Autor: Szwaja, M. - Katalog OPAC zbiorów

Skocz do pozycji: 1.

Tytuł:: Thermodynamic analysis of combustion events in the natural gas fuelled SI engine with VVT
Autorzy:: Szwaja, M.
Mazuro, P.
Szwaja, S.
Powiązania:: https://bibliotekanauki.pl/articles/242837.pdf
Data publikacji:: 2018
Wydawca:: Instytut Techniczny Wojsk Lotniczych
Tematy:: internal combustion engine
variable valve timing
heat release rate
IMEP
combustion phases
Opis:: The main aim of the research was to investigate influence of overlap of the natural gas fuelled spark ignited engine on the following parameters: Indicated Mean Effective Pressure (IMEP), heat rate release including combustion phases (ignition lag, main combustion phase). The content of the study includes results from processing in-cylinder pressure measurements, heat release rate analysis, combustion phases, and finally the conclusions. The tests were carried out on the test bed including the single cylinder research engine with a displacement volume of 550 cm3. The engine was equipped with independent cam phasors for both intake and exhaust valves, but for this investigation, the exhaust valve timing was fixed (the exhaust cam centre line was fixed at -95 crank angle (CA) deg before Top Dead Centre) and intake valve timing was changed (the intake cam centre line was varied from 90 to 150 CA deg after Top Dead Centre). The overlap was changed in the range from 85 to 25 CA deg. 8 tests series were performed, each singular series consisted of 300 consecutive engine combustion cycles. As observed, by varying the valve overlap it contributes to significant change in the peak combustion pressure, peak of heat release rate, and combustion phases. Summing up, variable valve timing affects compression and expansion strokes by changing polytropic indexes due to various amounts of exhaust residuals trapped in the cylinder. It affects not only engine volumetric efficiency but also the heat release rate and IMEP, so it does engine performance. Thus, variable valve timing can be considered as valuable tool that can be applied to the natural gas fuelled internal combustion engine.
Źródło:: Journal of KONES; 2018, 25, 4; 421-427
1231-4005
2354-0133
Pojawia się w:: Journal of KONES
Dostawca treści:: Biblioteka Nauki

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Skocz do pozycji: 2.

Tytuł:: New concept of a rocker engine - kinematic analysis
Autorzy:: Szymkowiak, M.
Szwaja, S.
Powiązania:: https://bibliotekanauki.pl/articles/246829.pdf
Data publikacji:: 2012
Wydawca:: Instytut Techniczny Wojsk Lotniczych
Tematy:: rocker
engine
kinematics
piston motion
Opis:: The paper presents concept and design of a four-stroke 4-cylinder internal combustion engine consisted of a single connecting rod to a crankshaft and four additional rods joining pistons with a rocker. The rocker is a specific element in the engine construction that makes this engine different from the typical reciprocating internal combustion piston engine. Furthermore, kinematical analysis of this piston - rocker - crankshaft mechanism was conducted. As concluded from the analysis, this mechanism implemented to the engine, provides several advantages with respect to both dynamic and thermodynamic related issues. First of all, a profile of the piston motion can be easily changed with change in the mechanism geometry e.g. major dimensions of connecting rods, the rocker etc. Thus, the piston motion profile can be asymmetrical with slow motion to and relatively fast distancing from the TDC. This feature can be useful in reducing thermal losses to an engine cooling system. Additionally, the mechanism characterizes itself with low transverse force from the piston, which acts on a cylinder liner. As a result, it significantly reduces frictional losses and should increase the overall efficiency of the engine. Among disadvantages, higher inertial forces are the most important problem. As analyzed, the rocker is the main component that contributes to increase in inertial forces by approximately three to four times. On the other hand, total inertia forces, due to specific kinematical chain of the mechanism, can be remarkably reduced in case the mechanism is correctly optimized.
Źródło:: Journal of KONES; 2012, 19, 3; 443-449
1231-4005
2354-0133
Pojawia się w:: Journal of KONES
Dostawca treści:: Biblioteka Nauki

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Skocz do pozycji: 3.

Tytuł:: Flame propagation in gas feeding pipelines to the IC engine
Autorzy:: Gruca, M.
Szwaja, S.
Pyrc, M.
Powiązania:: https://bibliotekanauki.pl/articles/242810.pdf
Data publikacji:: 2018
Wydawca:: Instytut Techniczny Wojsk Lotniczych
Tematy:: flame propagation
laminar flame speed
methane
hydrogen
combustion
Opis:: Results from experimental investigation on flame propagation in a pipeline filled with gaseous combustible mixture consisted of hydrogen, methane or 20% hydrogen-methane is presented in the article. The mixture was prepared in separate cylinders and premixed before filling the pipeline. The tests were conducted under various relative equivalence ratio – lambda from 1.0 to 3.0 at pressure of 1 bar and temperature of 25ºC. Hydrogen and methane were selected because these gases are main combustible fractions in several gaseous engine fuels (e.g. natural gas, syngas, biogas). Additionally, the mixture 20% hydrogen and methane, as potential engine fuel, was also under investigation. Flame front was detected with aid of IR photodetectors. Hence, the flame speed was resulted from distance divided by time. As observed, the flame propagation speed was over 100 m/s for both hydrogen and methane premixed mixtures. It was several times higher if compared with the laminar flame speed for these gases. It can be explained by additional acoustic effects (standing waves) taking place inside the pipeline. Results from this investigation can be useful in design and construction of the gas feeding system in the gas fuelled internal combustion engine.
Źródło:: Journal of KONES; 2018, 25, 3; 205-212
1231-4005
2354-0133
Pojawia się w:: Journal of KONES
Dostawca treści:: Biblioteka Nauki

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Skocz do pozycji: 4.

Tytuł:: Dual-fuel hydrogen-diesel compression ignition engine
Dwupaliwowy silnik wysokoprężny zasilany olejem napędowym i wodorem
Autorzy:: Borecki, R.
Szwaja, S.
Pyrc, M.
Powiązania:: https://bibliotekanauki.pl/articles/241801.pdf
Data publikacji:: 2008
Wydawca:: Instytut Techniczny Wojsk Lotniczych
Tematy:: dwupaliwowy silnik spalinowy
olej napędowy
wodór
internal combustion engine
dual fuel
diesel
hydrogen
Opis:: Od wielu lat w ośrodkach naukowych na całym świecie prowadzone są badania nad zasilaniem wodorem silników pojazdów mechanicznych. Prowadzone są także próby spalania wodoru w silniku dwupaliwowym zasilanym dodatkowo olejem napędowym. W Instytucie Maszyn Tłokowych i Techniki Sterowania Politechniki Częstochowskiej zbudowano stanowisko badawcze umożliwiające spalanie wodoru w silniku wysokoprężnym, który był dodatkowo zasilany olejem napędowym wtryskiwanym bezpośrednio do cylindra. Natomiast wodór doprowadzany był do silnika poprzez układ wtryskowy zamontowany na kolektorze dolotowym lub poprzez mieszalnik. Stanowisko zbudowano na bazie silnika wysokoprężnego firmy DEUTZ typ FL511 napędzającego prądnicę synchroniczną o mocy 20 kVA. W artykule przedstawiono przykładowe wyniki eksperymentalne badań silnika zasilanego dwupaliwowo olejem napędowym i wodorem o proporcji 50/50% pod względem udziału energetycznego oraz silnika zasilanego wyłącznie wodorem, którego zapłon inicjowany był samoczynnie. Wyniki badań przedstawiają przebiegi ciśnienia w cylindrze, składową zmienną tego ciśnienia, rozkłady statystyczne położenia 10, 50 i 90% spalonego ładunku (MFB) oraz charakterystykę spalania stukowego.
Investigation on a hydrogen fuelled engine has been conducted all over the world for several years. Hydrogen-diesel bi- fuelling application to a compression ignition (CI) engine is also of the interest. A test bed, which provides opportunities for both hydrogen combustion and diesel-hydrogen co-combustion research in the CI engine, has been built in the Institute of Internal Combustion Engines and Control Engineering of Czestochowa University of Technology. A classic direct injection system has been applied for fuelling the engine. Hydrogen can be delivered to the engine combustion chamber in two different ways: by a port fixed hydrogen injector or by a mixer, installed in the inlet manifold just pass the injector. Main parts of the test bed are as follows: 2 in-line air-cooled compression ignition (CI) engine FL511 made by Deutz and a synchronous generator of power output of 20 kVA. Tests were carried out for the hydrogen fuelled engine. Hydrogen was self-ignited due to high compression ratio of the engine. Additionally, there were tests of combustion of hydrogen, ignited by a diesel dose directly injected into the cylinder under proportion of 50/50% concerning energy share of the ach fuel. The research, presented in the paper, contains results of in-cylinder pressure analysis with respect to combustion knock intensity and mass fraction burnt (MFB) location against crank angle. There is also comparison made between these two tests and the test conducted for an original diesel engine.
Źródło:: Journal of KONES; 2008, 15, 4; 49-56
1231-4005
2354-0133
Pojawia się w:: Journal of KONES
Dostawca treści:: Biblioteka Nauki

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Skocz do pozycji: 5.

Tytuł:: Combustion of RME – diesel and NExBTL – diesel blends with hydrogen in the compression ignition engine
Autorzy:: Juknelevičius, R.
Szwaja, S.
Pyrc, M.
Gruca, M.
Pukalskas, S.
Powiązania:: https://bibliotekanauki.pl/articles/247823.pdf
Data publikacji:: 2018
Wydawca:: Instytut Techniczny Wojsk Lotniczych
Tematy:: hydrogen
RME
HVO
NExBTL
PRO Diesel
diesel fuel
CI engine
combustion
emission
Opis:: The article presents the test results of the single cylinder compression ignition engine with common rail injection system operating on biofuels and conventional diesel blends with hydrogen. Two types of liquid fuels were tested: blend of the 7% Rapeseed Methyl Ester (RME) with conventional diesel fuel and Neste Pro Diesel – blend of the 15% Hydrotreated Vegetable Oil (HVO), produced by Neste Oil Corporation with conventional diesel fuel. The purpose of this investigation was to examine the influence of the hydrogen addition to biofuels and diesel blends on combustion phases, autoignition delay, engine performance efficiency and exhaust emissions. Hydrogen fraction was changed within the range from 0 to 43% by energy. Hydrogen was injected into the intake manifold, where it created homogeneous mixture with air. Tests were performed at both fixed and optimal injection timings at low, medium, and nominal engine load. After analysis of the engine bench tests and simulation with AVL BOOST software, it was observed that increasing hydrogen fraction shortened the fuel ignition delay phase and it affected the main combustion phase. Moreover, decrease of carbon monoxide (CO), carbon dioxide (CO2) and smoke opacity was observed with increase of hydrogen amounts to the engine. However, increase of the nitrogen oxide (NOx) concentration in the engine exhaust gases was observed.
Źródło:: Journal of KONES; 2018, 25, 3; 261-274
1231-4005
2354-0133
Pojawia się w:: Journal of KONES
Dostawca treści:: Biblioteka Nauki

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Skocz do pozycji: 6.

Tytuł:: Torgas condensate combustion in the SI engine
Autorzy:: Chwist, M.
Szwaja, S.
Grab-Rogaliński, K.
Poskart, A.
Powiązania:: https://bibliotekanauki.pl/articles/949504.pdf
Data publikacji:: 2018
Wydawca:: Instytut Techniczny Wojsk Lotniczych
Tematy:: SI engine
butanol
bio-oil
torgas condensate
exhaust emission
torrefaction
Opis:: The article presents results from IC engine tests on combustion of alcohol fuel with the addition of torgas condensate. Torgas is a by-product created from the torrefaction of Sida hermaphrodita. It was obtained from torrefaction carried out at a temperature of 400°C. Torgas was condensed in a tubular cooler. The basic fuel was butanol. This fuel was chosen, because regular hydrocarbon based fuels got delaminated while blended with torgas condensate. The condensate dissolves in alcohol therefore the choice was justified. In the mixture, the volume ratio of alcohol to condensate was 4:1. The combustion was carried out in a spark-ignition, single-cylinder engine with a cubic capacity of 650 cm3. The engine was able to vary its compression ratio. The engine worked at full load at maximum open throttle. The engine body was heated to a temperature of 95°C and this temperature was maintained throughout the testing period. The engine was running at 850 rpm. The first stage of the experiment included determination of the optimal ignition angle for butanol as a reference fuel and for a mixture of butanol and torgas condensate. The optimal spark angle was estimated based on the maximum indicated work. Three compression ratios, i.e.: CR=8.8, 10 and 11.2 were used. All tests were performed for a stoichiometric air fuel ratio. The obtained in-cylinder pressure diagrams for the reference fuel and the fuel with the addition of condensate were compared with each other. The rate of pressure increase inside the cylinder was calculated. For all tests, the following exhaust components were measured: CO2, CO and HC.
Źródło:: Journal of KONES; 2018, 25, 3; 33-38
1231-4005
2354-0133
Pojawia się w:: Journal of KONES
Dostawca treści:: Biblioteka Nauki

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