Investigation of the current management agreement between the Illinois Sports Facilities Authority and the Chicago White Sox : report.

"November 1989."

Analysis and improvement of the envelope, heating and ventilation of a low energy building with district heating

In this thesis project, a building in Vegagatan 12, Gävle has been analysed in order to see why it does consume more energy than it was expected. This building is a low energy building certified by Miljöbyggnad and it should use less than 55kWh/m2 year and nowadays it is using 62.23 kWh/m2. To get the needed data, some information about the building has been gathered, some measurements have been done in the building and some calculations have been done with those measurements. Finally, some possible solutions have been offered to reduce the energy use of the building. Insulating the floor, the pipes and the walls, reducing the indoor temperature in winter... All of these changes need the help of environmentally friendly attitudes, which is a very important fact in low energy buildings.

Projecte d’instal·lacions d’un club esportiu

Aquest projecte desenvolupa el càlcul de les instal·lacions d’un club esportiu.Un dels objectiu es poder comprovar el correcte dimensionament de les instal·lacionsactuals, degut a que les instal·lacions han sofert múltiples modificacions respecte alque es va preveure originalment. També s’ aprofita per realitzar uns plànols actualitzat de les instal·lacions

Projecte d'instal·lació d'un mòdul autònom per producció de calefacció amb caldera de biomassa

L’Ajuntament d’un municipi de la comarca de la Selva disposa d’un complex esportiuformat per un edifici amb piscines climatitzades i un pavelló d’esports. Actualment laproducció de calefacció es realitza mitjançant calderes amb cremador de gasoil. Degut al’antiguitat d’aquests equips, a l’elevat cost que suposa la producció amb aquest tipus decombustible i tenint en compte que el municipi no disposa de xarxa de distribució de gasciutat, l’ajuntament contempla la possibilitat d’instal•lar un sistema de producciócentralitzat amb caldera de biomassa.L’objecte d’aquest projecte és el disseny i definició de la instal•lació d’una caldera deproducció d’aigua calenta sanitària i de calefacció mitjançant l’ús de biomassa tipuspellets de fusta integrada dins un mòdul prefabricat que inclou la sitja d’emmagatzematgei tots els elements necessaris, formant un sistema compacte i autònom per alsubministrament i distribució de l’aigua calenta per als dos edificis que formen el complexesportiu de la población. L’àmbit d’aplicació d’aquest projecte és:- Disseny i implantació del Mòdul autònom de producció de calefacció- Dimensionat dels circuits hidràulics de distribució a punts deCom a punt de partida per dimensionar la nova instal•lació de producció s’han tingut encompte les potències instal•lades actuals però també s’han realitat els càlculs de lesnecessitats actuals tenint en compte les exigències del nou Reglament d’Instal•lacionsTèrmiques en els Edificis (RITE 2007) quant a condicions interiors i d’estalvi energètic

Projecte d’instal·lacions d’un club esportiu

Aquest projecte desenvolupa el càlcul de les instal·lacions d’un club esportiu. Un dels objectiu es poder comprovar el correcte dimensionament de les instal·lacions actuals, degut a que les instal·lacions han sofert múltiples modificacions respecte al que es va preveure originalment. També s’ aprofita per realitzar uns plànols actualitzat de les instal·lacions

The Heating and ventilating magazine.

Published by: National Trade Journals, -1929.

A practical treatise on gas and ventilation, with special relation to illuminating, heating and cooking by gas. Including scientific helps to engineer-students and others.

Mode of access: Internet.

Planning and design of outdoor sports facilities /

"Matching funds were obtained from the Departments of the Navy and the Air Force."

Mechanical refrigeration and ventilation in cold-storage facilities.

"August 1982."

Home Tightening, Insulation and Ventilation, 2011

The average Iowa family spends more than half of its annual household energy bill on heating and cooling. That’s a significant number, but you can dramatically reduce these costs—up to 20 percent, according to ENERGY STAR®—by making some simple energy-saving weatherization and insulation improvements to your home. In addition—with a little attention to proper ventilation—you can protect your home from moisture damage year-round, reduce problems caused by ice dams on the roof during the winter and significantly cut summer cooling costs. As a bonus, these projects can extend the life of your home and may increase the resale value of your property. If you like to fix things around the house, you can handle many of the projects suggested in this book and make the most of your energy-improvement budget. However, don’t hesitate to call a professional for help if you’d rather not do the work yourself; the dollars gained through energy savings in upcoming years will be worth the expense.

Effect of mountain breeze in ventilating the city under calm and neutral atmospheric environment: Interaction of airflow structures and ventilation efficiency

Many modern cities locate in the mountainous areas, like Hong Kong, Phoenix City and Los Angles. It is confirmed in the literature that the mountain wind system developed by differential heating or cooling can be very beneficial in ventilating the city nearby and alleviating the UHI effect. However, the direct interaction of mountain wind with the natural-convection circulation due to heated urban surfaces has not been studied, to our best knowledge. This kind of unique interaction of two kinds of airflow structures under calm and neutral atmospheric environment is investigated in this paper by CFD approach. A physical model comprising a simple mountain and three long building blocks (forming two street canyons) is firstly developed. Different airflow structures are identified within the conditions of different mountain-building height ratios (R=Hm/Hb) by varying building height but fixing mountain height. It is found that the higher ventilation rate in the street canyons is expected in the cases of smaller mountain-building ratios, indicating the stronger natural convection due to increasing heated building surfaces. However, there is the highest air change rate (ACH) in the lowest-building-height case and most of the air is advective into the street canyon through the top open area, highlighting the important role played by the mountain wind. In terms of the ventilation efficiency, it is shown that the smallest R case enjoys the best air change efficiency followed by the highest R case, while the worst ventilative street canyons occur at the middle R case. In the end, a gap across the streets is introduced in the modeling. The existence of the gap can greatly channel the mountain wind and distribute the air into streets nearby. Thus the ACH can be doubled and air quality can be significantly improved.

Energy efficient and economic renovation of residential buildings with low-temperature heating and air heat recovery

With the building sector accounting for around 40% of the total energy consumption in the EU, energy efficiency in buildings is and continues to be an important issue. Great progress has been made in reducing the energy consumption in new buildings, but the large stock of existing buildings with poor energy performance is probably an even more crucial area of focus. This thesis deals with energy efficiency measures that can be suitable for renovation of existing houses, particularly low-temperature heating systems and ventilation systems with heat recovery. The energy performance, environmental impact and costs are evaluated for a range of system combinations, for small and large houses with various heating demands and for different climates in Europe. The results were derived through simulation with energy calculation tools. Low-temperature heating and air heat recovery were both found to be promising with regard to increasing energy efficiency in European houses. These solutions proved particularly effective in Northern Europe as low-temperature heating and air heat recovery have a greater impact in cold climates and on houses with high heating demands. The performance of heat pumps, both with outdoor air and exhaust air, was seen to improve with low-temperature heating. The choice between an exhaust air heat pump and a ventilation system with heat recovery is likely to depend on case specific conditions, but both choices are more cost-effective and have a lower environmental impact than systems without heat recovery. The advantage of the heat pump is that it can be used all year round, given that it produces DHW. Economic and environmental aspects of energy efficiency measures do not always harmonize. On the one hand, lower costs can sometimes mean larger environmental impact; on the other hand there can be divergence between different environmental aspects. This makes it difficult to define financial subsidies to promote energy efficiency measures.

Environmental readiness document : solar heating and cooling of buildings /

September 1979.

Transactions of the American Society of Heating and Ventilating Engineers.

Mode of access: Internet.

A popular treatise on the warming and ventilation of buildings; showing the advantages of the improved system of heated water circulation, &c. ...

Mode of access: Internet.