Modelling building infiltration using the airflow network model approach calibrated by air-tightness test results and leak detection

Heim, Dariusz; Miszczuk, Artur

doi:10.1177/0143624420904344

Cited by 7 publications

(4 citation statements)

References 25 publications

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“…Operative temperature is a simplified measure of human thermal comfort derived from air temperature, mean radiant temperature and air speed. It is influenced by many variables regarding the environment [6] and the building structure itself [7]. In order to check the influence of climate change on the operative temperature simulations were performed in TRNSYS 17.…”

Section: Calculation Results -Indoor Operative Temperaturementioning

confidence: 99%

Analysis of climate change and its potential influence on energy performance of building and indoor temperatures. Part 2: Energy and thermal simulation

2023

Archives of Civil Engineering

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The subject of this paper is the analysis of possible influence of climate change on the energy performance of building and indoor temperatures. The model is based on the Maison Air et Lumière house, which concept was developed as part of the Model Homo 2020 project. It was a low-energy, single family, detached house. The model was divided into three thermal zones and developed by using SketchUp software. The analysis of the climate change was made on the example of the city in Poland -Kielce and described in the first part of the paper. Dynamic calculations of the building model were performed by using the TRNSYS software. The calculations were made for three different scenarios relating to existing technical systems: ventilation, ventilation + heating, ventilation + heating + cooling. Annual energy consumption and rooms air temperature changes were estimated for each variant. The results showed higher risk of summer discomfort and change in energy balance of building what indicates the need to use the cooling system in the future during the summer to reduce the discomfort of overheating. In the variant without the cooling system, the percentage of time with an indoor temperature above 27 • C increased from 23.7% to 44.2% in zone 2. The energy demand for heating was reduced by 23.4% compared to the current climate, and the energy consumption for cooling (with the cooling option) increased significantly by 232% compared to the current demand. Summarizing, research indicates that with global warming, the energy demand for heating will decrease and the cooling demand will increase significantly in order to maintain the required user comfort.

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Section: Calculation Results -Indoor Operative Temperaturementioning

confidence: 99%

Analysis of climate change and its potential influence on energy performance of building and indoor temperatures. Part 2: Energy and thermal simulation

2023

Archives of Civil Engineering

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“…The airflow network-building model was developed according to the general assumptions presented in [44]. The basic theory of this approach can be found among others in [45].…”

Section: Air Flow Modelling and Calibrationmentioning

confidence: 99%

Parametric Study of Air Infiltration in Residential Buildings—The Effect of Local Conditions on Energy Demand

Miszczuk

Heim

2020

Energies

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Airtightness is nowadays one of the physical parameters which determine overall building energy performance. In a wide range of states, the upper limit for air change rate at a Pa (na), air permeability rate at a Pa (qa), or specific leakage rate at a Pa (wa) is determined by the formal regulations. It should be highlighted that airtightness requirements are mainly the same around the world, disregarding any site and climatic conditions. The main goal of the presented work was to reveal the effect of individual location and surrounding infiltration rate and heat demand. The analyses were done using numerical techniques and computational models of the three buildings developed and calibrated based on the blower door test results. The compared buildings characterize by a similar geometry but differ in the air change rate at 50 Pa (n50). Analyses done for different locations and levels of sheltering by surrounding elements allow the determination of the real effect of local conditions. The obtained differences in energy demand between two locations from the same climatic zone were from 70% to 90%, depending on the airtightness of the buildings. Considering different sheltered conditions, the differences for the same location can be even 200%. The obtained results allowed for the formulation of the general conclusion that building location and level of exposure could be considered in future airtightness regulations.

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“…Air tightness detection device is used to detect the sealing performance of objects or equipment, and judge whether there is leakage under normal operating conditions. It is widely used in industrial sectors such as aviation [1] , aerospace, navigation, vehicles and so on [2,3] , in order to ensure the reliability and safety. For airplanes, inadequate air tightness can cause problems such as cabin pressure loss, equipment failure, and in severe cases, even lead to accidents and casualties.…”

Section: Introductionmentioning

confidence: 99%

Air tightness detection method in parallel for aerospace: mechanical design, system modeling and optimum control

Yang,

Yuan,

Wang

et al. 2024

J. Phys.: Conf. Ser.

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To address the problems of high cost, complex operation, and low efficiency of existing equipment for aerospace, a simple but efficient multichannel air tightness detection device is designed. A physical system model is constructed for the process of inflation, deflation, and inflation with leakage. The expression between the inflation/deflation rate and the valve area is obtained. Through modeling the intersection and rotation of spatial curves, the relationship between the valve area and the valve core angle is derived, and the optimal valve core angle calculation method is proposed to achieve precise rate control of inflation and deflation. Simulation experiments and numerical analysis demonstrate the superiority of the proposed system scheme, the effectiveness of the control method, as well as the accuracy of the mathematical model. For the tested object of 0.3 L, the target pressure of 400 KPa, and the inflation and deflation rate of 75 Kpa/min, by using four channels with a 10 s interval for sequential operation and adjusting valves every 60 s, the efficiency of inflation and deflation is more than 3.5 times that of a single device with a single circuit. Its performance is not much different from real-time automatic control equipment, but the economy is greatly improved.

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Modelling building infiltration using the airflow network model approach calibrated by air-tightness test results and leak detection

Cited by 7 publications

References 25 publications

Analysis of climate change and its potential influence on energy performance of building and indoor temperatures. Part 2: Energy and thermal simulation

Analysis of climate change and its potential influence on energy performance of building and indoor temperatures. Part 2: Energy and thermal simulation

Parametric Study of Air Infiltration in Residential Buildings—The Effect of Local Conditions on Energy Demand

Air tightness detection method in parallel for aerospace: mechanical design, system modeling and optimum control

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