Your search keyword '"Šikula, Ondřej"' showing total 3 results

1. Adapting the construction of radiant heating and cooling systems for building retrofit.

Author

Junasová, Barbora, Krajčík, Michal, Šikula, Ondřej, Arıcı, Müslüm, and Šimko, Martin

Subjects

*RADIANT heating, *RETROFITTING of buildings, *COOLING systems, *HEAT storage, *WALLS, *RENEWABLE energy sources

Abstract

• Construction rules were studied for wall and ceiling systems suitable for retrofit. • Adding insulation was not necessary with insulating core even for low wall thickness. • Increase in output per 1 cm of pipe spacing was maximal at 6 cm. • A dense spacing maximized the system output per energy input. • A metal fin attached to a pipe in insulation led to the highest output. The application of radiant heating and cooling systems in building retrofit could facilitate the use of renewable energy sources in existing buildings. This research focused on adapting the design of a ceiling and wall system with pipes underneath the surface and a wall system with the pipe embedded in a bricklayer. These systems are suitable for installation in retrofitted rooms, but the findings are also applicable to new buildings. Heat transfer was computed using a validated numerical model. With a conductive core, insulation thickness of up to 3 cm was appropriate for an internal wall. With an insulating core, insulation was not necessary even if the core was only 15 cm thin. The increase in output per 1 cm of pipe spacing was maximal at 6 cm. Spacing below 3 cm was inefficient. A dense spacing maximized the system output per energy input by creating a uniform surface temperature, while also shortening the response time. Attaching a metal fin to a pipe in plaster increased the output by as much as reducing the pipe spacing from 10 to 6 cm (14 W/m2, i.e. 20%). Attaching a metal fin to a pipe embedded in insulation for a compact design led to the highest output of all cases studied. Placing the pipe in a brick layer added to a conductive wall did not increase the heat storage capacity of the wall. [ABSTRACT FROM AUTHOR]

Published

2022

2. Review of water-based wall systems: Heating, cooling, and thermal barriers.

Author

Krajčík, Michal, Arıcı, Müslüm, Šikula, Ondřej, and Šimko, Martin

Subjects

*SCIENTIFIC literature, *SOLAR heating, *AERODYNAMIC heating, *RETROFITTING of buildings, *PHASE change materials, *RENEWABLE energy sources, *ENERGY consumption

Abstract

[Display omitted] • Water-based wall systems for heating and cooling and thermal barriers are reviewed. • A classification scheme is proposed for heating/cooling systems and thermal barriers. • Benefits and drawbacks are summarized, design recommendations are provided. • Alternating between heating, cooling, and thermal barrier is perspective operation strategy. • Incorporating PCM in the wall and use in building retrofit are research opportunities. This study reviews water-based wall systems for space heating and cooling and thermal barriers (TB) for the reduction of buildings' thermal load. The review gives a general overview of the research and groups it into subtopics that are discussed in detail. For space heating and cooling, the subtopics entail thermal performance, thermal comfort, renewable energy sources, use for building retrofit, and combination with phase change materials (PCM). For TB, especially the working principle, types and designs, and performance are discussed. A classification system is proposed separately for wall heating and cooling systems and TB based on the designs found in scientific literature. Benefits and drawbacks are summarized, and design recommendations are provided for the wall systems. It was shown that in certain cases, radiant wall systems can be preferable to radiant floors and ceilings, but further comparisons would be useful to provide conclusive evidence. For TB, the studies uniformly declare that TB reduce buildings' thermal loads and energy demands. Few studies focused on the economic and environmental aspects of using TB. Most of the studies about TB are based on calculations. Measurements to quantify the benefits of TB under real operation and refine the conditions under which various types of TB are feasible are lacking. Enhancing the wall performance by PCM in the active layer, application of the wall systems in building retrofit, and alternating between the functions of heating, cooling, and TB present the biggest research opportunities and challenges. [ABSTRACT FROM AUTHOR]

Published

2021

3. Thermal performance of a radiant wall heating and cooling system with pipes attached to thermally insulating bricks.

Author

Krajčík, Michal, Šimko, Martin, Šikula, Ondřej, Szabó, Daniel, and Petráš, Dušan

Subjects

*RADIANT heating, *COOLING systems, *WATER temperature, *THERMAL insulation, *RETROFITTING of buildings, *BRICKS, *SURFACE temperature

Abstract

A radiant wall heating and cooling system with pipes attached to thermally insulating bricks was tested using climate chambers and a hotbox. This system is especially suitable for building retrofit due to its affordability and ease of installation but can be also applied in new buildings. Besides walls, the design tested can be also used for ceilings. Thermal output and response, wall surface and cross-section temperature, and water temperature were measured under a range of thermal loads. The thermal response was fast despite the coupling of the pipe with the bricks; the time constant τ 63 was 0.5 h. The low-conductivity core substantially reduced thermal losses meaning that the system can properly function even without thermal insulation. These qualities may present an advantage compared to systems with pipes coupled to a conductive core which require insulation and have longer response times. The difference between water and average surface temperature was small, up to 7.0 °C at the peak output of 100 W/m2, which benefits the energy source efficiency. However, the surface temperature was non-uniform, which should be considered to prevent local condensation. Numerical simulations at room level showed that locating the system at one wall leads to a non-homogeneous thermal environment. Installation at multiple walls can be preferable to attain more uniform conditions. [ABSTRACT FROM AUTHOR]

Published

2021