Design Analysis of Furnace Of A Steam Generator

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Design Analysis of Furnace Of A Steam Generator P M V Subbarao Professor Mechanical

Design Analysis of Furnace Of A Steam Generator P M V Subbarao Professor Mechanical Engineering Department Perfection of Primary Cause for All that Continues…. .

Basic Anatomy of A SG Convection Pass Transfer only Furnace Creation, Generation & Transfer

Basic Anatomy of A SG Convection Pass Transfer only Furnace Creation, Generation & Transfer of Thermal Energy

Details of Basic Processes • Flow of Air and Prepared Fuel – Fluid Dynamics.

Details of Basic Processes • Flow of Air and Prepared Fuel – Fluid Dynamics. • Generation of Thermal Energy – Using Natural Resources. – Combustion Sciences. • Transfer of Thermal Energy to working fluid. – Science of Heat Transfer.

Aerodynamics Dynamics of Stationary Flame • • Along local Normal to Flame Surface: Burning

Aerodynamics Dynamics of Stationary Flame • • Along local Normal to Flame Surface: Burning Velocity > Flow Velocity : Flash Back Limit Burning Velocity < flow Velocity : Blow Off Limit Burning Velocity = Flow Velocity : Stable Flame. g n i n lo e V y t i c r u B Air Fuel Flow velocity

Stability & Flammability Limits Fuel Flow rate Rich Mixture Flash Back Stable Flame Lean

Stability & Flammability Limits Fuel Flow rate Rich Mixture Flash Back Stable Flame Lean Mixture Air Flow rate Blow off

Burning Velocity & Residence Time • Quality of Fuel & Fuel Chemistry. • Air-fuel

Burning Velocity & Residence Time • Quality of Fuel & Fuel Chemistry. • Air-fuel ratio • Turbulence level • Time to be spent by fuel particle in the furnace before it burns completely. • Residence time is inversely proportional to burning velocity. • Fuel particle is continuously moving. • The distance traveled by the fuel particle should be much larger than furnace height. • Swirl motion will ensure the required residence time. • Internally generated swirl : Swirl Burners. • Externally generated swirl: Direct Burners.

Basics of Coal Combustion: Burning Time Coal is a complex organic polymer consisting of

Basics of Coal Combustion: Burning Time Coal is a complex organic polymer consisting of large polycyclic aromatic clusters of several fused rings strung together by assorted hydrocarbon chains of varying lengths and other hetroatom (O, N, S) linkages.

Phases of Coal Particle Combustion

Phases of Coal Particle Combustion

Phases of Combustion • The first phase is associated with moisture evolution and occurs

Phases of Combustion • The first phase is associated with moisture evolution and occurs at very low temperatures at about 373 K. • The second phase at a heating rate of 1273 K/sec begins at about 723 K. • This is associated with a large initial evolution of carbon dioxide and a small amount of tar. • The third phase involves evolution of water chemically formed in the range 773 -973 K and carbon dioxide as the other significant product. • The fourth phase involves a final rapid evolution of carbon -containing species such as carbon oxides, tar, hydrogen, and hydrocarbon gases in the temperature range 973 -1173 K. • The fifth phase is the high temperature formation of carbon oxides.

Second Phase of Coal Combustion

Second Phase of Coal Combustion

Final Phase of Coal COmbustion

Final Phase of Coal COmbustion

Modelling of Coal Cloud Combustion

Modelling of Coal Cloud Combustion

Typical Flame Speed of PC. Flame speed m/s 30%VM & 5 % Ash 30%VM

Typical Flame Speed of PC. Flame speed m/s 30%VM & 5 % Ash 30%VM & 15 % Ash 30%VM & 30 % Ash 30%VM & 40 % Ash A/F ratio

Typical Flame Speed of PC. Flame speed m/s 30%VM & 5 % Ash 20%VM

Typical Flame Speed of PC. Flame speed m/s 30%VM & 5 % Ash 20%VM & 5 % Ash 15%VM & 5 % Ash A/F ratio

Heat available for Radiation • Incomplete combustion loss • Unburned Carbon loss • Loss

Heat available for Radiation • Incomplete combustion loss • Unburned Carbon loss • Loss due to slag • Energy brought in by preheated air & fuel.

Combustion Limits on Furnace Design • • The lower limit of the furnace volume

Combustion Limits on Furnace Design • • The lower limit of the furnace volume is dominated by the space required for burning the fuel completely, or to an extent less than the allowable unburned fuel loss. To complete the fuel combustion within the furnace space, the fuel injected into the furnace has to reside there for a certain time longer than some critical time t*r. • The fuel residence time can be estimated by the residence time of the combustion gas produced in the furnace. • An average residence time tr can be proposed.

Intensity of Heat Release Combustion Factor Macro Particles Micro Particles A volumetric combustion intensity,

Intensity of Heat Release Combustion Factor Macro Particles Micro Particles A volumetric combustion intensity, Iv (k. W/m 3) 250 – 750 1500 – 2500 Area Combustion Intensity, IA (k. W/m 2) 300 – 1800 Up to 7500 Coal Firing Density Jf, V ( kg/m 3. hr) 30 – 100 1500 – 3000 Area Firing Density, Jf, A (kg/m 2. hr) 40 – 250 Up to 1000 Air Velocity (m/sec) Up to 0. 5 Up to 20 Exhaust Gas Velocity (m/sec) Up to 3 Up to 20 Combustion time (sec) Up to 5000 ~1 Particle Heating Rate (0 C/sec) <1 10000 Heat Transfer Coefficients (W/m 2 K) ~10 50 – 500 Heat Fluxes to Heat exchange (k. W/m 2) ~ 10 50 – 500

 • Fuel combustion time is mainly dominated by the combustion reaction velocity and

• Fuel combustion time is mainly dominated by the combustion reaction velocity and the rate at which oxygen is supplied into the reaction zone. • The combustion reaction velocity depends on chemical characteristics of the fuel. • Main technical factors that affect the combustion time are: • Combustion characteristics of the fuel. • Mixing characteristics. • Fluid flow characteristics of the furnace. • The combustion time of an oil fuel droplet is generally less than 0. 1 msec. • In the case of coal combustion time is much longer.

Design Constrains: Heat Release Rate • Heat Release Rate per Unit Volume, qv, k.

Design Constrains: Heat Release Rate • Heat Release Rate per Unit Volume, qv, k. W/m 3 • Heat Release Rate per Unit Cross Sectional Area, qa, k. W/m 2 • Heat Release Rate per Unit Wall Area of the Burner Region, qb, k. W/m 2 • The maximum allowable heat flux of the water wall is restricted by its water-side burnout (dryout) heat flux.

Heat available to the furnace • Incomplete combustion loss • Unburned Carbon loss •

Heat available to the furnace • Incomplete combustion loss • Unburned Carbon loss • Loss due to slag • Energy brought in by preheated air & fuel. • A part of this total heat should be absorbed in furnace. • The designer should provide an environment for the same.