Development of technical solutions for optimizing the hydraulic and thermal process circuits of the P-90 heat-recovery boiler used as part of the PGU-450T combined-cycle plant at the severozapadnaya cogeneration station

In the present work a procedure for optimum design of waste heat recovery boiler of a combined cycle power plant has been developed. This method enables the optimization of waste heat recovery boiler independent of the rest of the system and the design thus obtained can directly be employed in an existing plant.

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Influence of the sizes and initial temperature of the drum of a combined-cycle plant’s heat recovery boiler on its stressed state during the startup

Thermal Engineering ◽

10.1134/s0040601511110048 ◽

2011 ◽

Vol 58 (11) ◽

pp. 953-956 ◽

Cited By ~ 1

Author(s):

V. A. Dvoinishnikov ◽

E. A. Popov

Keyword(s):

Stressed State ◽

Heat Recovery ◽

Initial Temperature ◽

Combined Cycle ◽

Heat Recovery Boiler ◽

Recovery Boiler

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Considerations on the Design Principles for a Binary Mixture Heat Recovery Boiler

Journal of Engineering for Gas Turbines and Power ◽

10.1115/1.2906645 ◽

1992 ◽

Vol 114 (4) ◽

pp. 701-706 ◽

Cited By ~ 5

Author(s):

S. S. Stecco ◽

U. Desideri

Keyword(s):

Heat Transfer ◽

Binary Mixture ◽

Binary Mixtures ◽

Heat Recovery ◽

Combined Cycle ◽

Working Fluid ◽

Heat Recovery Boiler ◽

Water Mixture ◽

Volume Viscosity ◽

Recovery Boiler

The use of a binary mixture as a working fluid in bottoming cycles has in recent years been recognized as a means of improving combined cycle efficiency. There is, however, quite a number of studies dealing with components of plants that employ fluids other than water, and particularly binary mixtures. Due to different specific volume, viscosity, thermal conductivity, and Prandtl number, heat recovery boilers designed to work with water require certain modifications before they can be used with binary mixtures. Since a binary mixture is able to recover more heat from the exhaust fumes than water, the temperature difference between the hot and the cold fluids is generally lower over the whole recovery boiler; this necessitates greater care in sizing the tube bundles in order to avoid an excessive heat transfer surface per unit of thermal power exchanged. The aim of this paper is to provide some general criteria for the design of a heat recovery boiler for a binary mixture, by showing the influence of various dimensional parameters on the heat surface and pressure drop both in the cold and the hot side. Heat transfer coefficients and pressure drops in the hot side were computed by means of correlations found in the literature. A particular application was studied for an ammonia-water mixture, used in the Kalina cycles, which represents one of the most interesting binary cycles proposed so far.

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Perancangan turbin uap untuk siklus gabungan

Jurnal POLIMESIN ◽

10.30811/jp.v7i1.1343 ◽

2009 ◽

Vol 7 (1) ◽

pp. 581

Author(s):

Jenne Syarief

Keyword(s):

Heat Recovery ◽

Combined Cycle ◽

Heat Recovery Boiler ◽

Recovery Boiler

Turbin gas beroperasi pada temperatur yang tinggi, sekitar 1100 — 1650”C. Temperatur gas-gas hasil pembakaran pada turbin gas biasanya masih cukup tinggi, sehingga masih mengandung energi yang cukup besar. Energi ini masih bisa dimanfaatkan untuk meningkatkan efisiensi siklus turbin gas sekaligus meningkatkan daya yang dihasilkannya. Salah satu cara untuk memanfaatkan energi ini adalah dengan menggunakan siklus turbin uap. Siklus turbin gas yang dilanjutkan dengan siklus turbin uap disebut sebagai siklus gabungan (Combined Cycle)Pada siklus turbin uap, energi gas-gas hasil pembakaran dimanfaatkan untuk memanaskan uap pada suatu Heat Recovery Boiler. Uap dari Boiler digunakan untuk menggerakkan turbin uap yang selanjutnya akan menjalankan generator. Uap yang dapat dihasilkan oleh Heat Recovery Boiler biasanya memiliki laju aliran massa yang cukup kecil, sehingga daya yang dapat dibangkitkan oleh turbin uap juga akan relatif kecil.Kata kunci: Turbin Uap, Combined Cycle, Siklus Gabungan

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Nuclear Air-Brayton Combined Cycle (NACC) With Natural Gas Peak Power

Volume 2: Reliability, Availability and Maintainability (RAM); Plant Systems, Structures, Components and Materials Issues; Simple and Combined Cycles; Advanced Energy Systems and Renewables (Wind, Solar and Geothermal); Energy Water Nexus; Thermal Hydraulics and CFD; Nuclear Plant Design, Licensing and Construction; Performance Testing and Performance Test Codes ◽

10.1115/power2013-98119 ◽

2013 ◽

Cited By ~ 1

Author(s):

Charles Forsberg ◽

Daniel Curtis

Keyword(s):

High Temperature ◽

Natural Gas ◽

Heat Recovery ◽

Peak Power ◽

Combined Cycle ◽

Operating Conditions ◽

Heat Recovery Boiler ◽

Coated Particle ◽

Recovery Boiler ◽

Base Load

The Fluoride-Salt-Cooled High-Temperature Reactor (FHR) is a new reactor concept that uses the graphite-matrix coated-particle fuel from gas-cooled reactors and a high-temperature liquid salt coolant. The reactor exit temperatures exceed 700°C with reactor inlet temperatures of ∼600°C. Because of these high temperatures the FHR can be coupled to a nuclear air-Brayton combined-cycle (NACC) plant with one or more air-Brayton turbines with hot exhaust directed to a steam recovery boiler. Under normal base-load operating conditions, air is compressed, heated using salt-air heat exchangers, passed through a turbine, and exhausted to a heat recovery boiler, and added electricity is made from the steam that is generated. The NACC can have one or more salt-to-air reheat stages. After air compression and nuclear heating, the hot compressed air is above the auto-ignition temperature of natural gas (NG). Natural gas can be injected to increase gas temperatures and produce peak power. Because the plant operates continuously as a base-load system connected to the grid and there is no need to control the fuel-to-air ratio, the peak power can be varied and increased rapidly. At times of low electricity prices, steam from the heat recovery boiler can be sold to industrial users at lower prices than they can generate it from NG but above its value for electricity generation. The incremental capital cost for peaking capabilities is less than the cost of stand-alone NG plants. There is the potential for the NG-to-electricity efficiencies exceeding those of stand-alone NG plants. These capabilities imply plant revenue 20 to 50% greater than from an equivalent base-load nuclear plant. The market requirements are being assessed to determine the requirements for the FHR and NACC power cycle. As a new-type of plant, much additional work is required to understand the design options and limitations.

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M21 Cruise Marine Combined Cycle Plant

Volume 2: Aircraft Engine; Marine; Microturbines and Small Turbomachinery ◽

10.1115/95-gt-450 ◽

1995 ◽

Author(s):

V. I. Romanov ◽

O. G. Zhiritsky ◽

A. V. Kovalenko ◽

V. V. Lupandin

Keyword(s):

Gas Turbine ◽

Plant Development ◽

Heat Recovery ◽

Waste Heat Recovery ◽

Waste Heat ◽

Combined Cycle ◽

Heat Recovery Boiler ◽

Technical Data ◽

Power Turbine ◽

Combined Cycle Plant

The paper describes M21 cruise marine combined cycle plant for SLAVA class cruisers (COGAG arrangement). Three guided missile cruisers (Figure 1) are powered by these plants (two plants for each cruiser). During this plant development the more strict demands on weight and size had been taken into account as compared with M25 plants for merchant ships. The paper shows technical data of M21 combined cycle plant, descriptions and design features of SPA MASHPROEKT GT 6004R gas turbine with reversible free power turbine, waste-heat recovery boiler, steam turbine with a condenser and a common gear unit. More than 10 year service experience of these plants is shown in this paper.

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