Wyniki wyszukiwania - BazTech

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Modeling of a tall building

Mlonek Sandra

Inżynieria Bezpieczeństwa Obiektów Antropogenicznych

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2022

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Nr 3

42--47

EN

Rapid economic, environmental changes and finite energy resources dictate the need for rational use of energy. Civil engineering is the sector responsible for the highest energy consumption. Therefore, efforts should be made to reduce the energy consumption of construction works in progress. An indispensable factor of development is the introduction of modern technologies. Contemporary architectural thought aiming at increasing the share of transparent facades may be helpful in achieving these goals. This is an important aesthetic aspect. Large panes of glass give the building a modern character, but also visually increase the space and passively allow you to acquire large amounts of heat. Despite the difficulties and costs associated with the construction and operation of high-rise buildings, they are erected more and more often, also in Poland. Modern technology and advanced calculation theory make it possible to build these structures much more economically than previous conventional systems. In this paper, I present a variant static analysis of a tall building structure with large glazing.

2

Design of joints of thin sheet parts with mechanical connections (according to EN 1993-1-3)

Broniewicz Mirosław, Mlonek Sandra, Szeląg Romuald

Inżynieria Bezpieczeństwa Obiektów Antropogenicznych

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2021

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Nr 4

19--27

EN

The main direction of development of steel building structures is to reduce the cost of implementation of buildings without changing their load-bearing capacity and value in use. Therefore, an essential factor in the development is the introduction of modern technologies. Solutions from other industries such as automotive or aerospace, have been adapted to perform building structures. As a result, today in the construction industry we use lightweight steel profiles from cold-bent elements. Modern technology and advanced calculation theory make it possible to build these structures much more economically than previous conventional systems. Elements and products made of thin sheets allow to reduce costs of construction, but at the same time is associated with the possibility of defects resulting in the appearance of a state of failure of structural elements or the entire facility. Connection zones of thin-walled elements are always the critical points, hence the need for a particularly thorough assessment at the design stage, and then at the implementation of the investment. Correct application of the presented calculation procedure in article will allow the design and realization of modern structures, which will be durable and safe in operation for the expected period of time.

3

Analiza wpływu dodatku wodoru do gazu ziemnego na szczelność połączeń mechanicznych wybranych elementów sieci i instalacji gazowych

Szewczyk Piotr, Jaworski Jacek

Prace Naukowe Instytutu Nafty i Gazu

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2020

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nr 231

1--134

PL

Jednym ze sposobów wykorzystania energii elektrycznej pozyskiwanej z odnawialnych źródeł energii jest produkcja wodoru, który w wyniku spalania wytwarza jedynie parę wodną. Dodanie wodoru do gazu ziemnego, a następnie jego spalanie, będzie powodowało mniejszą emisję dwutlenku węgla, sprawiając, że paliwo to stanie się bardziej przyjazne środowisku. Wodór dodawany do gazu ziemnego może być przesyłany gazociągami przesyłowymi, a następnie poprzez sieci dystrybucyjne docierać do odbiorców przemysłowych i indywidualnych. Ze względu na znacznie mniejszą gęstość wodoru od gazu ziemnego istotne jest zachowanie szczelności połączeń mechanicznych elementów sieci i instalacji gazowych. W publikacji przedstawiono wyniki prowadzonych w INiG – PIB badań wpływu dodatku wodoru do gazu ziemnego na szczelność połączeń wybranych elementów instalacji i sieci gazowych. Według opracowanej metodyki przeprowadzono badania wybranych elementów sieci i instalacji gazowej, w których połączenia wykonywane były różnymi metodami oraz z zastosowaniem różnorodnych materiałów uszczelniających. Na podstawie przeprowadzonych badań i analizy ich wyników stwierdzono, że dodatnie 15% wodoru do metanu nie spowodowało nieszczelności łączonych elementów. Ponadto stwierdzono, że w przypadku wystąpienia nieszczelności w elementach instalacji czy sieci gazowej mieszanka metanu z wodorem będzie wypływała szybciej niż gaz ziemny i w zamkniętych pomieszczeniach może powodować osiągnięcie w krótszym czasie dolnej granicy wybuchowości.

XX

One of the ways to use electrical energy obtained from renewable energy sources is hydrogen production, which produces only energy and water vapour when burned. Adding hydrogen to natural gas and burning it will lower carbon dioxide emission, making this fuel more eco-friendly. Hydrogen added to natural gas can be transported using gas transmission pipelines and can then be provided to industrial and individual consumers via a distribution pipeline network. Due to the much lower density of hydrogen compared to natural gas, it is especially important to maintain the tightness of mechanical connections of network elements and gas installations. This publication presents the results of research carried out at the Oil and Gas Institute-National Research Institute on the influence that adding hydrogen to natural gas has on the tightness of connections of selected elements of gas installations and networks. According to the developed methodology, tests were performed on selected elements of gas networks and gas installations, in which joints were made using differing methods and using various sealing materials. In the case of steel pipes used in gas installations in buildings, joined by means of threaded connections with tightness obtained on the thread, the test samples were prepared with the use of linen hemp with sealing paste, Teflon tapes and threads, and anaerobic adhesives. Samples made of copper pipes were joined with press fittings. Other installation elements - such as flexible hoses, both extensible and non-extensible, and metal hose assemblies - were attached by means of threaded connections with tightness obtained beyond the thread; the sealing material was NBR rubber gaskets and klingerite. The gas network elements were connected by means of threaded connections with hemp and sealing paste, flare fittings, and steel and polyethylene flanges (sealing with a flat gasket made of NBR and klingerite). PE/Steel connectors where also tested. The tests included tightness tests of the prepared samples with the use of methane, and then a mix of 85% methane and 15% hydrogen. The tests on samples with simulated leaks were also performed. Based on the tests and the analysis of the results, it was found that adding the hydrogen to the methane did not cause leaks in the joined elements. In addition, it was found that in the case of leaks appearing in elements of installations or gas networks, the methane-hydrogen mixture flows out faster than methane alone, and in closed rooms this may result in the lower explosion limit being reached in a shorter time.