Annual Performance of Sensible and Total Heat Recovery in Ventilation Systems: Humidity Control Constraints for European Climates

Tafelmeier, Stefanie; Pernigotto, Giovanni; Gasparella, Andrea

doi:10.3390/buildings7020028

Cited by 10 publications

(7 citation statements)

References 16 publications

Supporting

Mentioning

Contrasting

Unclassified

Order By: Relevance

“…The main results obtained in the inlet and outlet nozzle zones during the sampling process in the open loop wind tunnel are reflected in Table 1 and in the CFD simulations of the third test shown in Figure 7. The inlet conditions-consistent with previous research works about this validation procedure [27][28][29]-were the same in the real process than in the simulation, as we can see, for instance, in the third test of Table 1 and in Figure 7, in terms of relative humidity (Figure 7a) and velocity (Figure 7b…”

Section: Experimental Nozzle Results and Simulation Validationsupporting

confidence: 88%

“…Figure 8 shows the maximum velocity value in the nozzle-diffuser throat for an inlet velocity of 5 m/s and relative humidity of 95%. The maximum relative humidity of 100% and its related moist The inlet conditions-consistent with previous research works about this validation procedure [27][28][29]-were the same in the real process than in the simulation, as we can see, for instance, in the third test of Table 1 and in Figure 7, in terms of relative humidity (Figure 7a) and velocity (Figure 7b) distributions, and even in point values in the centre line.…”

Section: Nozzle Diffuser Simulation Under Internal Flowsupporting

confidence: 88%

See 1 more Smart Citation

Eco-friendly Pressure Drop Dehumidifier: An Experimental and Numerical Analysis

et al. 2019

View full text Add to dashboard Cite

The northwest of Spain is defined by very high relative humidity values, with an average relative humidity of 85% throughout the year, which is considered too high by most standards and therefore can be related to various health problems and fungi growth. To reduce the relative humidity level in the indoor environment, different dehumidification technologies are being employed. However, commonly employed cooling based dehumidification systems have a very high energy consumption, from 720 W in residential buildings to 3150 W in industrial buildings. This article aims to show a new method for indoor moist air dehumidification, based on a controlled adiabatic expansion of moist air, similar to the Foehn effect, by means of a nozzle–diffuser system. The main results, based on computational fluid dynamics (CFD) simulations and experimental tests in wind tunnels, show an initial working range of up to 80% relative humidity, with almost ten times reduction in energy consumption compared to the classical mechanical refrigeration dehumidifiers. Moreover, future improvements, such as a Peltier cooling system, which allows a reduction of the temperature in the nozzle throat, improving the condensation process, and a variable inlet area, could potentially improve the working range towards the required 30–60% relative humidity in buildings.

show abstract

Section: Experimental Nozzle Results and Simulation Validationsupporting

confidence: 88%

Section: Nozzle Diffuser Simulation Under Internal Flowsupporting

confidence: 88%

Eco-friendly Pressure Drop Dehumidifier: An Experimental and Numerical Analysis

et al. 2019

View full text Add to dashboard Cite

show abstract

“…Дослідження показують низьку ефективність їх застосування як в цілях температурної, так і вологої обробки повітря [29].…”

Section: результати дослідженняunclassified

Analysis of Ways to Increase Energy Efficiency of Ventilation and Air Conditioning Systems

Літовко¹,

Lider²

2021

VVPI

View full text Add to dashboard Cite

Метою роботи є аналіз та розробка енергоефективних рішень для пристроїв утилізації теплоти витяжного повітря в системах вентиляції і кондиціонування з урахуванням динаміки кліматичних і внутрішніх характеристик експлуатації. Проведено аналіз науково-технічної та нормативної документації в області підвищення енергоефективності систем вентиляції і кондиціонування. Показано вплив систем життєзабезпечення на енергоспоживання у світі. Подано опис методики технікоекономічної оцінки енергетичних характеристик активних утилізаторів, які працюють в умовах, що відрізняються від паспортних значень. Розглянуто вплив відхилення таких експлуатаційних факторів, як витрата повітря, температура зовнішнього повітря перед утилізатором, температура і вологість витяжного повітря. Проведено порівняльний аналіз способів підвищення енергоефективності систем вентиляції і кондиціонування. У статті подано огляд основних технологічних та економічних бар'єрів, які запобігають переходу таких систем на якісно новий рівень енергоефективності. Обґрунтований вибір з усього різноманіття технічних рішень можливий тільки за умови введення критеріїв енергетичної та економічної ефективності, які можна застосувати для різних типів теплоутилізаторів в складі систем вентиляції та кондиціонування. Тому розробка нових підходів до аналізу показників довгострокової експлуатації, які дозволяють на ранніх етапах проектної діяльності прогнозувати економічний і екологічний ефект впровадження конкретних пристроїв в заданих умовах експлуатації систем вентиляції та кондиціонування, є актуальним завданням.

show abstract

“…There are also the uncertainties of future energy prices, which may prolong or shorten this period. In a recent research [21] it was concluded that the payback period of a sensible recovery HE, in 24-hour operating ventilation systems, is less than 4 months in Mediterranean countries. Any increase in electricity price by 10% reduces the cost savings rate by 5% in the case of full occupancy and by about 8% in the case of half occupancy.…”

Section: Energy Analysismentioning

confidence: 99%

Energy and economic analysis of an auditorium’s air conditioning system with heat recovery in various climatic zones

2018

View full text Add to dashboard Cite

In many heating, ventilation and airconditioning (HVAC) applications, heat recovery devices are installed, aiming at reducing energy consumption. Especially in buildings requiring a high percentage of outside air for ventilation, there is a high potential for heat recovery from exhaust air. Climatic conditions are an important parameter which affects the recovered heat and the payback period of the heat recovery device. In this paper, a 250 person auditorium is used as a model to estimate the applicability of an air-to-air fixed-plate heat exchanger installed in the air handling unit of the HVAC system. The application is considered for four cities, representative of climatic zones A, B, C, D of Greece, which also represent typical Mediterranean climate conditions. Zone A, Crete and Southern Greece, is similar to Nicosia (Cyprus) and Palermo (Sicily), Zone B, with Athens, corresponds to Rome (Italy) and coastal Spain, Zone C with Thessaloniki is similar to the Toulon (France) and Split (Croatia) and Zone D, with its continental climate is more like Milan (Italy) and Lyon (France). An energy analysis with the modified bin method energy calculation was performed to calculate (a) the heating and cooling energy that can be recovered, (b) the reduction in HVAC equipment, and (c) the expected payback period. For the specific climatic conditions examined, it was proven that: heating energy consumption decreased by 31 to 40%, depending on occupancy, while electric energy consumption didn't change notably; the payback period does not exceed 24 months, depending on climate zone and occupancy.

show abstract

Annual Performance of Sensible and Total Heat Recovery in Ventilation Systems: Humidity Control Constraints for European Climates

Cited by 10 publications

References 16 publications

Eco-friendly Pressure Drop Dehumidifier: An Experimental and Numerical Analysis

Eco-friendly Pressure Drop Dehumidifier: An Experimental and Numerical Analysis

Analysis of Ways to Increase Energy Efficiency of Ventilation and Air Conditioning Systems

Energy and economic analysis of an auditorium’s air conditioning system with heat recovery in various climatic zones

Contact Info

Product

Resources

About