Abstract
A scaled transparent modular model of pressure-swirl (PS) atomizer was prepared from cast PMMA (Poly(methyl methacrylate), Perspex™, Plexiglas™) with the aim to achieve a better understanding of internal flow and subsequent spray formation. Because of use of high-speed imaging and Laser Doppler Anemometry (LDA) the working liquid had to be selected with respect of a refractive index matching (RIM) with the atomizer material. The liquid should be colourless and chemically non-aggressive to the model material with suitable viscosity to achieve the Reynolds number of the internal flow of the original atomizer. Froude number should be high enough to neglect the influence of gravity on the flow. An extensive search for transparent liquids and materials of enlarged models was made with a focus on RIM in performed experiments. Several liquids were chosen, and their chemical effect on PMMA was tested. Despite the successful tests that proved the liquid suit the case, the model material was damaged and the tests proved to be insufficient. For this reason, the tests were modified to better involve the stress of the bolted model. It turned out that a force effect (bolt in the thread, pre-stressed bolt connection) on the material has a significant influence on the acceleration of the chemical effect. The internal flow was examined using a high-speed camera with several liquids.
Highlights
The PS atomizers are used industrially for example in combustion, painting, water cooling, etc
The internal flow determines the formation and shape of the air core, which indicates the form of the liquid sheet and subsequently the resulting spray
Due to the negative chemical behaviour of liquids, the production of the model from another material was considered. 2.1 The atomizer The model is made of cast PMMA and consisted of three pieces, one with the swirl chamber, the second part with the tangential inlet ports, and the last one is a cap
Summary
The PS atomizers are used industrially for example in combustion, painting, water cooling, etc. The pumped liquid is injected via tangential ports into a swirl chamber. High tangential velocity causes a swirl motion of liquid under which it leaves the exit orifice. The centrifugal motion of the liquid creates low-pressure zone with an air core along the centreline of the swirl chamber. The air core prevents the liquid from exiting and liquid flows out as a liquid sheet. The internal flow determines the formation and shape of the air core, which indicates the form of the liquid sheet and subsequently the resulting spray
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
