Methodology for Designing Bespoke Air Handling Units

Malysheva, Alexandra

January 2023

This master's thesis explores the role of bespoke air handling units in enhancing energy efficiency in existing buildings. The context for the study is set against the backdrop of global initiatives, including the United Nations' Sustainable Development Goals, specifically Goal 7, which emphasizes the need to improve energy efficiency to combat climate change. The significance of enhancing energy efficiency is well-established, evident both at the EU level and in national policies and regulations. Buildings represent a significant portion of the energy utilization puzzle, with substantial potential for enhancing energy efficiency, although it is often underutilized. One of the contributing factors to inefficiency is outdated ventilation systems, which lead to high thermal losses. This challenge can be addressed by retrofitting these systems with modern, efficient air handling units, thus contributing to energy conservation and cost savings. This study focuses on the adoption of bespoke air handling units adjusted to the site and capable of accommodating constraints related to factors such as space limitations in machine rooms, existing ductwork layouts, and the location of shafts. The primary goal is to empower engineers to move beyond conventional approaches, enabling them to optimize technology choices based on local conditions, specific system performance requirements, and the economic viability of each project. The aim of this study is twofold: first, to develop a methodology for designing bespoke air handling units; and second, to demonstrate the practical application of this methodology in the context of two distinct renovation projects. In line with the aim of the thesis, a design methodology for site-tailored units equipped with a two stage flat crossflow heat exchanger and an indirect evaporative cooling system was developed. The methodology delves into different aspects of data analysis, 3D modeling, and the conduct of performance calculations.The established methodology was applied in two reconstruction projects in central Stockholm, where bespoke air handling units were designed in compliance with provided technical specifications. In both scenarios, a viable option emerged for accommodating a tailored unit within the technical room situated on the first floor. For both units, the energy performance metrics signify a notable achievement in terms of heat recovery efficiency, coupled with relatively modest requirements for heating and cooling power capacity from the combined heating and cooling aircoil. However, the calculated maximum specific fan power for a single unit with heat recovery exceeded the stipulated value specified in the technical specifications, which was accepted by the client. The results of the study included air handling unit product drawings, ventilation blueprints of the technical room with the integrated air handling unit, component specifications, unit flowcharts, performance calculations, and control operating pictures. The results of this work indicate that the improvement of the building's energy efficiency is rendered feasible through the installation of bespoke air handling units in the studied reconstruction projects. / Se filen

bespoke air handling unit

evaporative cooling system

two-stage crossflow heat exchanger

3D-modeling

platsbyggt luftbehandlingsaggregat

evaporativt kylsystem

tvåstegs motströmsvärmeväxlare

3D-modeling

Energy Engineering

Energiteknik

Utvärdering av avfrostning med ackumulatortank för motströmsvärmeväxlare : En teoretisk forskningsstudie med fokus på effektiviserad avfrostning för motströmsvärmeväxlare i ventilationsaggregat

Hedman, Martin

January 2017

The energy consumption in the world continues to increase, which makes energy saving measures important. In Sweden, where buildings account for a large part of total energy use, heat exchangers in ventilation are important to reduce energy consumption. However, Sweden's winters are often cold over large parts of the country, causing frost in the heat exchanger and high and uneven heating power requirements for ventilation units. The heating system in the building is required to manage the biggest power demand that may arise. From the ventilation unit, the greatest heating power requirement is arise in the event of frost conditions, as the power requirement from the heating coil increases during defrosting. By installing an accumulator tank together with the ventilation unit, the power requirement can be evened out. Power requirement for three different scenarios where the storage tank is used has been calculated. By using thermodynamic equations and measurements from Swegon counter flow heat exchanger results were accomplished. Optimal defrosting cycle times were evaluated by theory and equations. Other defrosting methods have been calculated to be compared to the solution with the accumulator tank. In a case with 600 litres per seconds supply and exhaust air flow, outdoor temperature at -10 ° C, the power requirement to the unit could be reduced by 67 % using an accumulator tank. An accumulator tank with a volume of 73 litres was required. By using an accumulator tank with the ventilation unit, investment costs could decrease by approximately 18 000 SEK when district heating is used as energy source. However, the solution with the storage tank will not be able to reduce district heating costs more than reduced flow cost for the district heating. If a heat pump I used approximately 95 000 SEK in investment cost could be saved when using an accumulator tank. Electricity cost could also be reduced but not much. Compared to other defrosting methods, the solution with accumulator tank will require the lowest power requirement for the ventilation unit, heat recover  most energy in the heat exchanger and at the same time create an even heat power requirement at frost conditions. / Energianvändningen i världen fortsätter öka vilket gör energisparåtgärder viktiga. I Sverige där byggnader står för en stor del av den totala energianvändningen är värmeväxlare inom ventilation viktiga för att minska energiförbrukningen. Dock är Sveriges vintrar ofta kalla över stora delar av landet vilket orsakar frostproblem i värmeväxlaren och högt och ojämnt värmeeffektbehov till ventilationsaggregat. Byggnadens värmesystem måste dimensioneras efter det största effektbehov som kan uppstå. Från ventilationsaggregatet sker det största värmeeffektbehovet vid frostförhållanden eftersom effektbehovet från värmebatteriet ökar vid avfrostning. Genom att installera en ackumulatortank tillsammans med ventilationsaggregatet skulle effektbehovet kunna jämnas ut. Effektbehov för tre olika scenarion där ackumulatortank används har beräknats. Det skedde genom användande av termodynamiska ekvationer och mätningar från Swegons motströmsvärmeväxlare. Tiden för hur lång avfrostningscykel som är optimal har utvärderas genom teori och ekvationer. Andra avfrostnings metoder har beräknats för att kunna jämföras med lösningen med ackumulatortank. I ett fall med till-och frånluftflöde på 600 l/s och dimensionerande utomhustemperatur på -10 °C kunde effektbehovet fram till aggregatet minskas med 67% genom att använda en ackumulatortank. En ackumulatortank med volymen 73 liter krävdes. Genom att använda en ackumulatortank tillsammans med ventilationsaggregatet kunde investeringskostnaden kunna minskamed cirka 18000 kr när fjärrvärme används som energikälla. Lösningen med ackumulatortank kommer dock inte kunna minska fjärrvärmekostnaden mer än att minska eventuell flödeskostnad för fjärrvärmen. Vid användande av bergvärmepump skulle cirka 95000 kr i investeringskostnad kunna sparas vid användande av ackumulatortank. Eleffektkostnaden kunde även minskas men relativt lite. Jämfört med andra avfrostningsmetoder kommer en lösning med ackumulatortank kräva lägst effektbehov till ventilationsaggregatet, återvinna mest energi i värmeväxlaren och samtidigt skapa ett jämt värmeeffektbehov under frostförhållanden.

Ventilation

heat exchanger

counter flow heat exchanger

accumulator tank

energy storage

power

power reduction

defrosting

costs

tank

plate heat exchanger

ventilation

värmeväxlare

motströmsvärmeväxlare

ackumulatortank

plattvärmeväxlare

energilagring

effekt

effektminskning

avfrostning

kostnader

tank

Energy Systems

Energisystem

Ventilation i flerbostadshus- hur fungerar den ur ett fuktperspektiv? / Ventilation in apartment buildings- how does it work in a moisture perspective?

Israelsson, Simon, Hallgren, Anton

January 2018

För att skapa ett bra inomhusklimat i flerbostadshus ställs höga krav på ventilationssystemet för att ta hand om den fukt som skapas. Det finns således anledning att undersöka om Boverkets byggreglers krav för minsta luftflöde är tillräckligt ur fuktsynpunkt. Syftet är att uppmärksamma problem med ökande fukttillskott i nyproducerade flerbostadshus vilket skulle kunna förändra projekteringen av ventilation i framtiden. För att kunna undersöka om Boverkets byggreglers krav är tillräckligt ur fuktsynpunkt analyseras relativ fuktighet och fukttillskott i fyra flerbostadshus i Jönköping. Det framgår att flera lägenheter erhöll höga värden för fukttillskott och relativ fuktighet vilket kan skada byggnaden och påverka människors hälsa. Boverkets byggreglers krav för minsta luftflöde var otillräckligt ur fuktsynpunkt i flera av de undersökta flerbostadshusen. / To create a good indoor climate in apartment buildings, high demands are made on the ventilation system to take care of the moisture that is created. There is therefore reason to investigate if Boverket, the Swedish National Board of Housing, Building and Planning, requirements for minimum airflow are sufficient from a moisture point of view. The purpose is to rise awareness about increasing additional moisture in newly built apartment buildings, which could change the project planning of ventilation systems in the future. In order to investigate whether requirements of the Boverket building regulations are sufficient from a moisture point of view, relative humidity and additional moisture were analyzed in four apartment buildings in Jönköping. Several apartments received high values of additional moisture and relative humidity which could damage the building and affect human health. The requirements of Boverket building regulations for minimum airflow should therefore be reviewed.

Ventilation

additional moisture

relative humidity

apartment buildings

hygroscopic rotary heat exchanger

counterflow heat exchanger

airflow

airtightness.

Ventilation

fukttillskott

relativ fuktighet

flerbostadshus

hygroskopisk roterande värmeväxlare

motströmsvärmeväxlare

ventilationsflöde

lufttäthet

Building Technologies

Husbyggnad