, because it's sucking in air all the time.
It simply sucks the fuel up and up this little tube, and mixes it with the air in here.
Here we're going to use red ink instead of petrol so you can see it more clearly.
[vaccum cleaner starts up.]
Petrol by itself isn't explosive.
Only the mixture of petrol vapour and oxygen from the air.
You can see the petrol being sucked in, looking down a real carburetor.
[vaccum cleaner off.]
Unfortunately real engines need different concentrations of fuel for different conditions.
Starting, idling, accellerating, etc.
That's why the 1902 Wolsey had the mixture lever on the steering wheel.
Modern carburetors make all these adjustments automatically, but this is why they're so fiendishly complicated.
Today a completely different system, fuel injection, is becoming more common.
[whine of fuel pump, clicking of injectors.]
It's basically simple; there's just a row of electric valves, one for each cylinder, that squirt a bit of petrol into each inlet.
[roar of flame.]
The precise length of time the valve opens, controlled by a computer, varies the amount of fuel injected very accurately.
Once the fuel and air's been sucked into the cylinder and squashed up, it's ignited.
A spark's created by a high voltage jumping across a gap in the spark plug.
The high voltage itself is created by the coil connected to the battery.
Engines don't like getting wet, because water provides an easier path for the electricity than jumping across the gap which I think I can show you [squirting.]
put the spark out.
Fortunately though, you can often get the spark back again simply with a water-repelling oil.
[squirt.
squirtWoomph!.]
[quiet sparking noise.]
Although the ignition should be started by the spark, petrol's a complicated mixture of chemicals some of which are quite unstable.
These can ignite spontaneously under heat and pressure, causing a sort of uneven explosion, called detonation or knock.
As engines have become more powerful over the years, knock has become more of a problem.
It can be overcome, either by damping the unstable compounds with lead additives, or in lead-free petrol, by refining the unstable compounds out.
The other option, used in diesel engines, is to refine the fuel less, and to compress it more.
The more the fuel's squashed up in the cylinder, the hotter it gets.
It can get so hot that it ignites spontaneously without any spark.
We've blocked the bottom of this cylinder up completely and cut a hole in it Um and if I put a bit of fuel in the side here And bash the piston down with a hammer It should ignite [BANG!.]
If I blow out the burnt gasses, there may be enough fuel left to make it work a second time.
[compressed air.]
[smaller bang.]
It was a vicorian cigar lighter working ont his principle, that inspired Rudolph Diesel to design his first engine in the 1890s.
[clock ticking.]
Diesel believed that more compression would make his engine much more efficient.
Diesel: The vision I have, of a better future machines will free mankind from the slavery of work! Tim: The higher compression made the engine more dangerous, and a prototype nearly killed him.
[BANG!.]
Diesel: What! Nearly killed me! Men: Oh, oh, oh Jah! JAH! Tim: By 1895 though, Diesel had an design which ran on cheap fuel and was twice as efficient as any other engine of its time.
Diesel became a millionaire from his invention, and invested very badly, quickly getting heavily into debt.
And decided he couldn't carry on.
Diesel: Ah! Mein gott! I cannot pay this.
In May 1913, he set off on a night ferry to Britain.
Diesel: I go! Goodbye! [splash!.]
Tim: He was never seen again.
[Engine noise.]
Today, the diesel engine has been greatly improved, and it's now fitted in many cars.
This contraption, which Rex and I built for a TV series a few years ago, is diesel-powered.
The engine, from a Volkswagen Golf car, hardly looks any different from a petrol one.
However, as Diesel orignally thought, the higer compression does make the engine more efficient, and do more miles to the gallon.
Here, as well as powering the vehicle, the engine's also powering a hydraulic lift.
[engine running.]
[fairly quiet engine noise.]
The most dramatic change to both diesel and petrol engines in the last 10 years, has been the addition of sophisticated electronics.
Rex: This modern car engine, compared to the early ones, is horrendously complicated.
For example, there's two computers on board.
One controls the electronic fuel injection, another one controls the cruise control.
Even thought the engine is much more complicated, this makes the most of every drop of fuel and gives greater fuel economy and power.
Although the complex electronics would be impossible to repair by the roadside, I've driven 80,000 miles in it, and even with my poor maintenance, it's never even failed once.
Tim: The engine's improved enormously since 1900.
It starts at the flick of a switch [engine turns over, starts and idles.]
It's incredibly powerful [engine revs.]
And it's really very reliable.
But it's still far from perfect.
Despite it's power, it's really very wasteful.
4/5 of the energy released by the petrol is simply lost as heat through the radiator, or the exhaust.
And the exhaust gasses themselves, pose even worse problems There's an awful lot of them [revs engine.]
The average car releases four times its own weight in exhaust gasses during its life.
And it's all pretty horrid stuff! [engine revs.]
This wasn't such a problem when there weren't so many cars around.
[uplifting music.]
Voiceover: If we are to realise in full the motor car's vast potential for good, we must use it and care for it wisely.
The motor car has been the key to open new horizons.
Not for the few, but for all.
And all of us share the responsibility of safeguarding the benefits it has brought.
If we plan for the future, if we look ahead to clear all obstacles and roadblocks, if we recognise the importance of this great individual freedom of movement, the motor car will be the key to our ever-widening horizons of tomorrow.
[music ends triumphantly.]
# Oh beautiful, for spacious skies, # For amber waves of grain, # For purple mountain majesties, [coughs.]
# Above the fruited plain, [coughs.]
# America, [cough-cough.]
# America, [coughs.]
# God shed his grace on thee, Voiceover: If you want sing about America, you'd better sure you have the breath to sing with! [singing and coughing continues.]
We've been fighting air pollution, but it's time to fight harder.
Help us.
It's a beautiful country [coughs.]
let's not all get choked up about it! # sea! # In an attempt to clean up the exhaust gasses, catalytic converters are gradually becoming compulsory all over the world.
Child: Oh! Oh Dad! Dad, Dad, it smells all funny! Oh Dad! Dad stop! [sqeaks to a halt.]
Tim: Recent reports from America suggest in practice, catalysts may only remove 30% of the poisonous gasses, bacause the engine needs carfeul maintenance for them to work properly.
AA man: Don't worry sir, trouble with the catalytic? Very common these days I'll just adjust this screw, and then that'll be alright.
Tim: Even when they do work perfectly, they only convert the gasses to carbon dioxide, the greenhouse gas.
Child: Dad it's getting awfully hot.
I'm boiled Dad! [bubbling.]
Man: Nothing for it, we'll have to go electric, it's the only way to be really green Tim: Electric cars aren't perfect either, the electricity to charge their batteries just transfers a lot of the pollution to the power stations.
I don't think there's any such thing as a completely green car.
[electric motor whine.]
The engine's really a victim of its own success.
Despite its disgusting exhaust, it's such a reliable and potent source of power, it's made the car, and all sorts of other machines, completely indispensable.
It's so central to our modern way of life, that there's almost something rather religious about it.
[Starts engine.]
[engine fast-idles.]
[Jazzy music: 'Take 5' - Dave Brubeck.]