Cold Climate Challenges: Analysis of Heat Recovery Efficiency in Ventilation Systems

As building energy consumption gains ever-increasing attention worldwide, the focus on addressing it through the examination and optimization of efficient heat recovery solutions continues to intensify. With well-insulated and airtight buildings, the proportion of heating needs attributed to ventilation is growing, leading to the widespread integration and optimization of heat recovery solutions in mechanical ventilation systems. Heat recovery in ventilation is a highly efficient strategy for reducing heat losses and conserving energy. This study involves the investigation of a ventilation unit installed in an apartment situated in Riga, Latvia, as a practical examination of heat recovery system efficiency within the Latvian climate conditions, representing a cold climate region. The objective of this study was to examine the heat recovery efficiency of the ventilation system in the Latvian climate with variable outdoor and exhaust air parameters, given that the dry heat recovery efficiency is different from the actual heat recovery efficiency. The ventilation unit was equipped with a plate heat exchanger at an airflow rate of 105 m3/h. To evaluate heat recovery efficiency, extensive measurements of air temperature and relative humidity were conducted. The collected data was analyzed, employing statistical regression analysis to ensure measurement reliability and assess correlations. The findings indicated a strong correlation between variables such as heat content, moisture content, and sensible air parameters. It was observed that the actual heat recovery efficiency was 6% higher than the calculated dry efficiency, emphasizing the importance of considering real-world conditions in heat recovery assessments. Additionally, regression analysis demonstrated a positive linear correlation with a coefficient of 0.77, highlighting the dependency between actual measurements and the theoretical model. These quantitative outcomes provide essential insights for optimizing heat recovery systems and enhancing energy-efficient ventilation practices, especially in cold climate environments. Moreover, this study highlights the strong correlation between variables such as heat content, moisture content, and sensible air parameters. Findings offer essential insights for optimizing heat recovery systems and enhancing energy-efficient ventilation practices, especially in cold climate environments.

[1]  Junyong Liu,et al.  Multi-energy sharing optimization for a building cluster towards net-zero energy system , 2023, Applied Energy.

[2]  Xia Qi,et al.  Environment, social and governance research of infrastructure investment: A literature review , 2023, Journal of Cleaner Production.

[3]  Nam Tien Duong,et al.  Sustainable economic performance and natural resource price volatility in the post-covid-pandemic: Evidence using GARCH models in Chinese context , 2023, Resources Policy.

[4]  J. Gao,et al.  Performance investigation on a precision air conditioning system with a condensation heat recovery unit under varying operating conditions , 2023, Applied Thermal Engineering.

[5]  E. Georges,et al.  Framework to assess climate change impact on heating and cooling energy demands in residential building stock: a case study of Belgium in 2050 and 2100 , 2023, Energy and Buildings.

[6]  D. Palladino Energy performance gap of the Italian residential building stock: Parametric energy simulations for theoretical deviation assessment from standard conditions , 2023, Applied Energy.

[7]  D. Pohoryles,et al.  Heating energy demand estimation of the EU building stock: Combining building physics and artificial neural networks , 2023, Energy and Buildings.

[8]  S. Petersen,et al.  Overheating calculation methods, criteria, and indicators in European regulation for residential buildings , 2023, Energy and Buildings.

[9]  L. Montorsi,et al.  Combined numerical approach for the evaluation of the energy efficiency and economic investment of building external insulation technologies , 2023, Energy Nexus.

[10]  Sokol Dervishi,et al.  Early design evaluation of low-rise school building morphology on energy performance: Climatic contexts of Southeast Europe , 2023, Energy.

[11]  J. Laverge,et al.  Energy savings and exposure to VOCs of different household sizes for three residential smart ventilation systems with heat recovery , 2023, Energy and Buildings.

[12]  M. Bilec,et al.  Quantifying and spatializing building material stock and renovation flow for circular economy , 2023, Journal of Cleaner Production.

[13]  Peng Liu,et al.  Global sensitivity analysis and optimal design of heat recovery ventilation for zero emission buildings , 2023, Applied Energy.

[14]  Peng Liu,et al.  Understanding the role of moisture recovery in indoor humidity: An analytical study for a Norwegian single-family house during heating season , 2022, Building and Environment.

[15]  Michiyuki Yagi,et al.  The spillover effects of rising energy prices following 2022 Russian invasion of Ukraine , 2022, Economic Analysis and Policy.

[16]  C. Silva,et al.  Open Energy Data — A regulatory framework proposal under the Portuguese electric system context , 2022, Energy Policy.

[17]  Peng Liu,et al.  Heat recovery ventilation design limitations due to LHC for different ventilation strategies in ZEB , 2022, Building and Environment.

[18]  M. Odriozola-Maritorena,et al.  Use of sunspaces to obtain energy savings by preheating the intake air of the ventilation system: Analysis of its main characteristics in the different Spanish climate zones , 2022, Journal of Building Engineering.

[19]  A. Borodinecs,et al.  Estimation of Energy Profile and Possible Energy Savings of Unclassified Buildings , 2022, Buildings.

[20]  H. M. Mathisen,et al.  A review of heat recovery technologies and their frost control for residential building ventilation in cold climate regions , 2022, Renewable and Sustainable Energy Reviews.

[21]  Peng Liu,et al.  Development and optimization of highly efficient heat recoveries for low carbon residential buildings in cold climates , 2022, Energy and Buildings.

[22]  Khalid Khan,et al.  COVID-19 impact on multifractality of energy prices: Asymmetric multifractality analysis , 2022, Energy.

[23]  X. Oregi,et al.  Barriers and challenges of the assessment framework of the Commission Recommendation (EU) 2019/786 on building renovation by European RTD projects , 2022, Energy and Buildings.

[24]  V. Hoffmann,et al.  MANGOret: An optimization framework for the long-term investment planning of building multi-energy system and envelope retrofits , 2022, Applied Energy.

[25]  J. Kurnitski,et al.  Overview and future challenges of nearly zero-energy building (nZEB) design in Eastern Europe , 2022, Energy and Buildings.

[26]  Y. Tsai,et al.  A comprehensive analysis of the intervention of a fresh air ventilation system on indoor air quality in classrooms , 2022, Atmospheric Pollution Research.

[27]  M. Harasek,et al.  Membrane-based enthalpy exchangers for coincident sensible and latent heat recovery , 2022, Energy Conversion and Management.

[28]  Constantine E. Kontokosta,et al.  Building retrofit hurdle rates and risk aversion in energy efficiency investments , 2022, Applied Energy.

[29]  V. Deshko,et al.  Evaluation of energy use for heating in residential building under the influence of air exchange modes , 2021 .

[30]  Damira Keček,et al.  Economic and regional spillovers of energy efficiency investments in buildings , 2021, Energy and Buildings.

[31]  O. Olubusoye,et al.  Energy pricing during the COVID-19 pandemic: Predictive information-based uncertainty indexes with machine learning algorithm , 2021, Intelligent Systems with Applications.

[32]  J. M. Sala-Lizarraga,et al.  Ventilation of buildings with heat recovery systems: Thorough energy and exergy analysis for indoor thermal wellness , 2021, Journal of Building Engineering.

[33]  John Kaiser Calautit,et al.  A Deep Learning Approach Towards the Detection and Recognition of Opening of Windows for Effective Management of Building Ventilation Heat Losses and Reducing Space Heating Demand , 2021 .

[34]  P. Wargocki,et al.  Indoor humidity of dwellings and association with building characteristics, behaviors and health in a northern climate , 2021, Building and Environment.

[35]  Teresa Maria Gulotta,et al.  A bottom-up harmonized energy-environmental models for europe (BOHEEME): A case study on the thermal insulation of the EU-28 building stock , 2020 .

[36]  A. Borodinecs,et al.  Energy saving potential of ventilation systems with exhaust air heat recovery , 2019, IOP Conference Series: Materials Science and Engineering.

[37]  Samuel Domínguez-Amarillo,et al.  Thermal comfort and indoor air quality in low-income housing in Spain: The influence of airtightness and occupant behaviour , 2019, Energy and Buildings.

[38]  R. Zevenhoven,et al.  Energy efficiency of exhaust air heat recovery while controlling building air humidity: A case study , 2019, Energy Conversion and Management.

[39]  L. Gustavsson,et al.  Cost-optimized energy-efficient building envelope measures for a multi-storey residential building in a cold climate , 2019, Energy Procedia.

[40]  Xiaohua Liu,et al.  Experimental and numerical analysis on total heat recovery performance of an enthalpy wheel under high temperature high humidity working conditions , 2019, Applied Thermal Engineering.

[41]  D. Baranova,et al.  The extensive analysis of building energy performance across the Baltic Sea region , 2018 .

[42]  K. Bizer,et al.  Energy efficiency of residential buildings in the European Union – An exploratory analysis of cross-country consumption patterns , 2018, Energy Policy.

[43]  Xiaohua Xia,et al.  Energy-efficiency building retrofit planning for green building compliance , 2018 .

[44]  Paula Kivimaa,et al.  Technical skills, disinterest and non-functional regulation: Barriers to building energy efficiency in Finland viewed by energy service companies , 2018 .

[45]  Luigi Marletta,et al.  Controlled mechanical ventilation systems in residential buildings: Primary energy balances and financial issues , 2017 .

[46]  D Daniel Cóstola,et al.  Review of methods for climatic zoning for building energy efficiency programs , 2017 .

[47]  Izzet Yüksek,et al.  Energy-Efficient Building Design in the Context of Building Life Cycle , 2017 .

[48]  Targo Kalamees,et al.  Ventilation System Design in Three European Geo Cluster , 2016 .

[49]  Anatolijs Borodinecs,et al.  Enabling the Landscape for Deep Green Renovations , 2016 .

[50]  Giorgio Baldinelli,et al.  Experimental Performance Analyses of a Heat Recovery System for Mechanical Ventilation in Buildings , 2015 .

[51]  S. Thébault,et al.  Estimating Infiltration Losses for In-situ Measurements of the Building Envelope Thermal Performance☆ , 2015 .

[52]  Miklos Kassai,et al.  Evaluation of defrosting methods for air-to-air heat/energy exchangers on energy consumption of ventilation , 2015 .

[53]  S. A. Nada,et al.  Performance analysis of proposed hybrid air conditioning and humidification–dehumidification systems for energy saving and water production in hot and dry climatic regions , 2015 .

[54]  Jesper Kragh,et al.  Dynamic model of counter flow air to air heat exchanger for comfort ventilation with condensation and frost formation , 2009 .

[55]  A. Borodinecs,et al.  Modular retrofitting approach for residential buildings , 2023 .

[56]  Maria Kola-Bezka One size fits all? Prospects for developing a common strategy supporting European Union households in times of energy crisis , 2023, Energy Reports.

[57]  R. Cichowicz,et al.  Comparison of calculation and consumption methods for determining Energy Performance Certificates (EPC) in the case of multi-family residential buildings in Poland (Central-Eastern Europe) , 2023, Energy.

[58]  Molla Ramizur Rahman,et al.  Is geopolitical risk interconnected? Evidence from Russian-Ukraine crisis , 2023, The Journal of Economic Asymmetries.

[59]  N. Buyak,et al.  Сhanging Energy and Exergy Comfort Level after School Thermomodernization , 2021, Rocznik Ochrona Środowiska.

[60]  A. Prozuments,et al.  Retrofitting of fire stations in cold climate regions , 2019 .

[61]  M. Petrichenko Ventilated facade integrated with the HVAC system for cold climate , 2018 .

[62]  J. Zemitis,et al.  Management of energy efficient measures by buildings’ thermorenovation , 2018 .

[63]  Anatolijs Borodinecs,et al.  Modular retrofitting solution of buildings based on 3D scanning , 2017 .

[64]  Y. Man,et al.  On Site Measurement and Analysis on Indoor Air Environment of Classroom in University Campus , 2017 .