考虑椭圆孔组合偏转的冷却布局多维高效优化

doi:10.7527/S1000-6893.2025.31584

Abstract

Abstract:

To deeply explore the multivariate design space considering the combination of oval hole inclination angles， and further enhance the aero-thermal performance of the squealer tip， the steady-state RANS numerical simulation method was employed to optimize the cooling layout on a squealer tip. The variation of the flow field and the resulting performance improvement were analyzed. More importantly， to accelerate the rate of engineering optimization， a high fast-converging optimization algorithm suitable for high-dimensional engineering problems was developed based on the framework of a classical evolutionary algorithm and advanced optimization operators. Following classical function testing， a mixed optimization of single objective and bi-objective was conducted. The results demonstrated that in the optimal structure， the spacing between cooling holes is reduced， the wall attachment performance is improved with elevated positive axial inclination angles， and the coupling relationship between film coverage and cooling hole orientation is better balanced. The film cooling effectiveness is increased by 79.9%， and the enhancement of stage efficiency reaches 0.054% in comparison to the benchmark structure.

Key words: turbine, squealer tip, film cooling, oval hole, multi-objective optimization

CLC Number:

V232.4

Jiajie GUO, Zhi TAO, Liming SONG, Jun LI. Multi-dimensional and efficient optimization of cooling layout considering combination of oval hole inclination angles[J]. Acta Aeronautica et Astronautica Sinica, 2025, 46(16): 131584.

Figures/Tables 32

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References 30

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参数	值
进口总压/kPa	344.74
进口总温/K	709.0
出口静压/kPa	141.44
壁面温度/K	500.0
冷气温度/K	344.0
湍流度/%	5
冷气流量/（g·s^-1）	0.108 994

网格数/10⁶	泄漏流量/%	偏差/%	总压损失系数	偏差/%
9.46	2.438 1	0.685 5	0.074 395	0.910 2
12.36	2.430 8	0.384 1	0.073 960	0.320 1
16.07	2.424 4	0.119 8	0.073 800	0.103 1
20.59	2.421 5		0.073 724

变量	定义	范围
x₁/mm	H1位置	0.2~1.2
x₂/mm	H2位置	0.4~3.8
x₃/mm	H3位置	0.2~4.0
x₄/mm	H4位置	0.2~4.0
x₅/mm	H5位置	0.4~3.8
x₆/（°）	H1轴向偏转角	-60~60
x₇/（°）	H2轴向偏转角	-60~60
x₈/（°）	H3轴向偏转角	-60~60
x₉/（°）	H4轴向偏转角	-60~60
x₁₀/（°）	H5轴向偏转角	-60~60
x₁₁/（°）	H1径向偏转角	-30~30
x₁₂/（°）	H2径向偏转角	-30~30
x₁₃/（°）	H3径向偏转角	-30~15
x₁₄/（°）	H4径向偏转角	-30~15
x₁₅/（°）	H5径向偏转角	-30~30
x₁₆/（°）	H1自偏转角	-20~20
x₁₇/（°）	H2自偏转角	-20~20
x₁₈/（°）	H3自偏转角	-20~20
x₁₉/（°）	H4自偏转角	-20~20
x₂₀/（°）	H5自偏转角	-20~20

测试函数	特征	解析最优值	变量维度	算法	均值	标准差
Ellipsoid	单峰函数	0	50	AHEA	2.84×10^-18	8.42×10^-18
				RAHEA	6.90×10^-17	1.50×10^-16
				GSDE	1.03×10^-1	7.39×10^-2
				AHA	1.89×10^-4	3.12×10^-4
				GA	3.31×10³	3.85×10²
			100	AHEA	1.61×10^-19	4.77×10^-19
				RAHEA	5.55×10^-18	7.99×10^-18
				GSDE	3.27	3.92
				AHA	4.11×10^-4	5.34×10^-4
				GA	2.08×10⁴	1.49×10³
Rosenbrock	狭长山谷状函数	0	50	AHEA	4.87×10¹	7.14×10^-2
				RAHEA	4.83×10¹	3.16×10^-1
				GSDE	4.79×10¹	5.98×10^-1
				AHA	4.90×10¹	2.17×10^-2
				GA	4.28×10³	3.04×10²
			100	AHEA	9.88×10¹	4.11×10^-2
				RAHEA	9.87×10¹	1.14×10^-1
				GSDE	9.80×10¹	2.86×10^-1
				AHA	9.90×10¹	2.74×10^-2
				GA	1.74×10⁴	1.94×10³
Ackley	多峰函数	0	50	AHEA	1.78×10^-13	3.73×10^-13
				RAHEA	6.42×10^-11	1.21×10^-10
				GSDE	9.96×10^-3	1.87×10^-2

测试函数	特征	解析最优值	变量维度	算法	均值	标准差
Ackley	多峰函数	0	50	AHA	2.33×10^-2	2.31×10^-2
			50	GA	1.95×10¹	2.14×10^-1
			100	AHEA	5.49×10^-13	9.98×10^-13
				RAHEA	9.36×10^-12	1.91×10^-11
				GSDE	1.78×10^-1	1.20×10^-1
				AHA	9.64×10^-3	1.24×10^-2
				GA	2.02×10¹	1.23×10^-1
Griewank	多峰函数	0	50	AHEA	<1.0×10^-17	<1.0×10^-17
				RAHEA	4.13×10^-15	1.18×10^-14
				GSDE	5.52×10^-3	7.42×10^-3
				AHA	1.42×10^-2	2.76×10^-2
				GA	5.09×10²	5.45×10¹
			100	AHEA	<1.0×10^-17	<1.0×10^-17
				RAHEA	9.99×10^-17	2.014×10^-16
				GSDE	1.90×10^-1	5.69×10^-2
				AHA	4.85×10^-2	1.30×10^-1
				GA	1.63×10³	1.13×10²

Multi-dimensional and efficient optimization of cooling layout considering combination of oval hole inclination angles

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变量	定义	优化取值
x₁/mm	H1位置	0.38
x₂/mm	H2位置	0.60
x₃/mm	H3位置	0.20
x₄/mm	H4位置	0.31
x₅/mm	H5位置	0.40
x₆/（°）	H1轴向偏转角	60.0
x₇/（°）	H2轴向偏转角	60.0
x₈/（°）	H3轴向偏转角	48.9
x₉/（°）	H4轴向偏转角	58.1
x₁₀/（°）	H5轴向偏转角	39.0
x₁₁/（°）	H1径向偏转角	-19.2
x₁₂/（°）	H2径向偏转角	-30.0
x₁₃/（°）	H3径向偏转角	-30.0
x₁₄/（°）	H4径向偏转角	1.4
x₁₅/（°）	H5径向偏转角	-30.0
x₁₆/（°）	H1自偏转角	20.0
x₁₇/（°）	H2自偏转角	-3.1
x₁₈/（°）	H3自偏转角	20.0
x₁₉/（°）	H4自偏转角	14.0
x₂₀/（°）	H5自偏转角	-16.4

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