Projektering och energieffektivisering av värme- och ventilationssystem för ett flerbostadshus vid Vänern / Design and Energy Efficiency Calculations of the Heating and Ventilation System in a Building with Apartments Located at the lake Vänern in Sweden

Burrows, Michel

January 2021

En fastighet med ett antal lägenheter lokaliserad i den lilla tätorten Otterbäcken i Gullspångs kommun har brunnit ner. Fastigheten kommer att byggas upp på nytt igen. Det kommer att ske i enlighet med Boverkets byggregel BBR och de krav som är aktuella för 2021. Examensarbetet har varit ett samarbete mellan Högskolan i Borås och konsultföretaget Energitriangeln AB i Göteborg. Examensarbetet omfattar en ny projektering av fastigheten med avseende på val av teknisk lösning för uppvärmningssystemet och ventilationen. Som hjälp i projekteringen användes simuleringsprogrammet ”MagiCad från företaget Autodesk. De energitekniska beräkningarna av uppvärmningsbehovet genomfördes i simuleringsprogrammet BV2, ”Byggnadens Värmebalans i Varaktighetsdiagrammet” som tillhandahålls av företaget CIT, Chalmers Industriteknik. Den tekniska lösningen för lägenhetshuset omfattar en förbättring från den ursprungliga ventilationen som var ett självdragssystem till att bli antingen ett till- och frånluftssystem med värmeåtervinning, (FTX) eller ett frånluftssystem där värmeåtervinning i frånluften erhålls med hjälp av en frånluftvärmepump. Båda alternativen för en förbättrad ventilation projekterades med MagiCad programmet. Examensarbetet omfattar även en analys och beräkning av fastighetens energiprestanda med hjälp av simuleringsprogrammet BV2. Genom användningen av BV2 beräknades två fall och resultatet uttrycktes i specifik energiförbrukning av både el och värme i kWh/m2, år. Dels för fastigheten som projekteras med ett FTX- system för ventilationen och för projektering av en frånluftvärmepump för värmeåtervinning ur frånluften. För att kunna utföra detta projekt behövdes det bland annat tillgång till byggnadsritningar på den fastighet som håller på att byggas och projekteras oberoende av detta examensarbete. Syftet och huvudmålet med rapporten är att ge färdigheter och kunskap inom användningen och konfigurering av simuleringsprogrammet BV2 för energieffektivisering och på det viset kunna göra en jämförelse mellan två olika lösningar ur en ekonomisk synpunkt. Det är också viktigt att visa om de två tekniska lösningarna för ventilationen ger en energi-prestanda som överensstämmer med de krav som ingår Boverkets byggregler, BBR 28 från år 2019. Som en fortsättning av kursen CAD för VVS installationer ingick i examensarbetet en projektering av värme sekundär VS, tappvarmvatten, tappkallvatten och spillvatten med hjälp av MagiCad. Metodiken för energiprestandaberäkningarna i detta projekt var att mäta arean på skalet i fasaden, fönster och dörrar på byggnaden och använda som indata i simuleringsprogrammet av BV2. Resultatet av examensarbetet konstaterar att valet av en bergvärmepump är det bästa alternativet ur en ekonomisk synvinkel. Detta eftersom man behöver köpa färre antal kilowattimmar elektricitet för att kunna täcka värmebehovet i huset. Väljer man en bergvärmepump med ett FTX aggregat sparas i köpt värme för att kunna tillfredsställa fastighetens energibehov cirka 12 527 kWh/el som ger med ett rörligt elpris cirka 14 907 kr om året i besparing av köpt el för värmeproduktion i jämförelse med alternativet där en frånluftsvärmepump användes för värmeåtervinning från frånluften och där den kalla tilluften värms med en utökad area på radiatorsystemet. / A property with several apartments located in the small village of Otterbäcken in Gullspång municipality has burned down. The property will be rebuilt in accordance with Boverket buildings rules BBR and the requirements that are relevant for 2021.The diploma project has been a collaboration between the University of Borås and the consulting company Energi Triangeln AB located in the city of Gothenburg. As part of the project a re-design of the heating and ventilation system of the property will be carried out using two different simulation programs used when designing buildings. The first program is MagiCad from the company Autodesk. In this program drawings are made of the building including the drawings of the heating and ventilation systems. The second program is more focused at energy balances and energy efficiency calculation of the property. You get the energy performance of the property. The translated name is “Heat balances in a duration diagram”. The program is developed by a consulting company connected to Chalmers University of Technology named “Chalmers Industrial Technology”, CIT. The original technical solution for the ventilation in the building before it burned down was a system not using any fans. When rebuilding the house, the design of the ventilation system includes the comparison of two modern system both using extraction fans for forcing spent air to leave the building. The first alternative uses both a supply fan and exhaust fan with a heat exchanger for heat recovery of the heat in the exhaust ventilation duct. This system is used together with a heat pump taking heat from the ground. The second technical solution of ventilation system uses an exhaust fan in connection to a heat pump. That is a system where the heat recovery of the heat in the exhaust duct is recovered in the heat pump instead of extracting heat from the ground as in alternative one. Alternative two has no centralized intake of ventilation air, instead fresh air is coming into the apartments below windows in the sleeping rooms and living room of the apartments through individual ducts. By using the program energy performance program “BV2”, two different cases were calculated and expressed in specific energy consumption of both electricity and heat using the unit kWh/m2, per year. This means that the property which was designed with both an exhaust and a supply fan (and heat exchanger) for ventilation of the building and for the design with an exhaust air fan only but using a heat pump for heat recovery from the exhaust air, these two cases can be compared. To be able to carry out this project, it was necessary, among other things there was a need to access proper building drawings of the property that is being built and projected. The purpose and main objectives of the project are fulfilled. Furthermore, as a continuation of the course called “Computed Aided Design, (CAD), for buildings, the design of secondary heating, domestic hot and cold water and sewage water was carried out using MagiCad. The method used to carry out this project was to use the drawings of the building, measure the area of the shell, windows, doors, roofs and floor of the building and by using the second simulation program BV2 to be able to calculate the energy required of the building. The result of the degree project states that the choice of a geothermal heat pump with a heat exchanger for heat recovery between the exhaust duct and the duct with incoming fresh air provides the best alternative from an energy performance perspective. You consume fewer kilowatt hours to be able to cover the heating demand in the building. If you choose a geothermal heat pump with a heat recovery using only a heat exchanger the saving in purchased electricity to be able to satisfy the property´s energy demand is approximately 12 527 kWh/ electricity annually. which with a common electricity price in Sweden, (of 1.19 crowns/kWh) provides approximately 14 900 Swedish crowns per year in savings of purchased electricity for heat production.

Ventilation

energy

energy use

Building Services and Engineering

energy analysis

indoor climate

exhaust air

supply air

Ventilation

energieffektivisering

energianvändning

installationsteknik

energianalys

inomhusklimat

frånluft

tilluft

Building Technologies

Husbyggnad

Energy Engineering

Energiteknik

Energetické hodnocení budov / Energy assessment of buildings

Velísková, Eva

January 2012

The master’s thesis deals with energy assessment of buildings according to a current valid legislature. In the first part the energy assessments problems are solved. The next part solves the energy concept of the educational building, Pavilion P4, AdMaS centre of Faculty of Civil Engineering of BUT, in the form of project documentation. In the part of thesis there is a simulation characterizing dynamic behavior of building. The thesis point is the evaluation of energy balance and a draft of measures leading to the power consumption decrease.

Revitalizace víceúčelového objektu obce / Revitalization of a multi-purpose building in the village

Federla, Jakub

January 2022

The aim of master‘s thesis is to renovate old agricultural building and design it as nzeb building. The thesis contains three parts: 1st – design of the building, 2nd – design of building services, and 3rd – assessment of the impact of different operations in building on energy consumption. The results are then evaluated for economic and environmental savings. The renovated building in village Rozkoš will be used for many purposes. It will be divided into 3 parts – a multifunctional hall, a pub, and a club room. Multifunctional hall will be used for various activities for village itself or public. In the pub will be only cold kitchen with small dishes and beverages. Club room can be used for elderly people, workout or young people. The building is low rise and structural system is combined. The vertical load-bearing walls and columns are built of bricks. Horizontal load-bearing structures are cross vaults made also of bricks. Saddle roof is made of timber roof truss. The building site contains also an outdoor car park and a garden. The project was carried out in the Revit.

Systémy TZB v nemovitých památkách / The systems of building services in immovable heritage

Maurerová, Lenka

Unknown Date

The present PhD. thesis deals with the systems of building services (namely heating, ventilating and air conditioning, shading) which provide required indoor microclimate inside the immovable heritage. The work thus combines the exclusively technical field of building services (BS) and the general principles of heritage conservation. The aim of my PhD. thesis is the analysis of immovable heritage conservation processes, focusing on the current state of research and BS systems documentation. Furthermore the work concerns the possibilities of temporary measurements of indoor climate parameters inside the immovable heritage, and aims to develop a computer model (in BSim software) for the simulation of various working conditions in the selected buildings. For the stated aims were selected three representative historic houses: historical assembly hall at the Faculty of Civil Engineering, Brno University of Technology; the Palm Greenhouse at Lednice Chateau in Moravia; and Villa Tugendhat in Brno. These buildings had been surveyed for several years, and in this PhD. thesis I present their analysis, evaluation, and conclusions. The aims of this PhD. thesis broadly correspond to the transnational objectives. The present research is, for example, in accordance with the international document ICOMOS Charter (Zimbabwe, 2013) which is concerned with the analysis, conservation, and restoration of architectural heritage. The research of immovable heritage is also supported by European Union, e.g. by the Seventh Framework Programme of EU.