Gas Temperature Rise in a High-Pressure Gas Tube by an Adiabatic Compression

Combustion chamber wall heat transfer is a major contributor to efficiency losses in diesel engines. In this context, thermal swing materials (adapting to the surrounding gas temperature) have been pinpointed as a promising mitigative solution. In this study, experiments are carried out in a high-pressure/high-temperature vessel to (a) characterise the wall heat transfer process ensuing from wall impingement of a combusting fuel spray, and (b) evaluate insulative improvements provided by a coating that promotes thermal swing. The baseline experimental condition resembles that of Spray A from the Engine Combustion Network, while additional variations are generated by modifying the ambient temperature as well as the injection pressure and duration. Wall heat transfer and wall temperature measurements are time-resolved and accompanied by concurrent high-speed imaging of natural luminosity. An investigation with an uncoated wall is carried out with several sensor locations around the stagnation point, elucidating sensor-to-sensor variability and setup symmetry. Surface heat flux follows three phases: (i) an initial peak, (ii) a slightly lower plateau dependent on the injection duration, and (iii) a slow decline. In addition to the uncoated reference case, the investigation involves a coating made of porous zirconia, an established thermal swing material. With a coated setup, the projection of surface quantities (heat flux and temperature) from the immersed measurement location requires additional numerical analysis of conjugate heat transfer. Starting from the traces measured beneath the coating, the surface quantities are obtained by solving a one-dimensional inverse heat transfer problem. The present measurements are complemented by CFD simulations supplemented with recent rough-wall models. The surface roughness of the coated specimen is indicated to have a significant impact on the wall heat flux, offsetting the expected benefit from the thermal swing material.

Download Full-text

High pressure measurements in phospholipid bilayers using adiabatic compression

The Journal of Chemical Physics ◽

10.1063/1.443733 ◽

1982 ◽

Vol 77 (11) ◽

pp. 5766-5770 ◽

Cited By ~ 32

Author(s):

Ned D. Russell ◽

Peter J. Collings

Keyword(s):

High Pressure ◽

Phospholipid Bilayers ◽

Adiabatic Compression ◽

Pressure Measurements

Download Full-text

Harvesting the Potential of CO2 before it is Injected into Geological Reservoirs

Journal of Energy and Power Technology ◽

10.21926/jept.2104050 ◽

2021 ◽

Vol 3 (4) ◽

pp. 1-1

Author(s):

Tran X Phuoc ◽

◽

Mehrdad Massoudi ◽

Keyword(s):

High Pressure ◽

Mechanical Work ◽

Lower Pressure ◽

Co2 Injection ◽

Gas Temperature ◽

Expansion Valve ◽

Useful Power ◽

Turbine Disks ◽

Pressure Transport ◽

The Cost

To store CO2 in geological reservoirs, expansion valves have been used to intentionally release supercritical CO2 from high-pressure containers at a source point to lower-pressure pipelines and transport to a selected injection site. Using expansion valves, however, has some shortcomings: (i) the fluid potential, in the form of kinetic energy and pressure which can produce mechanical work or electricity, is wasted, and (ii) due to the Joule-Thomson cooling effect, the reduction in the temperature of the released CO2 stream might be so dramatic that it can induce thermal contraction of the injection well causing fracture instability in the storage formation. To avoid these problems, it has been suggested that before injection, CO2, should be heated to a temperature slightly higher than that of the reservoir. However, heating could increase the cost of CO2 injection. This work explores the use of a Tesla Turbine, instead of an expansion valve, to harvest the potential of CO2, in the form of its pressure and kinetics, to generate mechanical work when it is released from a high-pressure container to a lower-pressure transport pipeline. The goal is to avoid throttling losses and to produce useful power because of the expansion process. In addition, due to the friction between the gas and the turbine disks, the expanded gas temperature reduction is not as dramatic as in the case when an expansion valve is used. Thus, as far as CO2 injection is concerned, the need for preheating can be minimized.

Download Full-text

Analisis Pengaruh High Pressure Compressor Rotor Clearance Terhadap Exhaus Gas Temperature Margin pada CFM56-7

Jurnal Teknologi Kedirgantaraan ◽

10.35894/jtk.v6i2.35 ◽

2021 ◽

Vol 6 (2) ◽

pp. 50-55

Author(s):

Wildan Sofary Darga ◽

Edy K. Alimin ◽

Endah Yuniarti

Keyword(s):

High Pressure ◽

Engine Performance ◽

Exhaust Gas ◽

Gas Temperature ◽

Compressor Rotor ◽

High Pressure Compressor ◽

The Difference ◽

Gas Turbine Exhaust ◽

Temperature Margin ◽

Pressure Compressor

Exhaust Gas Temperatue is an parameter where the hot gases’s temperature leave the gas turbine. Exhaust gas temperature margin is the difference between highest temperature at take off phase with redline on indicator (???????????? ???????????????????????? °????=???????????? ????????????????????????????−???????????? ???????????????? ????????????). EGTM is one of any factor to determine engine performance. A good perfomance of an engine when it has a big margin (EGTM), during operation of an engine the EGTM could decrease untill 0 (zero). So many factors could affect EGTM deteroration there are: distress hardware such as airfoil erosion, leak of an airseals, and increase of clearance between tip balde and shroud. Increase of clearance happens in high pressure compressor rotor clearance. In CFM56-7 have 9 stage(s) of high pressure compressor and each stage give the EGT Loses. The calculation of EGT Effect/Losses is actual celarance – minimum clearance x 1000 x EGT Effect °C, where actual clearance define by the substraction of outside diameter’s rotor with inside diameter’s shroud, minimum clearance define in the manual, 1000 is adjustment from mils/microinch to inch, and EGT Effect is temperature that define in the manual. The analysist had done with 6 (six) engine serial number and proceed by corelation that shown linkage between clearance and EGT Effect, the corelation is strong shown the result of corelation (r) is 0.994275999 or nearest 1.

Download Full-text

Application of Ultra-Low NOx Combustor to the MHPS Existing Gas Turbine

10.1115/gt2021-02403 ◽

2021 ◽

Author(s):

Takashi Nishiumi ◽

Hirofumi Ohara ◽

Kotaro Miyauchi ◽

Sosuke Nakamura ◽

Toshishige Ai ◽

...

Keyword(s):

High Pressure ◽

Gas Turbine ◽

Gas Turbines ◽

Combined Cycle ◽

Inlet Temperature ◽

Operational Experience ◽

Emission Rates ◽

Gas Temperature ◽

Design Development ◽

And Control

Abstract In recent years, MHPS achieved a NET M501J gas turbine combined cycle (GTCC) efficiency in excess of 62% operating at 1,600°C, while maintaining NOx under 25ppm. Taking advantage of our gas turbine combustion design, development and operational experience, retrofits of earlier generation gas turbines have been successfully applied and will be described in this paper. One example of the latest J-Series technologies, a conventional pilot nozzle was changed to a premix type pilot nozzle for low emission. The technology was retrofitted to the existing F-Series gas turbines, which resulted in emission rates of lower than 9ppm NOx(15%O2) while maintaining the same Turbine Inlet Temperature (TIT: Average Gas Temperature at the exit of the transition piece). After performing retrofitting design, high pressure rig tests, the field test prior to commercial operation was conducted on January 2019. This paper describes the Ultra-Low NOx combustor design features, retrofit design, high pressure rig test and verification test results of the upgraded M501F gas turbine. In addition, it describes another upgrade of turbine to improve efficiency and of combustion control system to achieve low emissions. Furthermore it describes the trouble-free upgrade of seven (7) units, which was completed by utilizing MHPS integration capabilities, including handling all the design, construction and service work of the main equipment, plant and control systems.

Download Full-text

Effect of temperature rise on microstructural evolution during high-pressure torsion

Materials Science and Engineering A ◽

10.1016/j.msea.2017.12.095 ◽

2018 ◽

Vol 714 ◽

pp. 167-171 ◽

Cited By ~ 34

Author(s):

Kaveh Edalati ◽

Yuki Hashiguchi ◽

Pedro Henrique R. Pereira ◽

Zenji Horita ◽

Terence G. Langdon

Keyword(s):

High Pressure ◽

Microstructural Evolution ◽

Temperature Rise ◽

High Pressure Torsion ◽

Effect Of Temperature

Download Full-text

Gas Turbines for Coal-Fired Turbocharged PFBC Boiler Power Plants

Volume 3: Coal, Biomass and Alternative Fuels; Combustion and Fuels; Oil and Gas Applications; Cycle Innovations ◽

10.1115/84-gt-209 ◽

1984 ◽

Author(s):

Richard Wenglarz ◽

Steven Drenker

Keyword(s):

High Pressure ◽

Gas Turbines ◽

Power Plants ◽

Modular Construction ◽

Fluidized Bed Combustion ◽

Gas Temperature ◽

Utility Industry ◽

Advantages And Disadvantages ◽

Construction Methods ◽

Standard Gas

A coal-fired turbocharged boiler using fluidized bed combustion at high pressure would be more compact than a pulverized coal fired boiler. The smaller boiler size could permit the utility industry to adopt efficient modular construction methods now widely used in other industries. A commercial turbocharger of the capacity needed to run a 250 MWe power plant doe not exist; commercial gas turbines of the correct capacity exist, but they are not matched to this cycle’s gas temperature of less than 538°C (1000°F). In order to avoid impeding the development of the technology, it will probably be desirable to use existing machines to the maximum extent possible. This paper explores the advantages and disadvantages of applying either standard gas turbines or modified standard gas turbines to the turbocharged boiler.

Download Full-text

Application of time-division-multiplexed lasers for measurements of gas temperature and CH_4 and H_2O concentrations at 30 kHz in a high-pressure combustor

Applied Optics ◽

10.1364/ao.49.004963 ◽

2010 ◽

Vol 49 (26) ◽

pp. 4963 ◽

Cited By ~ 11

Author(s):

Andrew W. Caswell ◽

Thilo Kraetschmer ◽

Keith Rein ◽

Scott T. Sanders ◽

Sukesh Roy ◽

...

Keyword(s):

High Pressure ◽

Gas Temperature ◽

Time Division

Download Full-text

Unexpected increase in C5+ selectivity at temperature rise in high pressure Fischer-Tropsch synthesis over Co-Al2O3/SiO2 catalyst

Catalysis Communications ◽

10.1016/j.catcom.2017.05.021 ◽

2017 ◽

Vol 99 ◽

pp. 25-29 ◽

Cited By ~ 5

Author(s):

Alexander P. Savost'yanov ◽

Roman E. Yakovenko ◽

Grigoriy B. Narochniy ◽

Sergey I. Sulima ◽

Vera G. Bakun ◽

...

Keyword(s):

High Pressure ◽

Temperature Rise ◽

Tropsch Synthesis ◽

Fischer Tropsch ◽

Fischer Tropsch Synthesis

Download Full-text

Performance improvement of a 330MWe power plant by flue gas heat recovery system

Thermal Science ◽

10.2298/tsci140104099x ◽

2016 ◽

Vol 20 (1) ◽

pp. 303-314

Author(s):

Changchun Xu ◽

Min Xu ◽

Ming Zhao ◽

Junyu Liang ◽

Juncong Sai ◽

...

Keyword(s):

High Pressure ◽

Power Plant ◽

Flue Gas ◽

Power Output ◽

Heat Recovery ◽

Waste Heat ◽

Gas Temperature ◽

Recovery System ◽

Heat Recovery System ◽

Plant Efficiency

In a utility boiler, the most heat loss is from the exhaust flue gas. In order to reduce the exhaust flue gas temperature and further boost the plant efficiency, an improved indirect flue gas heat recovery system and an additional economizer system are proposed. The waste heat of flue gas is used for high-pressure condensate regeneration heating. This reduces high pressure steam extraction from steam turbine and more power is generated. The waste heat recovery of flue gas decreases coal consumption. Other approaches for heat recovery of flue gas, direct utilization of flue gas energy and indirect flue gas heat recovery system, are also considered in this work. The proposed systems coupled with a reference 330MWe power plant are simulated using equivalent enthalpy drop method. The results show that the additional economizer scheme has the best performance. When the exhaust flue gas temperature decreases from 153? to 123?, power output increases by 6.37MWe and increment in plant efficiency is about 1.89%. For the improved indirect flue gas heat recovery system, power output increases by 5.68MWe and the increment in plant efficiency is 1.69%.

Download Full-text