Fulfillment of EU Goals in the Field of Waste Management through Energy Recovery from Waste

Is it really necessary for the more than 200 million tons of municipal waste produced by the EU to end up in landfills? Nowadays, there are many methods for using the raw materials and energy potential of waste in ways that are economical and environmentally acceptable. But first it is necessary to understand what waste is being produced, the possibilities for recycling, and the amount of waste deposited in landfills. Many studies show that, with the ever-increasing standard of living, which is accompanied by increasing consumption as well as increasing waste production, increasing separation of waste is a positive trend. However, it is essential to realize that many materials cannot be recycled indefinitely. Therefore, in our research, we focused on reducing the share of waste that goes into landfill with the goal of zero waste to landfill, so as to increase recycling and the amount of energy obtained from waste. We focused on the analysis of waste production in individual EU states, using the available data for the years 1995–2019. For a more detailed analysis, EU countries were evaluated in terms of individual waste management processes, according to available statistical data. We found that Switzerland, Germany, Sweden, Belgium, the Netherlands, Norway, Denmark, and Austria put the least amount of waste into landfills, which means that they obtain the most energy and raw materials from waste

Enhancing Small Heat Source Performance through Gravitational Loop Heat Pipes

This experimental study aimed to validate the integration of a gravitational loop heat pipe (GLHP) with respect to a gas fireplace insert. The GLHP was utilized to enhance the efficiency of the fireplace by preheating the combustion air with waste heat from flue gases. The experiment involved monitoring key parameters such as vapor and condensate temperatures and absolute pressure within the LHP. The results demonstrated that a filling volume of 0.1 L of water in the LHP allowed for successful operation, while exceeding 0.2 L resulted in flooding and decreased system efficiency. Challenges related to vapor production and condensate return were identified, suggesting the need for further research and design improvements. The experimental verification confirmed the feasibility of implementing the gravitational LHP in a gas fireplace insert and emphasized the importance of optimizing vapor production and condensate return mechanisms. This study contributes to the advancement of thermal management strategies and provides valuable insights for enhancing the design and performance of such systems