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Abstract

With the increasing demand for high reliability and refined maintenance of marine diesel generators under diverse operating conditions, traditional experience-based condition assessment methods have become insufficient to meet the requirements for high precision and reliability. To address this issue, this study focuses on the convective heat transfer characteristics of marine diesel generators under typical operating conditions and proposes a systematic evaluation method for convective heat transfer effectiveness. First, a heat transfer efficiency evaluation framework was established, comprehensively considering key influencing parameters. Then, based on numerical simulations under multiple operating conditions, the convective heat transfer characteristics of the generator were systematically analyzed, and an empirical regression model was developed to quantitatively describe the temperature evolution of the stator coil. Finally, the model was validated using experimental data collected at different time points within the maintenance cycle, forming a closed-loop process of evaluation and verification. The results show that the convective heat transfer efficiency of the generator exhibits a significant decline over time: approximately 97.09% in the early stage, 91.54% in the middle stage, and 84.97% in the later stage, with reductions of 5.55% and 6.57% in the two intervals, respectively. This finding indicates that the continuous accumulation of fouling considerably accelerates the degradation of heat transfer performance. The proposed evaluation method demonstrates strong quantitative capability in assessing the heat transfer efficiency of the generator’s stator coil under various operating conditions. It effectively characterizes the evolution of heat transfer performance and provides a reliable theoretical foundation for condition assessment and maintenance strategy optimization of marine diesel generators.

Keywords

generator system convective heat transfer numerical simulation regression analysis effectiveness evaluation

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References

Ahmadi

Shahnazari

Vaziri Sarashk

. An efficient integrated model for diesel-engine three stage brushless synchronous generator. IET Electric Power Appl 2023; 17(12): 1535–1547.

Ouyang

Gao

, et al. Research on fault diagnosis of ship diesel generator system based on IVY-RF. Energies 2024; 17(22): 5799.

Christian

Iraklis

. Mar-RUL: A remaining useful life prediction approach for fault prognostics of marine machinery. Appl Ocean Res 2023; 140: 103735.

Dang

Pham

Labbe

, et al. CFD analysis of turbulent convective heat transfer in a hydro-generator rotor-stator system. Appl Therm Eng 2018; 130: 17–28.

Mikhail

. Numerical simulation of convective heat transfer. Energies 2023; 16(4): 1761.

Tang

Liu

, et al. Research status and development trends of thermal management technologies for motors. Iran J Sci Technol Trans Mech Eng 2024; 48(4): 2025–2057.

Prabir

Rao

. Natural convection of nanofluids in a wavy porous cavity. Proc Inst Mech Eng C J Mech Eng Sci 2022; 236(7): 3847–3863.

Degavath

Hina

Salman

, et al. Impact of convective heat transfer and buoyancy on micropolar fluid flow through a porous shrinking sheet: an FEM approach. Proc Inst Mech Eng C J Mech Eng Sci 2022; 236(8): 3974–3985.

Ibrahim

Alp

Sibel

. Experimental investigation of natural convection heat transfer from functionally graded annular fins on an inclined cylinder. Proc Inst Mech Eng C J Mech Eng Sci 2025; 239(12): 4774–4791.

10.

Liu

, et al. Influence analysis of convective heat transfer of circular tubes and flat plates in a polar environment. Front Energy Res 2022; 10: 937343.

11.

Liu

Zhou

Yang

, et al. Methodology for determining convective heat transfer coefficients on the tubesheet surface of shell-and-tube heat exchangers under single-phase flow. Numer Heat Transf A Appl 2025; 86(4): 919–936.

12.

Chen

Zhang

, et al. Modeling of turbulent convective heat-transfer characteristics in a concentric annular channel. Energies 2023; 16(4): 1998.

13.

Wang

Yang

. Corrected correlation for turbulent convective heat transfer in concentric annular pipes. Energies 2025; 18(14): 3643.

14.

Rodriguez

Campo

. Numerical investigation of forced convection heat transfer from a sphere at low Prandtl numbers. Int J Therm Sci 2023; 184: 107970.

15.

Jia

, et al. Heat transfer characteristics of external ventilated path in compact high-voltage motor. Int J Heat Mass Transf 2018; 124: 1136–1146.

16.

Pang

Zhang

Wang

, et al. A three-dimensional analytical model for performance evaluation of thermoelectric generators. Case Stud Therm Eng 2024; 64: 105579.

17.

Stefan

Rico

Jens

. Experimental investigation of unsteady convective heat transfer under airflow velocity and temperature variations. Meas Sci Technol 2021; 33(1): 015106.

18.

Wang

Liu

Wang

, et al. Numerical and experimental investigation on the integrate performance of axial flow cooling fan and heat exchanger. Appl Therm Eng 2024; 245: 122814.

19.

Wang

Blocken

Lin

. CFD simulation of the stratified atmospheric boundary layer: consistency between Monin-Obukhov similarity theory and the standard k-ε model. Build Environ 2025; 267: 112284.

20.

Gong

Shen

. Study on heat flow decay in vertical jet of aircraft deicing fluid based on phase field and realizable k-ε turbulence model. Therm Sci Eng Prog 2025; 60: 103446.

21.

Zhang

Song

, et al. Calibration of RNG k-ε model constants based on experimental data assimilation: a study on the flow characteristics of air-lifted plunger interstitial flow. Appl Sci 2025; 15(8): 4515.

22.

Zhai

Fuhrman

Damgaard Christensen

. Numerical simulations of flow inside a stone protection layer with a modified k-ω turbulence model. Coast Eng 2024; 189: 104469.

23.

Rahman

Vuorinen

Taghinia

, et al. Wall-distance-free formulation for SST k-ω model. Eur J Mech B Fluids 2019; 75: 71–82.

24.

Zhao

Wei

Hao

, et al. Turbulence simulations with an improved interior penalty discontinuous Galerkin method and SST k-ω model. Comput Fluids 2023; 263: 105967.

25.

Younoussi

Ettaouil

. Calibration method of the k-ω SST turbulence model for wind turbine performance prediction near stall condition. Heliyon 2024; 10(1): e24048.

26.

Bin

Park

, et al. Large eddy simulation of separated flows on unconventionally coarse grids. J Fluid Eng 2024; 146(9): 091501.

27.

Möller

Tucker

Wang

, et al. Transitional delayed detached-eddy simulation for a compressor cascade: a critical assessment. J Propulsion Power 2024; 40(4): 533–546.

An innovative method for evaluating convective heat transfer effectiveness in generator systems under complex operating conditions

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