面向中等身材儿童安全的校车智能气囊优化设计

doi:10.16265/j.cnki.issn1003-3033.2025.12.0140

摘要/Abstract

摘要：

为减轻校车正面碰撞中,中等身材儿童的生物力学损伤程度,开展智能气囊的优化设计研究。首先,基于台车试验,构建、验证校车仿真模型;其次,确立10岁儿童全方位人体安全模型(THUMS)假人头部、胸部与腿部损伤指标的输出方法,搭建校车-THUMS假人-智能气囊耦合模型;然后,基于第三代非支配排序遗传算法(NSGA-III),提出自适应传播因子、引入高斯变异算子、融合粒子群进化机制、改变非支配排序方法,从而提出改进型NSGA-III;最后,利用改进型NSGA-III,开展优化设计,获得气囊的最优配置。结果表明:改进型NSGA-III的性能优于其他3种著名的优化算法;正常、前倾10和20°、右倾5和10°及躺卧坐姿下,当充气阀的气体质量流率比例系数、泄气阀的开启压力和开度系数、气袋的安装点高度分别为1.23、1.37×10⁵ Pa、2.10与478 mm时,中等身材儿童的头部伤害指标(HIC₁₅),颅内压力(IP),肝脏压力(LP),左、右大腿力(F_L、F_R),加权伤害指标(WICC)明显下降。

关键词: 中等身材儿童, 校车, 智能气囊, 优化设计, 全方位人体安全模型(THUMS)假人, 改进型第三代非支配排序遗传算法(NSGA-III)

Abstract:

In order to mitigate biomechanical injuries sustained by middle-sized children during frontal collisions of school buses, this study investigated the optimal design of intelligent airbags. Initially, a validated school bus simulation model was constructed based on sled test data. Subsequently, methods for determining head, thorax, and femur injury values for a 10-year-old THUMS dummy were established, and the model, including the school bus restraint system, THUMS dummy and intelligent airbag, was developed. Next, based on NSGA-III, the adaptive propagation factors were proposed, the Gaussian mutation operator and the evolutionary mechanism of the particle swarm optimization method were introduced, and the non-dominated sorting level was improved, thus putting forward the improved NSGA-III. Finally, the design optimization of the intelligent airbag was conducted using the improved NSGA-III to determine the optimal configuration of the airbag. The results demonstrate that the improved NSGA-III outperforms the other three state-of-the-art optimization algorithms. Under normal, 10° forward tilt, 20° forward tilt, 5° right tilt, 10° right tilt and lying sitting postures, the head injury criterion (HIC₁₅), intracranial pressure (IP), liver pressure (LP), left and right femur forces (F_L and F_R, respectively), and weighted injury criterion (WICC) for middle-sized children are significantly reduced when the proportional coefficient of the gas mass-flow rate of the inflation valve, the opening pressure and opening coefficient of the deflation valves, and the installation height of the air bag are set at 1.23, 1.37×10⁵ Pa, 2.10, and 478 mm, respectively.

Key words: middle-sized children, school bus, intelligent airbag, design optimization, total human model for safety(THUMS)dummy, improved non-dominated sorting genetic algorithm-III(NSGA-III)

中图分类号:

X912.9安全人机学

洪亮, 陈志豪, 刘鹏. 面向中等身材儿童安全的校车智能气囊优化设计[J]. 中国安全科学学报, 2025, 35(12): 78-87.

HONG Liang, CHEN Zhihao, LIU Peng. Optimal design of school bus intelligent airbags for enhanced safety of middle-sized children[J]. China Safety Science Journal, 2025, 35(12): 78-87.

图/表 9

图1

图2

图3

图4

图5

表1

DTLZ测试函数下改进型NSGA-III与其他算法的IGD均值与标准差

测试函数	目标	MOEAD-DU	MOMBI-II	NSGA-III	改进型NSGA-III
DTLZ1	3	2.066 2×10^-2(8.17×10^-5) -	2.084 6×10^-2(1.66×10^-4) -	2.065 5×10^-2 (1.03×10^-4)-	2.055 6×10^-2 (1.23×10^-6)
	5	7.024 5×10^-2(5.87×10^-4) -	8.586 8×10^-2(3.20×10^-2) -	6.828 2×10^-2 (2.49×10^-4)-	5.272 7×10^-2 (4.93×10^-5)
	8	1.093 0×10^-1 (1.69×10^-3) -	2.725 0×10^-1 (2.31×10^-2) -	1.244 5×10^-1 (4.08×10^-2) -	1.057 8×10^-1 (1.63×10^-2)
	10	1.149 3×10^-1 (6.92×10^-4) -	2.039 4×10^-1 (3.74×10^-2) -	1.111 3×10^-1 (6.60×10^-3) ≈	1.139 6×10^-1 (1.65×10^-2)
	15	2.098 2×10^-1 (1.60×10^-2) -	2.704 4×10^-1 (1.59×10^-2) -	1.863 1×10^-1 (1.46×10^-2) ≈	1.904 7×10^-1 (2.08×10^-2)
DTLZ2	3	5.585 5×10^-2 (6.17×10^-4) -	5.504 6×10^-2 (2.73×10^-4) -	5.448 4×10^-2 (1.01×10^-5) -	5.447 0×10^-2 (2.20×10^-5)
	5	2.216 2×10^-1 (1.74×10^-3) -	2.184 5×10^-1 (1.46×10^-3) -	2.123 0×10^-1 (5.74×10^-5) -	1.651 1×10^-1 (2.63×10^-5)
	8	3.899 8×10^-1 (1.59×10^-3) -	4.610 1×10^-1 (1.09×10^-1) -	4.366 8×10^-1 (7.85×10^-2) -	3.229 2×10^-1 (3.84×10^-2)
	10	4.314 0×10^-1 (8.69×10^-4) +	4.376 0×10^-1 (5.59×10^-3) -	4.224 3×10^-1 (9.30×10^-3) ≈	4.321 2×10^-1 (3.64×10^-2)
	15	6.369 8×10^-1 (1.24×10^-2) ≈	8.562 9×10^-1 (8.33×10^-2) -	6.412 5×10^-1 (2.03×10^-2) ≈	6.400 0×10^-1 (1.81×10^-2)
DTLZ3	3	5.482 4×10^-2 (2.84×10^-4) -	5.485 8×10^-2 (3.43×10^-4) -	5.462 5×10^-2 (1.72×10^-4) -	5.446 4×10^-2 (7.20×10^-7)
	5	2.210 2×10^-1 (2.18×10^-3) -	2.217 5×10^-1 (2.37×10^-2) -	2.130 3×10^-1 (5.42×10^-4) -	1.652 0×10^-1 (7.36×10^-5)
	8	3.932 2×10^-1 (1.50×10^-3) +	8.937 4×10^-1 (4.04×10^-2) -	6.816 6×10^-1 (6.60×10^-1) -	5.733 0×10^-1 (6.53×10^-1)
	10	4.307 2×10^-1 (7.21×10^-4) +	6.116 7×10^-1 (1.37×10^-1) -	4.802 2×10^-1 (8.20×10^-2) +	5.035 1×10^-1 (1.23×10^-1)
	15	6.300 0×10^-1 (1.34×10^-3) +	1.037 1×10⁰ (2.39×10^-2) -	1.019 0×10⁰ (7.49×10^-2) -	7.313 5×10^-1 (6.33×10^-2)
DTLZ4	3	5.461 5×10^-2 (7.11×10^-5) -	7.181 2×10^-2 (8.88×10^-2) -	1.491 2×10^-1 (2.26×10^-1) -	5.446 5×10^-2 (2.05×10^-6)
	5	2.173 5×10^-1 (1.31×10^-3) -	2.956 5×10^-1 (1.17×10^-1) -	3.144 6×10^-1 (1.20×10^-1) -	1.651 2×10^-1 (1.13×10^-5)
	8	4.493 0×10^-1 (5.90×10^-2) -	5.196 4×10^-1 (1.03×10^-1) -	4.887 4×10^-1 (8.95×10^-2) -	3.151 2×10^-1 (1.08×10^-4)
	10	4.324 4×10^-1 (1.77×10^-3) -	4.523 5×10^-1 (5.33×10^-4) -	4.287 6×10^-1 (2.98×10^-2) -	4.204 5×10^-1 (2.86×10^-4)
	15	6.318 6×10^-1 (5.09×10^-3) -	6.480 0×10^-1 (1.19×10^-2) -	6.417 5×10^-1 (1.87×10^-2) -	6.228 3×10^-1 (7.09×10^-3)
SDTLZ1	3	5.623 8×10^-2 (6.61×10^-4) -	5.234 7×10^-2 (4.47×10^-4) -	5.173 9×10^-2 (2.66×10^-4) -	5.148 2×10^-2 (2.79×10^-6)
	5	3.526 4×10^-1 (3.86×10^-3) +	3.854 8×10^-1 (2.18×10^-3) -	3.831 8×10^-1 (9.07×10^-4) ≈	3.831 1×10^-1 (4.21×10^-4)
	8	3.688 1×10⁰ (1.11×10^-1) +	4.762 7×10⁰ (1.44×10⁰) -	3.580 7×10⁰ (7.50×10^-1) +	3.772 6×10⁰ (9.80×10^-1)
	10	1.324 3×10¹ (3.06×10^-1) +	1.678 7×10¹ (3.11×10⁰) -	1.229 8e×10¹ (1.89×10⁰) +	1.437 8×10¹ (3.17×10⁰)
	15	5.558 6e×10² (3.73×10¹) -	1.146 5×10³ (5.80×10²) -	4.50 20×10² (9.46×10¹) +	5.404 0×10² (9.91×10¹)
SDTLZ2	3	1.420 2×10^-1 (2.13×10^-3) -	1.307 9×10^-1 (3.81×10^-4) -	1.299 3×10^-1 (6.82×10^-5) ≈	1.299 0×10^-1 (3.21×10^-5)
	5	1.047 8×10⁰ (9.83×10^-3) -	9.854 9×10^-1 (4.37×10^-3) ≈	9.854 5×10^-1 (8.22×10^-4) ≈	9.858 2×10^-1 (1.83×10^-3)
	8	1.143 1×10¹ (2.66×10^-1) -	1.060 1×10¹ (1.39×10^-1) +	1.052 6×10¹ (4.03×10^-1) +	1.136 6×10¹ (2.80×10⁰)
	10	4.250 7×10¹ (8.25×10^-1) -	4.000 0×10¹ (8.42×10^-1) +	3.971 8×10¹ (3.07×10⁰) -	3.950 0×10¹ (2.02×10^-1)
	15	2.016 6×10³ (7.98×10¹) -	2.787 1×10³ (7.26×10²) -	1.580 5×10³ (2.10×10²) -	1.559 7×10³ (1.91×10²)
+/-/≈	—	7/22/1	2/27/1	5/18/7	—

表1

图6

表2

表3

6种坐姿下中等身材儿童头部、胸部与腿部损伤指标

儿童坐姿	HIC₁₅	IP/kPa	THPC/mm	LP/kPa	F_L/N	F_R/N	WICC
NP(原工况)	807.38	372.9	2.81	198.0	474.55	477.68	1.3881
NP(优化前)	157.29	138.5	5.54	162.2	428.87	436.85	0.4976
NP(优化后)	51.19	90.5	1.70	132.7	379.27	390.65	0.2997
变化率1/%	-93.66	-75.73	-39.50	-32.98	-20.08	-18.22	-78.41
变化率2/%	-67.46	-34.66	-69.31	-18.19	-11.57	-10.58	-39.77
FP10(原工况)	754.25	293.9	1.04	151.6	459.92	462.98	1.1717
FP10(优化前)	75.88	144.1	3.60	125.8	420.11	414.50	0.4140
FP10(优化后)	26.18	108.7	4.95	122.4	377.51	368.91	0.3196
变化率1/%	-96.53	-63.01	+375.96	-19.26	-17.92	-20.32	-72.72
变化率2/%	-65.50	-24.57	+37.50	-2.70	-10.14	-11.00	-22.80
FP20(原工况)	501.12	242.2	2.85	230.4	442.75	450.52	0.9633
FP20(优化前)	30.17	129.7	10.87	135.5	406.12	401.47	0.3939
FP20(优化后)	14.49	90.5	11.28	101.8	356.12	358.81	0.2918
变化率1/%	-97.11	-62.63	+295.79	-55.82	-19.57	-20.36	-69.71
变化率2/%	-51.97	-30.22	+3.77	-24.87	-12.31	-10.63	-25.92
RP5(原工况)	477.99	326.8	1.34	140.9	467.74	451.71	1.0228
RP5(优化前)	198.01	158.2	6.22	148.6	412.64	422.29	0.5542
RP5(优化后)	69.24	107.3	0.67	137.5	367.68	371.49	0.3408
变化率1/%	-85.51	-67.17	-50.00	-2.41	-21.39	-17.76	-66.68
变化率2/%	-65.03	-32.17	-89.23	-7.47	-10.90	-12.03	-38.51
RP10(原工况)	450.91	327.8	2.37	324.7	492.61	424.51	1.1412
RP10(优化前)	138.79	154.6	4.19	147.5	430.15	408.95	0.4958
RP10(优化后)	36.53	94.3	0	136.5	386.71	369.90	0.2911
变化率1/%	-91.90	-71.23	-100.00	-57.96	-21.50	-12.86	-74.49
变化率2/%	-73.68	-39.00	-100.00	-7.46	-10.10	-9.55	-41.29
SP(原工况)	598.67	291.4	0	166.5	413.41	427.02	1.0609
SP(优化前)	167.28	128.3	7.78	184.8	389.80	397.52	0.5123
SP(优化后)	97.08	97.0	2.08	110.0	349.45	350.20	0.3292
变化率1/%	-83.78	-66.71	N/A	-33.93	-15.47	-17.99	-68.97
变化率2/%	-41.97	-24.40	-73.26	-40.48	-10.35	-11.90	-35.74

表3

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优化参数	初始值	最优值
x₁	1.0	1.23
x₂/Pa	1.50×10⁵	1.37×10⁵
x₃	1.00	2.10
x₄/mm	460	478