This document discusses worldwide consumption and waste problems and proposes a solution using LTC technology. It notes that consumption is increasing rapidly worldwide, leading to issues like increased pollution from mass production, urbanization, and energy demands. Waste is also a growing global problem, with garbage covering the planet and each person producing half a ton per year. The proposed solution is the LTC (Low Temperature Conversion) technology, which can convert any organic waste into recyclable materials and renewable energy through a thermocatalytic process without combustion at temperatures below 650 degrees Celsius. This process avoids pollution, replaces fossil fuels, reduces emissions, and increases energy production efficiency compared to conventional plants.
Waste to energy projects with reference to MSW, Sourabh Manuja, TERI, IndiaESD UNU-IAS
This lecture is part of the 2016 ProSPER.Net Young Researchers’ School on sustainable energy for transforming lives: availability, accessibility, affordability
World Bank estimated, in 2025 the production of municipal solid waste will be 2.2 billion tones worldwide. With this amount, we are more and more polluting our own environment. Seven to eight percent of the total greenhouse gas emissions arise from continued landfilling. EfW (WtE) does not only decrease the volume of waste, it also protects natural resources like land and water. There is no additional need for landfills, where leakage can occur and pollute our tap water. It also protects air and climate because the regulations by law for EfW are more stringent than for coal fired power plants or any other industry. EfW plants decrease the greenhouse gases which come from landfill.
Waste-to-energy (WtE) or energy-from-waste (EfW) is the process of generating energy in the form of electricity and/or heat from the primary treatment of waste. WtE is a form of energy recovery. Most WtE processes produce electricity and/or heat directly through combustion, or produce a combustible fuel commodity, such as methane, methanol, ethanol or synthetic fuels.
Waste-to-energy technologies convert waste matter into various forms of fuel that can be used to supply energy. Waste feed stocks can include municipal solid waste (MSW); construction and demolition (C&D) debris; agricultural waste, such as crop silage and livestock manure; industrial waste from coal mining, lumber mills, or other facilities; and even the gases that are naturally produced within landfills.
Waste to energy projects with reference to MSW, Sourabh Manuja, TERI, IndiaESD UNU-IAS
This lecture is part of the 2016 ProSPER.Net Young Researchers’ School on sustainable energy for transforming lives: availability, accessibility, affordability
World Bank estimated, in 2025 the production of municipal solid waste will be 2.2 billion tones worldwide. With this amount, we are more and more polluting our own environment. Seven to eight percent of the total greenhouse gas emissions arise from continued landfilling. EfW (WtE) does not only decrease the volume of waste, it also protects natural resources like land and water. There is no additional need for landfills, where leakage can occur and pollute our tap water. It also protects air and climate because the regulations by law for EfW are more stringent than for coal fired power plants or any other industry. EfW plants decrease the greenhouse gases which come from landfill.
Waste-to-energy (WtE) or energy-from-waste (EfW) is the process of generating energy in the form of electricity and/or heat from the primary treatment of waste. WtE is a form of energy recovery. Most WtE processes produce electricity and/or heat directly through combustion, or produce a combustible fuel commodity, such as methane, methanol, ethanol or synthetic fuels.
Waste-to-energy technologies convert waste matter into various forms of fuel that can be used to supply energy. Waste feed stocks can include municipal solid waste (MSW); construction and demolition (C&D) debris; agricultural waste, such as crop silage and livestock manure; industrial waste from coal mining, lumber mills, or other facilities; and even the gases that are naturally produced within landfills.
Waste-to-energy uses trash as a fuel for generating power, just as other power plants use coal, oil, or natural gas. The burning fuel heats water into steam that drives a turbine to create electricity.
Waste-to-energy technologies convert waste matter into various forms of fuel that can be used to supply energy. Waste feed stocks can include municipal solid waste (MSW); construction and demolition (C&D) debris; agricultural waste, such as crop silage and livestock manure; industrial waste from coal mining, lumber mills, or other facilities; and even the gases that are naturally produced within landfills.
Widespread infectious disease, air and water pollution, energy poverty, and high unemployment are growing problems in many developing nations. These have become delicate issues for humanitarian organizations like the UN, OECD, WHO, and World Bank. Most of these developing countries have been struggling to meet the Millennium Development Goals. However, many of these problems can be linked together and solved with a new class of waste-to-energy (W2E) systems. Waste has become an uncontrollable problem in many developing countries and in Latin America. Nearly 100 percent of waste in low-income countries goes to landfills. However, a W2E system can reduce waste and generate electricity at the same time. The actual gasification and pyrolysis technologies used in waste to energy conversion are nothing new as it was widely used in Europe during WWII, but now several companies are packing the system in a convenient shipping container size. This means it can be deployed throughout the world quickly and efficiently, over both land and sea. These new W2E systems obviate the technological barriers to building a W2E facility in a developing country. And, the system can significantly improve both rural and urban communities in the following ways: 1. Improve health and sanitation The W2E systems use almost any organic waste as the fuel. This includes paper, plastics, used tires, spoiled food, and dry manure. Thus, it cuts down on the size of landfills and there is an incentive to collect waste together rather than littering along the roads. By cleaning up the streets and reducing landfill sizes, you have also eliminated the breeding grounds for many infectious diseases. Agricultural by-products such as saw mill waste, nut shells, sugar and rice bagasse, corn stoves, cassava peels, and sorghum. Many of these potential fuels are currently either left to rot or are disposed of by burning in the field, emitting dangerous plumes of greenhouse gasses and pollutants. 2. Improve local economy The W2E system does not require in depth technical knowledge to operate, but it still needs a workforce to maintain it. It will also create jobs for waste collection and sorting. . And, not only does the system create jobs, it creates sources of revenue for the entire community. The electricity can be sold; and depending on the W2E technology and feedstock, the end byproduct can be sold as well. In many cases the W2E system will displace a diesel powered generator, and even in an oil producing nation such as Nigeria, the return on investment can be 12 months or less based solely on fuel savings. 3. Increase productivity and raise living standards The W2E system will be able to provide rural communities with electricity and or heat. Electricity can extend working hours and productivity. Access to electricity has been closely linked to higher levels of education, lower levels of poverty, and reduced gender inequality in developing nations.
Conversion of Plastic Wastes into Fuels - Pyrocrat systems reviewSuhas Dixit
The document is aimed to share a review on how Plastic waste can be converted into Industrially usable fuel. We at Pyrocrat Systems manufacture machinery to establish pyrolysis plants that convert waste plastic into pyrolysis oil.
How to Start Biogas Production, Biogas – An Intense Opportunity (Landfill Gas...Ajjay Kumar Gupta
Generally, biogas is a renewable fuel. In any country, for cooking or heating purposes biogas can be used as a low-cost fuel. Biogas can be used as a fuel in stationary and mobile engines, to supply motive power, pump water, drive machinery (e.g., threshers, grinders) or generate electricity. It can be used in both spark and compression (diesel) engines. The spark ignition engine is easily modified to run on biogas by using a gas carburetor.
See more
http://goo.gl/itobCF
http://goo.gl/rUX6nR
http://goo.gl/euQMeR
Contact us:
Niir Project Consultancy Services
Email: npcs.ei@gmail.com , info@entrepreneurindia.co
Tel: +91-11-23843955, 23845654, 23845886, 8800733955
Mobile: +91-9811043595
Website : http://www.niir.org , http://www.entrepreneurindia.co
Tags
Anaerobic Treatment and Biogas Production from Organic Waste,Biofuel, Biogas an Intense Opportunity, Biogas and Its Applications, Biogas Application, Biogas Based Profitable Projects, Biogas business plan, Biogas Digester, Biogas digester construction, Biogas from waste, Biogas plant construction, Biogas plant in India, Biogas Plants, Biogas Plants: Processes for Biogas Production, Biogas production, Biogas production book, Biogas Production Business, Biogas production from kitchen waste, Biogas Production from Organic Wastes, Biogas production Industry in India, Biogas Production Plants, Biogas production process, Biogas production Projects, Biogas production technology, Biogas Small Business Manufacturing, Biogas start up, Biogas technologies and applications, Biogas Technology Book, Biomass, Build a Biogas Plant, Business guidance for Biogas Production, Business guidance to clients, Business opportunities for biogas production, Business plan bio gas, Business plan for biogas production, Business start-up, How to build a biogas digester, How to make a Bio-gas Digester, How to Make Biogas, How to produce biogas from waste, How to Profit from Biogas Production, How to Start a Biogas production Business, How to Start a Biogas Production?, How to start a successful Biogas Production business, How to start biogas plant business in India, How to Start Biogas production Industry in India, Landfill Gas (LFG), Methane Generation from Livestock Waste, Methane Production from Agricultural and Domestic Wastes, Methane production from animal wastes, Methane Production from Farm Wastes, Mini Bio-gas plant using decomposable organic material, Mini Bio-gas plant using food waste, Modern small and cottage scale industries, Most Profitable Biogas production Business Ideas , New small scale ideas in Biogas production industry, Organic waste types for biogas production, Producing biogas from kitchen waste, Production of Biogas from Biomass, Profitable small and cottage scale industries, Profitable Small Scale Biogas Production, Project for startups, Renewable Energy, Setting up and opening your Biogas Production Business
Plastic and Tire Pyrolysis Plant Manufacturers - Pyrocrat Systems LLPPyrolysis Plant
Pyrolysis plant is an industry that converts waste plastic & tires into Pyrolysis Oil, Carbon Black & Hydrocarbon Gas. End products are used as industrial fuels for producing heat, steam or electricity. Pyrolysis plant is also known as: pyrolysis unit, plastic to fuel industry, tire to fuel industry, plastic and tire recycling unit etc.
More info at http://www.pyrolysisplant.com/
The Presentation cover all details related to Electricity Generation from Waste Material, Which is very good technlogy. In this we can find that, how we are creating this energy, and how we are using.
Waste-to-energy uses trash as a fuel for generating power, just as other power plants use coal, oil, or natural gas. The burning fuel heats water into steam that drives a turbine to create electricity.
Waste-to-energy technologies convert waste matter into various forms of fuel that can be used to supply energy. Waste feed stocks can include municipal solid waste (MSW); construction and demolition (C&D) debris; agricultural waste, such as crop silage and livestock manure; industrial waste from coal mining, lumber mills, or other facilities; and even the gases that are naturally produced within landfills.
Widespread infectious disease, air and water pollution, energy poverty, and high unemployment are growing problems in many developing nations. These have become delicate issues for humanitarian organizations like the UN, OECD, WHO, and World Bank. Most of these developing countries have been struggling to meet the Millennium Development Goals. However, many of these problems can be linked together and solved with a new class of waste-to-energy (W2E) systems. Waste has become an uncontrollable problem in many developing countries and in Latin America. Nearly 100 percent of waste in low-income countries goes to landfills. However, a W2E system can reduce waste and generate electricity at the same time. The actual gasification and pyrolysis technologies used in waste to energy conversion are nothing new as it was widely used in Europe during WWII, but now several companies are packing the system in a convenient shipping container size. This means it can be deployed throughout the world quickly and efficiently, over both land and sea. These new W2E systems obviate the technological barriers to building a W2E facility in a developing country. And, the system can significantly improve both rural and urban communities in the following ways: 1. Improve health and sanitation The W2E systems use almost any organic waste as the fuel. This includes paper, plastics, used tires, spoiled food, and dry manure. Thus, it cuts down on the size of landfills and there is an incentive to collect waste together rather than littering along the roads. By cleaning up the streets and reducing landfill sizes, you have also eliminated the breeding grounds for many infectious diseases. Agricultural by-products such as saw mill waste, nut shells, sugar and rice bagasse, corn stoves, cassava peels, and sorghum. Many of these potential fuels are currently either left to rot or are disposed of by burning in the field, emitting dangerous plumes of greenhouse gasses and pollutants. 2. Improve local economy The W2E system does not require in depth technical knowledge to operate, but it still needs a workforce to maintain it. It will also create jobs for waste collection and sorting. . And, not only does the system create jobs, it creates sources of revenue for the entire community. The electricity can be sold; and depending on the W2E technology and feedstock, the end byproduct can be sold as well. In many cases the W2E system will displace a diesel powered generator, and even in an oil producing nation such as Nigeria, the return on investment can be 12 months or less based solely on fuel savings. 3. Increase productivity and raise living standards The W2E system will be able to provide rural communities with electricity and or heat. Electricity can extend working hours and productivity. Access to electricity has been closely linked to higher levels of education, lower levels of poverty, and reduced gender inequality in developing nations.
Conversion of Plastic Wastes into Fuels - Pyrocrat systems reviewSuhas Dixit
The document is aimed to share a review on how Plastic waste can be converted into Industrially usable fuel. We at Pyrocrat Systems manufacture machinery to establish pyrolysis plants that convert waste plastic into pyrolysis oil.
How to Start Biogas Production, Biogas – An Intense Opportunity (Landfill Gas...Ajjay Kumar Gupta
Generally, biogas is a renewable fuel. In any country, for cooking or heating purposes biogas can be used as a low-cost fuel. Biogas can be used as a fuel in stationary and mobile engines, to supply motive power, pump water, drive machinery (e.g., threshers, grinders) or generate electricity. It can be used in both spark and compression (diesel) engines. The spark ignition engine is easily modified to run on biogas by using a gas carburetor.
See more
http://goo.gl/itobCF
http://goo.gl/rUX6nR
http://goo.gl/euQMeR
Contact us:
Niir Project Consultancy Services
Email: npcs.ei@gmail.com , info@entrepreneurindia.co
Tel: +91-11-23843955, 23845654, 23845886, 8800733955
Mobile: +91-9811043595
Website : http://www.niir.org , http://www.entrepreneurindia.co
Tags
Anaerobic Treatment and Biogas Production from Organic Waste,Biofuel, Biogas an Intense Opportunity, Biogas and Its Applications, Biogas Application, Biogas Based Profitable Projects, Biogas business plan, Biogas Digester, Biogas digester construction, Biogas from waste, Biogas plant construction, Biogas plant in India, Biogas Plants, Biogas Plants: Processes for Biogas Production, Biogas production, Biogas production book, Biogas Production Business, Biogas production from kitchen waste, Biogas Production from Organic Wastes, Biogas production Industry in India, Biogas Production Plants, Biogas production process, Biogas production Projects, Biogas production technology, Biogas Small Business Manufacturing, Biogas start up, Biogas technologies and applications, Biogas Technology Book, Biomass, Build a Biogas Plant, Business guidance for Biogas Production, Business guidance to clients, Business opportunities for biogas production, Business plan bio gas, Business plan for biogas production, Business start-up, How to build a biogas digester, How to make a Bio-gas Digester, How to Make Biogas, How to produce biogas from waste, How to Profit from Biogas Production, How to Start a Biogas production Business, How to Start a Biogas Production?, How to start a successful Biogas Production business, How to start biogas plant business in India, How to Start Biogas production Industry in India, Landfill Gas (LFG), Methane Generation from Livestock Waste, Methane Production from Agricultural and Domestic Wastes, Methane production from animal wastes, Methane Production from Farm Wastes, Mini Bio-gas plant using decomposable organic material, Mini Bio-gas plant using food waste, Modern small and cottage scale industries, Most Profitable Biogas production Business Ideas , New small scale ideas in Biogas production industry, Organic waste types for biogas production, Producing biogas from kitchen waste, Production of Biogas from Biomass, Profitable small and cottage scale industries, Profitable Small Scale Biogas Production, Project for startups, Renewable Energy, Setting up and opening your Biogas Production Business
Plastic and Tire Pyrolysis Plant Manufacturers - Pyrocrat Systems LLPPyrolysis Plant
Pyrolysis plant is an industry that converts waste plastic & tires into Pyrolysis Oil, Carbon Black & Hydrocarbon Gas. End products are used as industrial fuels for producing heat, steam or electricity. Pyrolysis plant is also known as: pyrolysis unit, plastic to fuel industry, tire to fuel industry, plastic and tire recycling unit etc.
More info at http://www.pyrolysisplant.com/
The Presentation cover all details related to Electricity Generation from Waste Material, Which is very good technlogy. In this we can find that, how we are creating this energy, and how we are using.
As the world’s population keeps growing, it will need 45 % more energy by 2030. Finland provides holistic solutions for the whole value chain - from waste and biomass feedstock to energy conversion.
Plastic waste to energy opportunities - PyrolysisPlant.comPyrolysis Plant
Pyrolysis plant is an industry that converts waste plastic & tires into Pyrolysis Oil, Carbon Black & Hydrocarbon Gas. End products are used as industrial fuels for producing heat, steam or electricity. Pyrolysis plant is also known as: pyrolysis unit, plastic to fuel industry, tire to fuel industry, plastic and tire recycling unit etc.
More info at http://www.pyrolysisplant.com/
SOLID WASTE MANAGEMENT PROJECT at KALUTHARA(KALUTHARA URBAN COUNCIL)
A presentation Done by the 1st Year Students (Group 2) of the Department of Forestry and Environmental Sciences, University of Sri Jayewardenepura for the Environmental Chemistry Assignment..
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Content:
What is Electronic Waste?
How these become E-Waste
Generation of E-waste by Countries
Why E-Waste a Problem?
Constituents of E-Waste
E-Waste Processing steps
Methods for E-Waste treatment
Incineration – Process Description, Types, Advantage and Disadvantage
Non-Incineration – Process Description, Types, Advantage and Disadvantage
Did you know?
Conclusion
Integrated green technologies for msw (mam ver.)mamdouh sabour
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Technical talk is describing various technologies about solid waste treatment and safe disposal :Detailed explanation of waste to energy treatment plant principle, operations and unit processes have been summerized.
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2. WORLDWIDE
CONSUMER
BEHAVIOUR
THE
PROBLEM
OF
CONSUMPTION
More
proteins
=
mass
producEon
Increasing
car
producEon
MetropolizaEon
=
megaciEes
=
poluEon
Growing
demand
for
energy
result
in
environment
demages
The
consumpEon
spiral
rotates
faster
and
faster
Worldwide.
We
have
created
a
«throw-‐away
society».
Raw
material
is
wasted
instead
of
using
it
to
produce
energy.
2
3. THE
WORLD
IS
ONE
BIG
GARBAGE
DUMP
THE
PROBLEM
OF
WASTE
Garbage
covers
the
planet
Earth.
One
person
produces
an
average
of
half
a
ton
garbage
per
year
It
is
stored
on
dumps,
consumes
landfills
and
swims
in
the
water
This
problem
needs
to
be
solved
to
protect
our
planet
3
4. WORLDWIDE
FACTS
APPROACH
The
LTC
method
offers
sustainable
soluEons
for
the
highly
efficient
and
environement
friendly
producEon
of
energy
out
of
all
oraganic
raw-‐
or
waste
material
A
conversion
from
garbage
to
energy
according
to
the
LTC
technology
avoids
poluEon,
replaces
fossil
fuels,
reducdes
CO2
emmissions
and
increases
the
operaEng
economoy
in
energy
extracEon.
• The
need
for
energy
is
increasing
each
year.
• Greenhouse
gas
emissions
must
be
reduced
fast
and
drasEcally
• The
amount
of
waste
rapidly
increases
and
it
has
become
a
global
problem
• The
natural
resources
of
fossil
fuels
decreases
4
5. SOME
CALL
IT
WASTE
WE
CALL
IT
ENERGY
With
the
patented
LTC
technology
all
carbonated
/
organic
substances
can
be
converted
into
recyclable
substances
and
renewable
energy.
Besides,
minerals,
oils
and
carbon,
each
quality
of
organic
waste
can
be
converted:
tyres,
plasEc,
cardboard
packaging,
paper,
green
&
houshold
waste.
Waste
landfills
turn
into
raw
materials
and
contribute
in
an
environmental
friendly
way
to
the
energy
supply
of
the
communiEes.
BIOMASS
Energy:
1,8
MW
el/to
PLASTIC
WASTE
Energy:
3.5
MW
el/to
USED
TIRES
Energy:
5.0
MW
el/to
BIOMASS
Energy:
2,4
MW
el/to
HOUSHOLD
WASTE
Energy:
2,2
MW
el/to
ELECTRIC
WASTE
Energy:
3,1
MW
el/to
5
6. LTC
–
TECHNOLOGY
INPUT
MATERIAL
With the patented LTC
technology all carbonated /
organic substances can be
converted into recyclable sub-
stances and renewable energy.
Besides, minerals, oils and
carbon, each quality of organic
waste can be converted:
tyres, plastic, cardboard
packaging houshold waste.
Waste landfills turn into raw
materials and contribute in an
environmental friendly way to
the energy supply of the
communities.
Flexible with input material.
Flexible & high Performance
with Energy production.
Biomass
Agricultural
waste
Wood scraps
and wood
chips
Industrial waste
Municipal waste
(
Hospital waste
Sewage sludge
Contaminated
oil
Waste oil and
fats
Animal manure
No fermentation
necessary
Used Tires
Plastic parts of
cars
PVC, PET, PE,
PA
6
7. LTC
–
TECHNOLOGIE
LTC-PROCESS
PROCESS SCHEME
LTC is a thermocatalytical
pulping process without air
supply (no combustion!), no
open flame.
LTC decomposes organic
material into their basic
elements and converts them
into a clean strong gas.
LTC produces gas or
electricity or oils with CO2-
emissions that have been
reduced by 70%.
LOW TEMPERATURE
CONVERSION
SyntheEc
diesel
SyntheEc
gas
Electricity
OUTPUT-‐PRODUCT-‐DESIGN
Product
mix
freely
selectable
Process
heat
for
drying
Power
generaBon
gas
turbine
CirculaBon
high
power
blower
Waste:
Inert
mineral
Process
about
4%
Baffle
reactor
material
crushing
INPUT-‐MATERIAL
PLASTIC
WASTE
USED
TIRES
ELEKTRONIC
SCRAP
HOUSEHOLD
RUBBISH
BIOMASS
SEWAGE
SLUDGE
150
o
C
=
biomass,
legovers
250
o
C
=
hardwood,
plywood,
texEles
450
o
C
=
plasEc,
oil,
used
Eres
650
o
C
=
composites
3
stage
conversion
process
or
or
7
8. THE
IDEA
OF
THE
LTC
TECHNOLOGY
WHAT
»
LTC
«
STANDS
FOR
LOW
TEMPERATURE
CONVERSION
WORKING
METHOD
OF
LTC
TECHNOLOGY
Ø The
process
works
in
a
closed
circuit
Ø At
temperature
not
exceeding
650
Celcius
Ø All
output
gases
are
cleaned
during
conversion
of
input
material
Ø Minor
emission
Ø Due
to
the
low
temperature
anorganic
substances
like
metals
or
minerals
remain
unchanged
and
result
in
high
value
reycable
materials
Ø Minimal
energy
transformaEon
loss
of
45
%
by
electricity
producEon
Ø LTC
produces
40
–
50
%
more
energy
than
convenEonal
cumbusEon
plants
.
Ø The
added
carbonaceous
material
can
be
transformed
in
pure
carbon
and
nano-‐carbon,
that
can
be
used
for
energy
extracEon
ADVANTAGES
OF
THE
LTC
TECHNOLOGY
Ø No
toxic
substances
as
furane
or
dioxins
are
produced
Ø The
chemical
structure
of
the
anorganic
material
will
not
be
changed
(e.g.
metals
or
minerals)
Ø Arising
carbonaceous
gas
(CO2,
CH4)
can
be
further
transformed
to
hydrocarbons
such
as
diesel
Ø The
efficiency
depends
on
the
input
material.
(1.8
-‐
5.0
MW
per
ton)
Ø 40
–
50
%
higher
than
combusEon
Ø The
plant
works
self
sufficient
Ø No
external
energy
is
required
(only
for
start-‐up)
Ø The
plants
are
built
modular
Ø The
size
is
scalable
8
9. LTC – TECHNOLOGIE
LTC-PROCESS
LTC-Systems guarantee an energy-
efficiency of 45% - 65%, depending on
the starting material.
This efficiency is possible because the
LTC process works in its own circulation
and therefore the produced heat can
be reused for the converting process.
LTC plants feed themselves with the
energy they have produced and do
not need any external energy supply
for heating or cooling.
LTC plants offer local solutions for
waste problems both for industry and
communities.
There is the possibility to store the
produced gas and generate the
electricity when needed
This leads to further possibilities to
generate optimal revenue for the
LTC plant operator.
Conventional combustion systems
convert only max. 35% of the waste
inputs into electricity
Loose a large part of heat not
converted into energy.
Energy can not be stored and only be
transported with a complex
infrastucture.
9
10. LTC
vs.
COMBUSTION
vs.
WIND
STATE
OF
ART
TECHNOLOGY
The
LTC
Technology
is
economically
and
ecologically
clean
«State-‐of-‐art»
technology
Higher
performance
than
running
combusEon
plants
with
combined
heat
and
power
Higher
performance
than
wind
turbines.
AddiEonal
advantage
is
the
high
energy
standard
Possiblity
to
apply
for
a
CO2
trading
cerEficaEon
Input
Emission
Waste
Category
Output
Products
Remaining
Material
Carbonic:
oil,
coal,
plasEc
household,
paper,
bio
mass
nearly
Zero
1
KW
=
365g
CO2
Any
organic
waste
and
landfill
disposal
Electriciy
Syn
gas
Syn
fuel
Syn
petrol
Charcoal
Energy
Storage
High
quality
inorganic
output
(e.g.
metals,
glas,
stones
Substances
with
high
condensing
are
preferred
CO2
1KW=1,5
kg
CO2
NOx
SOx
heavy
Metals
Only
High
condensing
waste
Electricity
Heat
Contamina
ted
ash
emissions
low
quality
metals
Wind
Noise
shadow
bird
Issues
ProducEon
&Install
=
CO2
None
Electricity
None
LTC-‐TECHNOLOGY
WIND
COMBUSTION
10
11. LTC
–
PLANT
SCENARIO
-‐
1
BASIC
MODEL
1
T
/
H
The
innovaEve
patented
LTC
technology
can
be
Build
in
a
modular
method.
The
construcEon
can
therefore
be
adapted
to
Input
requirements.
It
is
recommended
to
start
small
and
extend
LTC
plants
in
phases.
LTC
plants
guaranty
high
efficiency
and
long
lifeEme
Use
of
Material:
8000
t/per
Year
Energy
Performance:
15
–
42
GW
/
per
Year
*
Energy
Supply:
aprox.
2500
inhabitants
aprox.
300
households
Plant
Area:
aprox.
225
m2
*
Energy
performance
depends
on
the
used
raw
material
11
12. LTC
–
PLANT
SCENARIO
–
2
BASIC
MODEL
3
T
/
H
Use
of
Material:
24’000
t/per
Year
Energy
Performance:
45
–
126
GW
/
per
Year
*
Energy
Supply:
aprox.
7’500
inhabitants
aprox.
900
households
Plant
Area:
aprox.
675
m2
*
Energy
performance
depends
on
the
used
raw
material
12
13. LTC
–
PLANT
SCENARIO
–
3
BASIC
MODEL
5
T
/
H
Use
of
Material:
40’000
t/per
Year
Energy
Performance:
75
–
201
GW
/
per
Year
*
Energy
Supply:
aprox.
12’500
lnhabitants
aprox.
1’500
households
Plant
Area:
aprox.
1’125
m2
*
Energy
performance
depends
on
the
used
raw
material
13
14. LTC
vs.
COMBUSTION
COMPARISON
LTC-plots ensure highest
efficiency, resistance and a
long lifetime.
Low running costs because of
full automation and low
personnel requirements.
Simple and efficient installation
at the location.
Energy self-sufficient running
because of supply by the plot.
The operational control of the
LTC Power Plants runs on
remote maintenance and
therefore has low need for
servicing.
14
15. LTC
vs.
WIND
vs.
INCINERATORS
COMPARISON
Used Tires
2 – 4 years
Plastic Waste
3 – 4 years
Elektronic Waste
2 – 3 years
Sewage Sludge
6 – 8 years
Municipal Waste
6 – 8 Years
Biomass
4 – 6 years
LTC - AMORTISATION
WIND
LTC
AMORTISATION IN YEARS
20
YEARS
2
–
8
years
10-‐13
years
*
INCINERATORS >20
years
*
The
amorEzaEon
depends
on
the
prices
payed
by
the
garbage
collectors
to
the
combustors.
15
16. LTC
vs.
WIND
vs.
COMBUSTION
EFFICIENCY
LTC
delivers
1.85
–
5
.0
MWh
of
net
electricity
per
ton
waste
depending
on
the
Input
heaEng
value
*
The
best
combusEon
method
produces
about
0.25
MW
of
electricity
per
ton
LTC
produces
recyclable
remaining
materials
and
only
30
%
of
CO2
emissions
compared
to
combusEon
.
With
the
new
zero
emission
Modul
it
is
nearly
zero
CO2
The
LTC
investment
is
about
10-‐25
%
less
than
convenEonal
combusEon
plants
6
2.5
3.2
Electricity
per
ton
in
percentage
LTC
WIND
rated
power
at
6-‐7
Beauford
Scale
COMBUSTION
16
17. LTC
–
RETURN
ON
INVESTMENT
-‐
ROI
Household
Waste
1
t/h
HOUSE HOLD RUBBISH 1 t/h
An average European house-
hold consumes about 3.8 MWel/
a.
1 GW => 1.000 MW
1.000 MW : 3.8 MW =>
263 households =>
790 persons
In Germany the total of
household rubbish has stabilized
at about 13.6 mio. tons.
This corresponds to a per-capita
amount of about 0.15 tons p.a.
CAPACIITY
HOUSEHOLD RUBBISH
PLANT: 1 t/h
Energy => 2,2 MW/el/t/h
8.050 operating hours per year
=> 17.710 MW/el/t/a
=> 17.71 GW/el/t/a
FEED-IN TARIFFS *
D => 1 MW = EUR 145,00 (EUR 140-150)
* Depending on states
INVESTMENT
HOUSE HOLD RUBBISH
PLANT: 1 t/h
LTC-Plant / one-shot
=> EUR 11.000.000,00**
Refunding per year
(145 x 17.710)
=> EUR 2.567.950,00
ROI => 23,34%***
** Production cots / Example
*** Gross
17
18. LTC
vs.
WIND
vs.
COMBUSTION
CONSTRUCTION
TIME
Easy
and
efficient
installaEon
Modules
supplied
in
containers
Energy
Autonomous
operaEon
will
be
ensured
through
the
plant
delivery
LTC
plants
run
by
remote
maintenance
and
operaEonal
control
Minimal
low
labor
maintenance
requirements
LTC
construcEons
are
adapted
to
the
available
space
COMBUSTION: 3-5
WIND: 2-3
LTC: 1-1,5
CONSTRUCTION TIME IN YEARS
18
19. Contact
informaBon
LTC
PowerTech
UK
Ltd.
|
Kemp
House
|
152-‐160
City
Road
|
London
EC1V
2NX
|
Reg.no.
9287593
www.ltcpowertech.com
|
All
Rights
Reserved
info@ltcpowertech.com
19