Exergy-Optimum Coupling of Heat Recovery Ventilation Units with Heat Pumps in Sustainable Buildings

Kılkış, Birol

doi:10.13044/j.sdewes.d7.0316

Cited by 14 publications

(4 citation statements)

References 24 publications

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“…However, if the outdoor unit provides representative values of cooling and heating capacity, detailed tables will display capacity gaps against the nominal capacities. Systems with larger gaps should be suitable for downsizing [8][9][10]. In the case of existing systems, downsizing could be achieved by adjusting target evaporating and condensing temperatures.…”

Section: Capacity and Building Load Assessmentmentioning

confidence: 99%

Heat Recovery Variable Refrigerant Volume System Installation and Experiences from its Summer Operation

Straková,

Vojtaššák,

Takács

et al. 2024

Period. Polytech. Mech. Eng.

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Variable refrigerant volume (VRV) systems operate on the principle of a cooling machine. They extract heat from one side and return it on the other, enabling them to function as a source of heat for both heating and hot water preparation, as well as a source of cold for cooling within a single building. These systems efficiently remove unnecessary excess heat outside and only introduce the required amount of heat from the outside into the building. With an appropriate configuration and setting, a VRV system can transfer heat in both directions within one system, eliminating the requirement for waste heat to be removed without use in the building. Instead, it is transferred to the desired locations where it is needed. This principle necessitates the adjustment of not only the refrigerant temperature but also its flow rate. Consequently, the VRV system can fulfil tasks that are otherwise handled by several individual systems in a building.A heat recovery VRV system was installed in a small retail store to extract waste heat generated by baking ovens during the baking process. This report provides a brief summary of electricity and energy consumption measurements taken during the summer period for cooling purposes. Sequential logic is observed and coherence is ensured, with active voice predominating for clearer and more direct communication. The parameters of interest include cooling setpoints, cooling outside of working hours, and capacity assessment.

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Section: Capacity and Building Load Assessmentmentioning

confidence: 99%

Heat Recovery Variable Refrigerant Volume System Installation and Experiences from its Summer Operation

Straková,

Vojtaššák,

Takács

et al. 2024

Period. Polytech. Mech. Eng.

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“…They are already the main energy-consuming sector [104][105][106][107][108]. Heating, ventilation, and air conditioning (HVAC) systems alone account for 40-60% of a building's energy needs [109][110][111][112], and the ventilation systems themselves account for 20-30% [113]. With this in mind, in order to globally reduce energy consumption and CO 2 emissions, old buildings should be modernised [114][115][116][117], and also take reduction energy and CO 2 emissions into account in the risk assessment of project management [118,119].…”

Section: Façade Decentralised Ventilationmentioning

confidence: 99%

Review of IAQ in Premises Equipped with Façade–Ventilation Systems

Zender–Świercz

2021

Atmosphere

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Poor indoor air quality affects the health of the occupants of a given structure or building. It reduces the effectiveness of learning and work efficiency. Among many pollutants, PM 2.5 and 10 dusts are extremely important. They can be eliminated using mechanical ventilation equipped with filters. Façade ventilation devices are used as a way to improve indoor air quality (IAQ) in existing buildings. For their analysis, researchers used carbon dioxide as a tracer gas. They have shown that façade ventilation devices are an effective way to improve IAQ, but require further analysis due to the sensitivity of façade ventilation devices to the effects of wind and outdoor temperature. In addition, legal regulations in some countries require verification in order to enable the use of this type of solution as a way to improve IAQ in an era characterised by the effort to transform buildings into passive houses (standard for energy efficiency in a building).

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“…Efforts for improving the energy efficiency of a building's full lifecycle have been targeted in two main directions: one is the upgrade of envelope elements (e.g., façade [94], windows [95], roofs [96], etc. ), and the other is the improvement of applied facilities (e.g., heating, cooling [97], ventilation [98] and lighting [99]). The building envelope, which is another responsible architectural component of energy-saving efficiency in buildings, may also significantly impact their thermal comfort [100] and energy balance [101].…”

Section: Building Energy Savingmentioning

confidence: 99%

Recent Advances in Technology, Strategy and Application of Sustainable Energy Systems

et al. 2020

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The global COVID-19 pandemic has had strong impacts on national and international freight, construction and tourism industry, supply chains, and has resulted in a rapid decline in the demand for traditional energy sources. In fact, research has outlined that urban areas depend on global supply chains for their day-to-day basic functions, including energy supplies, food and safe access to potable water. The disruption of global supply chains can leave many urban areas in a very vulnerable position, in which their citizens may struggle to obtain their basic supplies, as the COVID-19 crisis has recently shown. Therefore, solutions aiming to enhance local food, water and energy production systems, even in urban environments, have to be pursued. The COVID-19 crisis has also highlighted in the scientific community the problem of people’s exposure to outdoor and indoor pollution, confirmed as a key element for the increase both in the transmission and severity of the contagion, on top of involving health risks on their own. In this context, most nations are going to adopt new preferential policies to stimulate the development of relevant sustainable energy industries, based on the electrification of the systems supplied by renewable energy sources as confirmed by the International Energy Agency (IEA). Thus, while there is ongoing research focusing on a COVID 19 vaccine, there is also a need for researchers to work cooperatively on novel strategies for world economic recovery incorporating renewable energy policy, technology and management. In this framework, the Sustainable Development of Energy, Water and Environment Systems (SDEWES) conference provides a good platform for researchers and other experts to exchange their academic thoughts, promoting the development and improvements on the renewable energy technologies as well as their role in systems and in the transition towards sustainable energy systems. The 14th SDEWES Conference was held in Dubrovnik, Croatia. It brought together around 570 researchers from 55 countries in the field of sustainable development. The present Special Issue of Energies, specifically dedicated to the 14th SDEWES Conference, focuses on four main fields: energy policy for sustainable development, biomass energy application, building energy saving, and power plant and electric systems.

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Exergy-Optimum Coupling of Heat Recovery Ventilation Units with Heat Pumps in Sustainable Buildings

Cited by 14 publications

References 24 publications

Heat Recovery Variable Refrigerant Volume System Installation and Experiences from its Summer Operation

Heat Recovery Variable Refrigerant Volume System Installation and Experiences from its Summer Operation

Review of IAQ in Premises Equipped with Façade–Ventilation Systems

Recent Advances in Technology, Strategy and Application of Sustainable Energy Systems

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