Yes you can, and the period is lower the taller the building is. And there are dampers installed at the ground level as part of the system. The dampers you're referring to are more for wind-induced loading.

@@HollywoodF1 You're incorrect, frequency is lower and period is longer when it comes to taller buildings (less stiffness). Also, I believe The Hyperlapser is right, I'm not sure how you could incorporate this into a tall structure without running into issues with overturning.

It’s a friction pendulum system.

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paint

I was just asking the same thing

If it's a skyscraper shown in the video I don't believe there is a meterial dense and strong enough to support it for a long period without getting deformed. The principle and is good though.

If they put enough amount of 'that' thing, the pressure would be distributed hence making the weight of the building bearable to the material. but still dont think it would still be able to move and act as a 'stabilizer'. nice concept tho

@@zandwu2678 They can. In fact, they already have. Friction pendulum bearings (which these are a type of) have been installed and in service for decades and gone through earthquakes with flying colors. In fact, studies have suggested that in spite of the outrageously expensive regulatory burden put upon them, base isolation systems like these are probably more cost-effective over the long-term than standard "earthquake-proofing" practices.

@@randomkitty2555 The yield strength of 440C stainless steel, a high-performing but not prohibitively expensive alloy, can reach ~1900MPa (275,000psi). That means that in order to permanently deform a block of 440C requires about 50x the force necessary to crush a similarly sized block of typical concrete. In theory, that means that you'd only need enough pendulum bearings that their sliders could cover 1/50th of your foundation. In practice, you'd need even fewer than that, because concrete structures have to be made far stronger than steel ones in order to deal with concrete's brittleness.

And you know better? Are a engineer?

@@ronaldbautista7134 more or less he's right

@@ronaldbautista7134 Just because you're ignorant doesn't mean everyone else is.

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Thank you for your comment. The anti-seismic isolators are designed for high vertical concentrated load. As reference, the sliding material used has a compression resistance of 180 MPa which for a disc of 20 cm diameter means more than 500 ton (5’000 kN) resistance

just like you repair a car tire

These are maintenance-free. They last longer than the building they support-- even if they experience design-level earthquakes.

Not conceptual. already in use, base isolation course would make you understand better.

​@@maheshkumar6781 - - base isolation course? The video should explain it. It doesn't show a demonstration of how it would react to P waves.

Thanks for your message. Yes, the holder of the copyright is mageba. You can you use it in your presentation with "© mageba" and only in its original version. Modifications of any kind are not allowed.

magebagroup thank you very much !

Thank you for your comment. Regarding your question there is actually no upper limit in principle. To date we have built pendulum bearings with up to 120 MN maximum vertical load.

Why would there be a maximum load? Just build bigger dampers.

Normally the life cycle of this isolators is around 60 years. For ease of replacement, the devices are installed using bolted connections. By using lifting devices (e.g. hydraulic jacks), it is possible to replace them by lifting few millimeters and unbolting the devices.

@@magebagroup That seems like very hard job, I think that there is not a lot of space under the building, and such a hydraulic tool weighs up to 500 kilos. Whether there is enough space below for some kind of forklift? Thank you for your answer and your time.

It looks suspiciously like a bearing cup from a double shear beam loadcell, on steroids! Trouble is, with the buildings, you have a lot of weight concerntrated in a very small area. As a result, you would need some serious hydraulic jacks to lift the building up a few millimetres to get the system changed. The only thing that worries me with this system is when the ground rises or falls. How does the system cope with vertical movement?

@@111jacare Thanks for your interest in our isolation system. Yes, we have hydraulic jacks that allow the replacement of anti-seismic isolators. The vertical component of the earthquake is also considered in the design of the device, in the respective NEd,max and NEd,min (as defined in EN 15129). In most cases the vertical component is not strong enough to create temporary gaps or shocks between the components of our isolators. While in structures where uplift forces are expected, uplift restraints are also foreseen

Thanks for contacting us. Our contact in Mexico: mageba México Prolongación Corregidora Norte, No. 1116 9PH, Colonia Arboledas, C.P. 76140, Santiago de Querétaro, México www.mageba.net/es/ We are looking forward to hearing from you.

thanks for you comment. Please visit: www.mageba-group.com/tr/tr/ You can find contact details on the bottom of the website. Or use contact form: www.mageba-group.com/tr/tr/1068/all.htm

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Nice

Thanks a lot for your interest in our animation and your comment. It indeed shows the approximate behavior you can expect during a real earthquake of high magnitude 8.0 - 9.0 (Richter): the relative displacements showed are quite long (several meters at the top of the building) and the oscillation frequency around 0.5 - 1.0 [Hz]; The isolated building shows some bending though much lower than the non-isolated building.