{"title":"利用物联网进行结构健康监测","authors":"Karanam Rajasekhar, Mr. Zeeshan Khan","doi":"10.55041/ijsrem36802","DOIUrl":null,"url":null,"abstract":"In the construction industry, maintaining structural integrity is pivotal for safety, efficiency, and economic viability. Traditional inspection methods, often sporadic and reliant on visual assessments, can overlook critical issues, especially in challenging environments where access is restricted or hazardous. The integration of IoT (Internet of Things) technology has revolutionized structural health monitoring by enabling continuous, remote data collection and analysis through sophisticated sensor networks. These networks, comprising wireless sensors strategically placed across buildings or infrastructure, monitor a range of parameters including temperature, humidity, light levels, vibration, and structural strain. This real-time data is transmitted wirelessly to central hubs or gateways, typically utilizing cost-effective solutions like Raspberry Pi devices programmed with Python for efficient data management. The collected data is then processed and stored in cloud servers, leveraging the scalability and accessibility of cloud computing to facilitate advanced signal processing and analysis. MATLAB is utilized for its robust capabilities in numerical computing and visualization, presenting the data in graphical formats that highlight trends, anomalies, and potential deterioration patterns. Crucially, this system incorporates an alert mechanism, notifying stakeholders via email of critical sensor readings or emerging issues, enabling swift responses to prevent accidents or structural failures. The adoption of IoT-enabled structural health monitoring offers multifaceted benefits to the construction industry and broader economic landscape. By continuously monitoring infrastructure health, this approach allows for early detection of defects or wear, facilitating proactive maintenance interventions that can significantly extend the service life of buildings and infrastructure. This proactive maintenance not only enhances safety and reliability but also reduces long-term costs associated with reactive repairs and unplanned downtime. Moreover, by minimizing the need for frequent physical inspections, IoT technology contributes to environmental sustainability by reducing carbon emissions associated with transportation and improving operational efficiency through data-driven decision-making. These efficiencies translate into tangible economic gains, as stakeholders can optimize resource allocation, prioritize maintenance efforts, and mitigate the financial impacts of unexpected structural failures or degradation. From a safety perspective, IoT-enabled monitoring systems enhance risk management by providing real-time insights into structural conditions. By identifying potential hazards or weaknesses early on, stakeholders can implement targeted interventions to mitigate risks and ensure compliance with stringent safety regulations. This proactive approach not only protects human lives but also safeguards investments in infrastructure by preemptively addressing issues before they escalate into costly emergencies. Furthermore, by leveraging cloud-based data storage and analytics, these systems empower stakeholders with unprecedented access to comprehensive, actionable insights.","PeriodicalId":504501,"journal":{"name":"INTERANTIONAL JOURNAL OF SCIENTIFIC RESEARCH IN ENGINEERING AND MANAGEMENT","volume":"43 14","pages":""},"PeriodicalIF":0.0000,"publicationDate":"2024-07-26","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":"{\"title\":\"Structural Health Monitoring Using IOT\",\"authors\":\"Karanam Rajasekhar, Mr. Zeeshan Khan\",\"doi\":\"10.55041/ijsrem36802\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"In the construction industry, maintaining structural integrity is pivotal for safety, efficiency, and economic viability. Traditional inspection methods, often sporadic and reliant on visual assessments, can overlook critical issues, especially in challenging environments where access is restricted or hazardous. The integration of IoT (Internet of Things) technology has revolutionized structural health monitoring by enabling continuous, remote data collection and analysis through sophisticated sensor networks. These networks, comprising wireless sensors strategically placed across buildings or infrastructure, monitor a range of parameters including temperature, humidity, light levels, vibration, and structural strain. This real-time data is transmitted wirelessly to central hubs or gateways, typically utilizing cost-effective solutions like Raspberry Pi devices programmed with Python for efficient data management. The collected data is then processed and stored in cloud servers, leveraging the scalability and accessibility of cloud computing to facilitate advanced signal processing and analysis. MATLAB is utilized for its robust capabilities in numerical computing and visualization, presenting the data in graphical formats that highlight trends, anomalies, and potential deterioration patterns. Crucially, this system incorporates an alert mechanism, notifying stakeholders via email of critical sensor readings or emerging issues, enabling swift responses to prevent accidents or structural failures. The adoption of IoT-enabled structural health monitoring offers multifaceted benefits to the construction industry and broader economic landscape. By continuously monitoring infrastructure health, this approach allows for early detection of defects or wear, facilitating proactive maintenance interventions that can significantly extend the service life of buildings and infrastructure. This proactive maintenance not only enhances safety and reliability but also reduces long-term costs associated with reactive repairs and unplanned downtime. 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引用次数: 0
摘要
在建筑行业,保持结构的完整性对于安全、效率和经济可行性至关重要。传统的检测方法往往是零星的,依赖于目测评估,可能会忽略关键问题,尤其是在限制进入或危险的挑战性环境中。物联网(IoT)技术的集成通过先进的传感器网络实现了连续的远程数据收集和分析,从而彻底改变了结构健康监测。这些网络由战略性放置在建筑物或基础设施中的无线传感器组成,可监测一系列参数,包括温度、湿度、光照度、振动和结构应变。这些实时数据以无线方式传输到中心集线器或网关,通常采用的是具有成本效益的解决方案,如使用 Python 编程的 Raspberry Pi 设备,以实现高效的数据管理。然后,收集到的数据将被处理并存储在云服务器中,利用云计算的可扩展性和可访问性来促进高级信号处理和分析。MATLAB 具有强大的数值计算和可视化功能,能以图形格式显示数据,突出显示趋势、异常和潜在的恶化模式。最重要的是,该系统集成了警报机制,可通过电子邮件将关键传感器读数或新出现的问题通知利益相关者,以便迅速采取应对措施,防止事故或结构故障的发生。采用由物联网支持的结构健康监测可为建筑行业和更广泛的经济领域带来多方面的益处。通过持续监测基础设施的健康状况,这种方法可以及早发现缺陷或磨损,促进主动维护干预,从而大大延长建筑物和基础设施的使用寿命。这种主动维护不仅能提高安全性和可靠性,还能降低与被动维修和计划外停工相关的长期成本。此外,物联网技术最大限度地减少了频繁的实际检查,减少了与运输相关的碳排放,并通过数据驱动的决策提高了运营效率,从而促进了环境的可持续发展。这些效率可以转化为实实在在的经济收益,因为利益相关者可以优化资源分配,确定维护工作的优先次序,并减轻意外结构故障或退化造成的经济影响。从安全角度来看,物联网监控系统可实时了解结构状况,从而加强风险管理。通过早期识别潜在危险或薄弱环节,利益相关者可以实施有针对性的干预措施,以降低风险并确保遵守严格的安全法规。这种积极主动的方法不仅能保护人的生命,还能在问题升级为代价高昂的紧急情况之前先发制人地加以解决,从而保障对基础设施的投资。此外,通过利用基于云的数据存储和分析,这些系统还能让利益相关者以前所未有的方式获得全面、可操作的见解。
In the construction industry, maintaining structural integrity is pivotal for safety, efficiency, and economic viability. Traditional inspection methods, often sporadic and reliant on visual assessments, can overlook critical issues, especially in challenging environments where access is restricted or hazardous. The integration of IoT (Internet of Things) technology has revolutionized structural health monitoring by enabling continuous, remote data collection and analysis through sophisticated sensor networks. These networks, comprising wireless sensors strategically placed across buildings or infrastructure, monitor a range of parameters including temperature, humidity, light levels, vibration, and structural strain. This real-time data is transmitted wirelessly to central hubs or gateways, typically utilizing cost-effective solutions like Raspberry Pi devices programmed with Python for efficient data management. The collected data is then processed and stored in cloud servers, leveraging the scalability and accessibility of cloud computing to facilitate advanced signal processing and analysis. MATLAB is utilized for its robust capabilities in numerical computing and visualization, presenting the data in graphical formats that highlight trends, anomalies, and potential deterioration patterns. Crucially, this system incorporates an alert mechanism, notifying stakeholders via email of critical sensor readings or emerging issues, enabling swift responses to prevent accidents or structural failures. The adoption of IoT-enabled structural health monitoring offers multifaceted benefits to the construction industry and broader economic landscape. By continuously monitoring infrastructure health, this approach allows for early detection of defects or wear, facilitating proactive maintenance interventions that can significantly extend the service life of buildings and infrastructure. This proactive maintenance not only enhances safety and reliability but also reduces long-term costs associated with reactive repairs and unplanned downtime. Moreover, by minimizing the need for frequent physical inspections, IoT technology contributes to environmental sustainability by reducing carbon emissions associated with transportation and improving operational efficiency through data-driven decision-making. These efficiencies translate into tangible economic gains, as stakeholders can optimize resource allocation, prioritize maintenance efforts, and mitigate the financial impacts of unexpected structural failures or degradation. From a safety perspective, IoT-enabled monitoring systems enhance risk management by providing real-time insights into structural conditions. By identifying potential hazards or weaknesses early on, stakeholders can implement targeted interventions to mitigate risks and ensure compliance with stringent safety regulations. This proactive approach not only protects human lives but also safeguards investments in infrastructure by preemptively addressing issues before they escalate into costly emergencies. Furthermore, by leveraging cloud-based data storage and analytics, these systems empower stakeholders with unprecedented access to comprehensive, actionable insights.