A comparative study between a Rankine cycle and a novel intra-cycle based waste heat recovery concepts applied to an internal combustion engine

Morgan, Rod; Dong, Guangyu; Panesar, Angad; Heikal, Morgan

doi:10.1016/j.apenergy.2016.04.026

Cited by 27 publications

(13 citation statements)

References 29 publications

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“…The novelty of the RSCE, compared to other SCEs, is that the crossover pipe utilises a recuperator (a heat exchanger). Waste heat from the exhaust is recovered to heat the charge air after compression but pre-combustion, which has been shown to be more efficient than recovery post-combustion using a Rankine cycle [22]. This concept is referred to as Dry Thermopower.…”

Section: Basic Principlesmentioning

confidence: 99%

Starting to Unpick the Unique Air–Fuel Mixing Dynamics in the Recuperated Split Cycle Engine

et al. 2021

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In this work air fuel mixing and combustion dynamics in the recuperated split cycle engine (RSCE) are investigated through new theoretical analysis and complementary optical experiments of the flow field. First, a brief introduction to the basic working principles of the RSCE cycle will be presented, followed by recent test bed results relevant to pressure traces and soot emissions. These results prompted fundamental questioning of the air-fuel mixing and combustion dynamics taking place. Hypotheses of the mixing process are then presented, with differences to that of a conventional Diesel engine highlighted. Moreover, the links of the reduced emissions, air transfer processes and enhanced atomisation are explored. Initial experimental results and Schlieren images of the air flow through the poppet valves in a flow rig are reported. The Schlieren images display shockwave and Mach disk phenomena. Demonstrating supersonic air flow in the chamber is consistent with complementary CFD work. The results from the initial experiment alone are inconclusive to suggest which of the three suggested mixing mechanism hypotheses are dominating the air–fuel dynamics in the RSCE. However, one major conclusion of this work is the proof for the presence of shockwave phenomena which are atypical of conventional engines.

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Section: Basic Principlesmentioning

confidence: 99%

Starting to Unpick the Unique Air–Fuel Mixing Dynamics in the Recuperated Split Cycle Engine

et al. 2021

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“…Heat lost in mechanical systems is usually through exhaust gases as in boilers [11][12][13][14], heat pump [15,16], industrial furnace [17,18], generators [19][20][21], internal combustion engines (ICE) [22][23][24][25][26][27][28], chimneys [29,30], and other applications [31][32][33][34][35] or by heating, ventilating, and air conditioning (HVAC) systems [36,37], and hot water [38][39][40][41][42]. Hossain and Bari [43] performed an experimental study on heat recovery from exhaust gases of a 40 kW diesel generator using different organic fluids.…”

Section: Heat Recovery From Exhaust Gasesmentioning

confidence: 99%

Domestic thermoelectric cogeneration system optimization analysis, energy consumption and CO2 emissions reduction

Jaber

Ramadan

Lemenand

et al. 2018

Applied Thermal Engineering

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“…One of the key tasks of achieving economic efficiency in the modern energy sector is to increase the production of electricity at thermal power plants through the use of non-traditional energy sources (Bhowmik et al, 2018;Akhmetshin et al, 2019;Kozhakhmetova et al, 2019). Combined technologies using waste heat of exhaust gases have great potential in the reconstruction This Journal is licensed under a Creative Commons Attribution 4.0 International License of old and the design of new diesel and gas turbine power plants (Robb, 2011;Morgan et al, 2016).…”

Section: Introductionmentioning

confidence: 99%

Evaluation of the Economic Efficiency of Heat Recovery From Exhaust Gas of Diesel Power Plants in Kazakhstan

Orynkanova

Stepanova

2020

IJEEP

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In today's world, the issue of efficient energy consumption and reducing dependence on fossil energy resources is especially acute. Each extra kilowatthour of electricity is a significant burden on the expenses of any type of enterprise, leading to a decrease in its competitiveness. The first step in solving this problem should be a general reduction in energy consumption by increasing the energy efficiency of the equipment used, choosing the best solutions for engineering systems and implementing a range of energy-saving measures. This study presents an instrument for achieving energy efficiency by utilizing waste gas heat on the example of existing fixed assets of diesel power plants in Kazakhstan. Based on an analysis of the technical indicators of the equipment, an economic analysis of the feasibility of utilizing the internal combustion engine's (ICE) waste heat is carried out. With the help of the latter it is determined that in the conditions of market electricity tariffs in Kazakhstan, the indicated innovations can be implemented in 3-3.5 years.

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A comparative study between a Rankine cycle and a novel intra-cycle based waste heat recovery concepts applied to an internal combustion engine

Cited by 27 publications

References 29 publications

Starting to Unpick the Unique Air–Fuel Mixing Dynamics in the Recuperated Split Cycle Engine

Starting to Unpick the Unique Air–Fuel Mixing Dynamics in the Recuperated Split Cycle Engine

Domestic thermoelectric cogeneration system optimization analysis, energy consumption and CO2 emissions reduction

Evaluation of the Economic Efficiency of Heat Recovery From Exhaust Gas of Diesel Power Plants in Kazakhstan

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