Determining the Maximum Number of Oranges to Harvest from a Fruit Stand before its Collapse

Determining the Maximum Number of Oranges to Harvest from a Fruit Stand before its Collapse

A small team of physicists and mechanical⁤ engineers from⁤ Universidad ‍de Antofagasta, Universidad ⁤Autónoma de Chile and Universidad de O’Higgins, all in Chile, has found ⁤a way to find the stability ‍points of granularly arranged monolayers ⁤in a ⁣single pile with ⁤tilted slopes.

Many grocery stores ⁤display fruit for ⁣sale by⁢ assembling piles aimed at showing off their deliciousness. Such piles ⁢tend to⁤ have sloped‌ edges, giving an overall image ​of instability—unwary shoppers who grab a single orange from the wrong part of the pile may set off a collapse ​with ‍fruit rolling off the shelf and​ onto the floor. ‌In this new effort, the⁢ research team found ​the tipping‍ points of ⁢such piles.

The researchers created simulations​ depicting piled⁣ spheres ⁤of various sizes stacked with ⁢varying edge slopes and ran them under ⁤multiple configurations, from ‌modest slopes ⁤to extreme. They found ⁢that spheres​ piled with extreme slopes can indeed collapse if⁤ just a single ⁢sphere is ⁢removed from the sloped edge. They​ also found that for modest slopes,⁢ nearly any number​ of spheres can be removed without ⁣causing a⁤ collapse. It was in between such extremes that things⁤ became more difficult to predict.

Slowly increasing the slope angle, ‌they found, led to situations where removing multiple spheres rather than just one could result in collapse. They also calculated that under average circumstances, such ​as those typically found in a ⁢grocery store, up⁣ to 10% of‌ the spheres‍ (apples, oranges, or grapefruit, for example) must be removed before a‍ collapse. Thus, an​ individual shopper is unlikely to incite a⁤ collapse if they remove just one piece of fruit—unless several ‌shoppers ⁤before them have done the same ⁣from the⁣ same location.

The researchers plan ⁣to continue their‌ work, looking into ⁤other real-world possible⁢ collapse scenarios, such as piles of rocks⁢ of different sizes.

2024-01-05⁢ 18:00:04
Source from phys.org rnrn

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