Understanding Sub and Supercritical Cryogenic Fluid Dynamics in Conditions Relevant to Novel Ultra Low Emission Engines

Jaya Madana Gopal,Robert Morgan,Konstantina Vogiatzaki,Giovanni Tretola,Guillaume De Sercey,Andrew Atkins

doi:10.3390/en13123038

Jaya Madana Gopal, Robert Morgan + Show 4 more

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https://doi.org/10.3390/en13123038

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Journal: Energies	Publication Date: Jun 12, 2020
Citations: 15	License type: CC BY 4.0

Affiliation: University of Brighton, Ricardo (United Kingdom)

Abstract

In this paper we provide insight into the thermophysical properties and the dynamics of cryogenic jets. The motivation of the work is to optimise the use of cryogenic fluids in novel ultra low emission engines. For demonstration, we use conditions relevant to an internal combustion engine currently being developed by Dolphin N2 and the University of Brighton, the CryoPower recuperated split cycle engine (RSCE). The principle of this engine is a split-cycle combustion concept which can use cryogenic injection in the compression cylinder to achieve isothermal compression and thus help maximise the efficiency of the engine. Combined experimental and numerical findings are presented and the effects of atomisation dynamics of the LN 2 are explored at both sub- and supercritical conditions in order to cover different pressure and temperature conditions representative of the engine compression cycle. For subcritical regimes, we observe that the appearance of the jet coincides with the predicted atomisation regimes based on the Weber, Ohnesorge and Reynolds numbers for other common fluids. For the modelling of supercritical jets, a new methodology within OpenFoam which accounts for Real Fluid Thermodynamics has been developed and the jet behaviour under various pressure and temperature conditions has been investigated. To our knowledge this is the first study where a cryogenic spray process evolution is examined for conditions relevant to the ones prevailing in a compression chamber accounting for both sub and supercritical conditions.

Highlights

Liquified gases such as liquid air, liquid nitrogen (LN2 ) or liquified natural gas (LNG) can serve as cost-effective energy vectors within power production units as well as transport “fuels” with zero emissions
Unlike other liquid or gas jets where the jet domain is comprised mostly of a single fluid phase, in a cryogenic jet that comes in contact with a hot supercritical environment, the fluid in the jet possesses properties corresponding to three different phases, namely liquid-like, transitional and gas-like
Following a comprehensive overview of thermodynamics properties of LN2 at various pressures and temperatures representative of a compression chamber, a combination of experimental analysis and numerical simulations was presented providing insight into the jet behavior at both sub and supercritical conditions in order to cover the full spectrum of conditions in the compression chamber

Summary

Introduction

Liquified gases such as liquid air, liquid nitrogen (LN2 ) or liquified natural gas (LNG) can serve as cost-effective energy vectors within power production units as well as transport “fuels” with zero emissions. Energy coming from renewable resources can be used in order to “cool” air or nitrogen, down to the point that they become liquids. Follow up injection of these liquids to a higher temperature environment causes rapid re-gasification and large expansion in volume. This can either drive a turbine or piston engine even without combustion (see for example the Dearman engine [1]). Because of the low boiling point of cryogenic liquids, low-grade or ambient heat can be used as a heat source, which otherwise is wasted. A better understanding and control of the injection dynamics of the Energies 2020, 13, 3038; doi:10.3390/en13123038 www.mdpi.com/journal/energies

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