Vytápění bytových domů / Heating of Apartament Buildings

Tichá, Hana

January 2013

The thesis is a technical solution for heating two apartment buildings. The project is designed in two versions. The first variant is source of heat boilers for pellets, in the second variant, the heat source heat pumps type of land / water. Part of this work is an experiment which deals with the measurement of floor heating.

Návrh vytápění nízkoenergetického rodinného domu / Heating system of a Low-energy house

Jankola, Mario

January 2016

This master’s thesis pertains to heating practices of low-energy houses using a heat pump (example 1) and low-temperature condensing boiler (example 2). The first part of the work contains calculations of suggested building’s heat efficiency and of under-floor heating. The second part of the work includes estimates of seasonal heating factors for construction with a heat pump. Based on the comparison: both of these heating systems are recommended; the capacity of the warm water container is established; and safety elements are chosen. Furthermore, a system of regulation for warm water heating is determined, and a curve of equithermal regulation for heating is calculated. Both of the recommended heating possibilities include calculations of costs of supplies and manufacturing, as well as blueprints for construction.

Vytápění administrativního objektu / Heating of administrative building

Bobek, Jan

January 2017

The dissertation deals with heating of the administrative building. The building is heated with the floor heating and the panel heating units. The heating source is an air to water heat pump with a bivalent heating from the central heat supplying (CZT). I deal in the project with design, dimension and connection of all these parts.

Obecní úřad s multifunkčním sálem / City hall with a multifunctional space

Zabáková, Laura

Unknown Date

The main task of the master project is to design a nearly zero energy local council building with multipurpose hall in Syrovice cadastral area. It is a three-storey building with basement. In the basement there are technical facilities and garage. Ground floor includes conference room, multipurpose hall, kitchen, cloak room and toilets. First floor includes offices, archive, staff kitchen and toilets. The building’s vertical load-bearing structures are a combination of ceramic block masonry and reinforced concrete columns. Envelope walls are insulated with mineral wool and XPS. The floor slabs and the staircase are designed from cast-in-place reinforced concrete. The building has flat extensive green roofs with photovoltaics installation. The building is equipped with HVAC system with mechanical ventilation with heat-recovery, floor heating and cooling supplied by a ground-water heat pump. The building is also equipped with rainwater accumulation system supplying rainwater for the toilets and watering.

A hybrid low - temperature heating system in geothermal retrofitting for public buildings in the Mediterranean climate

Bizimana, Boumediene

January 2019

More than 50 % of EU’s yearly energy demand is spent on heating and cooling systems with which most of its source is generated from non-renewable fossil fuel [1]. Furthermore, half of the EU buildings are heated with a non-efficient boiler of about 60% or less efficiency [1]. The report released by EU from 1990 to 2007 revealed that fuel combustion and fugitive emission contribute to about 79.3% of total greenhouse gas emissions in CO2 equivalents [1]. The EU-EBPD long-term renovation strategy is to improve the energy performance of all residential and non-residential buildings in its member countries through supporting the renovation of the existing buildings into highly energy efficient and decarbonised buildings [2]. Despite all these EU policies and efforts to replace these non-efficient heating systems, the main challenge is price comparison of different solutions and their efficiency in retrofitting of the heating old systems together with the lack of information about the functioning of those old systems [1]. Thus, the development of an easy to install heating system in retrofitting with low exergy heat supply is a significant contribution to a sustainable solution in minimizing energy resources depletion and environmental emission. Furthermore, efficient system control of these easy to install heating systems, hybrids combinations solution for retrofitting building could be a sustainable solution for the preservation of the existing building. The main objective of this work was to design an easy to install hybrid low-temperature floor heating system in retrofitting buildings and compare its results on energy performance, thermal comfort and indoor air quality with other conventional heating mainly used in the Mediterranean climate. This study was performed in two existing radiators heated buildings located in Sant Cugat del vallès in Catalonia, Spain.The results showed that the hybrid low-temperature heating system has the highest energy performance and energy saving of 48 % and 52% compared to that of existing radiator heating and all air heating, respectively. However, hybrid low-temperature floor heating showed a slow heating response, and consequently, it showed lower operative temperature compared to others even though it was within the recommended standards limits. The hybrid low-temperature heating system with demand-controlled ventilation also showed a better indoor air quality, while as existing radiator with its natural ventilation showed the worst indoor air quality. All three compared heating systems showed a better coefficient of performance with low-temperature heat supply and were able to operate with low-temperature heat supply. / Mer än 50% av EU:s årliga energibehov spenderas på värme- och kylsystem där de flesta av deras källor genereras från icke-förnybart fossilt bränsle [1]. Dessutom värms hälften av EU:s byggnader upp med en ineffektiv panna med cirka 60% eller mindre effektivitet [1]. EU:s rapport från 1990 till 2007 avslöjade att bränsleförbränning och flyktiga utsläpp bidrar till cirka 79% av de totala utsläppen av växthusgaser i koldioxidekvivalenter [1]. EU:s och EBPD:s långsiktiga renoveringsstrategi är att förbättra energiprestanda för alla bostäder och andra byggnader i dess medlemsländer genom att stödja renovering av befintliga byggnader till mycket energieffektiva byggnader [2].Trots alla dessa EU-policyer och ansträngningar för att ersätta dessa ineffektiva värmesystem, är den största utmaningen prisjämförelse av olika lösningar och deras effektivitet i renovering av de gamla värmesystemen tillsammans med bristen på information om hur de gamla systemen fungerar [1]. Därför är utvecklingen av ett installationsenkelt värmesystem med låg värmeförsörjning av exergi ett viktigt bidrag till en hållbar lösning för att minimera energiresurser och miljöutsläpp. Dessutom kan effektiv systemkontroll av dessa värmesystem med olika kombinationslösningar för renovering av byggnaden vara en hållbar lösning för att bevara den befintliga byggnaden.Huvudsyftet med detta arbete var att utforma ett lågtemperaturgolvvärmesystem att använda vid renovering av byggnader och jämföra dess resultat på energiprestanda, termisk komfort och inomhusluftkvalitet med annan konventionell uppvärmning som huvudsakligen används i medelhavsklimat. Denna studie utfördes i två befintliga radiatoruppvärmda byggnadet i Sant Cugat del vallès i Katalonien, Spanien. Resultaten visade att hybridsystemet med låg temperatur har den högsta energiprestandan och energibesparingen på 48% och 52% för den befintliga radiatorvärme respektive luftvärme. Emellertid visade lågtemperaturgolvvärme ett långsamt uppvärmningssvar, och följaktligen visade det lägre driftstemperatur jämfört med de andra systemen trots att det låg inom de rekommenderade standardgränserna. Lågtemperaturvärmesystem med efterfrågningsstyrd ventilation visade också en bättre inomhusluftkvalitet, medan befintliga radiatorer med sin naturliga ventilation visade den sämsta inomhusluftkvaliteten. Alla tre jämförda värmesystemen visade bättre prestanda med lågtemperaturvärmeförsörjning och kunde fungera med lågtemperaturvärmeförsörjning.

Hybrid low-temperature floor heating

Energy performance

Thermal comfort

Indoor air quality

Lågtemperaturgolvvärme

Energiprestanda

Termisk komfort

Inomhusluftkvalitet

Social Sciences

Samhällsvetenskap

Architectural Engineering

Arkitekturteknik

Energeticko-ekonomické hodnocení, a optimalizace, rodinného domu / Energy-ekonomical evaluation, and optimization, of a family house

Rodková, Daniela

January 2018

The main content of this thesis is a design and an assessment of energy-saving measures with an objective of energy economical optimization of a particular family house. The theoretical part of the thesis describes problems of the energy performance of the building. The calculating part is devoted to economical and environmental assessment of two solving options with a use of a computer program which enables a monthly calculating measure. One part constitutes a design of air-conditioning systems, heating and drawing up an Energy Performance Certificates. The part of the thesis which is focused on a computer technology application deals with energy performance optimization with a use of a program which enables a daily calculating measure and making models of pictures of flowing with a use of CFD methods.

Návrh solárního ohřevu vody a solárního přitápění v rodinném domě / Design of a solar space and DHW heating system for a detached dwelling

Čukat, Stanislav

January 2012

The master’s thesis deals with the design of solar assisted space heating and domestic hot water (DHW) heating in a detached single family dwelling. The thesis contains the heating load calculations as well as the calculation of the energy consumption for space and DHW heating. The thesis also contains the actual design and sizing of the heating system including the drawings. A simulation of solar heating was carried out with the use of the TRNSYS simulation tool in order to assess the yield of the solar heating system.

Environmentální řešení objektu domu s kavárnou v Zaječí / Environmental solution of a house with a café in Zaječí

Medková, Tereza

January 2022

In my master's project I design a nearly zero energy consumption house with a café in Zaječí. The 1ST part of this project deals with a structural part of the building, which has two above-ground floors and basement. On the basement are storerooms and rooms for technical equipment, on the ground floor is café and living room with kitchen, and on the second floor are bedrooms, bathrooms and cloakrooms. Footings are from cast-in-place concrete, the load bearing walls on basement are from formwork blocks with cast-in-place concrete, on above-ground floors are from ceramic blocks and every non-load bearing walls are also from ceramic blocks. On whole floor are reinforced concrete floor slab and flat green roof. The 2ND part deals with technical equipment of the building. There are gas boiler, floor heating, air conditioning, mechanical ventilation (HVAC), photovoltaics panels with energy storage, retention tank, external blinds and biodynamic lighting. The 3RD part compares several options for using solar energy in combination with different heat sources in terms of energy and economic efficiency of the building.

Vytápění objektu hotelového typu / Heating building a hotel-type

Duda, Jiří

January 2012

Design of heating of hotel type. The first part describes the analysis of the building and heating heat pumps theory and evaluation systems with heat pump. In the second part we find two variants of technical solutions. The third part contains solutions for selected variant and it is heating with gas boiler.

Termisk komfort med golvvärme eller luftvärme / Thermal comfort with floor heating or air heating

Boåsen, Filip, Khaled, Stiven

January 2018

Då varje människa tillbringar större del av dagen inomhus så är det viktigt att ha en bra termisk komfort, efter som den termiska komforten påverkar upplevelsen på jobbet i hemmet eller i skolan. Människor kan påverkas negativt när den termiska komforten inte uppfyller kraven.   Syftet med undersökningen är att undersöka hur lågtemperaturssystemens förmåga är med avseende på termisk komfort och om de uppfyller kraven. Undersökningen använder beräknings data från tidigare utfört arbete då beräkningarna valideras av jämförelse mot andra undersökningar.   I detta arbete undersöker vi skillnader mellan golvvärme och luftvärme, där vi ser hur de olika systemen jämförs mot varandra under kontrollerade förhållanden med avseende på termisk komfort. De olika systemen som undersöks är luftvärme som är placerad under tak, luftvärme placerad under ett fönster, golvvärme som är jämnfördelad över golvet och golvvärme jämnfördelad med extra slingor under fönster. I undersökningen utförs en litteraturstudie som kommer att ligga till grund för vad ämnet för lågtemperatur innefattar samt hur de olika systemen fungerar och hur dessa kan användas som lågtemperaturssystem. Då i denna undersökningen så beaktas operativa temperaturen PMV, PPD och dragindex för att få en bra uppfattning hur den termiska komforten upplevs med avseende på golvvärme och luftvärme. Undersökningen har gett goda resultat då skillnaden i termisk komfort mellan de olika systemen har varit minimala och uppfyllt alla krav enligt BBR. Resultaten har jämförts mot tidigare gjorda undersökningar av lågtemperaturteknik och resultaten sammanfaller bra med små avvikelser. För att välja ett av de fyra systemen som har visats bättre resultat med hänsyn på termisk komfort så har golvvärme med extra slingor under fönster bevisats vara det bättre alternativet, då PMV och PPD samt drag ligger under rekommendationen för termisk komfort. / When most people spend a larger part of the day indoors, it is important to have a good thermal comfort, as the thermal comfort affects the experience that you perceive when you are at work, at home or at school. This may then affect the health if the thermal comfort does not meet the requirements. The purpose of the survey is to investigate low temperature system performance in terms of thermal comfort and if it meets the requirements. The survey uses calculation data from previously performed surveys, as the calculations are validated by comparison with other surveys. In this survey we explore the differences between floor heating and air heating, where we look at how the different systems are compared to each other under controlled conditions regarding thermal comfort. The different systems under investigation are air heating placed on the wall, air heating placed under a window, floor heating evenly distributed over the floor and floor heating that has extra loops under windows. The study will carry out a literature study that will be based on the topic of low temperature and how the different systems work and how they can be used at low temperatures. In this survey, the operating temperature PMV, PPD and DR-index are considered to get a good idea of how thermal comfort is experienced regarding floor heating or air heating. The survey has given good results, since the difference in thermal comfort between the different systems has been minimal and fulfilled all BBR requirements. The results have been compared to previous studies of low temperature technology, as the results coincide well with minor deviations. To choose one of the four systems that have been shown superior in terms of thermal comfort, floor heating with extra loops under windows has been proven to be the better option, as PMV and PPD as well as values are below the recommendation for thermal comfort.

Thermal Comfort

Low Temperature Technology

Energy

Exergy

Air Heating

floor Heating

PPD

PMV

DR Index.

Termisk komfort

Lågtemperatur teknik

Energi

Exergi

Luftvärme

Golvvärme

PPD

PMV

DR-index.

Other Civil Engineering

Annan samhällsbyggnadsteknik