Méthodes de mesure in situ des performances annuelles des pompes à chaleur air/air résidentielles / In situ measurement methods of residential air-to-air heat pump annual performances

Tran, Cong-Toan

30 November 2012

Aujourd'hui, la pompe à chaleur (PAC) est largement utilisée pour les applications de chauffage du bâtiment en raison de ses bonnes performances énergétiques. Elle est même considérée comme une source d'énergie renouvelable et, selon la Directive Européenne 2009/28/CE, la part «renouvelable» de l'énergie produite doit être calculée à partir de la performance annuelle. Il est donc important d'être à même de mesurer cette dernière. Or, il n'existe pas, pour les PAC air/air, de méthode fiable et simple permettant de mesurer la performance chez le client pendant une saison.Dans ce contexte, la thèse propose deux méthodes in situ qui répondent à ce besoin. La première est basée sur des mesures non-intrusives des propriétés du fluide frigorigène. Elle utilise le bilan énergétique du compresseur pour déterminer le débit du fluide. La deuxième, fondée sur les mesures côté air, utilise un ensemble de capteurs à fil chaud afin de mesurer le débit et les températures d'air.La thèse développe également une méthode de mesure intrusive du fluide frigorigène, qui n'est pas adaptée aux conditions in situ mais sert de référence pour valider les deux méthodes in situ. Les résultats expérimentaux montrent que la méthode de référence est précise non seulement en conditions stabilisées mais également en fonctionnement dynamique (y compris lors des dégivrages).La validation des deux méthodes in situ a été réalisée par une campagne d'essais spécifique en laboratoire. Une suite intéressante de la thèse consistera à intégrer la méthode non intrusive côté frigorigène directement dans l'équipement de mesure et d'affichage de la PAC. / Today, heat pumps (HP) are widely used as heating systems in building thanks to their high energy efficiency. They are even considered as a source of renewable energy and, according to the EU Directive 2009/28/EC, the amount of renewable energy has to be calculated from the annual performance. Therefore, it is important to be able to measure the annual performance. However, concerning the air-to-air HP there is no reliable and simple method which allows measuring the performance in situ during at least a season.In this context, the thesis proposes two in situ methods that could fill this gap. The first one is based on non-intrusive measurements on refrigerant side. It uses a compressor energy balance to determine the flow rate. The second one, based on air measurements, uses a distribution of hot-wire sensors to determine the air flow rate and temperatures.The thesis also develops an intrusive refrigerant method, which is not necessarily adapted for in situ conditions but can be used as a reference to validate the in situ methods. The experimental results show that the reference method is accurate both in stationary conditions and in dynamic operations (including during defrosting period).The validation of the in situ methods was performed by a specific test campaign in laboratory. As a perspective, the thesis makes it possible to develop on-board measurement methods using non-intrusive refrigerant sensors, providing an opportunity for manufacturers to display the in situ performance in real time.

Pompe à chaleur air-air

Performance saisonnière

Mesure in situ

Débitmètre Coriolis

Capteur à fil chaud

Expérimentation

Air-to-air heat pump

Seasonal performance

In situ measurement

Coriolis flow meter

Hot-wire sensor

Experimentation

Energy saving opportunities in residential buildings: insights from technological and building energy code perspectives

Li, Bo

21 September 2020

The residential building sector plays an important role in combating climate change in Canada. Many energy efficiency solutions along with new building energy standards have been implemented to improve building energy performance. However, their effects on energy saving and GHG emissions reduction vary due to the complexity of the building systems and the variability of their operational conditions. This work quantifies such variability in both energy efficiency devices and building energy standards implementation, respectively. The first study in this dissertation assesses the energy savings from sensible heat recovery in a residential apartment suite in various locations across Canada. A series of detailed building energy performance models are developed in TRNSYS. The HVAC system’s annual energy consumption is simulated and the results are compared with and without HRV for each climate zone. The results show the heating energy savings of employing the HRV vary from 17 to 34% depending on the winter climatic conditions; while, the building cooling energy use can be increased due to the undesired thermal recovery occurring in the HRV during the cooling season. The second study investigates the free cooling potential of outside air in various Canadian cities. A series of thermal models developed using BEopt 2.8 for a hypothetical single-family house with various window-to-wall ratios and building aspect ratios simulates hourly building cooling load profiles. The free cooling potential is analyzed by comparing the maximum available and the actual usable free cooling for various building features and different climates. The results indicate that, although free cooling is widely available in most areas of Canada during the summer and shoulder seasons, only 17-42% of such free cooling is usable without the use of thermal storage. The last study examines the effects of two building energy standards - the BC Step Code and the Passive House criteria - on reductions in residential household space heating GHG emissions under different enforcement scenarios. The space heating energy and the GHG emissions are estimated using the forecast growth of single detached households for the period from 2020 to 2032. The results show that the space heating GHG emissions can be reduced by 77% and 89%, respectively if the BC Step Code or the Passive House criteria is implemented in Canada. It is also found the impacts of energy code on GHG emission mitigation are less significant in regions where the carbon intensity of the dominant heating fuels is low. / Graduate

Heat Recovery Ventilator

Air-Side Economizer

Free Cooling

BC Energy Step Code

Passive House Criteria

GHG emissions

Energy Savings

Air-to-Air Heat Pump

TRNSYS

Balanced Ventilation

Usable Free Cooling Potential

Maximum Free Cooling

Ventilation

Space Heating Energy

Carbon Intensity

Jämförelse av värmekällor : Byte av värmekälla i ett småhus ur ett energi-, ekonomi- och klimatperspektiv

Goblirsch, Amanda, Izat, Banaz, Österblad Rintanen, Melinda

January 2021

Purpose: The aim of this study is to present the economic, environmental impact, and energy saving benefits of replacing an electric boiler to a bedrock heat pump or district heating. Furthermore, the impact of additional insulation will also be presented. Method: The technical, environmental, and economical aspects of the various heat sources in this study are gathered through websites and reports from agencies, industry organisations and corporations. A case study on a family house built in 1971, heated with a combination of electric boiler and air-to-air heat pump has been made. The study investigates the impact of replacing the existing heat sources with newer and better alternatives along with additional insulation. Results: The results present the energy demand for active heating, economic analysis, environmental impact, and the impact of additional insulation. Moreover, a comparison between the heat sources and the additional insulation is presented to show the difference between them. The case study objects demand for active heating includes passive heating, heat losses through the building envelope, heat losses due to ventilation. With all these factors combined, the family house has an annual active heating demand of 11 700 kWh. The energy consumption of the electric boiler combined with air-to-air heat pump (COP 4) have an annual consumption of 7 500 kWh. The required energy from the district heating goes up to 11 700 kWh and the bedrock heat pump (COP 3) have the lowest energy consumption of 3 900 kWh. However, the amount of electricity needed is 400 kWh for district heating compared to the other alternatives that require 7 500 kWh and 3 900 kWh. For the economic aspects, the installation and operating costs for the electric boiler combined with the air-to-air heat pump, district heating and the bedrock heat pump are concluded. This shows that, on one hand the bedrock heat pump is the most expensive heat source to install but on the other hand, the cheapest to operate. Furthermore, this study compares the emissions of carbon dioxide equivalents from the production of district heating and electric energy. Due to the clean electric energy in Sweden, district heating has the highest negative impact on the greenhouse effect as it uses energy resources that have high emission of carbon dioxide equivalents. The environmental impact of the electric boiler, air-to-air heat pump and the bedrock heat pump vary depending on the energy source used to generate electricity and can in the worst case be higher than for district heating. New values with the additional insulation suggest that the improved building envelope will have a positive impact on the operation costs, energy saving and emissions. As an example, the demand for active heating can be reduced with up to 30%. Conclusions: The conclusion is that the comparison of heat sources contains many uncertain variables. Consequently, the result of this study does most likely not apply directly to other study objects. The results may vary if, for example, the geographical location or electricity agreement is changed.

Heat source

district heating

bed rock heat pump

ground source heat pump

electric boiler

air to air heat pump

energy saving

environment

economy

Aktiv uppvärmning

bergvärme

ekonomi

elpanna

energi

fjärrvärme

klimat

koldioxidekvivalenter

luft-/luftvärmepump

tilläggsisolering

värmekälla

Civil Engineering

Samhällsbyggnadsteknik

Building Technologies

Husbyggnad