Showing total 1,235 results

1. The hardest-hit home run?

Author

Warren, Donald C.

Subjects

*NUMERICAL solutions to differential equations, *COMPUTATIONAL physics, *AIR conditioning, *PHYSICS students, *HUMIDITY

Abstract

We present a problem to be assigned or done as an in-class activity in an upper-division undergraduate course on computational physics. The problem involves a home run hit by Mickey Mantle on May 22, 1963, which he famously called "the hardest ball I ever hit." Is this home run truly one for the record books, or has it been eclipsed by players in the modern era? Modeling the trajectory of a baseball involves consideration of both wind resistance and the Magnus effect and is an interesting application of numerical solutions to ordinary differential equations. Ultimately, the answer is that Mantle would compare favorably to the most powerful batters currently playing, but to arrive at that conclusion we must reflect on the plausibility of results and sources of uncertainty. Editor's Note: The physics of baseball is endlessly compelling. In this paper, the author analyzes a May 22, 1963, home-run hit by Mickey Mantle which struck a facade 118 feet above ground level at Yankee Stadium and nearly exited the park. Witnesses claimed that the ball was still rising when it struck the facade. This paper takes a numerical-analysis approach to attempting to determine the initial launch speed and angle of the ball, considering conditions of air density, temperature, relative humidity, wind, and spin. This is a fascinating case study of forensic physics subject to multiple uncertainties, and the reader's enjoyment is not diminished by the conclusion that witnesses were likely mistaken about the ball still rising. Appropriate for upper-level dynamics/computational physics students. [ABSTRACT FROM AUTHOR]

Published

2024

2. Research on Regulation Method of Variable-Air-Volume Air Conditioning System with "Personal Space".

Author

Chen, Tingting, Zhang, Mingyuan, Han, Shaoqing, and Han, Yuhang

Subjects

*PERSONAL space, *OPEN plan offices, *AIR conditioning, *THERMAL comfort, *ENERGY consumption

Abstract

In large public facilities, such as airport terminals or open-plan office spaces, the HVAC system typically consumes substantial amounts of energy. However, individuals often gather at specific areas while other zones are occupied by transient or occasional users. To minimize operational energy usage, this paper aims to reduce thermal comfort demands in non-targeted areas. This paper introduces a method for regulating the thermal environment around occupants exclusively in the variable-air-volume (VAV) air conditioning running mode. The investigation utilizes Airpak modeling and experimental verification techniques. Additionally, an analysis of temperature field and velocity field distributions within the room under the "personal space" operation mode is presented. The results suggest that adjusting the numbers of air vents, openings, airflow velocities, and air supply orientations can establish a comfortable thermal environment for inhabitants and reduce the overall ADPI value. The combined air supply mode leads to a 16.7% reduction in power usage compared to traditional full-space operation. [ABSTRACT FROM AUTHOR]

Published

2024

3. Research on Phase Change Cold Storage Materials and Innovative Applications in Air Conditioning Systems.

Author

Li, Zhengjing, Sha, Yishun, and Zhang, Xuelai

Subjects

*AIR conditioning, *LATENT heat

Abstract

Phase change cold storage materials are functional materials that rely on the latent heat of phase change to absorb and store cold energy. They have significant advantages in slight temperature differences, cold storage, and heat exchange. Based on the research status of phase change cold storage materials and their application in air conditioning systems in recent years, this paper provides an overview of the materials and their enhanced research progress. It summarizes the types of phase change cold storage air conditioning systems, optimization schemes, and system applications. This paper also identifies the current issues in phase change cold storage air conditioning and discusses the development trends in cold storage materials and air conditioning systems. It anticipates that future advancements will focus on composite phase change cold storage materials and low-energy consumption intelligent phase change cold storage air conditioning systems in steam compression using spherical capsules and concave–convex plate PCM. [ABSTRACT FROM AUTHOR]

Published

2024

4. An Improved Graph Deviation Network for Chiller Fault Diagnosis by Integrating the Sparse Cointegration Analysis and the Convolutional Block Attention Mechanism.

Author

Sun, Bingxu, Liang, Dekuan, and Zhang, Hanyuan

Subjects

*FAULT diagnosis, *FEATURE extraction, *AIR conditioning, *COINTEGRATION, *ENERGY consumption

Abstract

Chiller fault diagnosis plays a crucial role in optimizing energy efficiency within heating, ventilation, and air conditioning (HVAC) systems. The non-stationary nature of chiller fault data presents a significant challenge, as conventional methodologies often fail to adequately capture the relationships between non-stationary variables. To address this limitation and enhance diagnostic accuracy, this paper proposes an improved graph deviation network for chiller fault diagnosis by integrating the sparse cointegration analysis and the convolutional block attention mechanism. First, in order to obtain sparse fault features in non-stationary operation, this paper adopts the sparse cointegration analysis method (SCA). Further, to augment the diagnosis accuracy, this paper proposes the improved graph deviation network (IGDN) to classify fault datasets, which is a combination of the output of a graph deviation network (GDN) with a convolutional block attention mechanism (CBAM). This novel architecture enables sequential evaluation of attention maps along independent temporal and spatial dimensions, followed by element-wise multiplication with input features for adaptive feature optimization. Finally, detailed experiments and comparisons are performed. Comparative analyses reveal that SCA outperforms alternative feature extraction algorithms in addressing the non-stationary characteristics of chiller systems. Furthermore, the IGDN exhibits superior fault diagnosis accuracy across various fault severity levels. [ABSTRACT FROM AUTHOR]

Published

2024

5. Online identification and extraction method of regional large-scale adjustable load-aggregation characteristics.

Author

Siwei Li, Liang Yue, Xiangyu Kong, and Chengshan Wang

Subjects

*FEATURE extraction, *AIR conditioning, *ALGORITHMS, *ECONOMIC efficiency, *ACQUISITION of data

Abstract

This article introduces the concept of load aggregation, which involves a comprehensive analysis of loads to acquire their external characteristics for the purpose of modeling and analyzing power systems. The online identification method is a computer-involved approach for data collection, processing, and system identification, commonly used for adaptive control and prediction. This paper proposes a method for dynamically aggregating large-scale adjustable loads to support high proportions of new energy integration, aiming to study the aggregation characteristics of regional large-scale adjustable loads using online identification techniques and feature extraction methods. The experiment selected 300 central air conditioners as the research subject and analyzed their regulation characteristics, economic efficiency, and comfort. The experimental results show that as the adjustment time of the air conditioner increases from 5 minutes to 35 minutes, the stable adjustment quantity during the adjustment period decreases from 28.46 to 3.57, indicating that air conditioning loads can be controlled over a long period and have better adjustment effects in the short term. Overall, the experimental results of this paper demonstrate that analyzing the aggregation characteristics of regional large-scale adjustable loads using online identification techniques and feature extraction algorithms is effective. [ABSTRACT FROM AUTHOR]

Published

2024

6. Microstructure, joining mechanism, mechanical properties and optimization of inactive solder (Sn9Zn) in low temperature ultrasonic soldering of AlN ceramics and 2024Al.

Author

Fan, Zongkai and Chen, Chao

Subjects

*ELECTRONIC packaging, *THERMAL stresses, *CERAMIC materials, *STRAINS & stresses (Mechanics), *AIR conditioning, *SOLDER & soldering

Abstract

With the development of the electronic packaging industry, there is an increased demand for enhanced strength in DBA substrates. Ultrasonic soldering technology allows low-temperature joining of ceramic-metal materials under ambient air conditions. In this paper, we successfully achieved the joining between AlN ceramics and 2024Al using Sn9Zn solder and ultrasonic soldering technique, while also analyzing the joining mechanism through Comsol software simulations. It was observed that under the appropriate ultrasonic amplitude and frequency, the Sn9Zn solder exhibited complete wetting with both base materials, resulting in reliable joints. Building upon this finding, the conventional Sn9Zn solder was further optimized by adding Sb element. The addition of Sb element led to the formation of Zn 4 Sb 3 phase and β-Sn(Sb) phase with Sb acting as solute. Among them, the generation of β-Sn(Sb) solid solution phase effectively improved the joint strength. The maximum joint strength was achieved at an average value of 75.066 MPa when the Sb content reached 1 wt. %. At this point, the failure occurred within the AlN ceramic base material. [ABSTRACT FROM AUTHOR]

Published

2024

7. A Comparative Analysis of Machine Learning Techniques for Predicting the Performance of Microchannel Gas Coolers in CO 2 Automotive Air-Conditioning Systems.

Author

Ishaque, Shehryar, Ullah, Naveed, and Kim, Man-Hoe

Subjects

*NONLINEAR regression, *PRESSURE drop (Fluid dynamics), *HEAT transfer, *REGRESSION analysis, *AIR conditioning

Abstract

The automotive industry is increasingly focused on developing more energy-efficient and eco-friendly air-conditioning systems. In this context, CO2 microchannel gas coolers (MCGCs) have emerged as promising alternatives due to their low global warming potential (GWP) and environmental benefits. This paper explores the application of machine learning (ML) algorithms to predict the thermohydraulic performance of MCGCs in automotive air-conditioning systems. Using data generated from an experimentally validated numerical model, this study compares various ML techniques, including both linear and nonlinear regression models, to forecast key performance metrics such as refrigerant outlet temperature, pressure drop, and heat transfer rate. Spearman's correlation was employed to develop performance maps, whereas the R2 and MSE metrics were used to evaluate the models' predictive accuracy. The linear models gave around 70% forecasting accuracy for pressure drop across the gas cooler and 97% accuracy for refrigerant outlet temperature, whereas the nonlinear models achieved more accurate predictions, with an accuracy ranging from 71% to 99%. This implies that nonlinear regression generally performs better than linear regression models in assessing the overall thermohydraulic performance of microchannel gas coolers. This research brings forth new ideas on how ML methods can be applied to enhance efficiency and effectiveness in gas coolers, contributing to the development of more eco-friendly automotive air-conditioning systems. [ABSTRACT FROM AUTHOR]

Published

2024

8. Analysis of Energy Efficiency Measures in Integrating Light-Duty Electric Vehicles in NZEB Buildings: A Case Study in an Educational Facility in the Brazilian Amazon.

Author

Souza, Ana Carolina Dias Barreto de, Vasconcelos, Filipe Menezes de, Azevedo, Jackquelline C. do N., Muse, Larissa Paredes, Moreira, Gabriel Abel Massunanga, Alves, João Victor dos. Reis, Tostes, Maria Emília de Lima, Carvalho, Carminda Célia Moura de Moura, and Nascimento, Andréia Antloga do

Subjects

*ELECTRIC vehicle charging stations, *ENERGY levels (Quantum mechanics), *ELECTRIC vehicle industry, *AIR conditioning, *ENERGY consumption

Abstract

The increasing reliance on electric vehicle (EV) charging in buildings requires balancing the load from other building systems to support the new demand. This paper uses a study case in a Near-Zero Energy Building (NZEB) educational facility located in the Brazilian Amazon to verify how much the energy efficiency (EE) measures would improve the existing ratings of the building and supply the expansion of EV demand. A comprehensive building energy load and energy performance analysis were conducted in four steps, following the mandatory Brazilian requirements for EE in public buildings, using measured data, computer modeling, and thermoenergetic analyses using OpenStudio version 1.1.0 and EnergyPlus software version 9.4.0. First, the EE retrofit measures were proposed and evaluated, targeting the air conditioning and lighting systems. Subsequently, an equation was elaborated to indicate the maximum level of energy consumption that could be increased without compromising the building's energy performance and NZEB classification. Finally, Open DSS software version 10.0.0.2 was used to simulate the increased availability of EV charging after the retrofit. With the proposed retrofit, the building improved the EE ratings by three levels, and the percentage of the NZEB rating increased by 33.28%. These measures also increased the EV charging load by 20%, maintaining the maximum EE level and the NZEB classification, although EV maximization reduced self-sufficiency by 9.78% compared to the retrofit-only scenario. [ABSTRACT FROM AUTHOR]

Published

2024

9. A Systematic Review on Heat Transfer and Pressure Drop Correlations for Natural Refrigerants.

Author

Carella, Alberta and D'Orazio, Annunziata

Subjects

*PRESSURE drop (Fluid dynamics), *REFRIGERANTS, *HEAT transfer, *HEAT transfer coefficient, *AIR conditioning, *HEAT pumps

Abstract

Due to environmental concerns, natural refrigerants and their use in refrigeration and air conditioning systems are receiving more attention from manufacturers, end users and the scientific community. The study of heat transfer and pressure drop is essential for accurate design and more energy efficient cycles using natural refrigerants. The aim of this work is to provide an overview of the latest outcomes related to heat transfer and pressure drop correlations for ammonia, propane, isobutane and propylene and to investigate the current state of the art in terms of operating conditions. Available data on the existing correlations between heat transfer coefficients and pressure drops for natural refrigerants have been collected through a systematic search. Whenever possible, validity intervals are given for each correlation, and the error is quantified. It is the intention of the authors that this paper be a valuable support for researchers and an aid to design, with particular reference to heat pumps. A procedure based on the Preferred Reporting Items for Systematic Reviews and Meta-Analyses (PRISMA) statement was adopted, and the Scopus database was used to query the relevant literature. A total of 135 publications qualified for inclusion in the survey; 34 articles report experimental investigations for unusual geometric conditions. Of the 101 selected papers related to usual geometric conditions, N = 50 deal only with HTC, N = 16 deal only with pressure drop and the remainder (N = 35) analyse both HTC and pressure drop. Among the 85 HTC papers, N = 53 deal with the evaporating condition, N = 30 with condensation and only N = 2 with the heat transfer correlations under both conditions. Most of the 101 articles concern propane and isobutane. The high temperatures are less widely investigated. [ABSTRACT FROM AUTHOR]

Published

2024

10. Experimental determination of influences on a gauge block’s stack length.

Author

L. C., Lipus, B., Acko, and J., Tompa

Subjects

*SURFACE preparation, *MEASURING instruments, *GAGES, *AIR conditioning, *PAPER towels, *LUBRICATION & lubricants

Abstract

Gauge blocks are an important basis for maintaining traceability in dimensional metrology, used for calibrating length measuring instruments and for adjustments in all branches of manufacturing. Their important feature is that they can be wrung with small dimensional uncertainty. An overview of the factors influencing the accuracy of a stack length, such as the quality of the gauge blocks (grade, wear), surface preparation (cleaning and usage of a lubricant), wringing (way and time, temperature of hands and gloves) is given in the paper. Experiments for determining these influences were performed with a highly precise gauge block comparator. Proper selection of gauge blocks, preparation of their surfaces and oiling improve the accuracy of a stack length. Application of a lubricant, wiped with a dry cloth or paper towel, helps to wring them more easily, but its contribution to the stack length in the experiment was 0.1 μm for oil and 0.2 μm for grease. Temperature changes of gauge blocks were estimated by holding them, and, during wringing in well controlled air conditions, monitoring them to yield the empirical coefficients of their warming up. The results showed that usage of gloves reduces the warming up by approximately half, but still the stack must be stabilised in well controlled conditions for at least one hour if it is used for micrometre-level precise measurements. [ABSTRACT FROM AUTHOR]

Published

2022

11. Decomposition of air conditioning electricity consumption considering the dependence between the temperature and electricity consumption.

Author

Xun, Chao, Liu, Lin, Wang, Chang, and Ni, Junhong

Subjects

*ELECTRIC power consumption, *ELECTRIC power distribution grids, *AIR conditioning, *DECOMPOSITION method, *AIR warfare

Abstract

With the continuous increase in air conditioning installations, the proportion of air conditioning electricity consumption to total electricity consumption is growing. Research on the decomposition of air conditioning electricity consumption is of great significance for assessing electricity usage, formulating electricity scheduling plans, and ensuring the stable operation of the power grid. Currently, typical day selection strategies for the decomposition of air conditioning electricity consumption often overlook the corresponding relationship between typical daily electricity consumption and temperature. Therefore, this paper proposes an air conditioning electricity consumption decomposition method based on the dependence between temperature and electricity consumption. This method filters typical days based on Copula-based dependence indicators and equiprobable ellipses, determines the baseline electricity consumption curve through model selection voting, and ultimately calculates the air conditioning electricity consumption. The effectiveness of the proposed method is validated by applying it to electricity consumption data in Fuzhou from 2019 to 2022. [ABSTRACT FROM AUTHOR]

Published

2024

12. Decomposition of air conditioning electricity consumption based on effective duration.

Author

Xun, Chao, Zheng, Huan, and Han, Zhaoyu

Subjects

*ELECTRIC power consumption, *AIR conditioning, *ELECTRIC power distribution grids, *ELECTRIC breakdown, *AIR quality

Abstract

As the share of air conditioning electricity consumption within total grid electricity consumption grows, the decomposition of such consumption becomes increasingly crucial for assessing electricity usage patterns, devising consumption scheduling strategies, and maintaining the stability of the power grid. Although there is a strong correlation between apparent temperature and air conditioning electricity consumption, the literature currently available seldom explores the impact of apparent temperature on this consumption. Moreover, there is a scarcity of effective assessment indices to evaluate the efficacy of air conditioning electricity consumption breakdown. This study introduces a method for decomposing electricity consumption from air conditioning units, utilizing effective duration as a basis to tackle these issues. By employing an apparent temperature model as a constraint, this approach identifies the effective operating time of air conditioning and constructs a constrained convex optimization problem to estimate air conditioning power usage. Additionally, a novel evaluation index for the effectiveness of air conditioning electricity consumption decomposition is proposed, which includes penalties for negative decomposed consumption, alongside the traditional consistency index. Comparative experiments are conducted using real electricity consumption data from Fujian Province. Empirical results indicate that the methodology for air conditioning electricity consumption decomposition presented in this paper aligns more closely with actual conditions. Furthermore, the evaluation metrics introduced for the decomposition of air conditioning electricity consumption are adept at precisely gauging the quality of the air conditioning electricity consumption data. [ABSTRACT FROM AUTHOR]

Published

2024

13. Investigation of the Optimal Operation Method of the Heat Recovery Ground Source Heat Pump System Installed in an Actual Building and Evaluation of Energy Saving Effect.

Author

Katsura, Takao, Nakamura, Yasushi, Ohara, Tomoya, Kinouchi, Ken, and Nagano, Katsunori

Subjects

*GROUND source heat pump systems, *HOT-water supply, *COOLING loads (Mechanical engineering), *HEAT exchangers, *AIR conditioning, *HEAT recovery, *ENERGY consumption

Abstract

In this paper, a heat recovery ground source heat pump (HR-GSHP) system, in which the primary pipes of the GSHP for air conditioning and the GSHP for hot water are connected to ground heat exchangers (GHEs) and each GSHP is operated simultaneously or within a short period of time, was installed in a dormitory building on a trial basis. Then, the optimal operation method to minimize the energy consumption of the system was investigated. The operating period of the GSHP for HW was changed and simulations were conducted to determine the operating period with the lowest energy consumption, which was 8 months from April to November. Furthermore, the HR-GSHP system was operated for 8 years from 2012 to 2019, and actual measurements were carried out to verify the system performance and the energy saving effect in optimal operation. In actual operation, it was confirmed that the minimum temperature was about 10 °C or higher even when the GSHP for HW was operated year-round. Therefore, the GSHP for HW was operated year-round after the third year of operation. It was confirmed that the operation of the GSHP for HW in summer, especially in August and September when the cooling load is large, can improve the system's efficiency by the effect of recovering cooling exhaust heat. In the eighth year of operation, when the GSHP for HW was operated most during the summer season, the system was able to reduce power consumption for air conditioning and hot water supply by approximately 17%. [ABSTRACT FROM AUTHOR]

Published

2024

14. A Multi-Type Dynamic Response Control Strategy for Energy Consumption.

Author

Jing, Lantao, Wei, Enyu, Wang, Liang, Li, Jinkuo, and Zhang, Qiang

Subjects

*ENERGY consumption, *WIND power, *RENEWABLE energy sources, *ENERGY demand management, *SUPPLY & demand, *INDUSTRIAL clusters, *AIR conditioning

Abstract

In the context of the "Dual-Carbon Strategy", the seamless integration and optimal utilization of renewable energy sources present a pressing challenge for the emerging power system. The advent of demand-side response technology offers a promising solution to this challenge. This study proposes a two-stage response control strategy for multiple DR clusters based on the specific response time characteristics of industrial and residential loads. The strategy enhances the utilization rate of wind power, harnesses the joint response capability of various types of loads on the demand side, and ensures the overall revenue of the load aggregator (LA). It underscores the importance of industrial loads in large-scale energy consumption control throughout the overall consumption response process, while residential load clusters exhibit quick response flexibility. A homogeneous energy consumption sorting unit response strategy is established from the perspective of a residential load variable-frequency air conditioning cluster unit. This strategy addresses the challenge faced by industrial electrolytic aluminum plants in coping with long-term response intervals amidst significant fluctuations in wind power consumption demand, which may lead to incomplete consumption. This study constructs a response model based on industrial and residential time-sharing tariffs, as well as the aggregator consumption penalty price, with the optimal load energy economy index serving as the evaluation criterion. A series of simulations are conducted to comprehensively evaluate the energy consumption of the two load clusters at all times and the total revenue of the aggregator in the response zone. The objective is to achieve a win–win situation for the total wind power energy consumption rate and the aggregator's economy. The results of the simulations demonstrate that the response control strategy proposed in this study enhances the overall energy consumption rate by nearly 4 percentage points compared to a single industrial cluster. The total benefit of the load aggregator can reach CNY 941,732.09. The consumption response scheduling strategy put forward in this paper bolsters wind power consumption, triggers demand response, and significantly propels the comprehensive construction and development of the dual-high power grid. [ABSTRACT FROM AUTHOR]

Published

2024

15. Thermal performance analysis of local building materials for energy efficiency in Iraq.

Author

ALJAWAD, Riyadh Husni, HASAN, Atif Ali, KHALEEL, Mahmood Hussain, and ZAINAL, Omer Adil

Subjects

*CONSTRUCTION materials, *ELECTRICAL energy, *ZIP codes, *AIR conditioning, *CONSTRUCTION cost estimates

Abstract

Due to the harsh climate in summer of the Iraq, the outer shell of buildings is exposed to heat flow from the outside ambient to the inside building space, and causes increase of heat gain in the space, so it requires the using of air conditioning units, which is led to consume electrical energy to remove that heat gain. The objective of this paper to reduce levels of electrical consumption by choosing best building materials. The best building materials which are those have good resistance against heat flow, that's why the cost of building material difference each of other in the local market. While Aso Company for Bricks is considered one of the largest modern companies producing building materials and the most present in the entire area of Iraq. The aim of this study to focus was on its products, and five types models were selected and compared with the traditional model that is still used now. Therefore, heat gain test was experimentally conducted in a test room located in Baghdad city (zip code 10016, latitude of 33.2°N and longitude of 44°E) for one day from 6 a.m. to 7 p.m. and for the 21st day of each of the summer months (May to September) in 2021. The electrical energy consumed by the air-conditioning unit in the test room was measured, and the researchers concluded that the percentage of energy savings achieved within the limits (13.88-1.2%) depending on the type and thickness of the building material. Results shown the best building material is (Type IV), these blocks can be used to create walls with a thickness of 200 mm or 100 mm. Building blocks (the fourth kind), on the other hand, have a delay time of 6:30 hours and a thermal shrinkage coefficient of 0.63. They also have a density of 919 kg/m3. Therefore, the electrical consumption by A.C. units if used the blocks (Type IV) less than others. [ABSTRACT FROM AUTHOR]

Published

2024

16. Study of Performance Changes in Centrifugal Compressors Working in Different Refrigerants.

Author

Wang, Yintao and Yan, Jin

Subjects

*CENTRIFUGAL compressors, *WORKING fluids, *HEAT pipes, *REFRIGERANTS, *COMPUTATIONAL fluid dynamics, *COMPRESSOR performance, *OZONE layer depletion, *AIR conditioning

Abstract

Centrifugal compressors are commonly used in heating, ventilation, and air conditioning (HVAC) systems. The current generation of refrigerants in HVAC systems have very low ozone depletion potential, but most of them are still considered as containing high global warming potential (GWP) chemicals. Facing the regulatory pressure to eliminate the high-level GWP refrigerants, some of the existing HVAC systems will need to switch to low-GWP refrigerants. In this paper, we studied the performance changes in a refrigerant centrifugal compressor when switching from R134a to R1234ze(E) and R1234yf through a method that combined numerical simulation and an 1D meanline code. By combining these two methods, a reliable compressor performance change prediction was generated using limited results from the computational fluid dynamics (CFD) simulations. The results show that the property differences in the working fluid can significantly change the refrigerant compressor performance, including the compressor efficiency, pressure ratio, power consumption, working range and cooling capacity. [ABSTRACT FROM AUTHOR]

Published

2024

17. Research on Virtual Energy Storage Scheduling Strategy for Air Conditioning Based on Adaptive Thermal Comfort Model.

Author

Lv, Ran, Wu, Enqi, Lan, Li, Fu, Chen, Guo, Mingxing, Chen, Feier, Wang, Min, and Zou, Jie

Subjects

*AIR conditioning, *THERMAL comfort, *ENERGY storage, *AIR warfare, *ENERGY research

Abstract

With the rapid development of a social economy, the yearly increase in air conditioning load in the winter and summer seasons may bring serious challenges to the safe and economic operation of the power grid during the peak period of electricity consumption. So, how we reasonably adjust the set temperature of air conditioning so as to cut down the load during peak periods is very important. In this paper, considering the thermal inertia of air-conditioned buildings and the adaptability of human thermal comfort to temperature changes, the air conditioning load is regarded as virtual energy storage, the air conditioning temperature adjustment range for different users is determined based on the adaptive thermal comfort model of different geographic locations and climatic conditions, and a compensation mechanism is set up based on air conditioning users' level of participation. Then, an optimal scheduling strategy for a microgrid was constructed with the objectives of user satisfaction, carbon emissions, and microgrid operation benefits, as well as regulating the users' electricity consumption behavior, and the strategy was solved by using a multi-objective JAYA algorithm. Finally, winter and summer are used as case studies to analyze the results, which demonstrate that regulating the virtual energy storage of air conditioning can effectively improve the economy and environmental friendliness of a microgrid operation and reduce the cost of electricity consumption for the users, taking into account the comfort of the users. [ABSTRACT FROM AUTHOR]

Published

2024

18. Experimental Testing of Filter Materials for Two-Stage Inlet Air Systems of Internal Combustion Engines.

Author

Dziubak, Tadeusz

Subjects

*MATERIALS testing, *DUST removal, *CYCLONES, *INTERNAL combustion engines, *DUST, *AIR filters, *AIR conditioning

Abstract

This paper presents an experimental study of the effect of the mass of dust retained on a fibrous filter bed operating singly and in a "cyclone-filter-bed" system on changes in filtration efficiency and accuracy, as well as the increase in flow resistance. The research was carried out using a novel and unprecedented method, determining the dust absorption coefficient km of the filter baffle under laboratory conditions. A filtration system built of a single cyclone and a cylindrical filter cartridge with an appropriately sized surface set behind it was studied. Conditions corresponding to the actual operating conditions of the air filter were maintained: dust concentration, filtration speed and dust extraction from the cyclone settling tank. The purpose of the research was to evaluate filter materials with different structures in terms of filtration efficiency and accuracy, as well as flow resistance. The study showed that the parameters of the structure of filter materials—permeability, grammage and thickness—affect the process of retaining dust particles. It was shown that the increase in the flow resistance of the filter bed has a higher intensity when dust grains of small sizes are directed at it, which is the case when the bed is operated behind a cyclone, which separates larger dust grains from the air. There is a reduction in the operating time of the filtration system due to the limitation of the permissible resistance ∆pfdop, and the corresponding dust absorption km has a lower value. For a fixed value of the flow resistance, the dust absorption coefficient km2 of three different filtration baffles AC, B2, and B, working with a cyclone, take values 50–100% smaller than when working in a single-stage system. It has been shown that the "cyclone-filter baffle" unit, due to its greater dust separation capability, allows the filter cartridge to operate for a longer time until a certain flow resistance is reached. This allows the unit to operate longer at lower flow resistance without changing the filter cartridge, thus saving energy. The km values obtained during the tests, using the proposed original method, allow the selection of the filter bed for specific vehicle operating conditions by modelling its course. [ABSTRACT FROM AUTHOR]

Published

2024

19. Experimental Measurements in Schools with Natural Ventilation.

Author

Štefanič, Pavol and Straková, Zuzana

Subjects

*NATURAL ventilation, *INDOOR air quality, *ALTERNATIVE schools, *YOUNG adults, *SCHOOL day, *AIR conditioning

Abstract

Facilities for children and young people should be established in a healthy environment that is protected from external health-damaging factors, such as noise, air pollution, and negative educational influences. A school building should also be a safe and healthy environment for pupils and students, as legally required. However, although some school buildings have been renovated, most were constructed in the last century, and their indoor microclimate remains unsatisfactory. Schools must maintain optimal thermal and humidity conditions to ensure the healthy development of children and their ability to function properly in a classroom. While natural ventilation through opening windows is a good practice, it may not always guarantee sufficient air exchange, especially for schools located in busy traffic areas. This paper presents experimental measurements and a comparison between two primary schools in Bratislava, which describes the current thermal and humidity conditions in the indoor environment of both schools. Experimental measurements were carried out on five school days in each primary school to determine the thermal-humidity conditions and indoor air quality, depending on the concentrations of carbon dioxide. [ABSTRACT FROM AUTHOR]

Published

2024

20. Improving the Indoor Air Quality of Office Buildings in the Post-Pandemic Era—Impact on Energy Consumption and Costs.

Author

D'Agostino, Diana, Minelli, Federico, Minichiello, Francesco, and Musella, Maddalena

Subjects

*ENERGY consumption, *INDOOR air quality, *ENERGY industries, *VENTILATION, *NATURAL ventilation, *OFFICE buildings, *AIR conditioning, *SOFTWARE validation, *COVID-19

Abstract

Before the COVID-19 pandemic, ventilation in buildings was not always given its due importance. The World Health Organization has highlighted the important role of air exchange with the outdoors in improving the air quality in buildings; buildings should, therefore, be equipped with mechanical ventilation or adequate air conditioning systems. This paper aims to investigate different retrofit solutions for air conditioning, evaluating them in terms of energy consumption and cost and the impact of increased outdoor air exchange rates on countering the propagation of COVID-19; the latter is the main novelty of the paper. As a case study, we take an existing office building located in Central Italy that was previously not equipped with a mechanical ventilation system (a system with primary air was introduced during the study). The energy analysis was conducted using dynamic simulation software after validation through energy bills; energy and economic analyses were conducted considering different external-air exchange rates. An optimal number of outdoor air changes was found to mitigate the risk of COVID-19 infection, a finding in line with the international literature. The increase in air changes with outdoor air leads to a rise in energy consumption and costs. These values were evaluated for different air conditioning systems and operational schedules. These drawbacks can be made less significant by combining interventions in the system with energy-efficiency measures applied to the building envelope. [ABSTRACT FROM AUTHOR]

Published

2024

21. Preventing Glass Misting in Indoor Showcases with Burial Remains at Al Ain, UAE.

Author

Camuffo, Dario, Giorio, Roberta, della Valle, Antonio, Rizzi, Francesco, Barucco, Patrizia, Suma, Marivita, Ahmed, Jalal, Chabbi, Amel, Shaker, Ola, and Sheehan, Peter

Subjects

*HUMAN comfort, *WORLD Heritage Sites, *GLASS, *AIR conditioning, *ENVIRONMENTAL monitoring

Abstract

The historic house of Sheikh Mohammed Bin Khalifa, Al Ain (Abu Dhabi, UAE) belongs to the World Heritage Cultural Sites. The courtyard and two rooms include mudbrick archaeological remains that are preserved in showcases for public display. The building lies in a hot desert climate and needs air conditioning to be comfortable. This paper is concerned with indoor showcases and their compatibility with the indoor climate. Sometimes, misting for condensation is generated on the glass panes for the temperature and humidity contrast between the room climate and the showcases that are embedded in the floor. When misting occurs, the remains cannot be viewed. This paper investigates indoor glass misting, the exchanges of heat and moisture between archaeological remains, showcases and rooms, and the results after a year of environmental monitoring. An aim is to assess the potential risks for the preservation of the remains, recognizing the frequency and severity of the conditions for condensation. Another aim is to discuss mitigation methodologies to avoid glass misting, e.g., (i) reducing the room cooling; (ii) raising the glass pane temperature with electrical devices; (iii) increasing air exchanges between showcases and rooms; (iv) adopting a combination of these methodologies. [ABSTRACT FROM AUTHOR]

Published

2024

22. Influence of Impregnation with Modified Starch of a Paper Core on Bending of Wood-Based Honeycomb Panels in Changing Climatic Conditions.

Author

Słonina, Michał, Dziurka, Dorota, Molińska-Glura, Marta, and Smardzewski, Jerzy

Subjects

*CLIMATE change, *HONEYCOMB structures, *STARCH, *AIR conditioning, *FONTS & typefaces, *HUMIDITY

Abstract

The main objective of the study was to determine the effect of impregnation of the paper core with acetylated starch on the mechanical properties and absorbed energy in the three-point bending test of wood-based honeycomb panels under varying temperatures and relative air humidity conditions. Nearly six hundred beams in various combinations, three types of facings, three core cells geometries, and two paper thicknesses were tested. The experiment results and their statistical analysis prove a significant relationship between the impregnation of paper with modified starch and mechanical properties. The most effective in absorbing energy, the honeycomb panels, consisted of a core with a wall thickness of 0.25 mm and a particleboard facing. [ABSTRACT FROM AUTHOR]

Published

2022

23. A hierarchical coordinated control strategy of air‐conditioning loads for peak regulation service.

Author

Wang, Wei, Lin, Shunfu, Wang, Lulu, Mi, Yang, Tan, Jin, Qian, Liang, Li, Dongdong, and Li, Fangxing

Subjects

*PEAK load, *AIR conditioning, *RENEWABLE energy sources, *LOAD management (Electric power)

Abstract

The increased penetration of renewable energy sources and the intensification of peak‐valley differences present challenges to peak regulation in the power system. Fulfilling the peak regulation needs of the power system solely through generation‐side resources proves to be challenging. Large‐scale fixed frequency air‐conditioning (FFAC) and inverter air‐conditioning (IAC) are high‐quality flexible load resources. This paper proposes a hierarchical coordinated control strategy of air‐conditioning (AC) loads for peak regulation service. In the first layer of the control strategy, the load aggregator collaborates with multiple AC groups to ensure the completion of peak regulation tasks with specific power‐constrained requirements. In the second layer of the control strategy, the control centre of each group optimizes the temperature adjustment values for each AC load, aiming to reduce incentive costs. Finally, the proposed method is validated through simulations, demonstrating its capability to achieve coordinated control of FFAC and IAC loads under various power‐constrained requirements. Furthermore, the simulation demonstrates the effectiveness of the control strategy in reducing user discomfort and the AC's incentive costs. [ABSTRACT FROM AUTHOR]

Published

2024

24. Intelligent Controlling Model for Cleaning of Rice–Wheat Combine Harvester Based on Multi-Objective Optimization Particle Swarm Method.

Author

Zhang, Jing, Hu, Zelin, Zhou, Xiancun, Xu, Xueying, and Zhang, Yifan

Subjects

*COMBINES (Agricultural machinery), *PARTICLE swarm optimization, *INTELLIGENT control systems, *AIR conditioning, *CLEANING

Abstract

Intelligent control has become an important research direction of a combine harvester. However, the impact of cleaning control parameters in rice–wheat combine harvesters on cleaning loss rate and impurity rate often tends to be contradictory. In this paper, an intelligent controlling model based on multi-objective optimization particle swarm (MOPSO) was constructed to solve this problem. The control model can real-time monitor the cleaning performance such as the cleaning loss rate and impurity rate and regulate the cleaning operation conditions such as the angle of the air distributor plate, the opening of the upper sieve and the fan speed. The field operation experiment of 10 kg feeding rice–wheat combine harvester proves that the control model based on MOPSO is more effective than the model based on fuzzy control. [ABSTRACT FROM AUTHOR]

Published

2024

25. Elicitation of Rank Correlations with Probabilities of Concordance: Method and Application to Building Management.

Author

Ramousse, Benjamin, Mendoza-Lugo, Miguel Angel, Rongen, Guus, and Morales-Nápoles, Oswaldo

Subjects

*BAYESIAN analysis, *AIR conditioning, *JUDGMENT (Psychology), *ASSET management, *BUILDING maintenance

Abstract

Constructing Bayesian networks (BN) for practical applications presents significant challenges, especially in domains with limited empirical data available. In such situations, field experts are often consulted to estimate the model's parameters, for instance, rank correlations in Gaussian copula-based Bayesian networks (GCBN). Because there is no consensus on a 'best' approach for eliciting these correlations, this paper proposes a framework that uses probabilities of concordance for assessing dependence, and the dependence calibration score to aggregate experts' judgments. To demonstrate the relevance of our approach, the latter is implemented to populate a GCBN intended to estimate the condition of air handling units' components—a key challenge in building asset management. While the elicitation of concordance probabilities was well received by the questionnaire respondents, the analysis of the results reveals notable disparities in the experts' ability to quantify uncertainty. Moreover, the application of the dependence calibration aggregation method was hindered by the absence of relevant seed variables, thus failing to evaluate the participants' field expertise. All in all, while the authors do not recommend to use the current model in practice, this study suggests that concordance probabilities should be further explored as an alternative approach for the elicitation of dependence. [ABSTRACT FROM AUTHOR]

Published

2024

26. STUDY ON AN ENERGY-SAVING THERMAL MANAGEMENT SYSTEM IN OUTDOOR BASE STATIONS.

Author

Jing BAI, Chuang XU, Siqi CUI, Huifang FAN, Yi ZHANG, Hanfei YANG, Size GUAN, Chao ZHANG, and Huifan ZHENG

Subjects

*HEAT pipes, *AIR conditioning efficiency, *AIR ducts, *AIR conditioning, *HIGH temperatures

Abstract

In order to solve the poor heat dissipation in the outdoor mobile communication base station, especially in summer, high temperature alarm phenomenon occurs frequently, affecting the normal operation of building base band unite, this paper designs an energy-saving and efficient integrated thermal management system, which has achieved good results by applying the combined operation of heat pipe cooling and air conditioning system using the outdoor temperature switching mode. A mobile communication base station in Zhengzhou City was chosen for a pilot application. The measured results showed that the system ran stably, the temperature inside the cabinet was controlled between 12 °C and 39 °C with no high temperature alarm, the compressor running time was significantly reduced, the power consumption of the air conditioner was significantly reduced, and the annual power saving rate was as high as 58.63%. [ABSTRACT FROM AUTHOR]

Published

2024

27. ENERGY-SAVING MEASURES AND TEMPERATURE CONTROL FOR OUTDOOR COMMUNICATION CABINETS.

Author

Siqi CUI, Yi ZHANG, Jing BAI, Hanfei YANG, Chuang XU, Size GUAN, and Huifang FAN

Subjects

*TEMPERATURE control, *HEAT pipes, *ENERGY consumption, *HEATING control, *TEST systems, *HEATING

Abstract

In view of the prominent and intractable problems of frequent high temperature alarms of the communication equipment and high energy consumption of air conditioners in Zhengzhou communication outdoor cabinets, a temperature control system with heat pipe as the main part and air conditioner as the auxiliary part is proposed in this paper. A prototype is developed and its applications are discussed. The annual field test shows the system works well, and it has a remarkable energy saving efficiency. [ABSTRACT FROM AUTHOR]

Published

2024

28. Experimental Investigation on Thermoelectric Power Generation Using Diurnal Temperature Difference Through Glazed Windows.

Author

Souppornsingh, Pasinpong, Chantawong, Preeda, and Khedari, Joseph

Subjects

*THERMOELECTRIC power, *AIR conditioning, *TEMPERATURE, *HIGH temperatures, *HIGH voltages

Abstract

Harvesting ambient temperature is attractive for different purposes. In this paper, a pioneer study on thermoelectric power generation using natural diurnal temperature difference between ambient and indoor space through glazed windows (TEGW) is investigated experimentally. To this end, a small south facing window with 5 mm green tinted glass, 0.45 m wide and 1.05 m high located in a room of 25.74 m³ volume located at the first floor of a residential house in Nonthaburi province (Thailand) was used. Three thermoelectric (TE) modules (MT2-1, 6-127) 40×40 mm were installed at the inner side of the glass window at three positions near the top, middle and bottom. Tests were conducted with close and open curtain and air and non-air-conditioned spaces. Measured data demonstrated that the proposed concept is feasible as an electrical current could be generated: The hotter the day, the higher is the temperature difference between the hot and cold sides of TE modules and the higher the amount of current generated. When air conditioning is used, the temperature difference between the sides of TE modules increased and higher electrical voltage is generated varying between 0.5-1.9 mV compared to 0.1-0.6 mV without air conditioning. Closing curtain did affect the generated electrical voltage significantly as it reduced the cooling of the inner side of TE modules due to reduced air circulation especially at the middle and top of window. Due to its simplicity, the proposed concept offers new perspectives for thermoelectric power generation development and its application in residences and buildings. [ABSTRACT FROM AUTHOR]

Published

2024

29. Integrated Heat Recovery System Based on Mixed Ionic–Electronic Conducting Membrane for Improved Solid Oxide Co-Electrolyzer Performance.

Author

Sánchez-Luján, José, Molina-García, Ángel, and López-Cascales, José Javier

Subjects

*HEAT recovery, *HEATING, *FUEL cells, *ELECTROLYTIC cells, *CHEMICAL reactors, *CERAMICS, *AIR conditioning, *SOLID oxide fuel cells, *MEMBRANE reactors

Abstract

The current state of mixed ionic–electronic conducting ceramic membrane technology presents significant advancements with potential applications in various fields including solid oxide electrolyzers, fuel cells, hydrogen production, CO2 reduction, and membrane reactors for chemical production and oxygen separation. Particularly in oxygen separation applications, optimal conditions closely align with the conditions of oxygen-rich air streams emitted from the anode of solid oxide co-electrolyzers. This paper describes and analyzes a novel integrated heat recovery system based on mixed ionic–electronic conducting membranes. The system operates in two stages: firstly, oxygen is separated from the anode output stream using mixed ionic–electronic conducting membranes aided by a vacuum system, followed by the heat recovery process. Upon oxygen separation, the swept gas stream is recirculated at temperatures near thermoneutral conditions, resulting in performance improvements at both cell and system levels. Additionally, an oxygen stream is generated for various applications. An Aspen HYSYS® model has been developed to calculate heat and material balances, demonstrating the efficiency enhancements of the proposed system configuration. [ABSTRACT FROM AUTHOR]

Published

2024

30. Microclimate Investigation in a Conference Room with Thermal Stratification: An Investigation of Different Air Conditioning Systems.

Author

Longhitano, Andrea, Costanzo, Vincenzo, Evola, Gianpiero, and Nocera, Francesco

Subjects

*CONFERENCE rooms, *AIR conditioning, *CHAPELS, *COMPUTATIONAL fluid dynamics, *RADIANT heating, *ELECTRIC power consumption

Abstract

This paper investigates the microclimate in a conference room with thermal stratification, taking as a case study the chapel of Villa San Saverio, now the seat of the "Scuola Superiore" of the University of Catania (Italy). Surveys of the former chapel were conducted to monitor air temperature and relative humidity. Subsequently, the investigation relied on numerical simulations of a simplified computational fluid dynamics (CFD) model built with the DesignBuilder v7.0 software and validated by comparison with measured values. Simulations were then carried out considering three different scenarios: the current state without any HVAC system and two possible HVAC system configurations providing both air conditioning and ventilation. The results show that, from a comfort perspective, a lightweight radiant floor heating system, assisted by an appropriate ventilation system for air renewal placed at the floor level near the occupants, is preferable to floor-level fan coils and high ventilation channels. Furthermore, this was also confirmed by a preliminary energy analysis of the two HVAC options, where the ventilation effectiveness of the winter period, the temperature of the water the emitters are fed, the consequent COP value of the heat pump, and the electricity consumption were taken into consideration. [ABSTRACT FROM AUTHOR]

Published

2024

31. Energy Performance and Thermal Comfort Delivery Capabilities of Solid-Desiccant Rotor-Based Air-Conditioning for Warm to Hot and Humid Climates—A Critical Review.

Author

Halawa, Edward and Bruno, Frank

Subjects

*THERMAL comfort, *AIR conditioning, *DRYING agents, *INDOOR air quality, *EVAPORATIVE cooling, *OZONE layer

Abstract

There has been considerable research worldwide on desiccant-based air-conditioning during the past 30 years. The rationale for the push for this new research focus has been twofold: (a) the need to provide an alternative to conventional refrigerative air-conditioning systems which rely heavily on fossil fuels as their energy sources, and (b) the need to provide better thermal comfort in air-conditioned spaces in warm to hot and humid climates. A desiccant air-conditioning system consists of several components to cool and dehumidify the air before it is supplied to a conditioned space. Earlier research work has identified the potential advantages of this technology, which include the following: (1) working fluids that do not impact on the ozone layer, (2) reduced electricity consumption, (3) improved indoor air quality, (4) simpler construction and less maintenance, and (5) integral provision of heating and cooling for cold/temperate climates. On the other hand, the authors of this paper identified the following drawbacks: (1) inevitable heating of air while being dehumidified, (2) the need for desiccant regeneration and low thermal COP paradox, (3) limited options for regeneration heat sources, (4) limited options for reliable cooling, and (5) low electrical coefficient of performance (COP). This paper presents a critical review of the energy and thermal comfort performance of solid-desiccant rotor-based air-conditioning systems, and discusses in detail their potential advantages and drawbacks. This critical review found that the drawbacks of the systems outweigh their identified advantages. The main reason for this is the inevitable heating of air while being dehumidified and counterintuitive addition of moisture to air during the evaporative cooling process. During the past 30 years of research and development efforts, no significant innovations have been discovered to resolve these crucial issues. Unless future research and development is directed to find a breakthrough, this technology will have limited commercial application. [ABSTRACT FROM AUTHOR]

Published

2023

32. Data-driven adaptive GM(1,1) time series prediction model for thermal comfort.

Author

Li, Xiaoli, Xu, Chang, Wang, Kang, Yang, Xu, and Li, Yang

Subjects

*THERMAL comfort, *PREDICTION models, *HUMAN comfort, *WIND speed, *AIR conditioning

Abstract

In this paper, the future prediction of predicted mean vote (PMV) index of indoor environment is studied. PMV is the evaluation index used in this paper to represent the thermal comfort of human body. According to the literature, the main environmental factors affecting PMV index are temperature, humidity, black globe temperature, wind speed, average radiation temperature, and clothing surface temperature, and there is a complex nonlinear relationship between the six variables. Due to the coupling relationship between the six parameters, the PMV formula can be simplified under specific conditions, reducing the monitoring of variables that are difficult to observe. Then, the improved grey system prediction model GM(1,1) with optimized selection dimension is used to predict the future time of PMV. Due to the irregularity, uncertainty and fluctuation of PMV values in time series, based on the original GM(1,1) time series prediction, an adaptive GM(1,1) improved model is proposed, which can continuously change with time series and enhance its prediction accuracy. By contrast, the improved GM(1,1) model can be derived from the sliding window of the adaptive model through changes in the dataset and get better model grades. It lays a foundation for the future research on the predicted index of PMV, so as to set and control the air conditioning system in advance, to meet the intelligence of modern intelligent home and humanized function of sensing human comfort. [ABSTRACT FROM AUTHOR]

Published

2023

33. Economic Load-Reduction Strategy of Central Air Conditioning Based on Convolutional Neural Network and Pre-Cooling.

Author

Lu, Siyue, Zhang, Baoqun, Ma, Longfei, Xu, Hui, Li, Yuantong, and Yang, Shaobing

Subjects

*CONVOLUTIONAL neural networks, *AIR conditioning, *AIR warfare, *ENERGY consumption of buildings

Abstract

Central air conditioning in large buildings is an important demand-response resource due to its large load power and strong controllability. Demand-response-oriented air conditioning load modeling needs to calculate the room temperature. The room temperature calculation models commonly used in the existing research cannot easily and accurately calculate the room temperature change of large buildings. Therefore, in order to obtain the temperature change of a large building and its corresponding power potential, this paper first proposes a building model based on CNN (convolutional neural network). Then, in order to fully apply the demand-response potential of the central air conditioning load, this paper puts forward an evaluation method of the load-reduction potential of the central air conditioning cluster based on pre-cooling and develops an economic load-reduction strategy according to the different energy consumption of different buildings in the pre-cooling stage. Finally, multiple building examples with different building parameters and temperature comfort ranges are set up, and the economic advantages of the proposed strategy are illustrated by Cplex solution examples. [ABSTRACT FROM AUTHOR]

Published

2023

34. Temperature Regulation Strategy of Heterogeneous Air Conditioning Loads for Renewable Energy Consumption.

Author

Zhang, Shu, Zhou, Liping, Fan, Dejin, and Tang, Jie

Subjects

*TEMPERATURE control, *AIR conditioning, *ENERGY consumption, *RENEWABLE energy sources, *AIR warfare, *WIND power, *PHOTOVOLTAIC power generation

Abstract

In a power system with a high proportion of renewable energy, sudden increases in wind power or photovoltaic output can lead to huge challenges, such as difficulties in accommodating excess renewable energy and imbalances between supply and demand on the grid. As an important adjustable resource on the demand side, air conditioning load is a flexible load for realizing output consumption. In this paper, a heterogeneous air conditioning load regulation strategy for renewable energy consumption is proposed. Each air conditioning load regulation quantity is obtained based on the day-ahead dispatching mode. Then, the temperature setting value, rated power, and duty cycle are selected as the indexes. The load regulation sequence is obtained by the entropy weight method. Finally, the load regulation time of each air conditioning load is obtained based on the constraint of the quantity of loads during the possible adjustment time. The simulation analysis shows that the temperature regulation strategy presented in this paper can effectively reduce the power fluctuations of air conditioning loads, while ensuring that users with lower temperature settings are selected in the adjustment process. [ABSTRACT FROM AUTHOR]

Published

2023

35. A Trip-Based Data-Driven Model for Predicting Battery Energy Consumption of Electric City Buses.

Author

Dabčević, Zvonimir, Škugor, Branimir, Cvok, Ivan, and Deur, Joško

Subjects

*ELECTRIC motor buses, *ENERGY consumption, *FEATURE selection, *SOLAR temperature, *AIR conditioning, *ELECTRIC vehicles, *MACHINE learning

Abstract

The paper presents a novel approach for predicting battery energy consumption in electric city buses (e-buses) by means of a trip-based data-driven regression model. The model was parameterized based on the data collected by running a physical experimentally validated e-bus simulation model, and it consists of powertrain and heating, ventilation, and air conditioning (HVAC) system submodels. The main advantage of the proposed approach is its reliance on readily available trip-related data, such as travel distance, mean velocity, average passenger count, mean and standard deviation of road slope, and mean ambient temperature and solar irradiance, as opposed to the physical model, which requires high-sampling-rate driving cycle data. Additionally, the data-driven model is executed significantly faster than the physical model, thus making it suitable for large-scale city bus electrification planning or online energy consumption prediction applications. The data-driven model development began with applying feature selection techniques to identify the most relevant set of model inputs. Machine learning methods were then employed to achieve a model that effectively balances accuracy, simplicity, and interpretability. The validation results of the final eight-input quadratic-form e-bus model demonstrated its high precision and generalization, which was reflected in the R2 value of 0.981 when tested on unseen data. Owing to the trip-based, mean-value formulation, the model executed six orders of magnitude faster than the physical model. [ABSTRACT FROM AUTHOR]

Published

2024

36. Energy, exergy and entropy analysis with R1234yf as an alternate refrigerant to R134a of automobile air conditioning system.

Author

PATEL, Bhaveshkumar and PAREKH, Ashok

Subjects

*AIR conditioning, *GREENHOUSE gas mitigation, *EXERGY, *VAPOR compression cycle, *REFRIGERANTS, *COOLING loads (Mechanical engineering), *ENTROPY

Abstract

A major portion of the worldwide emissions arise from mobile air-conditioning systems with hydrofluorocarbon refrigerant as working substance and which is one of major cause for the greenhouse effect. R134a refrigerant having GWP of 1400 has been extensively used in car air conditioning. To reduce greenhouse gas emissions, the current R134a refrigerant must be phase out as per Kigali Amendment. The present study deals with cooling load calculation of car model by heat balance method as per ASHRAE standard using local climate condition. Further, thermodynamic analysis of R1234yf as an alternate refrigerant to R134a has been carried out for automobile air conditioning system. The required properties of refrigerants are extracted from Engineering Equation Software. The thermodynamic analysis is carried out to study the effect of operating parameters viz. condensing temperature, evaporating temperature, degree of superheating and degree of subcooling on COP, EDR, exergy efficiency and entropy generation. The previous literature reports mainly focus on separate study of either cooling load calculation or energy analysis or exergy analysis of R1234yf and R134a for automobile air conditioning system, while this paper presents the comprehensive study of new low GWP R1234yf as an alternate refrigerant to R134a in automobile air conditioning system with cooling load calculation including the concept of energy, entropy and exergy analysis. The percentage difference in COP between R134a and R1234yf system varies from 2.44 % to 4.78 % while percentage difference in EDR varies from 6.79 % to 2.87 % when evaporating temperature varied from -10 °C to 10 °C. With 12 °C of superheating at compressor inlet, the COP of R134a is 3.9 whereas COP of R1234yf is 3.75, which makes 3.85 % lower than that of R134a. The R1234yf has 4.78 % lower value of exergy efficiency as compared to that of R134a at evaporating temperature of -10 °C and it is found that maximum exergy destruction takes place in compressor. [ABSTRACT FROM AUTHOR]

Published

2024

37. Study on the Heat and Mass Transfer Characteristics of Humidifiers in Humidification–Dehumidification Desalination Systems.

Author

Zhu, Qundong, Wu, Weidong, Ren, Yan, Wang, Fengxian, and Han, Yipeng

Subjects

*HEAT transfer, *MASS transfer, *HUMIDIFIERS, *HUMIDITY control, *AIR conditioning, *ENERGY consumption, *SPRAYING & dusting in agriculture, *CELLULOSE fibers

Abstract

The humidifier plays a key role in a humidification–dehumidification (HDH) desalination system; it directly affects both the freshwater production efficiency and energy consumption ratio of the system. In this study, for a humidifier in an HDH system, a heat–mass coupled differential equation model of spray water and air on the surface of the packing material was established, and the effects of parameters such as the spray water temperature (tw), mass flow rate of spray water (mw), air temperature (ta), and air mass flow rate (ma) on the humidification performance of humidifiers composed of eight different types of packing materials were investigated. The results show the following: (1) Under the same inlet spray water and air conditions, the humidification performance of different packing materials from good to bad is as follows: cellulose paper, polypropylene, hackettes, saddles, snowflakes, wooden slats, polyvinyl chloride, gunny bag cloth. (2) Increasing the tw can significantly improve the humidification performance. To achieve higher humidification energy efficiency, it is recommended to increase the tw to above 80 °C. (3) With the increase in the mw, although the humidification efficiency (εhum) decreases slightly, the humidification rate (mhum) increases, and the specific humidification energy ratio (ηhum) decreases accordingly. To maintain a high mhum and a low ηhum, it is advisable to control the mw at not less than 0.5 kg/s. (4) Increasing the humidifier inlet ta can improve the mhum, εhum, and ηhum, although not as effectively as increasing tw. (5) Increasing the ma can improve mhum and εhum. However, it simultaneously increases the ηhum. The results of this study can provide theoretical guidance for the selection of efficient packing materials and the optimization of humidifier operating conditions in HDH desalination systems. [ABSTRACT FROM AUTHOR]

Published

2023

38. Coating of Filter Materials with CeO 2 Nanoparticles Using a Combination of Aerodynamic Spraying and Suction.

Author

Abramova, Anna V., Kozlov, Daniil A., Veselova, Varvara O., Kozlova, Taisiya O., Ivanova, Olga S., Mikhalev, Egor S., Voytov, Yuri I., Baranchikov, Alexandr E., Ivanov, Vladimir K., and Cravotto, Giancarlo

Subjects

*CERIUM oxides, *NANOPARTICLES, *AIR conditioning, *ANTIBACTERIAL agents, *NONWOVEN textiles, *SURFACE coatings

Abstract

Textiles and nonwovens (including those used in ventilation systems as filters) are currently one of the main sources of patient cross-infection. Healthcare-associated infections (HAIs) affect 5–10% of patients and stand as the tenth leading cause of death. Therefore, the development of new methods for creating functional nanostructured coatings with antibacterial and antiviral properties on the surfaces of textiles and nonwoven materials is crucial for modern medicine. Antimicrobial filter technology must be high-speed, low-energy and safe if its commercialization and mass adoption are to be successful. Cerium oxide nanoparticles can act as active components in these coatings due to their high antibacterial activity and low toxicity. This paper focuses on the elaboration of a high-throughput and resource-saving method for the deposition of cerium oxide nanoparticles onto nonwoven fibrous material for use in air-conditioning filters. The proposed spraying technique is based on the use of an aerodynamic emitter and simultaneous suction. Cerium oxide nanoparticles have successfully been deposited onto the filter materials used in air conditioning systems; the antibacterial activity of the ceria-modified filters exceeded 4.0. [ABSTRACT FROM AUTHOR]

Published

2023

39. Improved Isothermal Relaxation Current Measurement Based on Isolated Circuit for Nondestructive Evaluation of High-Voltage Cable Insulation.

Author

Gu, Huangjing, Zhang, Yongkang, Shen, Bin, Liu, Ziqi, Zhou, Yunjie, Wang, Xiaodi, Zhu, Xinyang, and Wang, Yalin

Subjects

*NONDESTRUCTIVE testing, *AIR conditioning, *MEASUREMENT errors, *CABLES, *TEST systems, *WIRE

Abstract

The Isothermal Relaxation Current (IRC) method, as a non-destructive condition evaluation method based on insulation dielectric response, has been applied in the maintenance of power cables. However, the relaxation current is usually conducted through the outer shield of the high-voltage wire, which will introduce the extra depolarization current into the test circuit, affecting the accuracy of the test results. Furthermore, most IRC cable measurements are single-phase, which means depolarization currents are measured for each cable separately. In order to improve the measurement accuracy and efficiency of the IRC test, this paper proposes an improved IRC measurement method based on an isolated circuit, which discharges the interference current from the high-voltage insulated wire back to the earth and reduces the measurement error of depolarization current. At the same time, a three-phase IRC simultaneous test system is designed, and the control software is developed. Furthermore, by verifying the accuracy of the test system, the independence of the single-phase circuit and the consistency of the three-phase circuit is achieved. The effect of depolarization time and temperature on the relaxation current is then explored to determine the suitable parameter of the IRC test. Finally, the IRC system is used to evaluate the aging state of 10 kV cables with various aging conditions in the air and water for the longest 12 months. Critical parameters such as aging factor and time constants are compared to investigate the aging characteristics of tested cables with various aging conditions in the air and water. The proposed method and research conclusions can provide helpful references for the non-destructive condition evaluation for high-voltage cable insulation. [ABSTRACT FROM AUTHOR]

Published

2023

40. Performance and Efficiency of Cross-Flow Fans—A Review.

Author

Vanaei, Hamid Reza, Khelladi, Sofiane, Dobrev, Ivan, Bakir, Farid, Himeur, Rania M., Mammeri, Amrid, and Azzouz, Kamel

Subjects

*CROSS-flow (Aerodynamics), *AIR conditioning, *OPEN innovation, *UNIVERSITY research, *TURBOMACHINES

Abstract

Cross-Flow Fans (CFFs) have been widely applied in the automotive and domestic air conditioning industries in recent decades. They are high-pressure coefficient turbomachines compacted diametrically, and thus, the complex interactions of these fans require thorough evaluation. Their innovation has opened up new directions in turbomachinery, and both academic research and industry have seen numerous efforts to develop these types of fans. Despite extensive work, optimizing and improving their performance remains a challenge. Enhancing their efficiency necessitates improvements in structural characteristics, aerodynamic features, and acoustic properties. In this review, we aim to demonstrate the essential aspects of CFFs by introducing their fundamentals and primary characteristics. Furthermore, we delve into a discussion on the acoustic performance of these fans. We also summarize the flow characteristics and different flow-field patterns in CFFs and their impact on aeroacoustic behavior. The main objective of this review paper is to provide an overview of the research in this field, summarizing the critical factors that play a significant role in studying CFFs' performance. [ABSTRACT FROM AUTHOR]

Published

2023

41. An Innovative Heating, Ventilation, Air Conditioning and Refrigeration Circular Economy System for Reducing Carbon Dioxide Emissions in Europe via Extensive Reuse of Existing Fluorinated Gases.

Author

Barmparitsas, Nikolaos, Karellas, Sotirios, Pallis, Platon, Thanopoulos, Sotirios, and Kobelt, Daniel

Subjects

*CARBON emissions, *CIRCULAR economy, *AIR conditioning, *GREENHOUSE gases, *GREENHOUSE gas mitigation, *VENTILATION

Abstract

Reducing emissions from fluorinated gases (F-gases) is considered one of the key conditions for the European Union (EU) to be able to meet the requirements of the European Green Deal, primary objectives of which are the reduction in greenhouse gas emissions by at least 55% by 2030 compared to 1990 and the gradual transition to net climate neutrality by 2050. To this end, a quota system for hydrofluorocarbons (HFCs) is already in place, introduced through the updated F-Gas Regulation (517/2014). The aim of this paper is to review an innovative scheme currently under development that strongly promotes the Recovery, Recycling and Reuse (3R) of F-gases extracted from the heating, ventilation, air conditioning and refrigeration (HVAC-R) equipment of the building sector, thus offering a sustainable alternative source for refrigerant supplies. Therefore, the basic operating principles of the so-called "3R ECOSYSTEM" are outlined and especially its three main components, which are: the self-certification/self-declaration platform, the F-gas identification and recycling units (prototypes) and the Retradeables marketplace. In addition, an overview of both the demonstration phase and the scheduled replication phase of the 3R ECOSYSTEM is provided, including the estimated impact on carbon dioxide (CO2) savings due to the progressive uptake of the circular use of existing F-gases across Europe. [ABSTRACT FROM AUTHOR]

Published

2023

42. EXPERIMENTAL AND HYBRID NUMERICAL ANALYTICAL APPROACH OF AN EARTH-TO-AIR HEAT EXCHANGER.

Author

Aissaoui, Faris, Rouag, Amar, Belloufi, Yousef, Zerouali, Sakina, Atmani, Rachid, Benchabane, Adel, Brima, Abdelhafid, Moummi, Noureddine, and Belatrache, Djamel

Subjects

*HEAT exchangers, *THERMAL conductivity, *AIR conditioning, *CLIMATE change, *NUMERICAL analysis

Abstract

The primary goal of this paper is to assess the thermal behaviour of Earth-to- Air Heat Exchanger (EAHE) under continuous operation mode during the cooling period in warm climatic conditions. An experimental setup was conducted in Biskra University (Algeria) to test the ability to use EAHE as an alternative solution to conventional air conditioning systems. Besides, a transient numerical approach for the flowing air within the EAHE was developed using energy balance equations, discretised by the implicit finite differences method and solved by Thomas method. Furthermore, the transient temperature profile of the soil around the EAHE was investigated in order to determine the adiabatic radius of the soil as a function of the duration of operation. In this context, a transient semi-analytical model was integrated to the air model to estimate the transient EAHE's performance deterioration. This deterioration is produced by the thermal saturation of the soil, which is influenced by the heat released from the air inside the pipe. Results showed that continuous operation for a duration of four days has minimal impact on the outlet air temperatures due to the implementation of night purging. Furthermore, the design and thermal efficiency of the EAHE are impacted by factors such as higher air velocity and reduced soil thermal conductivity. [ABSTRACT FROM AUTHOR]

Published

2023

43. Pump-Valve Combined Control of a HVAC Chilled Water System Using an Artificial Neural Network Model.

Author

Gao, Bo, Ni, Ji, Yuan, Zhongyuan, and Yu, Nanyang

Subjects

*CHILLED water systems, *WATER use, *ENERGY consumption, *ARTIFICIAL neural networks, *AIR conditioning

Abstract

A chilled water system transports cooling functionality from refrigerators to users via heating, ventilation, and air conditioning (HVAC) systems. This paper investigated an optimal control strategy to regulate the volume flow rate of each user branch in a chilled water system, considering the minimum resistance operation to reduce energy consumption. An artificial neural network (ANN) was adopted to establish the nonlinear relationship between the volume flow rate of each user branch, pump frequency, and valve opening of each user branch. An optimal control strategy for a chilled water HVAC system is proposed in this article, according to the pump-valve combined control (PVCC) principle and an ANN model, i.e., pump-valve combined control using an artificial neural network model (PVCC-ANN). A series of tests were conducted to collect data to train the ANN model and analyze the performance of the PVCC-ANN in an experimental chilled water system. The results show that the trained ANN model has good prediction performance. A minimum resistance operation can be achieved to control the volume flow rate of each user branch independently by using the PVCC-ANN model. Moreover, the proposed PVCC-ANN method shows good energy-saving performance in chilled water systems, which can be attributed to the minimum resistance operation. Taking the energy consumption of the pump's constant frequency operation as the reference, the energy saving rate using the PVCC-ANN is between 14.3% and 58.6% under 10 operating conditions, as reported in this paper. [ABSTRACT FROM AUTHOR]

Published

2023

44. Heating Degree Days Relevancy: Why a 55-Degree Balance Point is Better than 65 for Building Energy Analysis in Heating Dominant Climates.

Author

Heizer, Mark and Thomas, Kelly

Subjects

*ENERGY consumption of buildings, *COOLING loads (Mechanical engineering), *HEATING load, *AIR conditioning, *COMMERCIAL buildings, *ATMOSPHERIC temperature, *DWELLINGS

Abstract

Heating Degree Days at 65°F (HDD65) is still utilized by ASHRAE Standard 169 for determining Climate Zones and in other fundamental HVAC resources, such as Air Conditioning Contractors of America's (ACCA's) Manual J and S calculations. The U.S. Energy Information Administration (EIA) also uses HDD65 and it even occurs within the Passive House Institute US (PHIUS) where heating is not in demand until Outdoor Air Temperatures (OAT) reach 45°F. This paper explores and supports utilization of Heating Degree Days at 55°F (HDD55) for building energy analysis in heating dominant climates. This is supported by EnergyPlus modeling results for a sample of building types. A degree days overview on Energycap states that "The 65-degree balance point standard was developed 75 years ago to help the gas industry predict heating loads in residences. Studies back then showed that when the average daily temperature fell below 65°F, residences began turning on the heat." Today, HDD65 doesn't reflect structures built to modern energy codes, because internal loads are offsetting thermal envelope losses and when combined with the continued tightening of ventilation energy recovery requirements, heating is not necessary until much cooler than 65°F. According to a Regional Technical Forum (RTF) presentation titled "Overview of Updated Commercial EnergyPlus Building Models and Alignment with CBSA Data" dated August 31, 2021, the 'apparent balance point range between 50-60°F' was the reasonable OAT before heating was utilized by occupants. When energy modeling to HDD65, decisions are being made relative to temperature ranges that have minimal impact on building energy use. For example, when the OAT is in the 50-65°F range, this may mean more economizer hours are available without having to reheat the outdoor air or heat exterior spaces/operating zones. This would decrease the amount of energy the building utilizes, allowing for more accurately sized equipment. Similarly, utilizing Cooling Degree Day's at 50°F (CDD50), as ASHRAE Standard 169 does to determine Climate Zones, to predict cooling loads isn't appropriate as most building types don't need cooling starting at 50°F. Economizers are essentially mandatory for larger buildings which might need cooling at 50oF OAT, but smaller buildings will possibly be in heating mode when the OAT is 50oF. Utilizing CDD in the range of 60-70°F would give a more accurate representation of required cooling loads and will also be a minor focus of this technical paper. New HDD and CDD figures should be produced for ASHRAE Standard 169, Technical Resource Manuals (TRM's), and other publications that utilize degree days. With this information, end users can better analyze the weather's impact on actual building energy usage and better determine equipment sizing and other impacts. [ABSTRACT FROM AUTHOR]

Published

2022

45. Overall and local environmental collaborative control based on personal comfort model and personal comfort system.

Author

Wu, Yeyu, Jiang, Haihua, Chen, Weiming, Fan, Junhui, and Cao, Bin

Subjects

*THERMAL comfort, *AIR conditioning, *HEATING control, *AUTOMATIC control systems, *INDIVIDUAL differences, *SKIN temperature

Abstract

Most methods for creating an indoor thermal environment are based on controlling heating, ventilation, and air conditioning (HVAC) systems and do not consider the various needs of individuals in a multiperson space. Personal comfort systems (PCS) and personal comfort models (PCM) are popular technologies for achieving personal thermal comfort. This paper presents a thermal environmental collaborative control system (TECCS) that regulates environments at different spatial scales by leveraging the advantages of the HVAC system, PCS, PCM, and PCM-based automatic control to address the issue of individual differences in thermal demand in multiperson environments. The TECCS predicts thermal sensation votes (TSV) by combining facial skin temperature data obtained by an infrared sensor with environmental parameters. Subsequently, it performs the corresponding PCS control and adjusts the air conditioner according to the operating state of the PCS. This study proposes a collaborative control strategy with PCS at the core, enabling communication between thermal state recognition, HVAC system, and PCS. Twenty-eight adult males participated in the experiments testing the TECCS's performance. The results indicate that the TECCS can automatically regulate environments at different spatial scales based on thermal sensation prediction and that the operating state of the PCS can effectively guide air conditioning operations. Compared with constant setpoint control, the TECCS offers the advantage of improving thermal comfort. This paper also proposes future optimization directions based on the research results, focusing on recognition, equipment, and control. [Display omitted] • Skin-temperature-based comfort model and device collaborative control strategy. • Match occupant needs with environmental heat and cold supply. • Personal comfort system plays the role of both feedback and effector. • Realize the information interaction between occupants, PCS, and HVAC. • Prove the comfort improvement effect of the proposed system by subject experiments. [ABSTRACT FROM AUTHOR]

Published

2024

46. Energy-Saving Control Method for Factory Mushroom Room Air Conditioning Based on MPC.

Author

Wang, Mingfei, Zheng, Wengang, Zhao, Chunjiang, Chen, Yang, Chen, Chunling, and Zhang, Xin

Subjects

*AIR conditioning, *ENERGY consumption in factories, *COMMERCIAL buildings, *EDIBLE mushrooms, *MUSHROOMS, *TEMPERATURE control

Abstract

The energy consumption of the mushroom room air conditioning system accounts for 40% of the total energy consumption of the mushroom factory. Efficient and energy-efficient mushroom factories and mushroom houses are the development direction of the industry. Compared with maintenance structure transformation and air conditioning equipment upgrading, energy-saving technology based on regulation methods has the advantages of less investment and fast effectiveness, which has attracted attention. The current methods for regulating air conditioning in edible mushroom factories include simple on/off thermostat control or PID. In the field of energy efficiency in commercial building air conditioning, a large number of studies have shown that compared with traditional control algorithms such as classic on/off or PID control, model predictive control can significantly improve energy efficiency. However, there is little literature mentioning the application of MPC in factory mushroom production rooms. This paper proposes a data-driven MPC and PID combined energy-saving control method for mushroom room air conditioning. This method uses the CNN-GRU-Attention combination neural network as the prediction model, combined with prediction error compensation and dynamic update mechanism of the prediction model dataset, to achieve an accurate prediction of indoor temperature in mushroom houses. Establish an objective function for air conditioning control duration and temperature, use the non-dominated sorting genetic algorithm II (NSGA-II) to solve for the optimal control sequence of the air conditioning in the control time domain, and use the entropy weight method to determine the optimal decision quantity. Integrate rolling optimization, feedback mechanism, and PID to achieve precise and energy-saving control of the mushroom room environment. The experimental results show that compared with the on/off thermostat and PID controller, the designed controller reduces power consumption by 12% and 5%, respectively, and has good application and demonstration value in the field of industrial production of edible mushrooms. [ABSTRACT FROM AUTHOR]

Published

2023

47. LOW PRESSURE CENTRIFUGAL FANS OPERATING WITH DIFFERENT AIR TEMPERATURES.

Author

BOGDANOVIĆ-JOVANOVIĆ, Jasmina B., STAMENKOVIĆ, Živojin M., and PETROVIĆ, Jelena D.

Subjects

*ATMOSPHERIC temperature, *STATIC pressure, *AIR conditioning, *HIGH temperatures, *ENERGY consumption

Abstract

For normal operating conditions of the centrifugal fan, the manufacturers provide operating curves (total pressure of the fan, static pressure of the fan, power, and efficiency) for standard air conditions. However, when a fan operates with air at different, usually elevated temperatures, their operating curves can significantly differ. As a result, the fan efficiency decreases, and the energy efficiency of the fan may be reduced. Fan operation in such air conditions also affects its acoustic characteristics. This paper investigates two types of centrifugal fans: with forward curved and backward inclined blades. The main goal was to determine how their operating and acoustic characteristics change with the change in air temperature. For this analysis, low pressure centrifugal fans are used, for which we already had measured operating and acoustic characteristics. The influence of the type of impeller and the curvature of the blades play an important role in the operation of the fan. For numerical investigation, ANSYS CFX software was used, and obtained results show excellent agreement with experimental measurements. [ABSTRACT FROM AUTHOR]

Published

2023

48. Low‐cost air quality monitoring networks for long‐term field campaigns: A review.

Author

Carotenuto, F., Bisignano, A., Brilli, L., Gualtieri, G., and Giovannini, L.

Subjects

*AIR quality monitoring, *AIR quality, *AIR pollution, *AIR conditioning, *OPEN scholarship

Abstract

The application of low‐cost air quality monitoring networks has substantially grown over the last few years, following the technological advances in the production of cheap and portable air pollution sensors, thus potentially greatly increasing the limited spatial information on air quality conditions provided by traditional stations. However, the use of low‐cost air quality sensors still presents many limitations, mostly related to the reliability of their measurements. Despite the increasing number of papers focusing on these issues, some of the challenges connected to the use of low‐cost air quality sensors are still poorly investigated and understood, considering in particular those related to long‐term applications of low‐cost air quality networks and their integration within the reference air quality monitoring system. The present review aims at filling this gap, by analysing the characteristics of low‐cost air quality monitoring networks that were run across long‐term field campaigns, including their geographical location, the pollutants monitored, the type and number of stations employed, and the length of the field campaign, with a particular attention on assessing the aims for their deployment and on the evaluation of their integration within official air quality monitoring networks. Moreover, a critical analysis of the most insightful suggestions and recommendations delivered in the literature, as well as of the relevant critical issues, is presented, highlighting still open research areas and outlining future challenges. [ABSTRACT FROM AUTHOR]

Published

2023

49. Transfer Learning in the Transformer Model for Thermal Comfort Prediction: A Case of Limited Data.

Author

Zhang, Xin and Li, Peng

Subjects

*DEEP learning, *TRANSFORMER models, *THERMAL comfort, *ENERGY consumption, *ARTIFICIAL intelligence, *AIR conditioning

Abstract

The HVAC (Heating, Ventilation, and Air Conditioning) system is an important component of a building's energy consumption, and its primary function is to provide a comfortable thermal environment for occupants. Accurate prediction of occupant thermal comfort is essential for improving building energy utilization as well as health and work efficiency. Therefore, the development of accurate thermal comfort prediction models is of great value. Deep learning based on data-driven techniques has excellent potential for predicting thermal comfort due to the development of artificial intelligence. However, the inability to obtain large quantities of detailed thermal comfort labeling data from residents presents a substantial challenge to the modeling endeavor. This paper proposes a building-to-building transfer learning framework to make deep learning models applicable in data-limited interior building environments, thereby resolving the issue and enhancing model predictive performance. The transfer learning method (TL) is applied to a novel technology dubbed the Transformer model, which has demonstrated outstanding performance in data trend prediction. The model exploits the spatiotemporal relationship of data regarding thermal comfort. Experiments are conducted using the source dataset (Scales project dataset and ASHRAE RP-884 dataset) and the target dataset (Medium US office dataset), and the results show that the proposed TL-Transformer achieves 62.6% accuracy, 57% precision, and a 59% F1 score, and the prediction performance is better than other existing methods. The model is useful for predicting indoor thermal comfort in buildings with limited data, and its validity is verified by experimental results. [ABSTRACT FROM AUTHOR]

Published

2023

50. Indoor Climate Monitoring in Office Buildings—Comparative Analysis of Two Office Buildings without Air Conditioning.

Author

Voss, Karsten, Voß, Tjado, and Kaliga, Marvin

Subjects

*AIR conditioning, *AIR quality, *POWER resources, *INDOOR air quality, *COMPARATIVE studies

Abstract

Against the background of climate protection and the rising costs of a fossil-fuel-based energy supply, the interest in the energy performance and indoor climate of buildings in real operation is rising. This paper, therefore, deals with the indoor climate investigation of two medium-sized office buildings in Germany by taking measurements over a whole year. These relate to one new building and one refurbished building. Sensors of various types were installed and operated in a large number of office rooms, so that in total results are available for over 100 rooms, typically occupied by one or two persons. The analysis focuses on the indoor temperature in summer and the air quality in winter based on the CO2 concentration. The comfort classes according to DIN EN 16798 including the adaptive comfort approach are used as a basis to cluster the results. Both buildings have movable sun protection and openable windows but no facilities for active cooling. They, thus, represent a large number of existing 'low tech' office buildings in Germany and central Europe. The results reflect the respective building concepts but also show a wide range between the rooms due to the user preferences and behaviour. The refurbished building shows better results, especially in terms of air quality but also in terms of summer room temperatures. This underlines the benefit of the targeted measures as a result of an analysis of the deficits in the existing building before the refurbishment. The additional measures for decentralised mechanical ventilation and passive cooling are having positive effects. As part of the projects, further measures to improve the indoor climate were investigated in both buildings. In one case, this involved CO2 traffic lights to stimulate personal window ventilation in winter, and in the other, the use of newly developed individual ceiling fans supports convective heat dissipation on the human body during hot spells in summer. The positive effect could be demonstrated for both measures. [ABSTRACT FROM AUTHOR]

Published

2023