Early Autumn - Apple and Cinnamon

New VapeSafe Early Autumn eLiquid.

Early Autumn - Apples and Cinnamon flavored eLiquid evokes memories of the beginning of fall. The feel of the warm autumn sun on the skin. The sight of vibrant hues of amber and crimson leaves hanging in gently swaying trees soaking up the light. The rustling sound of the breeze slipping through the tree branches tugging and teasing the remaining leaves into releasing their hold and floating downward. The laughing children raking the leaves into piles and then running and jumping into the soft, luscious piles scattering the leaves again. The delicious smells of baking apple and cinnamon pies wafting through open windows. These are the sights, smells and tastes of Early Autumn.

Early Autumn eLiquid by VapeSafe captures the essence of Autumn no matter what season it is. Early Autumn eLiquid is flavorful combination of apples and cinnamon. As with all of the VapeSafe eLiquids, our mixtures are designed to produce nice, heavy vapors and the most succulent flavors. Try Early Autumn eLiquid today!

Technology Information:

Resonance penetration of gas bubbles through a thin liquid layer: a capillary resonator and its use for the generation of droplets [An article from: Journal of Aerosol Science]

Description

This digital document is a journal article from Journal of Aerosol Science, published by Elsevier in 2004. The article is delivered in HTML format and is available in your Amazon.com Media Library immediately after purchase. You can view it with any web browser.

Description:
As it is well known, a bounded layer of liquid forms an oscillatory system (resonator) for surface waves. We consider a capillary wave resonator that is composed by a thin liquid layer placed on a substrate and surrounded by a solid ring. The dimensions of the system are chosen so that gravity forces are small compared with forces from surface tension. Standing capillary waves are excited by a gas flow supplied through a small orifice in the substrate. Stable oscillations in various resonator modes are described which are accompanied by ordered formation and destruction of gas bubbles producing the regular streams of identical droplets. The mechanism of self-oscillatory behaviour based on the correspondence between bubble growth time and oscillation period is proposed and analysed. Possible applications of the phenomenon, in particular, for the generation of monodisperse droplets without special periodic stimulation, are discussed.

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