Search or ask a question

What are the challenges of implementing smart waste management in school?

Global Positioning System

Garbage collection

Dispose pattern

Waste collection

Best insight from top research papers

Implementing smart waste management in schools faces challenges such as turnover of students and teachers, lack of available technicians, and the need for environmental education. Additionally, the management of waste in a cost-optimal way with high performance is crucial for smart cities, where waste collection and processing are complex tasks due to growing populations and resource constraints. Smart waste management systems utilizing IoT technologies can address these challenges by providing real-time monitoring of waste levels in smart garbage bins, optimizing collection routes, and sending notifications to authorities when bins are full . To enhance waste management in smart cities, innovative solutions like "iSmartWMS" have been proposed, focusing on improving existing smart waste management systems through advanced technologies and efficient processes.

Answers from top 4 papers

PDF

Open Access

More filters

Papers (4)	Insight
Journal Article•DOI “Jogar para não gerar”: o desafio de um minicurso online / "Play not to generate": the challenge of an online minicourse Regiane Cristina Mareze Sipioni Castione, Renata Camacho Bezerra, Eliane Pereira - Show less +2 more 02 Apr 2022-Brazilian Journal of Development	Challenges in implementing smart waste management in schools include turnover of staff and students, lack of technical support, and the need for effective environmental education strategies like game-enhanced minicourses.
Proceedings Article•DOI Design and Development of Smart Waste Management System Sachin Gajjar 31 Mar 2023	Challenges of implementing smart waste management in schools include efficient waste handling, timely disposal, and inactive local disposal systems, which can lead to health hazards and environmental pollution.
Proceedings Article•DOI Design and Development of Smart Waste Management System 31 Mar 2023	Challenges of implementing smart waste management in schools include efficient waste handling, timely disposal, and overcoming inactive disposal systems to ensure a clean and sustainable environment.
Journal Article•DOI Smart Waste Management System using IoT Rahul Singh 31 May 2020-International Journal for Research in Applied Science and Engineering Technology 1 Citations	Challenges of implementing smart waste management in schools include cost optimization, efficient waste handling, and preventing overflow or odors in public areas, addressed by IoT-based systems in smart cities.

My columns

Related Questions

What are the current challenges faced by schools in ensuring proper disposal of waste materials?5 answersSchools face various challenges in ensuring proper disposal of waste materials. One common issue is the inadequate resources for effective waste management, prevalent in both urban and rural schools. Additionally, poor student attitudes towards waste management pose a significant constraint, particularly in rural schools, while urban schools struggle with poor waste collection routines. Furthermore, open burning of rubbish is still a common practice in some schools due to lack of awareness, convenience, and perceived cost-effectiveness, leading to environmental and health hazards. Implementing intervention programs, such as environmental education clubs and workshops, can help in raising awareness and changing behaviors among students to improve waste management practices in schools. Overall, addressing these challenges through education, resource allocation, and policy enforcement is crucial for promoting proper waste disposal in school settings.

Issue of waste management in the School5 answersThe issue of waste management in schools is a prevalent concern highlighted in the provided research contexts. Schools like SMPN 1 and SMPN 5 in Bangko Pusako District face challenges due to the conventional practice of burning waste, lack of control over waste quantities, and inadequate infrastructure for effective waste management. Implementing composting approaches can significantly improve solid waste disposal in schools, promoting environmental sustainability through techniques like project-based learning and hands-on learning. Furthermore, managing food waste from school lunches is crucial, requiring circular economy perspectives and stakeholder engagement for successful waste mitigation. Educational initiatives in schools, such as waste management education programs, have shown positive impacts on student attitudes and behaviors towards waste disposal and management. Thematic workshops and interactive activities can also enhance students' understanding and perceptions of solid waste management, fostering a sense of responsibility towards proper waste handling.

Why solid waste management should not be practice in school?5 answersSolid waste management should not be practiced in schools due to various reasons highlighted in the research papers. Issues such as open burning of rubbish, lack of awareness, inadequate resources, poor waste management policies, and limited infrastructure contribute to the challenges faced by schools. Additionally, studies reveal low levels of awareness, knowledge, and systematic waste management practices among students, indicating a need for more structured waste management programs in educational institutions. Implementing effective waste management practices in schools requires addressing these challenges through educational approaches, policy development, and resource allocation to ensure sustainable waste management without resorting to harmful practices like burning trash.

What is the challenges implementation encounter in waste management?5 answersThe challenges encountered in waste management implementation include poor enforcement of policies and regulations, lack of political will and cooperation, corruption, and inadequate funding. Other challenges include administrative, procedural, and policy issues. Inefficient waste management systems, underdeveloped infrastructure, and lack of surveillance contribute to economic and environmental threats. Additionally, the increasing volume and complexity of waste, along with rapid urbanization and economic development, pose significant challenges. Planning for integrated nuclear waste management requires addressing challenges such as inventory, time frame, facility needs assessment, cost estimation, and funding. Overall, the challenges in waste management implementation stem from a lack of efficient implementation and enforcement of policies, as well as socioeconomic, political, and environmental factors.

What are the issues about waste management in school?5 answersWaste management in schools is a significant issue that needs attention. Open burning of rubbish is still frequently practiced in schools, which is in conflict with government programs aimed at lowering greenhouse gas emissions and waste management policies. Waste disposal management practices in schools are often inadequate, with waste being disposed of in open spaces without proper separation. Recycling has been identified as the best way to manage solid waste in schools, but there is a need for increased awareness and involvement of students, teachers, administrators, staff, cleaners, and local communities in recycling projects. Poor waste disposal management practices in schools can lead to poor sanitation, environmental degradation, and disease outbreaks. To address these issues, it is recommended to provide adequate dustbins, regular waste collection, and monitoring of waste management practices in schools.

What are the challenges of implementing smart waste management?3 answersImplementing smart waste management faces several challenges. These challenges include the complex industry structure involving numerous stakeholders, changing consumer behavior, and lack of strong standards. In addition, there is a lack of understanding of the diverse factors that influence waste management, inefficient route planning, and insufficient resources. Developing countries face social, environmental, economic, and technical challenges when adopting IoT technologies for waste management. Furthermore, waste management in public areas often faces the problem of overflowing trash cans before the next scheduled cleaning, leading to health issues. Overall, the challenges of implementing smart waste management include industry complexities, lack of understanding, resource limitations, and public health concerns.

See what other people are reading

How do waste management practices contribute to sustainability goals in smart manufacturing?

Waste management practices play a crucial role in achieving sustainability goals in smart manufacturing. By implementing digital systems to reduce wastages, segregating waste effectively using solutions like smart dustbins, and integrating lean and green manufacturing approaches, industries can significantly minimize environmental impact. Additionally, the development of TOPSIS-based models for sustainable smart manufacturing practices provides a structured approach for organizations to enhance sustainability. These practices not only help in reducing waste and pollution but also contribute to efficient resource utilization, energy conservation, and overall environmental sustainability. Therefore, by adopting smart waste management strategies, manufacturing industries can move towards achieving sustainable competitiveness and long-term environmental goals.What are the top necessity when making a tourist map in terms of spatial locations of faciities?

When creating a tourist map focusing on spatial locations of facilities, key considerations include integrating diverse data sources like GPS for precise geographic information, representing tourism flows based on the origin countries of tourists and their spatial characteristics using GIS-based Kernel density, understanding that tourist maps actively shape destination spaces through diagrammatic operations like extending matter and placing objects, and utilizing a dasymetric approach to define tourism density per land use types for accurate distribution assessment. These aspects highlight the importance of incorporating technology, spatial analysis, theoretical frameworks, and accurate data representation to ensure that tourist maps effectively guide visitors to facilities in a given area.What are the practices of green shipping?

Green shipping practices encompass various strategies aimed at enhancing the sustainability of the shipping industry. These practices include implementing green port strategies focusing on indicators like air quality, climate change, energy efficiency, noise pollution, community relations, water quality, ship waste, dredging operations, and waste management. Additionally, green shipping practices involve adopting a triple bottom line framework, incorporating dimensions such as company policies, shipping documentation, equipment, service providers' cooperation, materials, and design for compliance. Furthermore, to achieve decarbonization and sustainability in maritime transport, green port development models emphasize the use of alternative energy sources, energy-efficient technologies, and environmentally friendly applications to reduce air and water pollution, conserve energy, and promote sustainable development. These practices collectively aim to steer the shipping industry towards a greener and more sustainable future.Are there any qualitative research papers on high school food wastage in the phillipines?

Qualitative research papers on high school food wastage in the Philippines are scarce in the provided contexts. However, studies on solid waste management (SWM) awareness and practices in educational institutions in the Philippines shed light on related issues. These studies focus on waste management practices, including segregation, reduction, reuse, recycling, and disposal, among high school students. While the emphasis is on solid waste in general, the findings can provide insights into food wastage patterns within educational settings. The data suggest a positive correlation between awareness, attitude, and practice regarding SWM, indicating a foundation for addressing food wastage concerns in high schools. Further research specifically targeting food wastage in high schools could benefit from building upon the existing knowledge on SWM practices in educational institutions in the Philippines.How to process waste in the philippines?

To process waste in the Philippines, various methods and technologies are being explored. Municipal solid waste management (MSWM) systems are being optimized using linear programming models to reduce environmental burdens and enhance sustainability. Fish processing industries are considering anaerobic treatment methods to convert fish processing wastes into energy, particularly through high-rate anaerobic systems like UASB for efficient wastewater treatment. Additionally, the management of electrical and electronic waste (e-waste) is a growing concern, with informal sectors handling most e-waste due to the lack of a formal comprehensive e-waste management system in the country. These diverse approaches highlight the importance of implementing sustainable waste processing practices in the Philippines to address environmental challenges and promote resource recovery.How does designing for disassembly impact the material recovery process at the end of a building's lifecycle?

Designing for Disassembly (DfD) significantly enhances the material recovery process at the end of a building's lifecycle by facilitating the separation and reuse of components, thereby reducing waste and promoting sustainability. DfD strategies, as highlighted by Gooday, involve considering the end-of-life phase during the initial design process, ensuring that materials can be efficiently reclaimed and recycled, which is particularly challenging with complex multi-material structures. Crowther's research further supports this by demonstrating how applying DfD principles in architectural design can lead to a reduction in future demolition waste through easier deconstruction and material separation. Aygars' thesis emphasizes the role of DfD in enabling buildings to be modified and disassembled for material reuse, thus avoiding landfill and supporting the next generation of buildings. Sternberg's study on the life cycle assessment (LCA) of wood structural systems underlines the importance of DfD in minimizing the production of new materials by considering additional life cycles for reused materials, thereby reducing the carbon footprint. O'Grady et al. introduce a circular economy-based index, highlighting how DfD, along with deconstruction and resilience, can significantly improve material loop closure by enabling building refurbishment and relocation with minimal waste. Vandervaeren et al. propose a method to model material flows initiated by disassembly, demonstrating the environmental benefits of DfD through a more accurate life cycle environmental impact assessment. Garg discusses the necessity of flexibility and adaptability in buildings, where DfD plays a crucial role in meeting changing consumer needs and promoting sustainable architecture. Marzouk and Elmaraghy's integration of Building Information Modeling (BIM) with lean principles for deconstruction planning further illustrates how DfD aids in optimizing the recovery of building elements, thereby enhancing material reuse. Lastly, Davis explores the synergy between DfD and Industrialised Construction (IC) for creating sustainable and affordable housing solutions, highlighting the potential of DfD in extending building lifespans and improving end-of-life material recovery.How does designing for disassembly impact the recovery of materials at the end of a building's lifecycle?

Designing for Disassembly (DfD) significantly impacts the recovery of materials at the end of a building's lifecycle by facilitating the separation and reuse of components, thus contributing to material sustainability and the reduction of waste. Gooday highlights the potential of advanced polymer composites to be recycled, emphasizing the importance of DfD in aiding the reclamation of materials from end-of-life (EoL) waste through efficient disassembly of complex structures. Crowther's research supports this by demonstrating how DfD principles, when applied in architectural design, can lead to a reduction in future demolition waste by making material and component recovery easier. Aygars' thesis further explores the role of DfD in architecture, proposing buildings designed for modification and disassembly to provide materials for future constructions, thereby reducing material waste. This approach aligns with the European Green Deal's emphasis on circular economy principles, where DfD is seen as a key strategy in achieving climate targets through the reuse of building components. Sternberg's study on the life cycle assessment (LCA) of structural systems underlines the environmental benefits of DfD, showing a reduction in the carbon footprint of buildings through the reuse of materials. Garg discusses DfD's contribution to architectural flexibility and adaptability, enabling buildings to evolve according to consumers' needs and facilitating the reuse and recycling of materials. Mahmoudi Motahar et al. introduce an integrated method for disassembly planning, enhancing the deconstructability of buildings and promoting a circular economy by closing material loops. Munaro emphasizes the need for guidelines and training in DfAD to support the construction sector's transition toward circularity, highlighting the importance of standardization and modularization. Lastly, O'Grady et al. present the 3DR index, showcasing a practical application of DfD principles in a prefabricated building, which resulted in significant material reuse and waste reduction. In summary, designing for disassembly profoundly impacts the recovery of materials at the end of a building's lifecycle by enabling efficient material separation, promoting reuse and recycling, and supporting the transition towards a more sustainable and circular construction industry.When was the first arduino-based waste segregation system developed?

The first Arduino-based waste segregation system was developed as part of a research project that aimed to address the challenges of waste management. The system utilized various sensors such as ultrasonic sensors, IR sensors, and proximity sensors, along with Arduino Uno for coding and control. This innovative system not only facilitated the segregation of different types of waste, such as metal and non-metal materials, but also included features like a notification system to alert when the bins were full. The development of this system marked a significant advancement in waste management technology, contributing to initiatives like the Swachh Bharat Abhiyan and promoting environmental cleanliness through efficient waste segregation. Additionally, the system's success in accurately segregating waste materials demonstrated the practicality and effectiveness of using Arduino-based solutions for waste management.When was the date of the first arduino-based waste segregation system developed?

The first Arduino-based waste segregation system was developed on 12th February 2021, as per the patent application number 202111006039. This system aimed to assist in waste management by segregating bio and non-biodegradable waste efficiently. Additionally, another waste sorting system utilizing Arduino UNO was designed and successfully implemented, separating metal and non-metal materials. Furthermore, a color segregation system based on sensor data and color identification was proposed for waste management, achieving high accuracy and fast response times. Moreover, a system utilizing metal and ultrasonic sensors for waste segregation was developed, with doors opening based on the type of waste detected. These innovative systems showcase the diverse applications of Arduino technology in waste management solutions.What was the proposed system of Swachh Bharat Abhiyan in arduino?

The proposed system for Swachh Bharat Abhiyan using Arduino involves a smart garbage management model that automatically opens and closes its lid, detects humans, sends alerts when full, and promotes efficient waste maintenance. This system integrates Arduino Uno, ultrasonic sensors, a servo motor, and a battery jumper cable to create an effective solution for maintaining clean and eco-friendly environments. Additionally, the system includes features like ultrasonic sensors, calorimetric sensors, LEDs, and programming languages for waste segregation, enhancing waste management efficiency and promoting cleanliness. The innovation has been patented and copyrighted in India, showcasing its significance in waste management and its potential to contribute to the objectives of Swachh Bharat Abhiyan.What is the objectives of Swachh Bharat Abhiyan in arfuino based segregation system?

The objectives of Swachh Bharat Abhiyan in an Arduino-based segregation system are to improve waste management efficiency and promote cleanliness. The system aims to segregate waste into categories like bio and non-biodegradable waste, dry waste, wet waste, and e-waste using sensors like ultrasonic and color sensors. By incorporating IoT technology and automation, the system helps in reducing pollution caused by mixed waste dumping and overfilled bins, aligning with the goals of the Swachh Bharat Abhiyan to create a cleaner and greener environment. Additionally, the system contributes to the inclusive growth envisioned by the Swachh Bharat Abhiyan by promoting sustainable sanitation practices and community participation in waste management.