基于消冗时段网络的集装箱班轮干扰恢复研究

doi:10.16381/j.cnki.issn1003-207x.2023.1943

Abstract

Abstract:

The resilience of maritime supply chain guarantees the transportation efficiency of the global industry and supply chain. The uncertainty factor of shipping makes container liner transportation often delayed， which not only causes the increase of economic cost in transportation but seriously affects the smooth operation of the maritime supply chain. In order to reduce the total cost of the disruption recovery process and improve the supply chain resilience of container liner transportation， it focuses on the liner disruption recovery problem and considers the difference in the demand for container loading and unloading in different ports， innovatively propose a time-band network model， and designs two targeted network redundancy elimination strategies in this paper. Through numerical simulation of an actual container liner route， the model's validity is verified， and the effect of the redundancy elimination strategies is analyzed. The analysis results show that the disruption recovery scheme considering the difference in the demand of container loading and unloading in different ports can further reduce the propagation of disruption effects， reduce the total cost by at least 16%， and significantly reduce the number of containers affected by disruption at higher levels. At the same time， the disruption recovery model based on the redundancy elimination time-band network enables more efficient acquisition of lower-cost disruption recovery solutions. The research results can provide decision support for the maritime container liner transportation industry to recover from disruption， reduce the degree of delay and transportation cost after the disruption， and improve the resilience of the container liner transportation supply chain.

Key words: liner disruption recovery, container transportation resilience, redundancy elimination strategy, time-band network

CLC Number:

F830.9

Yuzhen Hu, Jianxia Liu. Container Liner Disruption Recovery Based on Redundancy Elimination Time-band Network[J]. Chinese Journal of Management Science, 2025, 33(2): 118-130.

Figures/Tables 23

$∆$ v （节）	传统时空网络				消冗时段网络				成本差值百分比（%） ((2)-(1))/(1)
$∆$ v （节）	总成本（美元）(1)	求解时间（秒）	弧数量	节点数量	总成本（美元）(2)	求解时间（秒）	弧数量	节点数量	成本差值百分比（%） ((2)-(1))/(1)
0.5	5793259	1.19	68555	24763	5667431	0.17	2741	272	-2.17
1	5794641	0.42	36071	13151	5686852	0.17	2529	272	-1.86
1.5	5798510	0.20	23092	8580	5730046	0.11	2077	268	-1.18
2	5798873	0.16	19929	7440	5689898	0.16	2081	272	-1.88
2.5	5839299	0.13	16693	6291	5744129	0.06	1590	238	-1.63

$∆$ h （小时）	传统时空网络				消冗时段网络				成本差值百分比(%) ((2)-(1))/(1)
$∆$ h （小时）	总成本（美元）(1)	求解时间（秒）	弧数量	节点数量	总成本（美元）(2)	求解时间（秒）	弧数量	节点数量	成本差值百分比(%) ((2)-(1))/(1)
3	5690042	5.52	142883	50581	5683890	1.82	14813	1108	-0.11
6	5716746	1.38	71661	25619	5686852	0.43	6520	562	-0.52
9	5747453	0.66	48161	17522	5710214	0.20	4032	382	-0.65
12	5794641	0.42	36071	13151	5686852	0.17	2529	272	-1.86
15	6036027	0.28	28767	10471	5683890	0.08	1621	195	-5.83
18	6126982	0.19	24004	8782	5710214	0.08	1654	197	-6.80

References 22

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港口	香港(XG)	盐田(YT)	厦门(XM)	上海(SH)
EA	0	30	80	180
Ts	20	20	20	20
Tin	0	2	2	2
Tout	2	2	2	0
M	XG-YT(100) XG-XM(100) XG-SH(200)	YT-XM(50) YT-SH(100)	XM-SH(50)	——

港口名称	港口编号	计划到达时间	在港时间	进港时间	出港时间
天津新港	a0	0	36	0	3
青岛港	a1	70	36	2	2
上海外高桥港	a2	141	24	5	5
上海洋山港	a3	177	24	2	2
长滩港	a4	517	81	2	2
鲁珀特王子港	a5	709	65	2	2
天津新港	a6	1176	36	2	0

港口	a0	a1	a2	a3	a4	a5	a6
a0	0	457	695	682	6117	4893	0
a1	457	0	359	391	5904	4923	457
a2	695	359	0	67	5820	4839	695
a3	682	391	67	0	5702	4805	682
a4	6117	5904	5820	5702	0	1427	6117
a5	4893	4923	4839	4805	1427	0	4893
a6	0	457	695	682	6117	4893	0

票次	港口a (装载）	港口b （卸载）	集装箱数量（TEU）
1	a0	a4	1000
2	a0	a5	800
3	a1	a4	1000
4	a1	a5	800
5	a2	a4	800
6	a2	a5	600
7	a3	a4	500
8	a3	a5	500
9	a4	a6	1000
10	a5	a6	1000

航线规模	CEN航线	航线2	航线3
挂靠港口数量	7	14	21
班轮容量（TEU）	8000	10020	13800
班轮结束恢复的时间（小时）	1212	1516	1886

Container Liner Disruption Recovery Based on Redundancy Elimination Time-band Network

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Figures/Tables 23

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dt （小时）	传统时空网络			消冗时段网络				成本差值百分比(%) ((2)-(1))/(1)
dt （小时）	总成本（美元）(1)	弧数量	节点数量	模型目标值	总成本（美元）(2)	弧数量	节点数量	成本差值百分比(%) ((2)-(1))/(1)
24	5794641	36071	13151	5679038	5686852	2529	272	-1.86
48	6248616	36071	13151	6093481	6093481	2868	291	-2.48
72	6767797	36071	13151	6589827	6589827	2976	297	-2.63
96	7342384	36071	13151	7130481	7130481	2893	292	-2.89
120	8007409	36071	13151	7903608	7903608	2863	289	-1.30

对比项目	消冗时段网络(S1)	消冗时段网络(S2)	消冗时段网络(S1+S2)
总成本（美元）	5686852	5686852	5686852
网络构建时间（秒）	21.66	24.33	22.24
消冗前求解时间（秒）(1)	0.24	0.24	0.24
消冗后求解时间（秒）(2)	0.18	0.23	0.17
减少求解时间((2)-(1))/(1)（%）	-26	-3	-27
消冗前弧数(3)	12989	12989	12989
消冗后弧数(4)	4122	10676	2529
减少弧幅度((4)-(3))/(3)（%）	-68	-18	-81
消冗前节点数(5)	350	350	350
消冗后节点数(6)	328	292	272
减少节点幅度((6)-(5))/(5)（%）	-6	-17	-22

dt （小时）	选项一		选项二		选项三		成本降低百分比1 ((c3)-(c1))/(c1)(%)	成本降低百分比2 ((c3)-(c2))/(c2)(%)
dt （小时）	总成本（美元） (c1)	受干扰影响的集装箱数量(n1)	总成本（美元） (c2)	受干扰影响的集装箱数量(n2)	总成本（美元） (c3)	受干扰影响的集装箱数量(n3)	成本降低百分比1 ((c3)-(c1))/(c1)(%)	成本降低百分比2 ((c3)-(c2))/(c2)(%)
24	6740779	3300	5686852	0	5686852	0	-15.64	0.00
48	12788016	6000	6093481	0	6093481	0	-52.35	0.00
72	20588016	6000	7890979	3300	6589827	0	-67.99	-16.49
96	28388016	6000	12373336	6000	7130481	0	-74.88	-42.37
120	36188016	6000	13588371	6000	7903608	1800	-78.16	-41.84

港口	选项一		选项二		选项三
港口	延误情况/小时 (dt=72)	延误情况/小时 (dt=120)	延误情况/小时 (dt=72)	延误情况/小时 (dt=120)	延误情况/小时 (dt=72)	延误情况/小时 (dt=120)
a1	71.56	119.56	61.28	109.28	61.28	——
a2	66.00	114.00	50.38	98.38	50.38	50.80
a3	65.19	113.19	48.57	96.57	48.57	48.99
a4	53.29	101.29	8.09	32.48	0	0
a5	35.48	83.48	0	4.76	0	0
a6	0.00	0.00	0	0	0	0

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对比项目	消冗时段网络(S1)	消冗时段网络(S2)	消冗时段网络(S1+S2)
总成本（美元）	5686852	5686852	5686852
网络构建时间（秒）	89.36	93.67	90.54
消冗前求解时间（秒）(1)	0.47	0.47	0.47
消冗后求解时间（秒）(2)	0.43	0.44	0.43
减少求解时间((2)-(1))/(1)（%）	-8	-7	-9
消冗前弧数 (3)	25175	25175	25175
消冗后弧数 (4)	10286	20530	6520
减少弧幅度 ((4)-(3))/(3)（%）	-59	-18	-74
消冗前节点数 (5)	679	679	679
消冗后节点数 (6)	679	558	562
减少节点幅度((6)-(5))/(5)（%）	0	-18	-17