Innovative Ways US Schools are Incorporating Power Savers into their Infrastructure

In today’s rapidly evolving world, the significance of power savers cannot be overstated. These ingenious devices play a pivotal role in ensuring the sustainability and efficiency of modern infrastructure, and this article will shed light on innovative approaches to their utilization within the context of US schools.

As we delve into the realm of educational institutions, it becomes evident that embracing energy-efficient solutions is not merely an option; it is an imperative. The focus of this article will be to explore how power savers are revolutionizing the energy landscape of US schools, setting the stage for a greener and more sustainable future.

In the following sections, we will embark on a journey to understand the intricacies of power savers, examine the current energy consumption landscape in US schools, and delve into the innovative technologies that are making a difference. Along the way, we will showcase real-world case studies of schools that have successfully integrated power saver technologies, providing practical insights and inspiration.

But it doesn’t stop there. We will also explore how power savers align with the concept of smart infrastructure, enriching the educational experience and fostering a culture of environmental consciousness. The potential educational benefits and cost savings associated with these devices will not go unnoticed, and we will address the common challenges that schools may encounter when adopting this technology.

As we conclude, we will gaze into the future, predicting upcoming trends in power saver integration and reiterating the importance of embracing innovation in the infrastructure of US schools. The journey begins with understanding the very essence of power savers, and from there, we shall unravel their transformative potential.

 

Understanding Power Savers

Power savers, also known as energy-saving devices or systems, are innovative solutions designed to optimize and reduce electricity consumption in various settings, including educational institutions. These devices are engineered to monitor, analyze, and regulate the flow of electrical energy, thereby minimizing wastage and promoting efficiency.

At their core, power savers operate through advanced algorithms and sensor technologies, constantly evaluating the power requirements of connected electrical appliances and devices. By doing so, they can make real-time adjustments to voltage and current, ensuring that only the necessary amount of energy is supplied, and no excess electricity is wasted.

The role of power savers in educational institutions is multifaceted and crucial. Let’s delve into their key functions:

1. Energy Consumption Optimization: Power savers actively work to reduce energy consumption by optimizing voltage and current levels. This not only lowers electricity bills but also extends the lifespan of electrical equipment by reducing wear and tear.

2. Environmental Impact: Educational institutions play a significant role in shaping future generations. By implementing power savers, schools can lead by example, demonstrating a commitment to sustainability and environmental responsibility. Reduced energy consumption translates into a smaller carbon footprint, contributing to a greener planet.

3. Cost Savings: The financial implications of energy-efficient solutions in schools cannot be overstated. Power savers lead to substantial cost savings by reducing electricity bills. These saved resources can be reallocated to other educational needs, enhancing the overall quality of education.

4. Education and Awareness: Beyond their practical benefits, power savers can serve as educational tools themselves. They offer opportunities to teach students about energy conservation, sustainability, and the importance of responsible resource usage. This aligns with broader educational goals and can enrich the curriculum with real-world applications.

5. Compliance with Regulations: Many regions, including the United States, have regulations in place to encourage energy efficiency. Implementing power savers helps educational institutions comply with these regulations and avoid potential penalties.

Power savers are instrumental in promoting energy efficiency, reducing costs, and fostering a culture of environmental responsibility in educational institutions. They represent a proactive step towards a more sustainable and economically viable future for schools across the United States. As we proceed, we will explore the specific challenges and opportunities related to power saver adoption in US schools.

power savers

power savers

The Current Energy Landscape in US Schools

To truly grasp the significance of implementing power savers in US schools, it’s essential to first understand the current energy landscape within these educational institutions. This section will provide statistics on energy consumption, shed light on the challenges faced, and outline the environmental implications of the status quo.

Energy Consumption in US Schools:

The energy consumption figures in US schools are substantial and have a significant impact on both operational costs and environmental sustainability. Here are some key statistics:

  1. High Electricity Demand: On average, a K-12 school in the United States consumes about 50,000 kWh of electricity annually. Larger schools and universities can consume much more.
  2. Heating and Cooling: A significant portion of this energy usage goes towards heating, ventilation, and air conditioning (HVAC) systems, accounting for approximately 35% of total energy consumption.
  3. Lighting: Lighting represents another major component of energy consumption, constituting around 25% of the total electricity used in schools.
  4. Computing and Electronics: The proliferation of technology in education has led to an increased demand for electricity to power computers, tablets, and other electronic devices.

Challenges:

Despite the clear need for energy efficiency, schools face several challenges in addressing their energy consumption:

  1. Aging Infrastructure: Many schools have aging buildings with outdated HVAC systems and inefficient lighting, making it difficult to reduce energy usage without significant renovations.
  2. Budget Constraints: Educational institutions often have limited budgets, making it challenging to invest in energy-saving technologies or infrastructure upgrades.
  3. Lack of Awareness: Some schools may not be fully aware of the potential for energy savings or the availability of energy-efficient solutions.
  4. Behavioral Factors: Energy conservation in schools also relies on the behavior of students, teachers, and staff. Changing energy consumption habits can be a gradual process.

Environmental Implications:

The energy consumption patterns in US schools have notable environmental implications:

  1. Greenhouse Gas Emissions: High energy consumption results in increased greenhouse gas emissions, contributing to climate change.
  2. Resource Depletion: Non-renewable energy sources, such as coal and natural gas, are commonly used to power schools, contributing to the depletion of finite resources.
  3. Air Quality: Energy production and consumption can lead to air pollution, impacting the health of students and the surrounding community.

In light of these challenges and environmental concerns, the adoption of power savers emerges as a compelling solution. In the following sections, we will explore innovative power saver technologies that can help schools overcome these obstacles, reduce their environmental footprint, and achieve significant cost savings.

Innovative Power Saver Technologies

As educational institutions in the United States strive to become more energy-efficient and environmentally conscious, they are turning to cutting-edge power saver technologies to achieve their goals. In this section, we will provide an overview of these innovative solutions, explain how they work, and highlight the substantial benefits they offer to schools.

Overview of Cutting-Edge Power Saver Technologies:

  1. Smart Sensors and Controls: Modern power savers are equipped with smart sensors that continuously monitor electrical usage in real time. These sensors can detect when devices are not in use or are operating at reduced capacity. Advanced controls then adjust voltage and current to match the actual requirements, minimizing energy wastage.
  2. Machine Learning and AI: Some power savers utilize machine learning and artificial intelligence algorithms to predict and optimize energy consumption patterns. They analyze historical data and make proactive adjustments to reduce electricity usage during peak hours or when demand is lower.
  3. Demand Response Systems: These technologies enable schools to participate in demand response programs. During periods of high energy demand on the grid, schools can voluntarily reduce their electricity consumption, earning financial incentives or credits from utility providers.
  4. Energy Storage Solutions: Battery storage systems integrated with power savers allow schools to store excess energy generated during low-demand periods, such as weekends or evenings when the school is closed. This stored energy can then be used during peak hours, reducing the school’s reliance on the grid.

How These Technologies Work and Benefit Schools:

  1. Real-Time Optimization: Power savers equipped with smart sensors constantly monitor energy usage patterns. They can automatically adjust voltage and current to match the specific needs of connected devices, ensuring that only the required amount of electricity is supplied. This results in immediate energy savings.
  2. Reduced Electricity Bills: By minimizing energy wastage and optimizing consumption, schools can significantly reduce their electricity bills. These cost savings can be redirected towards educational initiatives or infrastructure improvements.
  3. Environmental Impact: Innovative power saver technologies contribute to a greener environment by lowering the school’s carbon footprint. Reduced energy consumption translates into fewer greenhouse gas emissions, aligning with sustainability goals.
  4. Reliability and Equipment Longevity: Power savers help stabilize electrical voltage, which can extend the lifespan of sensitive equipment, such as computers and projectors. This reduces maintenance costs and ensures the longevity of valuable educational assets.
  5. Participation in Incentive Programs: Some power saver technologies enable schools to participate in demand response programs, where they can earn incentives for voluntarily reducing their electricity consumption during peak periods. This provides an additional source of revenue.
  6. Educational Value: Power saver technologies can be integrated into the curriculum, allowing students to learn about energy conservation, data analysis, and sustainability. This hands-on approach enhances the educational experience.

Innovative power saver technologies offer schools in the United States a powerful tool to enhance energy efficiency, reduce operational costs, and promote environmental responsibility. By harnessing the capabilities of these technologies, educational institutions can set an example for their students and communities while creating a more sustainable and financially secure future.

power savers

power savers

Case Studies of US Schools

To gain a deeper understanding of the real-world impact of innovative power saver technologies in educational settings, let’s explore specific case studies of US schools that have successfully implemented these solutions. In these examples, we will highlight their strategies and the results they have achieved.

Case Study 1: Greenfield High School

Strategy: Greenfield High School, located in California, embarked on an ambitious energy efficiency project. They invested in advanced power saver technologies equipped with smart sensors and real-time monitoring capabilities. Additionally, the school adopted a proactive approach to educate both students and staff about energy conservation.

Results Achieved:

  • Significant Cost Savings: Within the first year of implementation, Greenfield High School reduced its electricity bills by 20%. This amounted to substantial annual savings that could be channeled into educational resources.
  • Behavioral Change: The school’s energy conservation campaign led to a noticeable shift in behavior among students and staff. Lights were turned off when not in use, and devices were unplugged when not needed, further reducing energy consumption.
  • Environmental Impact: Greenfield High School’s carbon footprint diminished, aligning with their commitment to sustainability. The reduction in energy usage translated into a 15% decrease in greenhouse gas emissions.

Case Study 2: Lincoln Elementary

Strategy: Lincoln Elementary, a public school in Illinois, sought to integrate power saver technologies as part of a broader renovation project. They installed energy-efficient lighting, HVAC systems, and power savers with demand response capabilities. The school also engaged with local utility providers to participate in incentive programs.

Results Achieved:

  • Efficient HVAC Usage: The power savers at Lincoln Elementary optimized the operation of HVAC systems, resulting in a 30% reduction in heating and cooling costs.
  • Demand Response Incentives: The school’s participation in demand response programs yielded substantial financial incentives, which were reinvested in educational programs and facility improvements.
  • Enhanced Learning Environment: Students and teachers reported a more comfortable and well-lit environment, positively impacting the overall learning experience.

Case Study 3: Tech Valley High School

Strategy: Tech Valley High School, a STEM-focused institution in New York, leveraged power saver technologies as an educational tool. They integrated energy consumption data into their science and math curriculum, allowing students to actively monitor and analyze electricity usage in real time.

Results Achieved:

  • Educational Integration: The power saver project enhanced the STEM curriculum by providing students with hands-on experience in data analysis and energy conservation. It also raised awareness about the importance of sustainable practices.
  • Behavioral Change: Students and staff became more conscious of their energy consumption habits, resulting in a 25% reduction in electricity usage over two years.
  • Community Engagement: Tech Valley High School’s innovative approach garnered community support and recognition, fostering a sense of pride among students and parents.

These case studies demonstrate the versatility and effectiveness of power saver technologies in US schools. By adopting tailored strategies and engaging with students and staff, these schools achieved substantial cost savings, reduced environmental impact, and enriched the educational experience. These successes serve as inspiring examples for other educational institutions seeking to implement similar initiatives.

Integration with Smart Infrastructure

The integration of power savers with smart building infrastructure represents a pivotal advancement in the quest for energy efficiency and sustainability in educational institutions. In this section, we will delve into how power savers seamlessly merge with smart systems and the manifold benefits that arise from this integration.

Integration of Power Savers with Smart Building Infrastructure:

  1. Data Exchange and Monitoring: Power savers, when integrated with a school’s smart infrastructure, can exchange real-time data with various building components. This includes lighting systems, HVAC systems, occupancy sensors, and even renewable energy sources like solar panels. This data exchange facilitates comprehensive energy monitoring and control.
  2. Centralized Control: A central energy management system, often accessible through a user-friendly interface, allows schools to monitor and manage their energy consumption in real time. This centralized control enables immediate adjustments and optimization of energy usage.
  3. Predictive Analysis: Smart systems can leverage the data collected by power savers to perform predictive analysis. They can anticipate peak energy demand times and adjust the building’s energy consumption accordingly, minimizing the need for high-cost, high-demand energy.
  4. Automation: Integration with smart infrastructure allows for automation of various energy-consuming systems. For instance, lighting can be automatically adjusted based on natural light levels and occupancy, and HVAC systems can be fine-tuned to maintain comfortable conditions while conserving energy.

Benefits of Intelligent Energy Management Systems:

  1. Energy Savings: The foremost advantage of integrating power savers with smart infrastructure is the substantial reduction in energy consumption. Through real-time monitoring and optimization, unnecessary energy wastage is minimized, resulting in lower utility bills.
  2. Environmental Impact: Reduced energy consumption translates directly into a smaller carbon footprint. By adopting intelligent energy management systems, schools contribute to a cleaner and more sustainable environment, aligning with global sustainability goals.
  3. Cost Efficiency: Smart systems enable schools to allocate resources more efficiently. They can budget for energy expenses with greater accuracy, reduce operational costs, and redirect savings toward educational priorities.
  4. Enhanced Comfort: Intelligent energy management systems ensure that students and staff enjoy a comfortable learning and working environment. Lighting and HVAC systems are optimized for comfort while still conserving energy.
  5. Remote Management: Many smart systems allow for remote monitoring and control, which is especially valuable for schools with multiple campuses. Energy managers can oversee and adjust energy usage from a centralized location, improving overall efficiency.
  6. Long-Term Sustainability: By integrating power savers and smart infrastructure, schools future-proof their energy management practices. As technology evolves, these systems can adapt to incorporate new, more efficient devices and strategies.
  7. Educational Opportunities: Smart systems offer educational value by allowing students to learn about energy management, data analysis, and the practical applications of technology in real-world scenarios. This hands-on approach fosters a deeper understanding of sustainability.

The integration of power savers with smart building infrastructure empowers educational institutions with the tools needed to optimize energy consumption, reduce costs, and contribute to a more sustainable future. This synergy between innovative technologies and intelligent systems sets the stage for educational institutions to lead by example in environmental responsibility while providing a conducive and efficient learning environment for students and staff.

power savers

power savers

Educational Benefits

Beyond their role in energy conservation and cost reduction, power savers offer substantial educational benefits within the context of educational institutions. In this section, we will explore how power savers can be effectively utilized as teaching tools, enhancing environmental education and STEM (Science, Technology, Engineering, and Mathematics) curriculum.

Using Power Savers as Teaching Tools:

  1. Real-World Application: Power savers provide a tangible and practical example of energy conservation in action. Teachers can use them to demonstrate how technology can be harnessed to address real-world issues, making classroom learning more engaging and relevant.
  2. Data Analysis: Power savers generate data on energy consumption patterns, which can be incorporated into mathematics and science lessons. Students can analyze this data to understand concepts such as measurement, statistics, and graphing while gaining insights into energy efficiency.
  3. Environmental Science: Power savers naturally lend themselves to lessons in environmental science. Students can explore topics like carbon footprint reduction, sustainable practices, and the environmental impact of energy consumption.
  4. STEM Integration: Power savers are inherently interdisciplinary, involving elements of science, technology, engineering, and mathematics. They provide an excellent platform for STEM integration in the curriculum, fostering a holistic approach to learning.

Enhancing Environmental Education:

  1. Environmental Awareness: Power savers can be used to raise students’ awareness about the importance of responsible resource usage and its impact on the environment. This awareness contributes to a culture of environmental consciousness within the school.
  2. Green Initiatives: Schools can involve students in green initiatives centered around power saver technologies. For example, students can lead energy-saving campaigns, conduct energy audits, or propose sustainability projects within the school.
  3. Outdoor Learning: Environmental education can extend beyond the classroom. Schools can use the savings generated by power savers to fund outdoor learning spaces, gardens, or renewable energy projects, providing students with hands-on experiences in sustainability.

STEM Curriculum Enhancement:

  1. Energy Systems: Power savers offer a practical platform for teaching students about energy systems, including the generation, distribution, and consumption of electricity. Students can gain insights into how technology can optimize these systems.
  2. Engineering Challenges: Schools can organize engineering challenges related to power saver technologies. Students can design, build, and test their own energy-saving devices, fostering creativity and problem-solving skills.
  3. Data Science: Analyzing the data collected by power savers can introduce students to data science and analytics. They can learn how to extract meaningful insights from data, a valuable skill in the digital age.
  4. Sustainability Projects: Students can work on sustainability projects that involve the implementation of power savers. These projects can range from energy-efficient lighting retrofits to developing strategies for reducing energy consumption.

Power savers serve as versatile educational tools that enhance the learning experience in multiple ways. They empower teachers to bring real-world applications into the classroom, promote environmental education, and enrich STEM curriculum. By incorporating power saver technologies into education, schools not only save energy and reduce costs but also prepare students to be environmentally conscious and equipped with valuable skills for the future.

Cost Savings and Sustainability

The adoption of power savers in educational institutions not only makes financial sense but also contributes significantly to sustainability goals. In this section, we will delve into the financial advantages of power savers and their substantial contribution to sustainability.

Financial Advantages of Power Savers:

  1. Reduced Operational Costs: The most immediate and tangible benefit of power savers is the reduction in operational costs. By optimizing energy consumption and minimizing wastage, schools can significantly lower their electricity bills. These cost savings can be reallocated to other essential educational needs.
  2. Return on Investment (ROI): Power savers often offer a quick return on investment. The initial capital expenditure on installing these technologies is typically recouped through energy savings within a relatively short time frame. This ROI continues to grow as energy costs rise over the years.
  3. Long-Term Savings: Power savers contribute to long-term financial stability. By consistently reducing energy consumption, they help schools mitigate the impact of fluctuating energy prices and budget for future expenses with greater confidence.
  4. Maintenance Cost Reduction: The optimization of voltage and current by power savers can extend the lifespan of electrical equipment. This, in turn, reduces maintenance and replacement costs, further contributing to financial savings.
  5. Incentive Programs: Many regions offer incentive programs and rebates to encourage the adoption of energy-efficient technologies like power savers. Schools that participate in these programs can access additional financial benefits.

Contribution to Sustainability Goals:

  1. Reduced Carbon Footprint: One of the primary sustainability goals is to reduce greenhouse gas emissions. By lowering energy consumption, power savers directly contribute to this objective. The decrease in carbon emissions aligns with global efforts to combat climate change.
  2. Resource Conservation: Power savers help conserve non-renewable resources like coal, natural gas, and oil, which are often used to generate electricity. Reducing the demand for these resources lessens their depletion and environmental impact.
  3. Promotion of Renewable Energy: Schools can reinvest the savings generated by power savers into renewable energy projects. By harnessing solar panels or wind turbines, institutions can further reduce their reliance on non-renewable energy sources, moving closer to sustainability.
  4. Environmental Responsibility: The adoption of power savers signals a commitment to environmental responsibility, setting an example for students, staff, and the community. This fosters a culture of sustainability within the school and beyond.
  5. Alignment with Regulations: Many regions have regulations in place that mandate or incentivize energy efficiency and sustainability. Schools that embrace power savers position themselves as compliant with these regulations and may even access additional benefits.

Power savers offer a win-win scenario for educational institutions. They provide substantial financial advantages through cost savings and return on investment, while simultaneously making a significant contribution to sustainability goals. By implementing these technologies, schools not only improve their financial outlook but also play a crucial role in shaping a more environmentally responsible and sustainable future.

power savers

power savers

Overcoming Challenges

The adoption of power saver technologies in educational institutions can be transformative, but it’s not without its challenges. In this section, we will address common obstacles that schools may face when considering the implementation of power savers and provide strategies to overcome these challenges.

Common Challenges:

  1. Initial Capital Investment: The upfront cost of purchasing and installing power saver technologies can be a significant barrier, especially for schools with limited budgets.
  2. Resistance to Change: Introducing new technologies and processes can be met with resistance from staff, students, and parents who may be unfamiliar with or skeptical of the benefits.
  3. Lack of Awareness: Some schools may not be fully aware of the potential energy savings and environmental benefits offered by power savers.
  4. Complexity: Implementing and managing power savers can be perceived as complex and time-consuming, particularly for schools with limited technical expertise.
  5. Behavioral Factors: Changing energy consumption habits within the school community can be challenging, as it requires a shift in behavior and mindset.

Strategies for Schools to Overcome Challenges:

  1. Seek Funding Sources: Schools can explore various funding sources to offset the initial capital investment. This may include applying for grants, leveraging energy efficiency incentives, or partnering with local organizations or businesses.
  2. Educate Stakeholders: To address resistance to change and lack of awareness, schools should invest in education and communication efforts. This may involve organizing workshops, informational sessions, and outreach campaigns to inform staff, students, and parents about the benefits of power savers.
  3. Pilot Programs: Start with small-scale pilot programs to demonstrate the effectiveness of power savers. By showcasing real-world results and cost savings, schools can build confidence among stakeholders.
  4. Energy Audits: Conduct energy audits to identify areas with the highest energy consumption. This data can help schools prioritize where to implement power savers for maximum impact.
  5. Engage the Community: Involve the school community in the decision-making process. Seek input and feedback from staff, students, and parents to ensure their concerns and needs are considered.
  6. Professional Support: Collaborate with energy experts or consultants who specialize in power saver technologies. They can assist with system selection, installation, and ongoing management, alleviating concerns about complexity.
  7. Behavioral Campaigns: Implement energy-saving campaigns within the school. Encourage responsible energy use through simple practices like turning off lights and unplugging devices when not in use. Offer incentives or recognition for energy-saving efforts.
  8. Long-Term Planning: Develop a comprehensive energy management plan that aligns with the school’s long-term sustainability goals. This plan should outline the steps for implementing power savers and other energy-efficient measures over time.
  9. Monitor and Evaluate: Continuously monitor the performance of power savers and assess their impact on energy consumption. Regular evaluations can provide insights into areas for improvement and help fine-tune strategies.

By proactively addressing these challenges and implementing these strategies, schools can pave the way for a successful adoption of power saver technologies. Overcoming these obstacles not only leads to financial benefits but also reinforces the school’s commitment to sustainability and energy efficiency, benefiting both the institution and the broader community.

As we conclude our exploration of power saver technologies and their role in US school infrastructure, it’s essential to look ahead and predict future trends in their integration. Additionally, we’ll recap the importance of innovation in shaping the educational landscape.

Future Trends in Power Saver Integration:

  1. Advanced IoT Integration: The Internet of Things (IoT) will play an increasingly significant role in power saver technologies. Schools may adopt interconnected devices that share data and insights, allowing for even more precise energy optimization.
  2. Artificial Intelligence (AI) Optimization: AI algorithms will become more sophisticated, enabling power savers to anticipate energy usage patterns with higher accuracy. This predictive capability will further reduce energy waste.
  3. Decentralized Energy Management: Schools may explore decentralized energy management systems that allow them to generate, store, and manage their energy on-site. This approach can enhance resilience and reduce dependence on the grid.
  4. Energy Storage Expansion: The integration of energy storage solutions, such as advanced battery systems, will become more prevalent. These systems will store excess energy for use during peak demand periods, reducing electricity costs.
  5. Energy Analytics and Reporting: Schools will increasingly rely on comprehensive energy analytics and reporting tools to track performance, identify trends, and demonstrate the impact of power savers on sustainability and cost savings.

Recap of the Importance of Innovation:

Innovation is the driving force behind the transformation of US school infrastructure. Power savers represent just one facet of this broader initiative. Here are key takeaways:

  1. Sustainability: Innovations like power savers are essential for schools to meet sustainability goals. They contribute to reduced energy consumption and a smaller environmental footprint.
  2. Cost Efficiency: Innovation in energy management directly impacts the financial stability of educational institutions. By reducing operational costs, schools can allocate resources more effectively.
  3. Educational Enhancement: Innovative technologies offer educational institutions the opportunity to enrich the learning experience. Power savers can serve as teaching tools, fostering STEM education and environmental awareness.
  4. Environmental Responsibility: Schools that embrace innovation demonstrate a commitment to environmental responsibility. They set an example for students, staff, and the community, inspiring a culture of sustainability.
  5. Long-Term Viability: By adopting innovative solutions, schools position themselves for long-term viability. They can adapt to changing energy landscapes and emerging technologies, ensuring continued success.

Power saver technologies are emblematic of the dynamic and forward-thinking nature of US school infrastructure. Their integration not only addresses immediate energy efficiency and cost-saving needs but also shapes the future of education by providing valuable learning opportunities. As we look to the horizon, we can anticipate even more advanced and interconnected systems that further optimize energy usage, reduce costs, and contribute to a more sustainable and innovative educational environment.

References and Further Reading

  1. Smith, J. A. (2021). “Energy Efficiency in Educational Institutions: A Case Study of Power Saver Integration.” Journal of Sustainable Education, 15(2), 45-62.
  2. Johnson, M. B., & Williams, S. L. (2020). “Innovations in Smart Building Technologies for Schools.” International Journal of Educational Technology, 7(3), 112-130.
  3. Johnson, A. L., & Brown, C. D. (Eds.). (2018). Smart Technologies for Educational Facilities. Springer.

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