Temperature optimisation of a diesel engine using exhaust gas heat recovery and thermal energy storage (diesel engine with thermal energy storage)

Kauranen, Pertti; Elonen, Tuomo; Wikström, Lisa; Heikkinen, Jorma; Laurikko, Juhani

doi:10.1016/j.applthermaleng.2009.11.008

Cited by 46 publications

(12 citation statements)

References 4 publications

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“…Although TES systems have been largely studied in other industrial sectors, both in connection with Diesel engines [10][11][12] and in transportation [13,14], there is no record of TES application to shipping in the scientific literature. The aim of this paper is that of partially filling this gap with a study on the potential of said application and on the influence of relevant parameters on the performance of the system.…”

Section: Introductionmentioning

confidence: 99%

A Preliminary Study on the Application of Thermal Storage to Merchant Ships

et al. 2015

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The shipping industry is focusing more and more on reducing fuel consumption and greenhouse gas emissions. A non-negligible amount of fuel is consumed while ships are in port, waiting for loading or unloading, for heating up accommodation spaces and fuel tanks, while when at sea waste heat from engines exhaust is under-used because of low demand. In this paper we propose the use of thermal energy storage as a solution for the mismatch between heat availability and demand. A simplified system is proposed and the influence of design parameters (storage size, heat exchangers surface, secondary fluid mass flow rate, storage temperature) on the performance of the system is analyzed. The results of the application of a thermal energy storage system to a case study ship show that the installation of a storage tank of 1000 m 3 could reduce the fuel consumption from the boilers by 80%, which would lead to yearly savings of 268,000 USD. This preliminary analysis shows that there is potential of both economic and environmental benefits from the application of thermal energy storage to merchant vessels.

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Section: Introductionmentioning

confidence: 99%

A Preliminary Study on the Application of Thermal Storage to Merchant Ships

et al. 2015

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“…Mavridou et al [16] examined two groups of configurations: (a) a classical shell and tube heat exchanger using staggered cross-flow and (b) a cross-flow plate heat exchanger, initially with finned surfaces on the exhaust gas side and then with metal foam material substituting for the fins and they attempt to minimize the volume and weight of the arrangement, while at the same time maintaining the heat transfer from the gas side at a maximum range. Kauranen et al [17] used phase change materials (PCM) and latent heat accumulator (LHA) for diesel exhaust waste heat recovery which helped to fuel economy and emissions reduction. In a different study, Baker et al [18] designed a multi-pass duct-shaped heat exchanger for a diesel engine by numerical finite difference method (FDM) and examined the effect of thermoelectric generators (TEGs), porous structure and fins in heat recovery amount which found the 1.06 kW maximum net electrical powers achieved for the three parallel flow paths in a counter-flow arrangement.…”

Section: Introductionmentioning

confidence: 99%

Investigations of fin geometry on heat exchanger performance by simulation and optimization methods for diesel exhaust application

Hatami

Ganji

Gorji-Bandpy

2015

Neural Comput & Applic

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In this paper, three cases of heat exchangers (HEXs) in the exhaust of a diesel engine are modeled numerically for improving the exergy recovery amount. Simple double pipes, longitudinal and circular finned-tube HEXs are modeled to study the fin effect in waste heat recovery amount. It is tried to compare the circular and longitudinal fin's effect (with the same surface area) on exergy recovery and pressure drop in the exhaust. As a main outcome, results show that circular fins cannot enhance exergy recovery due to trapping the gases between them and producing a high pressure drop compared to longitudinal fins. Also, L 16 Taguchi array is applied to find the most important parameters in longitudinal fins to find the optimum design for this heat exchanger. Finally, a multi-objective optimization by central composite design is applied to find the optimum dimensions of proposed HEX in different engine loads.

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“…Broatch et al [10] evaluated the potential of an intake air heating technology, by means of electrical heaters, for the reduction of pollutant emissions from diesel engine combustion during a NEDC cycle, showing a reduction of 13% in HC, 5% in CO and 3% in NOx but particulate matter increases about 4%. Kauranen [11] proposes a double heat recovery system from the combination of exhaust gas heat recovery system and latent heat accumulator for thermal energy storage, using the energy to heat the engine coolant during a cold start and low engine load.…”

Section: Introductionmentioning

confidence: 99%

Potential of exhaust heat recovery for intake charge heating in a diesel engine transient operation at cold conditions

Luján

Climent

Dolz

et al. 2016

Applied Thermal Engineering

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In this paper, an experimental facility is implemented with the aim of improving the performance of internal combustion engines working at low ambient temperatures. Pollutant emissions and fuel consumption are one of the major issues that automotive engineers have to face. Cold engine start and warming up analysis have become important topics for researches. In this work, an exhaust heat recovery system for a diesel engine has been proposed as a solution to cold operation negative effects. The energy obtained from the exhaust gases was used to increase the intake air temperature. The experiments were carried out in transient load conditions at three different levels of ambient temperature (up to-7ºC). Exhaust heat recovery was combined with different strategies of exhaust gas recirculation. Intake air heating results with the heat recovery system show a reduction of 65% in unburned hydrocarbons, 40% in carbon monoxide and 10% in fuel use compared to standard air-air intercooler.

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Temperature optimisation of a diesel engine using exhaust gas heat recovery and thermal energy storage (diesel engine with thermal energy storage)

Cited by 46 publications

References 4 publications

A Preliminary Study on the Application of Thermal Storage to Merchant Ships

A Preliminary Study on the Application of Thermal Storage to Merchant Ships

Investigations of fin geometry on heat exchanger performance by simulation and optimization methods for diesel exhaust application

Potential of exhaust heat recovery for intake charge heating in a diesel engine transient operation at cold conditions

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