化工学报
化工學報
화공학보
JOURNAL OF CHEMICAL INDUSY AND ENGINEERING (CHINA)
2014年
9期
3552-3558
,共7页
田野%董宏光%邹雄%李霜霜%王兵
田野%董宏光%鄒雄%李霜霜%王兵
전야%동굉광%추웅%리상상%왕병
计划与调度%不确定性%随机规划%优化%模型%系统工程
計劃與調度%不確定性%隨機規劃%優化%模型%繫統工程
계화여조도%불학정성%수궤규화%우화%모형%계통공정
planning and scheduling%uncertainty%stochastic programming%optimization%model%systems engineering
生产计划与调度是化工供应链优化中两个重要的决策问题。为了提高生产决策的效率,不仅要对计划与调度进行集成,而且要考虑不确定性的影响。对于多周期生产计划与调度问题,首先在每个生产周期内,分别建立计划与调度的确定性模型,通过产量关联对二者进行集成。然后考虑需求不确定性,使用有限数量的场景表达决策变量,建立二阶段随机规划模型。最后运用滚动时域求解策略,使计划与调度结果在迭代过程中达到一致。实例结果表明,在考虑需求不确定性时,与传统方法相比,随机规划方法可以降低总费用,结合计划与调度的分层集成策略,实现了生产操作性和经济性的综合优化。
生產計劃與調度是化工供應鏈優化中兩箇重要的決策問題。為瞭提高生產決策的效率,不僅要對計劃與調度進行集成,而且要攷慮不確定性的影響。對于多週期生產計劃與調度問題,首先在每箇生產週期內,分彆建立計劃與調度的確定性模型,通過產量關聯對二者進行集成。然後攷慮需求不確定性,使用有限數量的場景錶達決策變量,建立二階段隨機規劃模型。最後運用滾動時域求解策略,使計劃與調度結果在迭代過程中達到一緻。實例結果錶明,在攷慮需求不確定性時,與傳統方法相比,隨機規劃方法可以降低總費用,結閤計劃與調度的分層集成策略,實現瞭生產操作性和經濟性的綜閤優化。
생산계화여조도시화공공응련우화중량개중요적결책문제。위료제고생산결책적효솔,불부요대계화여조도진행집성,이차요고필불학정성적영향。대우다주기생산계화여조도문제,수선재매개생산주기내,분별건립계화여조도적학정성모형,통과산량관련대이자진행집성。연후고필수구불학정성,사용유한수량적장경표체결책변량,건립이계단수궤규화모형。최후운용곤동시역구해책략,사계화여조도결과재질대과정중체도일치。실례결과표명,재고필수구불학정성시,여전통방법상비,수궤규화방법가이강저총비용,결합계화여조도적분층집성책략,실현료생산조작성화경제성적종합우화。
Production planning and scheduling are two of the most important decision-making problems in supply chain optimization. To ensure the efficiency of decision-making, planning and scheduling were integrated, with consideration of demand uncertainty. For a multi-period production planning and scheduling problem, planning and scheduling deterministic models were established in each period firstly, and they were integrated through production correlation. Then, demand uncertainty was introduced and decision variables were represented with a finite number of scenarios in a two-stage stochastic programming model. At last, rolling horizon strategy was used to achieve consistency between planning and scheduling results in an iterative process. The case study demonstrated that compared with the conventional method, the stochastic programming method could reduce total cost under demand uncertainty. Combined with the hierarchical integration method, production operational and economic optimization was achieved.
