Biomass Gasification By Thermo-Chemical Conversion PDF

Summary

This presentation describes biomass gasification, a thermo-chemical process for converting solid biomass fuels into gaseous fuels like producer gas. It details the various stages, including drying, pyrolysis, oxidation, and reduction. The presentation also covers different types of gasifiers, applications, and limitations of producer gas.

Full Transcript

Fuel Engineering

Biomass Gasification
Thermo-Chemical
Conversion
By

Dr. M. Salman Haider
Biomass Gasification by Thermo-Chemical
Conversion

Objectives

To explore the Biomass Gasification by Thermo-Chemical
Process with the help of chemical reactions
BIOMASS GASIFICATION

Thermo-Chemical Conversion
 Introduction

Gasification is the process in which the supply of oxygen is
controlled and the raw materials are converted into chemical
product called producer gas/ syngas

This process transfers most of the chemically bound energy of
the solid fuel into the gas phase.
The oxygen supply will be 20 to 40 percent of the
stochiometric air requirement.
In combustion process, raw materials are directly converted
into heat energy
In gasification raw materials are converted into an
intermediate chemical product, which constitutes mainly of
carbon monoxide and hydrogen.
 Combustion
Combustion: rapid oxidation of a fuel

Complete combustion: total oxidation of fuel (adequate
supply of oxygen needed)

Air: 20.9% oxygen, 79% nitrogen and other

Nitrogen: (a) reduces the combustion efficiency (b)
forms NOx at high temperatures

Carbon forms (a) CO2 (b) CO resulting in less heat
production
 Gasification

To convert solid carbonaceous fuel (biomass and coal
etc.) into a gaseous mixture i.e. H2, CO CO2 and CH4.

Gasification Steps

Solid
Biomass
or Coal
Liquid
 Gasification

 Gasification means converting solid fuel into gaseous fuel
by Thermo Chemical process.
 Biomass gasification means incomplete combustion of
biomass resulting in production of combustible gases,
consisting of (mainly):

Carbon monoxide, CO,
Hydrogen, H2
Methane, CH4

The mixture is called Producer Gas
 Gasification
The equipment in which the gasification process takes
place it is known as Gasifier.
Gasifiers are used to convert the solid fuel materials into
producer gas.
The calorific value of producer gas is 950-1200 kcal /m3.
(Natural Gas calorific value 37.5-43.0 MJ/m3)
The main components of producer gas are :

Carbon Monoxide (13-19%),
Hydrogen (18-22%),
Carbon Dioxide (9-12%),
Nitrogen (45-55%),
Methane (1-5%)
Water Vapour (4%).

It has the thermochemical conversion efficiency of about 70
 Gasifier

Updraft Gasifier
Gasifier
Thermo-Chemical Process
Gasified Power Generation Systems
Gasified Power Generation Systems
 Thermo-Chemical Process

The solid biomass fuel is subjected to a series of thermochemical
processes like drying, pyrolysis, oxidation and reduction. The
resultant product is producer gas.

Drying Zone
Heat transfer from the lower parts causes drying of feedstock occurs
in this zone.
Biomass + Heat ⇢ Loss of water
 Thermo-Chemical Process

Pyrolysis Zone
At this zone feedstock starts pyrolysing. Large molecules such cellulose,
hemi cellulose and lignin break down into medium size molecules and
char.
Biomass + Heat ⇢ Carbon + Gas (CO, CO2 ,H2 , H2O, CH4 , tar vapors)

Pyrolysis: Pyrolysis is the application of heat to raw biomass, in an absence of
air, so as to break it down into charcoal and various tar gasses and liquids. It is
essentially the process of charring.

*Tar is a dark brown or black viscous liquid of hydrocarbons and free carbon,
obtained from a wide variety of organic materials through destructive
distillation.
 Thermo-Chemical Process
Oxidation Zone
Air is introduced at this zone.
Reaction with oxygen are highly exothermic and result in a sharp
rise of the temperature. Actual combustion of tar and charcoal
takes place producing Carbon Dioxide and Water Vapour and
Nitrogen.

Reduction Zone
The reaction products of the oxidation zone (charcoal and hot
gases) move downward into the reduction zone. Carbon Dioxide is
reduced to form CO and Hydrogen.

3C+2H2O+2CO2 +2H2 + Heat ⇢ 5CO+4H2 +H2O
 Pyrolysis
Biomass begins to rapidly decompose with heat once its temperature
rises above around 240°C.
The biomass breaks down into a combination of solids, liquids and
gasses. The solids that remain commonly; we call charcoal. The gasses
and liquids that are released we collectively call tars.
The gasses and liquids produced during lower temp pyrolysis are
simply fragments of the original biomass that break off with heat.
Pyrolysis is the application of heat to biomass in the absence of
air/oxygen. The volatiles in the biomass are evaporated off as tar gases,
and the fixed carbon-to- carbon chains are what remains— otherwise
known as charcoal.
 Pyrolysis
Pyrolysis: heat from the combustion zone is transferred via
radiation, conduction, and convective hot streams to the
surrounding biomass where oxygen/air is not sufficient or absent.

Due to the heat, pyrolysis occurs to form CO2, CO, CH4, C2H4,
H2O, char (C), and other organic solids and liquids as primary
tar
Pyrolysis Apparatus
 Reduction
Reduction is the process of stripping oxygen atoms off combustion
products of hydrocarbon (HC) molecules, to return the molecules to
forms that can burn again.
Reduction is the direct reverse process of combustion.
Combustion is the combination of combustible gases with oxygen to
release heat, producing water vapor and carbon dioxide as waste
products.
Reduction is the removal of oxygen from these waste products at high
temperatures to produce combustible gases.
Reduction in a gasifier is accomplished by passing carbon dioxide (CO2)
or water vapor (H2O) across a bed of red-hot charcoal (C).
 Reduction

Reduction: after the above two steps, hot reactants react in situ with the
biomass and each other via a series of reactions.

Water-gas reaction: C+H2O+118.5kJ/mol→CO+H2
Methanation reaction: C+2H2→CH4+87.5kJ/mol
Steam reforming methanation: CH4+H2O+206kJ/mol→CO+3H2
Boudouard reaction: C+CO2+159.9kJ/mol→2CO
Reverse water-gas shift reaction: CO2+H2+41.2kJ/mol→H2O+CO
 The Reduction Reactions
It’s the Heart of Gasification
 Limitation of Producer Gas

The main weakness of gasification by oxygen/air is due to a large portion of inert
nitrogen in the agent (79–80%), which makes the resulted syngas diluted.
It can be roughly estimated that syngas from this type of gasification mainly
contains around 30–60% of nitrogen and 10–15% of CO2 since its heating value
is typically between 4 and 6 MJ/m3 (for comparison, HHV of H2 = 12.76 MJ/m3,
CO = 12.63 MJ/m3, CH4 39.76 MJ/m3 and CH4 is commonly much less than CO
and H2).
Low quality syngas is the main disadvantage of this technique for applications
which require high temperature and steady operation, such as internal combustion
engine, metallurgy, and melting glass industries.
Five Processes of Gasification
 Applications of Producer Gas

Electric power generation from few kW to MW, either for local
consumption or for grid power
To operate diesel engine on dual fuel mode with 80-85% diesel
replacement
To operate the gas engine on 100% mode
To operate water pumps for irrigation purposes
Applications of
Producer Gas
 Biomass Gasification by Thermo-Chemical Conversion

Summary

This lecture has described in detailed Biomass Gasification by Thermo-
Chemical route. It details the various zones of the Biomass Gasification
Units with the help of major chemical reactions occurring due to heating of
the biomass.