B. Szczucka-Lasota, T. Wȩgrzyn, Abílio P. Silva, A. Jurek
{"title":"AHSS——用于智慧城市的建筑材料","authors":"B. Szczucka-Lasota, T. Wȩgrzyn, Abílio P. Silva, A. Jurek","doi":"10.3390/smartcities6020054","DOIUrl":null,"url":null,"abstract":"With the level of development of the smart city, there are more and more research sub-areas in which the latest material and technological solutions are used, enabling the proper management and functioning of these cities. On the one hand, the introduced materials and technologies are designed to facilitate the functioning of residents both in the urban space and at home; on the other hand, the implemented solutions strive to be consistent with the principles of sustainable development. As shown in this article, reports on new technical and technological solutions and their positive and negative effects are strongly emphasized in publications on the development of smart cities. The most highlighted materials research in the smart city area concerns smart materials and their characteristics and applications. A research gap in this area is in the presentation of material solutions, particularly materials intended for the load-bearing structures of vehicles (electric vehicles, flying vehicles) or infrastructure elements (buildings, shelters, etc.) designed to increase the durability of the structure while reducing its weight. This paper aims to comprehensively present the most important research areas related to the functioning of smart cities in light of previous research, with particular emphasis on new material solutions used for thin-walled load-bearing structures in smart cities made of AHSS (advanced high-strength steel). These solutions are very essential for smart cities because their use allows for the installation of additional devices, sensors, transmitters, antennas, etc., without increasing the total weight of the structure; they reduce the number of raw materials used for production (lighter and durable thin structures), ensure lower energy consumption (e.g., lighter vehicles), and also increase the passive safety of systems or increase their lifting capacity (e.g., the possibility of transporting more people using transports at the same time; the possibility of designing and arranging, e.g., green gardens on buildings; etc.). AHSS-welded joints are usually characterized by too-low strength in the base material or a tendency to crack. Thus, the research problem is producing a light and durable AHSS structure using welding processes. The research presented in this article concerns the possibility of producing welded joints using the Metal Active Gas (MAG) process. The test methods include the assessment of the quality of joints, such as through visual examination (VT); according to the requirements of PN-EN ISO 17638; magnetic particle testing (MT); according to PN-EN ISO 17638; and the assessment of the selected mechanical properties, such as tensile strength tests, bending tests, and fatigue strength checks. These methods enable the selection of the correct joints, without welding defects. The results have a practical implication; advanced production technology for obtaining AHSS joints can be used in the construction of the load-bearing elements of mobile vehicles or parts of point infrastructure (shelters, bus stops). The obtained joint is characterized by adequate strength for the production of the assumed structures. The originality of the manuscript is the presentation of a new, cheaper, and uncomplicated solution for obtaining an AHSS joint with good mechanical properties. The application of the presented solution also contributes to sustainable development (lower fuel and material consumption use by mobile vehicles) and may contribute to increasing the load capacity of mobile vehicles (the possibility of transporting more people).","PeriodicalId":34482,"journal":{"name":"Smart Cities","volume":" ","pages":""},"PeriodicalIF":7.0000,"publicationDate":"2023-04-13","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":"{\"title\":\"AHSS—Construction Material Used in Smart Cities\",\"authors\":\"B. Szczucka-Lasota, T. Wȩgrzyn, Abílio P. Silva, A. Jurek\",\"doi\":\"10.3390/smartcities6020054\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"With the level of development of the smart city, there are more and more research sub-areas in which the latest material and technological solutions are used, enabling the proper management and functioning of these cities. 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AHSS-welded joints are usually characterized by too-low strength in the base material or a tendency to crack. Thus, the research problem is producing a light and durable AHSS structure using welding processes. The research presented in this article concerns the possibility of producing welded joints using the Metal Active Gas (MAG) process. The test methods include the assessment of the quality of joints, such as through visual examination (VT); according to the requirements of PN-EN ISO 17638; magnetic particle testing (MT); according to PN-EN ISO 17638; and the assessment of the selected mechanical properties, such as tensile strength tests, bending tests, and fatigue strength checks. These methods enable the selection of the correct joints, without welding defects. 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引用次数: 0
摘要
随着智慧城市的发展水平,越来越多的研究子领域使用了最新的材料和技术解决方案,使这些城市能够进行适当的管理和运行。一方面,引入的材料和技术旨在促进居民在城市空间和家庭中的功能;另一方面,实施的解决办法力求符合可持续发展的原则。正如本文所示,在智慧城市发展的出版物中,关于新技术和技术解决方案及其积极和消极影响的报告被强烈强调。智能材料及其特性与应用是智慧城市领域材料研究的热点。该领域的一个研究缺口是材料解决方案的呈现,特别是用于车辆(电动汽车,飞行器)或基础设施元素(建筑物,庇护所等)的承重结构的材料,旨在增加结构的耐久性,同时减轻其重量。本文旨在根据以往的研究,全面介绍与智慧城市功能相关的最重要的研究领域,特别强调用于AHSS(先进高强度钢)制造的智慧城市薄壁承重结构的新材料解决方案。这些解决方案对于智慧城市来说非常重要,因为它们的使用允许安装额外的设备、传感器、发射器、天线等,而不会增加结构的总重量;它们减少了用于生产的原材料数量(更轻和耐用的薄结构),确保了更低的能源消耗(例如,更轻的车辆),并且还增加了系统的被动安全性或增加了其起重能力(例如,同时使用运输工具运送更多人的可能性;设计和布置的可能性,例如建筑物上的绿色花园;等等)。ahss焊接接头的特点通常是基材强度过低或容易开裂。因此,研究问题是如何利用焊接工艺制造轻便耐用的AHSS结构。本文研究了利用金属活性气体(MAG)工艺生产焊接接头的可能性。测试方法包括对关节质量的评估,如通过目视检查(VT);根据PN-EN ISO 17638的要求;磁粉检测;符合PN-EN ISO 17638;并对所选机械性能进行评估,如拉伸强度试验、弯曲试验和疲劳强度校核。这些方法可以选择正确的接头,没有焊接缺陷。研究结果具有一定的现实意义;获得AHSS接头的先进生产技术可用于制造移动车辆的承重元件或点基础设施(候车亭、公交车站)的部分。所得到的接头具有足够的强度,可用于生产假定的结构。原稿的独创性是一个新的,更便宜的,简单的解决方案,以获得一个具有良好的机械性能的AHSS关节的介绍。所提出的解决方案的应用还有助于可持续发展(降低移动车辆的燃料和材料消耗),并可能有助于提高移动车辆的负载能力(运送更多人员的可能性)。
With the level of development of the smart city, there are more and more research sub-areas in which the latest material and technological solutions are used, enabling the proper management and functioning of these cities. On the one hand, the introduced materials and technologies are designed to facilitate the functioning of residents both in the urban space and at home; on the other hand, the implemented solutions strive to be consistent with the principles of sustainable development. As shown in this article, reports on new technical and technological solutions and their positive and negative effects are strongly emphasized in publications on the development of smart cities. The most highlighted materials research in the smart city area concerns smart materials and their characteristics and applications. A research gap in this area is in the presentation of material solutions, particularly materials intended for the load-bearing structures of vehicles (electric vehicles, flying vehicles) or infrastructure elements (buildings, shelters, etc.) designed to increase the durability of the structure while reducing its weight. This paper aims to comprehensively present the most important research areas related to the functioning of smart cities in light of previous research, with particular emphasis on new material solutions used for thin-walled load-bearing structures in smart cities made of AHSS (advanced high-strength steel). These solutions are very essential for smart cities because their use allows for the installation of additional devices, sensors, transmitters, antennas, etc., without increasing the total weight of the structure; they reduce the number of raw materials used for production (lighter and durable thin structures), ensure lower energy consumption (e.g., lighter vehicles), and also increase the passive safety of systems or increase their lifting capacity (e.g., the possibility of transporting more people using transports at the same time; the possibility of designing and arranging, e.g., green gardens on buildings; etc.). AHSS-welded joints are usually characterized by too-low strength in the base material or a tendency to crack. Thus, the research problem is producing a light and durable AHSS structure using welding processes. The research presented in this article concerns the possibility of producing welded joints using the Metal Active Gas (MAG) process. The test methods include the assessment of the quality of joints, such as through visual examination (VT); according to the requirements of PN-EN ISO 17638; magnetic particle testing (MT); according to PN-EN ISO 17638; and the assessment of the selected mechanical properties, such as tensile strength tests, bending tests, and fatigue strength checks. These methods enable the selection of the correct joints, without welding defects. The results have a practical implication; advanced production technology for obtaining AHSS joints can be used in the construction of the load-bearing elements of mobile vehicles or parts of point infrastructure (shelters, bus stops). The obtained joint is characterized by adequate strength for the production of the assumed structures. The originality of the manuscript is the presentation of a new, cheaper, and uncomplicated solution for obtaining an AHSS joint with good mechanical properties. The application of the presented solution also contributes to sustainable development (lower fuel and material consumption use by mobile vehicles) and may contribute to increasing the load capacity of mobile vehicles (the possibility of transporting more people).
期刊介绍:
Smart Cities (ISSN 2624-6511) provides an advanced forum for the dissemination of information on the science and technology of smart cities, publishing reviews, regular research papers (articles) and communications in all areas of research concerning smart cities. Our aim is to encourage scientists to publish their experimental and theoretical results in as much detail as possible, with no restriction on the maximum length of the papers published so that all experimental results can be reproduced.