A smart load-speed sensitive cooling map to have a high- performance thermal management system in an internal combustion engine

A smart load-speed sensitive cooling map to have a high- performance thermal management system in an internal combustion engine

Considering the fact that electrification is increasingly used in internal combustion engines, this paper aims at presenting a smart speed-load sensitive cooling map for better thermal management. For this purpose, first, thermal boundary conditions for the engine cooling passage were obtained by th...

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Veröffentlicht in:Energy (Oxford) 2021-08, Vol.229, p.120667, Article 120667
Hauptverfasser: Naderi, Alireza, Qasemian, Ali, Shojaeefard, Mohammad Hasan, Samiezadeh, Saman, Younesi, Mostafa, Sohani, Ali, Hoseinzadeh, Siamak
Format: Artikel
Sprache:eng
Schlagworte:
Boundary conditions
Combustion
Coolant pumps
Cooling
Cooling flows (astrophysics)
Cooling map
Cooling rate
Electrification
Heat transfer
Internal combustion engine
Internal combustion engines
Load distribution
Power consumption
Power consumption reduction
Radiators
Stress concentration
Temperature distribution
Thermal management
Wall temperature
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container_end_page
container_issue
container_start_page 120667
container_title Energy (Oxford)
container_volume 229
creator Naderi, Alireza
Qasemian, Ali
Shojaeefard, Mohammad Hasan
Samiezadeh, Saman
Younesi, Mostafa
Sohani, Ali
Hoseinzadeh, Siamak
description Considering the fact that electrification is increasingly used in internal combustion engines, this paper aims at presenting a smart speed-load sensitive cooling map for better thermal management. For this purpose, first, thermal boundary conditions for the engine cooling passage were obtained by thermodynamic and combustion simulation. Next, the temperature distribution of the cooling passage walls was determined using conjugate heat transfer method. Then, the effect of engine load on wall temperature distribution was investigated, and it was observed that in the conventional mode where the cooling flow is only affected by the engine speed, the engine is faced with over-cooling and under-cooling. Therefore, the optimum flow for cooling the engine was achieved in such a way that the engine is hot enough and kept free from damage, while the engine has a more uniform temperature distribution. These calculations were performed by considering the boiling phenomenon. The results showed using the cooling map leads to a significant reduction in coolant flow, which in turn reduces the power consumption of the water pump and size of the radiator. Moreover, fuel consumption, hydrocarbon emission production, and the needed power of the coolant pump are enhanced by 2.1, 8.6, and 44.3%, respectively. •The coolant flow rate is 10.6% lower than the conventional system in the full load.•21.3% changes in comparison to the conventional cooling is seen for the part load.•More uniform temperature distribution is achieved by applying smart cooling.•Neither overcooling in the part load nor undercooling in the full load happens.•Compared to the conventional cooling, pump power consumption gets 44.3% lower.
doi_str_mv 10.1016/j.energy.2021.120667
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source Elsevier ScienceDirect Journals Complete
subjects Boundary conditions
Combustion
Coolant pumps
Cooling
Cooling flows (astrophysics)
Cooling map
Cooling rate
Electrification
Heat transfer
Internal combustion engine
Internal combustion engines
Load distribution
Power consumption
Power consumption reduction
Radiators
Stress concentration
Temperature distribution
Thermal management
Wall temperature
title A smart load-speed sensitive cooling map to have a high- performance thermal management system in an internal combustion engine
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