建筑业大型增材制造的一个新概念:深度强化学习控制的基于塔式起重机的3D打印

IF 3.1 Q2 CONSTRUCTION & BUILDING TECHNOLOGY Construction Innovation-England Pub Date : 2023-01-31 DOI:10.1108/ci-10-2022-0278
F. Parisi, V. Sangiorgio, N. Parisi, A. M. Mangini, M. P. Fanti, J. Adam
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引用次数: 1

摘要

目的大多数3D打印设备不符合现场、大型多层建筑施工的要求。本文旨在提出由人工智能(AI)控制的基于塔式起重机(TC)的3D打印的概念,作为开发多层建筑的大型3D打印的第一步。它还旨在通过开发该领域最重要的机器:TC来克服建筑行业增材制造的最重要限制(生产量)。它通过调查印刷过程中达到的精度来评估技术的可行性。设计/方法论/方法研究主要由三个步骤组成:首先,通过提出一种由螺旋桨稳定的航空摆式挤出机来控制挤出过程中的轨迹,定义了基于TC的3D打印概念;其次,利用深度强化学习(DRL)控制方法,定义了一个基于人工智能的系统来控制起重机和挤出机刀具路径;第三,通过对动力系统的仿真和性能分析,验证了该框架的有效性。发现基于TC的3D打印机可以有效地用于建筑行业的增材制造。TC及其挤出机都可以通过基于AI的控制系统进行适当控制。通过仿真和验证,证明了人工智能控制航空摆式挤出机的有效性。与没有稳定的系统公差相比,基于AI的控制系统允许相对于理想轨迹达到可接受的公差。原创性/价值在相关文献中,关于使用起重机系统进行3D打印和基于人工智能的控制系统的科学研究完全缺失。据作者所知,所提出的研究首次证明了用智能DRL代理概念化和控制这项技术的有效性。实际意义研究结果为开发基于TC的3D打印的多层建筑新增材制造系统迈出了第一步。概念化可行性和控制系统的演示为公司和研究中心激活实验研究开辟了新的可能性。
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A new concept for large additive manufacturing in construction: tower crane-based 3D printing controlled by deep reinforcement learning
Purpose Most of the 3D printing machines do not comply with the requirements of on-site, large-scale multi-story building construction. This paper aims to propose the conceptualization of a tower crane (TC)-based 3D printing controlled by artificial intelligence (AI) as the first step towards a large 3D printing development for multi-story buildings. It also aims to overcome the most important limitation of additive manufacturing in the construction industry (the build volume) by exploiting the most important machine used in the field: TCs. It assesses the technology feasibility by investigating the accuracy reached in the printing process. Design/methodology/approach The research is composed of three main steps: firstly, the TC-based 3D printing concept is defined by proposing an aero-pendulum extruder stabilized by propellers to control the trajectory during the extrusion process; secondly, an AI-based system is defined to control both the crane and the extruder toolpath by exploiting deep reinforcement learning (DRL) control approach; thirdly the proposed framework is validated by simulating the dynamical system and analysing its performance. Findings The TC-based 3D printer can be effectively used for additive manufacturing in the construction industry. Both the TC and its extruder can be properly controlled by an AI-based control system. The paper shows the effectiveness of the aero-pendulum extruder controlled by AI demonstrated by simulations and validation. The AI-based control system allows for reaching an acceptable tolerance with respect to the ideal trajectory compared with the system tolerance without stabilization. Originality/value In related literature, scientific investigations concerning the use of crane systems for 3D printing and AI-based systems for control are completely missing. To the best of the authors’ knowledge, the proposed research demonstrates for the first time the effectiveness of this technology conceptualized and controlled with an intelligent DRL agent. Practical implications The results provide the first step towards the development of a new additive manufacturing system for multi-storey constructions exploiting the TC-based 3D printing. The demonstration of the conceptualization feasibility and the control system opens up new possibilities to activate experimental research for companies and research centres.
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来源期刊
Construction Innovation-England
Construction Innovation-England CONSTRUCTION & BUILDING TECHNOLOGY-
CiteScore
7.10
自引率
12.10%
发文量
71
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