For over a century, escalators have followed a fairly straight path - with the exception of a few spiral and curved escalators found in cities including Reno and Osaka. Now a researcher at City University London has developed a new type of escalator called the Levytator that is capable of following freeform curves. This is achieved by replacing the traditional rectangular steps with curved modules that also allows the modules to be placed in a continuous loop. Not only does this open up the design possibilities for architects, it could also cut energy usage in half compared to conventional escalators.
Conventional escalators see redundant steps moving underneath those in use and require two separate escalators powered by two separate motors to carry passengers both up and down. Through the use of curved modules as steps, the Levytator, designed by Jack Levy, an Emeritus Professor of Mechanical Engineering at City University London, can be used in a continuous loop - following a curved path upwards, flattening and straightening out, before descending again. This means only one power source is required to carry passengers both up and down. Additionally, the weight of passengers traveling down can be used to offset the weight of passengers traveling up to further enhance energy savings.
As a result of mathematical modeling of the concept conducted with fellow University researcher, Elena Shcherbakova, Levy predicts that a fully-loaded Levytator with the maximum number of passengers traveling up and down would use around 80 percent of the power of two traditional escalators making the same trips. Meanwhile, a half-loaded Levytator with the down path full and the up path empty would use half the energy of the two equivalent escalators.
"The Levytator was primarily developed to give architects the ability to create escalators in any shape they want, but we've now shown that the design could significantly cut power consumption too. As utility bills rise and more organizations strive for green accreditation for their premises, we hope the Levytator can play an important role in cutting both energy use and the associated costs," says Levy.
But the advantages of the Levytator don't stop at aesthetics and energy savings. Because the curved modules are always "on top" and all the steps can be accessed from above, maintenance is much easier. Additionally, as no excavation is required for installation, the Levytator could be placed on top of an existing staircase.
"This could be particularly useful in the heritage sector, where the system could be placed on top of a grand staircase in a listed stately home, providing better access for elderly and disabled visitors, but not destroying the fabric of the building," points out Levy.
With such an ingeniously simple design and the obvious energy savings, it's hard to see Levytators not taking off. The only possible downside I can see is escalator walkers taking a dive after finding only thin air where they are used to finding a straight edged step. The technology has already been patented in the U.K., Europe, the U.S.A. and China. Revy has already built a scale model Levytator and City University London is currently in talks with investors, escalator manufacturers, architects and property developers worldwide, to build and install the first full-size Levytator.
Revy's functioning scale model Levytator can be seen in the following video.
Also I think the single person upper entrance/exit would cause traffic problems in a high volume area
The energy halving would be when there is nobody going up but lots of people going down. Makes sense. With a bit of engineering, it should be possible to create a \"regenerative energy harvesting function\" when say at a sports event, all the people coming down the \"stairs\" would be charging batteries, or pumping water to a great height so that that can be used when the next time somebody goes up. Just like regenerative braking on electric vehicles harvests energy.
I don\'t ever recall see a baggage moving system which works in three dimensions. They\'re usually flat.
P.S.: why the steps are so tall? IMO they would need only about 1.5 to 2× of step height, so about 40cm, but on the picture it seems like 5× or so (1m). Saving the height so weight and dimensions needed would make it even more power saving and fitting in more places.
@Laprivan of the Yellow Eyes - "I don't ever recall see a baggage moving system which works in three dimensions. They're usually flat", Joe Blake
@Tom Kapler - about the steps size? It's a model
How can you people keep talking about these innovations on this kind of website being such a short minded? Do something useful instead...
Fixed spiral or winding staircases are only allowed in the US now with a 6-8\" minimum depth at the narrowest edge of the tread - no more coming to a point, or even near that.
And yes, I am a builder.
Forrest
However it may be that this escalator needs to be narrow enough that most passengers can grasp both handrails, which could preclude the passing width common on American escalators.