考虑通道工作量均衡的补货阶段移动机器人拣选系统储位分配问题研究

doi:10.16381/j.cnki.issn1003-207x.2024.0687

摘要/Abstract

摘要：

在移动机器人拣货系统的补货阶段，由于消费者对商品需求的不断变化，需对补货商品储位分配进行及时决策，并适当调整货架在存储区的位置。同时，合理的货架布局能缓解机器人在通道中的拥塞。因此，本文研究补货阶段考虑通道工作量均衡的商品-货架储位联合分配问题。建立以货架上商品关联度之和最大化和货架与储位匹配度最大化的商品-货架储位分配双目标混合整数规划模型，并设计改进的NSGA-II（non dominated sorting genetic algorithm -II）算法求解，其中设计的分散式货架储位分配策略有利于实现通道工作量均衡。通过数值实验，与Gurobi求得的精确解对比证明了改进NSGA-II算法的精确性，与两阶段启发式算法对比证明了联合优化模型的优势。通过敏感性分析发现，通道拥堵权重系数越大，越有利于缓解通道拥堵，但会降低货架与储位的匹配度；补货率越大，货架上商品关联度、货架与储位的匹配度越大，但会造成额外的货架搬运距离；当仓库长宽比越接近于1，商品间关联度越小时，更有利于提高整体货架上商品的关联度及货架与储位的匹配度。

关键词: 移动机器人拣选系统, 补货阶段, 通道拥堵, 储位分配问题, 多目标进化算法

Abstract:

In the replenishment phase of mobile robot fulfillment systems， constantly changing consumer demand necessitates timely decisions regarding the allocation of replenished items to storage locations and the adjustment of pod positions within the storage area. A well-organized pod layout is crucial to mitigate congestion in the aisles where robots operate， which can significantly impact the efficiency of picking operations. The joint optimization of item and pod storage assignment problems is addressed during the replenishment phase， with a focus on achieving workload balance across picking aisles. The research problem originates from the need to enhance operational efficiency in robotic warehouses， where dynamic consumer demands and spatial constraints present significant challenges. Accurately assigning items to pods and optimally positioning these pods within the warehouse can lead to improved picking efficiency and reduced robot congestion. The problem is formulated to consider both the internal composition of pods and their spatial distribution in the warehouse. A bi-objective mixed-integer programming model is developed to maximize the total product correlation on pods and the matching degree between pods and storage locations. The product correlation objective aims to group items that are frequently ordered together onto the same pod， thereby reducing the number of pod visits required during order fulfillment. The matching degree objective ensures that pods are stored in locations that minimize travel distances. To solve this complex bi-objective optimization problem， an improved non-dominated sorting genetic algorithm II （NSGA-II） is designed. The algorithm is enhanced by incorporating a decentralized pod storage assignment strategy to facilitate balanced aisle workload distribution， ensuring efficiency and reducing congestion. Numerical experiments are conducted using data that reflect typical warehouse scenarios to validate the proposed algorithm. The results demonstrated the accuracy and effectiveness of our approach through comparisons with exact solutions obtained by Gurobi， a state-of-the-art optimization solver. Furthermore， advantages of the joint optimization model over a two-stage heuristic algorithm are highlighted in terms of achieving a better balance between product correlation and pod-storage matching. Sensitivity analysis is performed， and several key insights are obtained： increasing the weight coefficient for aisle congestion is found to alleviate congestion but decrease the matching degree between pods and storage locations. Conversely， higher replenishment rates are shown to enhance product correlation on pods and the matching degree but increase pod transportation distances. Additionally， it is observed that a warehouse length-to-width ratio closer to 1 and lower product correlation favor overall product correlation on pods and matching degree. It contributes to the field by offering a novel approach to managing the joint storage allocation and pod positioning in the replenishment phase. By balancing efficiency and operational constraints while addressing fluctuating consumer demands， the proposed model and algorithm provide valuable insights for optimizing warehouse operations. The findings can significantly aid related research in warehouse management and logistics optimization， offering strategies that enhance the responsiveness and efficiency of fulfillment systems in the face of dynamic market conditions.

Key words: robotic mobile fulfillment system, replenishment phase, aisle congestion, storage assignment problem, multi-objective evolutionary algorithm

中图分类号:

C943

张珺,杨惠晴,田凌坤. 考虑通道工作量均衡的补货阶段移动机器人拣选系统储位分配问题研究[J]. 中国管理科学, 2026, 34(5): 184-194.

Jun Zhang,Huiqing Yang,Lingkun Tian. Research on Storage Assignment Problem in Replenishment Phase of Robotic Mobile Fulfilment Systems Considering Picking Aisles' Workload Balance[J]. Chinese Journal of Management Science, 2026, 34(5): 184-194.

图/表 13

图1

表1

模型参数定义"

参数	定义
$K$	商品集合（ $k ∈ K$ ），其中不需要补货的商品集合 $K 0$ ，需要补货的商品集合为 $K 1$ ， $K = K 0 ⋃ K 1$
$R$	货架集合（ $i ∈ R$ ）
$L$	仓储货架存储区域位置集合（ $l ∈ L$ ）
$T$	拣选通道集合（ $t ∈ T, T ≥$ 3）
$Q$	货架的储位集合（ $q ∈ Q$ ）
$r k$	根据历史订单规律所得商品 $k$ 的周转率
$S k k'$	根据历史订单规律所得商品 $k$ 和 $k'$ 之间的关联度，等于同时购买 $k$ 和 $k'$ 的订单数除以总订单数^[9]
$b k i$	如果商品 $k$ 在补货之前就存放在货架 $i$ 上，则为1，否则为0
$C l$	存储区域位置 $l$ 到拣选站的曼哈顿距离
$R l t$	第 $l$ 个存储位置在第 $t$ 个通道
$θ$	待补货商品能存储的最大货架数量， $θ ≥$ 1
$σ$	拥堵权重系数的值， $0 ≤ σ < 1$
$α$	商品的补货率，即需要补货的储位比例
$x k i$	0-1变量，若待补货商品 $k$ 存储到货架 $i$ 上则为1，否则为0
$M k i q$	0-1变量，若待补货商品 $k$ 存储到货架 $i$ 上的第 $q$ 个储位则为1，否则为0
$y k i$	非负整数变量，待补货商品 $k$ 分配到货架 $i$ 上的储位数
$z i l$	0-1变量，若货架 $i$ 存储在 $l$ 位置则为1，否则为0
$P i$	补货完成后货架 $i$ 的周转率，即货架 $i$ 存储所有商品周转率的均值

表1

图2

图3

图4

图5

表2

小规模下改进NSGA-II与两个单目标模型最优解对比"

模型	$f 1$	$f 2$
M1（Gurobi）	4.18	1.48
M2（Gurobi）	1.00	1.69
J-IPSAP（NSGA-II）	4.18	1.62
J-IPSAP（NSGA-II）	1.76	1.65

表2

表3

改进NSGA-II算法与两阶段算法的比较"

K/R/L/T

f 1

(NSGA-II)

f 2

(NSGA-II)

f 1

(two-stage)

f 2

(two-stage)

$G a p 1$

（%）

$G a p 2$

（%）

20/10/16/3

4.15

1.62

4.14

1.61

0.24

0.62

50/30/48/5

2.20

1.43

2.20

1.30

0.00

9.09

100/60/84/7

1.38

1.20

1.38

1.08

0.00

10.00

表3

图6

表4

不同规模算例中通道拥堵权重系数的影响"

K/R/L/T	$σ$	$f 1$	$f 2$	方差
20/10/16/3	0	3.1515	1.6470	0.1689
	0.5	3.1735	1.6463	0.1449
	0.55	3.3790	1.6459	0.1315
	0.6	3.3980	1.6452	0.1285
	0.65	3.6230	1.6448	0.1198
	0.7	3.6565	1.6397	0.0907
50/30/48/5	0	2.1695	1.4338	0.0157
	0.5	2.2790	1.4328	0.0146
	0.55	2.2945	1.4305	0.0138
	0.6	2.4000	1.4291	0.0136
	0.65	2.4510	1.4288	0.0108
	0.7	2.4654	1.4200	0.0098
100/60/84/7	0	1.3595	1.2018	0.0130
	0.5	1.3625	1.1983	0.0122
	0.55	1.3760	1.1978	0.0120
	0.6	1.4110	1.1965	0.0110
	0.65	1.4175	1.1963	0.0106
	0.7	1.4220	1.1925	0.0101

表4

表5

不同规模算例中补货率的影响"

K/R/L/T	$α$	$f 1$	$f 2$
20/10/16/3	0.1	0.9800	1.6190
	0.2	1.9020	1.6266
	0.3	2.8875	1.6289
	0.4	2.9795	1.6311
	0.5	4.1720	1.6327
50/30/48/5	0.1	0.3175	1.4136
	0.2	1.1400	1.4237
	0.3	1.4514	1.4249
	0.4	1.7445	1.4311
	0.5	2.4315	1.4355
100/60/84/7	0.1	0.1910	1.1822
	0.2	0.7070	1.1824
	0.3	0.8270	1.1834
	0.4	1.0380	1.1882
	0.5	1.5560	1.1930

表5

表6

大规模算例中仓库布局的影响"

K/R/L/T	长宽比	$T$	$f 1$	$f 2$	方差
100/60/84/7	43:3	15	1.401	1.0036	0.0055
	22:6	8	1.402	1.1508	0.0087
	19:7	7	1.406	1.1997	0.0104
	10:14	4	1.411	1.1109	0.0101
	7:24	3	1.433	1.0318	0.0036

表6

表7

大规模算例中订单需求的影响"

K/R/L/T	ABC类商品占比	$f 1$	$f 2$
100/60/84/7	(0.4,0.3,0.3)	1.426	1.1981
	(0.4,0.4,0.2)	1.231	1.1991
	(0.5,0.3,0.2)	1.046	0.9832
	(0.5,0.4,0.1)	1.039	0.9858
	(0.6,0.3,0.1)	0.825	0.8560
	(0.6,0.2,0.2)	0.672	0.8380
	(0.7,0.2,0.1)	0.667	0.7661
	(0.8,0.1,0.1)	0.535	0.7832

表7

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