



WHEN the Wright brothers set out to develop the first controllable, powered, heavier-than-air flying machine at the turn of the last century, they had to invent almost everything they needed to get their Flyer off the ground. They had little choice: existing glider wing designs were certainly not up to the task, and the propellers used on airships were highly inefficient.
Their scrupulous, do-it-yourself approach has been a major source of inspiration for James Dyson, one of the UK’s best known industrial designers. The way they taught themselves the key physics and then tackled each problem as it came up should motivate anyone hoping to make a name for themselves as an inventor, he says. “It was the Wrights who really showed us how to develop technology. They broke the problem down into individual components that they then solved brilliantly: the shape of the wing, the control surface and the twisted aerofoil propeller. And then they built the first wind tunnel to test it all in. I admire what they did enormously.”
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Dyson’s design centre in leafy Malmesbury, Wiltshire, opened in 1993, is a long way from the gale-lashed, mosquito-ridden swamps of Kitty Hawk, North Carolina, where the Wrights had their beach workshop, yet the brothers’ influence over the Dyson design ethos is conspicuous. “We develop all the technology that goes into our products ourselves because we are not happy with the slow rate of development elsewhere.”
Dyson’s work on motors is a good example. The firm needs highly reliable electric motors to drive its appliances, such as its bagless dual-cyclone vacuum cleaners. In 1997, when it became clear that the motors it was buying in from external suppliers were using too much power and wearing out too soon, Dyson set up a small lab where engineers set about developing mass-producible motors of their own. “We wanted a quantum leap, not just tiny changes in motor performance every year,” he says.
By 2003, the lab had developed which delivered 33 per cent higher sucking pressure in a vacuum cleaner, compared with previous models. Last month the firm revealed a further development: a new high-speed motor a quarter the size of its predecessor (the new motor and an older version are pictured, left). Dyson claims its increased efficiency has doubled the battery life of his company’s hand-held vacuum cleaner (see diagram).
The motor lab has partly helped Dyson improve its once poor reliability record, which saw it hit the bottom of Which? magazine’s vacuum cleaner reliability league five years ago.
The lab is now developing motors for the company’s next move: its entry into the domestic robot market. This move is driven, no doubt, by the success of US-based iRobot’s , which has proved so compelling a domestic companion that some users make clothes for them and give them names. “We made a robot vacuum cleaner five years ago but didn’t launch it because, with 85 sensors, powerful motors and huge numbers of batteries, it was just too expensive,” says Dyson. The team’s goal is a robot that is able to navigate effectively but cheaply, so that it covers an entire floor with minimal path overlap.
The development of Dyson’s domestic robots – indeed his entire invention process – is being boosted by 3D printing, also known as rapid prototyping. This technology allows the creation of 3D prototypes from a design created on a computer. The design is fed into a machine, which builds the object bit by bit using twin laser beams that fuse together layers of powdered nylon or metal. The result? Almost magically, you pull out from the dust a near perfect 3D “printout” of the prototype you may later want to mass produce.
“Rapid prototyping has transformed the way we do things,” says Dyson. “You can prototype in days what would once have taken months to machine, mill and handcraft.”
“You can now prototype in days what would take months to machine, mill and handcraft”
He reckons 3D printing will have a profound impact on everybody’s ability to invent. “I can envisage a time when there will be open source design software, open source drawings and an open source library of components donated by designers – so that you could download invention components from a library seamlessly into a design that’s then built by rapid prototyping. I really think that will happen.”
This sounds like an inventor’s nirvana, but it could have drawbacks. If designs are as easily transmitted and shared as music and video files, inventors could find their ideas pirated – something Dyson thinks might need guarding against.
“It’s a bit like music. If you don’t protect inventor’s intellectual property with patents they won’t bother to create things.” Dyson is a long-standing critic of the annual renewal fees inventors currently have to pay to keep their patents valid. “The patent is your right and you shouldn’t lose it because you can’t afford to pay renewal fees. For individuals and small companies, paying these fees every year for every patent in every country is unaffordable.”
As you’d expect, Dyson opposes anything that might dissuade people from becoming inventors. “We need to encourage children, teachers and parents to realise that engineering is an exciting, profitable career.”
One thing that’s helping on that front, he says, is the proliferation of TV shows that have inventors pitching ideas to teams of investors, such as the BBC’s Dragon’s Den, ABC’s American Inventor and its upcoming follow-up, Shark Tank. “I must say I don’t really like the reality TV side of it, but I do like the principle of inventors demonstrating their ideas and getting backing.”
So would Dyson ever consider becoming a BBC “dragon” – one of the investors who quiz the inventors? “No way. I’d hate to be a dragon. I’ve already got 500 people coming to me with ideas all the time.”
A chronicle of curious contraptions
James Dyson set his sights on becoming an inventor in the mid-1960s after meeting Alec Issigonis, designer of the iconic Austin Mini, and Alex Moulton, who invented the rubber suspension system that allowed the Mini’s engineers to keep it so compact. He also counts Isambard Brunel and architect and futurist Buckminster Fuller among his influences.
While at London’s Royal College of Art in 1970, Dyson co-developed the Sea Truck, a shallow-draught fibreglass boat designed to carry cargo onto beaches and places with no jetty or harbour facilities. After , he moved on to his next brainwave, reinventing the wheel: in 1974 he launched the , a wheelbarrow with a ball in place of a wheel. By distributing pressure more effectively, the ball was less likely to get stuck in mud.
In 1978, Dyson began working on his signature invention: an alternative to traditional vacuum cleaners that clog their filters with dust as their bags fill, limiting their ability to suck up more dirt. His answer was to spin the dirt-carrying air to separate it out centrifugally, eliminating the need for a filter. His “dual cyclone” technology made Dyson’s vacuum cleaners a best-seller by 1995. Hoover came up with a variant on the cyclone idea, leading Dyson to sue for patent infringement. He won £4 million in damages in the UK High Court in 2002.
In 2003, Dyson’s lab unveiled a novel low-power, high-speed motor which then formed the heart of the Airblade, a superfast hand dryer.
One notable failure, however, was a washing machine launched in 2004, which provided an object lesson in over-engineering. With contra-rotating drums that mimicked the textile flexing involved in hand washing, it was by Dyson’s own admission over-complicated and expensive. It was discontinued.