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本文探讨了中国城市空间规划从二维走向三维的发展趋势特征、新的交通方式对城市变革的触发效应和信息科技的支持作用,提出了一种低空空域与城市地上地下空间协同开发的新的城市发展路径。笔者对国内外城市低空空域管制的发展历程开展了历史考察和文献综述,并对相关法规政策进行梳理,进而提出城市三维空间整体开发设计构想。首先,以“机场—卫星城—中心城区”为功能组团,构建“低高空—低中空—低低空”三个空域划设层级;其次,在中心城区,依托三个空域划设层级构建三级管道空域飞行交通系统,分别利用城市的生态绿廊、城市封闭型道路与轨道交通以及高层建筑集中建成区,为载人飞行器、大型和小型货运无人机设置特定飞行廊道以提供安全的运行环境;最后,依托城市民航机场、城市立体交通系统和中央商务综合体组团,综合利用高层建筑、停车楼、轻轨和地铁站点等地上地下空间开展协同布局,构建“低空空域—地上地下”三维一体的新型城市综合交通运输系统,拓展“TOD+无人机”模式,提升城市整体的运行效率。笔者期望抓住城市交通变革的新契机,推动城市组团间和邻近城市间的互动与协作,为城市经济注入新的活力。
Abstract:This paper explores the evolution of Chinese urban spatial planning from 2D to 3D, the transformative impact of new transportation modes on urban development, and the supportive role of information technology. It proposes a novel approach to urban development that integrates low-altitude airspace and above-ground space. The author conducts a historical investigation and literature review of the development process of domestic and foreign urban low-altitude airspace control, and sorts out relevant regulations and policies, and then puts forward the concept of overall development and design of urban three-dimensional space. Firstly, by establishing a functional group consisting of “airport-satellite city-central city”, three levels of airspace(low altitude-low medium altitude-low high altitude) are constructed. Secondly, within the central urban area, a three-tiered pipeline airspace flight traffic system is developed based on these levels of airspace; specific flight corridors are designated for manned aircraft as well as large and small cargo UAVs using ecological green corridors, closed roads within cities, rail transit systems, and areas with concentrated high-rise buildings, respectively, to ensure a safe operating environment. Lastly, by leveraging urban civil aviation airports, three-dimensional transportation systems, and central business complexes, a collaborative layout can be achieved through the comprehensive use of high-rise buildings, parking structures, light rail and subway stations to create a “low-altitude airspace-above-ground underground” integrated urban transportation system, expand the “TOD+ UAV” model and enhance overall city operation efficiency. Seizing the new opportunity of urban air traffic reform will promote interaction and cooperation between urban groups and neighboring cities while injecting new vitality into the urban economy.
[1]杨保军,陈鹏,董珂,等.生态文明背景下的国土空间规划体系构建[J].城市规划学刊, 2019(4):16-23.
[2]吴克捷,赵怡婷,石晓冬.国土空间规划体系下地下空间规划编制研究[J].隧道建设(中英文), 2020, 40(12):1683-1690.
[3]中共中央国务院关于建立国土空间规划体系并监督实施的若干意见[EB/OL].(2019-05-23)[2024-07-23]. http://www. gov.cn/zhengce/2019-05/23/content_5394187.htm.
[4]李满春,陈振杰,周琛,等.面向“一张图”的国土空间规划数据库研究[J].中国土地科学, 2020, 34(5):69-75.
[5]中华人民共和国中央人民政府.自然资源部关于加快测绘地理信息事业转型升级更好支撑高质量发展的意见[EB/OL].(2023-08-22)[2024-07-23]. https://www.gov.cn/zhengce/zhengceku/202308/content_6899855.htm.
[6]中华人民共和国中央人民政府.无人驾驶航空器飞行管理暂行条例[EB/OL].(2023-06-28)[2024-07-23]. https://www.gov.cn/zhengce/content/202306/content_6888799.htm.
[7]张雄化.低空经济兴起及高质量发展的理论与实践:深圳的视角[J].特区经济, 2023(8):15-19.
[8]杨开忠.新中国70年城市规划理论与方法演进[J].管理世界, 2019,35(12):17-27.
[9]孙施文.解析中国城市规划:规划范式与中国城市规划发展[J].国际城市规划, 2019(4):1-7.
[10]耿慧志.城乡规划管理与法规[M].北京:中国建筑工业出版社, 2015.
[11]姜忆湄,李加林,马仁锋,等.基于“多规合一”的海岸带综合管控研究[J].中国土地科学, 2018, 32(2):34-39.
[12]朱宇,李加林,汪海峰,等.海岸带综合管理和陆海统筹的概念内涵研究进展[J].海洋开发与管理, 2020, 37(9):13-21.
[13]刘洁敏,蔡高明.前沿经济地理学理论与方法对我国空间规划体系重构的技术支撑作用探析[J].城市发展研究,2020, 27(1):26-43.
[14]杨会军.美国交通经济史[M].中国社会科学出版社, 2013.
[15]李娟,王有为,黎明,等.规范空间秩序:国土空间规划中交通的价值思考[J].城市交通, 2021, 19(1):19-28.
[16]王旭.空港都市区:美国城市化的新模式[J].浙江学刊, 2005(5):12-17.
[17]KASRDA J D. Logistics and the rise of aerotropolis[J]. Real estate issues,2000, 25(4):43-48.
[18]郭辰阳,敖万忠,吕宜宏.充分把握发展机遇,加快推进低空经济高质量发展[J].财经界, 2022(25):36-38.
[19]樊邦奎,李云,张瑞雨.浅析低空智联网与无人机产业应用[J].地理科学进展, 2021, 40(9):1441-1450.
[20]张陶新,杨英,喻理.智慧城市的理论与实践研究[J].湖南工业大学学报(社会科学版), 2012, 17(1):1-7.
[21]韦颜秋,李瑛.新型智慧城市建设的逻辑与重构[J].城市发展研究,2019, 26(6):108-113.
[22]王成亮,张定强,倪宇智,等.基于“一张图”的金土工程建设模式探讨[J].地理信息世界, 2013, 20(2):89-93.
[23]唐任伍,赵国钦.公共服务跨界合作:碎片化服务的整合[J].中国行政管理, 2012(8):17-21.
[24]乔思伟,徐瑶.库热西:加强顶层设计创新建设推动智慧城市科学发展[N].中国国土资源报, 2014.
[25]陈楠枰.新基建为“路空一体”添翼[J].交通建设与管理, 2020(3):68-73.
[26]赵亚军,郁光辉,徐汉青. 6G移动通信网络:愿景、挑战与关键技术[J].中国科学:信息科学, 2019, 49(8):963-987.
[27]中华人民共和国中央政府.自然资源部关于印发《自然资源调查监测体系构建总体方案》的通知[EB/OL].(2020-01-17)[2024-07-23]. https://www.gov.cn/zhengce/zhengceku/2020-01/18/content_5470398.htm.
[28]Ippolito C A. Dynamic ground risk mitigation for autonomous small UAS in urban environments[C]//Proceedings of the AIAA Scitech Forum.American Institute of Aeronautics and Astronautics, 2019:1-6.
[29]MUELLER E R, KOCHENDERFER M. Simulation comparison of collision avoidance algorithms for small multi-rotor aircraft[C]//AIAA Modeling and Simulation Technologies Conference. American Institute of Aeronautics and Astronautics, 2016:3674.
[30]THIPPHAVONG D P, APAZA R, BARMORE B, et al. Urban air mobility airspace integration concepts and considerations[C]//2018 Aviation Technology, Integration, and Operations Conference. American Institute of Aeronautics and Astronautics, 2018:3676.
[31]Uber Elevate. Fast-for warding to a future of on-demand Urban Air Transportation[EB/OL].(2016-10-27)[2024-07-23]. https://evtol.news/__media/PDFs/UberElevateWhitePaperOct2016.pdf.
[32]BARRADO C, BOYERO M, BRUCCULERI L, et al. U-space concept of operations:a key enabler for opening airspace to emerging low-altitude operations[J]. Aerospace, 2020, 7(3):24.
[33]LIEB J, VOLKERT A. Unmanned aircraft systems traffic management:a comparsion on the FAA UTM and the European CORUS ConOps based on U-space[C]//2020 AIAA/IEEE 39th Digital Avionics Systems Conference. IEEE, 2020:1-6.
[34]张洪海,邹依原,张启钱,等.未来城市空中交通管理研究综述[J].航空学报, 2021, 42(7):024638.
[35]SUNIL E, ELLERBROEK J, HOEKSTRA J, et al. Analysis of airspace structure and capacity for decentralized separation using fast-time simulations[J]. Journal of guidance, control, and dynamics, 2017, 40(1):38-51.
[36]AGENCY E, UNDERTAKING S. U-space:blueprint[EB/OL].(2023-12-02)[2024-07-23]. https://policycommons.net/ar tifacts/265019/u-space/1058459/.
[37]SUNIL E, ELLERBROEK J, HOEKSTRA J M, et al. Three-dimensional conflict count models for unstructured and layered airspace designs[J].Transportation research part c:emerging technologies, 2018, 95:295-319.
[38]HOEKSTRA J M, MAAS J, TRA M, et al. How do layered airspace design parameters affect airspace capacity and safety?[C]//Proceedings of the7th international conference on research in air transportation. ICRAT Philadelphia, USA, 2016:1-8.
[39]BAURANOV A, RAKAS J. Designing airspace for urban air mobility:a review of concepts and approaches[J]. Progress in Aerospace Sciences, 2021,125(1):100726.
[40]SALLEH M F B M, TAN D Y, KOH C H, et al. Preliminary concept of adaptive urban airspace management for unmanned aircraft operations[C]//2018 AIAA Information Systems-AIAA Infotech@Aerospace, 2018:2260.
[41]SUNIL E, HOEKSTRA J, ELLERBROEK J, et al. Metropolis:relating airspace structure and capacity for extreme traffic densities[C]. ATM seminar2015, 11th USA/EUROPE Air Traffic Management R&D Seminar, 2015.
[42]RUIZ S, SOLER M. Conflict pattern analysis under the consideration of optimal trajectories in the European ATM[C]. FAA/Eurcontrol ATM Seminar, 2015.
[43]DASKILEWICZ M J, GERMAN B J, WARREN M M, et al. Progress in vertiport placement and estimating aircraft range requirements for e VTOL daily commuting[C]//2018 Aviation Technology, Integration, and Operations Conference, 2018:2884.
[44]ROBINSON J N, SOKOLLEK M D R, JUSTIN C Y, et al. Development of a methodology for parametric analysis of STOL airpark geo-density[C]//2018 Aviation Technology, Integration, and Operations Conference, 2018:3054.
[45]Japan Airline. JAL conducts demonstration of drone implementation model to support island life[EB/OL].(2022-12-28)[2024-07-23]. https://press.jal.co.jp/en/release/202211/007077.html.
[46]SINGIREDDY S R R, DAIM T U. Technology roadmap:drone delivery–amazon prime air[J]. Infrastructure and technology management:contributions from the energy, healthcare and transportation sectors, 2018:387-412.
[47]KELSEY R. Air taxi companies ramp up infrastructure plans as aircraft certification looms[EB/OL].(2021-08-25)[2024-07-23]. https://www.aviationtoday.com/2021/08/25/air-taxi-companies-ramp-up-infrastructureplans-as-aircraft-certification-looms-near/.
[48]Volocopter. Groupe ADP&Volocopter at forefront of electric urban air mobility:a world first in summer 2024[EB/OL].(2023-06-20)[2024-07-23].https://www.volocopter.com/en/newsroom/volocopter-paris-routes.
[49]PONS-PRATS J,ŽIVOJINOVIĆT, KULJANIN J. On the understanding of the current status of urban air mobility development and its future prospects:commuting in a flying vehicle as a new paradigm[J]. Transportation research part e:logistics and transportation review, 2022, 166:102868.
[50]中国民用航空局.国务院办公厅关于促进通用航空业发展的指导意见[EB/OL].(2016-05-18)[2024-07-23]. http://www.caac.gov.cn/XXGK/XXGK/ZFGW/201605/t20160518_37445.html.
[51]新华网.中共中央国务院印发《国家综合立体交通网规划纲要》[EB/OL].(2021-02-24)[2024-07-23]. http://www.xinhuanet.com/politics/zywj/2021-02/24/c_1127135212.htm.
[52]李诚龙,屈文秋,李彦冬,等.面向eVTOL航空器的城市空中运输交通管理综述[J].交通运输工程学报, 2020, 20(4):35-54.
[53]张扬军,钱煜平,诸葛伟林,等.飞行汽车的研究发展与关键技术[J].汽车安全与节能学报, 2020, 11(1):1-16.
[54]高志宏.我国低空空域管理体制改革的历史变迁与未来取向[J].海南大学学报(人文社会科学版), 2019, 37(1):40-47.
[55]湖南省人民政府.全域低空空域管理改革试点湖南取得突破性进展[EB/OL].(2022-05-08)[2024-07-23]. https://www.hunan.gov.cn/hnszf/hnyw/sy/hnyw1/202205/t20220508_24466890.html.
[56]海南省交通运输厅.海南省通用航空产业发展“十四五”规划[EB/OL].(2021-12-20)[2024-07-23]. http://jt.hainan.gov.cn/xxgk/0200/0202/202112/t20211220_3115923.html.
[57]南方网.深圳已建成超70个直升机起降点助力大湾区形成15分钟经济生活圈[EB/OL].(2022-02-28)[2024-07-23]. https://www.southcn.com/node_20d09eff75/1d565af896.shtml.
[58]深圳市人大常委会.深圳经济特区低空经济产业促进条例[EB/OL].(2024-01-03)[2024-07-23]. http://www.szrd.gov.cn//v2/zx/szfg/content/post_1123253.html.
[59]陆晓华,郑林,张奇.高密度城市低空空间综合开发利用的思考[C]//交通治理与空间重塑——2020年中国城市交通规划年会论文集.中国城市规划设计研究院城市交通专业研究院, 2020:279-285.
(1)转引自参考文献[52]。
(2)引自腾讯新闻纪录片《看得见的未来(第一季)》。
基本信息:
DOI:10.19830/j.upi.2024.236
中图分类号:TU984.113
引用信息:
[1]刘洁敏,苏雪娇,沈振江.无人机交通治理导向的城市低空空域与地上地下空间协同开发模式探析[J].国际城市规划,2026,41(02):120-128.DOI:10.19830/j.upi.2024.236.
基金信息:
国家自然科学基金青年项目“城市制造业与服务业协同演化的整体与个体效应关联性研究”(42201178)
2024-11-04
2024-11-04
2024-11-04