Emptying using Siphon Effect | Bell Shipon

Описание: The fundamental principle is based on hydrostatics, or the relationship between the height of a fluid column and its pressure. At the highest point in a siphon, the pressure is actually lower than atmospheric pressure, also known as a vacuum. This allows the atmospheric pressure to push water up over the peak of the siphon so gravity can carry it the rest of the way.

A bell siphon has three basic parts: a reservoir, the bell, and a riser.


Here’s how it works:

As water fills the reservoir, the surface of the water is equally exposed to atmospheric pressure.

Outside the bell, it’s exposed to the atmosphere from open top of the reservoir, and inside the bell it’s exposed to atmospheric pressure through the empty riser tube.

As the water rises, it eventually forms a seal over the riser tube inside the bell, closing off the bell’s connection to the atmospheric pressure.
As the water falls through the riser pipe, it creates a vacuum inside the bell, drawing more water from the reservoir up and out.

Eventually the water level in the reservoir drops below the bell, allowing air to enter and breaking the siphon. As the remaining water drains from the riser, the pressure inside the bell returns to atmospheric and the process starts over again.


The vacuum is not important in the first instants where the siphon is operating. Indeed, there will not be a vacuum at first. It will be atmospheric pressure inside the bell.

The vacuum becomes important as the siphon picks up speed and starts emptying the tank. As the water drains out of the drain tube, something has to occur to take the space of that volume of water. Either air needs to flow into that space, or water does. While the water level in the tank is above the level of the top of the drain, its pretty easy to see that what replaces it is water, because the water level outside of the bell is higher than inside.

Once the water level in the tank is below that of the drain, the vacuum becomes important. The volume of air in the bell can grow, as you show in your pseudo-answer. However, when it does so, the pressure in that air volume decreases, which pulls more water into the bell. Once there is enough water in the bell, gravity will smooth out the surface of the water to cover the siphon hole, and that will feed more water into the siphon.

If you cannot develop a sufficient vacuum, meaning you did not get the bell sufficiently full (because you didn't put enough water in the tank), then the slug of water that falls into the drain tube can further down the drain tube before the vacuum is strong enough to pull enough water up into the bell. When this happens, the slug of water in the drain tube is eventually pulled to one side by the difference in pressure between the outside air below the drain and the low-pressure area in the bell, and a bubble of air gets to travel backwards into the bell. This further reduces the pressure difference, so it can't pull the water up into the bell, and we quickly find the siphon fails to start.

#Siphon #Drainage #Science