北京市水-能源-粮食可持续发展系统动力学模型构建与仿真

›› 2016, Vol. 28 ›› Issue (10): 11-26.

北京市水-能源-粮食可持续发展系统动力学模型构建与仿真

李桂君¹, 李玉龙¹, 贾晓菁², 杜磊³, 黄道涵¹

1. 中央财经大学管理科学与工程学院, 北京 100081;
2. 中央财经大学商学院, 北京 100081;
3. 招商银行总行, 深圳 518040

收稿日期:2016-03-07 出版日期:2016-10-28 发布日期:2016-10-31
通讯作者: 李桂君(通讯作者),中央财经大学管理科学与工程学院教授,博士生导师,博士。
作者简介:李玉龙,中央财经大学管理科学与工程学院副教授,硕士生导师,博士;贾晓菁,中央财经大学商学院教授,博士生导师,博士;杜磊,招商银行总行投资银行部职员,硕士;黄道涵,中央财经大学管理科学与工程学院博士研究生。
基金资助:
国家自然科学基金面上项目（71473285）；国家自然科学基金青年项目（71301175）。

Establishment and Simulation Study of System Dynamic Model on Sustainable Development of Water-Energy-Food Nexus in Beijing

Li Guijun¹, Li Yulong¹, Jia Xiaojing², Du Lei³, Huang Daohan¹

1. School of Management Science and Engineering, Central University of Finance and Economics, Beijing 100081;
2. School of Business, Central University of Finance and Economics, Beijing 100081;
3. China Merchants Bank, Shenzhen 518040

Received:2016-03-07 Online:2016-10-28 Published:2016-10-31

摘要/Abstract

摘要：

资源与环境是人类生存和发展的重要基础。北京是中国的政治文化中心，资源高度依赖外省市供应，随着需求的不断增加,其可持续发展将面临更加严峻的挑战。本研究通过构建以水-能源-粮食（W-E-F）三者为主体并涵盖社会、经济和环境子系统的复杂系统因果关联网络；运用系统动力学仿真技术，实现了对北京市水-能源-粮食关联（W-E-F Nexus）系统的动力学仿真模拟，预测了北京市W-E-F变化趋势，并开展了W-E-F Nexus系统敏感性分析。研究发现2020年水资源消耗总量预计超过38亿吨；能源供应数量预计不足2600万吨标准煤，地热能等清洁一次能源供应逐渐占据主导地位，能源消费总量预计下降至6865万吨标准煤，其中超过62%的能源消耗将依赖省外调入；粮食消费总量预计将超过730万吨，粮食单产数量在2014-2016年经过短暂调整后开始持续提升，到2020年每公顷产量预计将超过7800公斤，粮食自给率经过调整将再度恢复到2012年20%的水平；能源系统是现阶段提升北京W-E-F综合可持续发展能力的突破口；相比于单一资源政策，基于非资源系统的决策行为影响效果将更为深广。

关键词: 水-能源-粮食, 关联系统, 可持续发展, 系统动力学

Abstract:

Resources and environment are important basis for human survival and development. Beijing, as the political and cultural center, is seriously short of natural resources, and depends exceptionally heavily on imports from other provinces. Therefore, the city is facing tougher challenges with resource needs rising steadily. This paper sets up a complex system of interconnections among water, energy and food. A W-E-F Nexus causal network is established after collecting influence factors. This paper realizes the simulation of regional W-E-F development trends, and carries out a sensitivity analysis based on system dynamics model. According to the simulation results, total consumption of water is expected to rise to 3.84 billion tons in Beijing by 2020. Energy supplies will tail off to below 26 million tons standard coal equivalent (SCE), primary energy is seeking continuous, incremental improvements, where the proportion of cleaner fuels is boosting, such as geothermal energy. Total consumption of energy will reduce gradually to 68.65 million tons SCE by 2020, of which more than 62 percent will be imported from other provinces. Total consumption of food is expected to rise to 7.3 million tons and after the short adjustment periods from 2014 to 2016, yield per unit area will increase continuously to more than 7.8 thousand kilograms by 2020 and degree of self-sufficiency will return to 20 percent. Meanwhile, policies and measures based on energy system will improve sustainable development ability fundamentally, and prove to be critical factors promoting regional development in Beijing. There will be larger and deeper influences when control measures are taken through social and economic means, saying non-resource factors, compared with direct resource regulations.

Key words: water-energy-food, nexus system, sustainable development, system dynamics

李桂君, 李玉龙, 贾晓菁, 杜磊, 黄道涵. 北京市水-能源-粮食可持续发展系统动力学模型构建与仿真[J]. , 2016, 28(10): 11-26.

Li Guijun, Li Yulong, Jia Xiaojing, Du Lei, Huang Daohan. Establishment and Simulation Study of System Dynamic Model on Sustainable Development of Water-Energy-Food Nexus in Beijing[J]. , 2016, 28(10): 11-26.

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