GR20190100159A - System for atmospheric carbon dioxide retention via charcoal biomass and permanent storage thereof - cooperation with mineral fuel power generation units - Google Patents

Abstract

The invention relates to a power generation system (A) producing electric energy from Biomass without CO2 emissions and with parallel retention of atmospheric carbon dioxide through the production and storage of charcoal derived from the pyrolytic carbonization of the biomass of plants in cooperation with modified old or new power generation units which consume the volatiles derived from the pyrolytic treatment of the biomass; for power generation, the combustion will be carried out by the biomass volatile gases, while a green fuel from volatiles and pyrolytic charcoal will be produced and transferred for permanent storage in exhausted charcoal mines where it can be either stored up for thousands of years without risk of escape to the atmosphere or used as a soil improver in agriculture.

Description

COAL CO2 CAPTURE SYSTEM WITH BIOMASS CHARCOAL AND PERMANENT CHARCOAL STORAGE IN COOPERATION WITH FOSSIL POWER PLANTS

A. GENERAL

Reducing carbon dioxide emissions alone, although now imperative to reducing global warming below 2°C by 2050, is nevertheless proving to be insufficient on its own, particularly to meet the new target of UN to reduce global warming below 1.5°C by 2050. New studies [6] show that this must be accompanied by five other measures, with the top one being the achievement of Negative Carbon Dioxide Emissions, which means reducing the total amounts of Carbon Dioxide in the atmosphere, where it remains trapped for more than 1000 years.

In addition, a very important parameter, which is introduced with the technology proposed in the present invention, which at first reading seems to contradict the above-mentioned need for negative carbon dioxide emissions, is the survival and continued operation of the Coal Power Plants, modified but with the proposed technology of the present invention in a way that not only does not burden but on the contrary cleans up the environment, otherwise they are destined to be closed and replaced by Power Plants from RES according to the COP21 decision of the UN in Paris in December 2015.

However, since coal-fired power generation is very important in most countries, where carbon-based fuel (coal, lignite) is domestic and substitutes expensive fossil fuel imports, efforts are being made to sequester the emitted carbon dioxide so that power generation does not burden the environment. To date this effort, despite the funding and demonstrative projects that have been implemented, has not succeeded in developing carbon dioxide capture technologies that are economically and environmentally sustainable to provide clean electricity generation from coal and are still at the stage research and development.

Furthermore, although it is necessary not only to reduce carbon dioxide emissions from its various emission sources, but also to reduce atmospheric carbon dioxide, where carbon dioxide survives for over a thousand years, no viable technology of negative of carbon dioxide emissions for power plants has not been proposed or demonstrated to date.

The amount of atmospheric carbon dioxide, which has already accumulated in the atmosphere, is estimated at 3500 Gigatons (2015) while the maximum amount allowed, so that Climate Change does not become irreversible according to COP21 in Paris in 2015, is 5000 Gigatons [5 ], i.e. the emission of a maximum of 1500 Gigatons in 35 years until 2050 (based on 2015) or 1330 Gigatons based on 2019 is allowed.

The UN has already announced that the limit of 2.0°C set in 2015 as the upper limit of global warming, so that Climate Change does not become irreversible with an 80% probability, must be reduced to 1.5°C [4 ] and the reduction of atmospheric carbon dioxide will contribute decisively to the achievement of this goal.

B. THE KNOWLEDGE FIELD TODAY

Carbon dioxide capture technology has made significant progress in other applications such as ammonia and fertilizer production, as well as applications where the produced carbon dioxide is sold as a commercial product for various industrial uses. However, for the application in Coal-fired Power Plants, it is necessary to reduce both the investment cost of the carbon dioxide capture (Capex) and the burden of the cost of the produced kilowatt-hour, so that its application becomes competitive and sustainable, as well as for the possibility of alternative storage of carbon dioxide, when it is not used as a commercial product.

The main obstacle to the use of carbon dioxide capture technology is the investment and storage costs, which are still an order of magnitude more expensive than the price level that would make the use of carbon dioxide capture technology competitive.

In the European Union, it is planned to increase the carbon dioxide tax from the current levels of €25/Ton.CO2 to €30-35/Ton.CO2, the enforcement of which will strengthen the sustainability of carbon dioxide capture and storage systems.

In a previous Patent Application with Number 20180100308/10.07.2018 we have proposed the sequestration of Carbon Dioxide by sprinkling the flue gases of Coal Power Plants with an Ammonia solution, which sequesters Carbon Dioxide at the same time as sequestration of Sulfur and Nitrogen Oxides resulting in the production of useful Fertilizers, i.e. Ammonia Bicarbonate, Ammonia Sulphate and Ammonia Nitrate while at the same time binding other dangerous pollutants such as Mercury and Hydrogen Chloride, where with the sale of the produced fertilizers a significant profit is obtained for the Carbonic Power Plant, which makes it competitive and sustainable.

In a second previous Patent Application with Number 20190100079/09.01.2019 we have proposed the use of the produced ammonia fertilizers to accelerate the growth of fast-growing trees in order to accelerate the sequestration of atmospheric carbon dioxide within the woody tissue (trunk, branches, roots) of trees.

The Australian Government has already announced a program to plant a billion trees to combat climate change [7], [8], which with an appropriate selection of trees, preferably fruit-bearing ones, can achieve not only a significant reduction in atmospheric carbon dioxide , but to also generate a very significant agricultural income, which would more than cover the cost of implementing the program with a profit, while Research by the Federal Institute of Technology in Zurich, states that there is scope for planting an additional 1.2 trillion trees on the Planet, very more than required to combat climate change [9].

C. ADVANTAGES OF THE PRESENT INVENTION

The main advantages of the Present Invention, Sequestration of Atmospheric Carbon Dioxide with Charcoal and Permanent Storage of Charcoal in Cooperation with Fossil Fuel Power Plants, are the following:

- The present invention is characterized by the fact that it aims, on the one hand, at the maximum utilization of the possibility of electricity production from Biomass by avoiding the emission of Carbon Dioxide with the parallel Sequestration of Atmospheric Carbon Dioxide through the corresponding production and storage of Charcoal from the Pyrolysis-Carbonization of Plant Biomass resulting in capture and reduction of atmospheric carbon dioxide, in cooperation with Modified existing or new Power Plants with initial Coal Combustion or Modified Combined Cycle Units with initial Combustion of Natural Gas, which instead of consuming Coal or Natural Gas and burdening the environment with additional emissions of Carbon Dioxide, they will consume by-products from the pyrolytic processing of Biomass that will mainly come from the clearing of forests, where according to studies by recognized research centers, the dead plant mass in the forests, which remains exposed to rot, putrefactive gases, mainly methane, which is 20 times more dangerous a greenhouse gas than carbon dioxide, with the result that forests from lungs of carbon dioxide reduction and limitation of greenhouse gases, turn into pollutants and indeed very dangerous [10] , [11]. In addition, the thick layer of thin biomass that remains and rots in forests is one of the greatest risks for fire outbreaks and the spread of forest fire destruction.

Consequently, clearing forests of dead woody and fine biomass, in addition to supplying the raw material for the conversion of coal-fired power plants into biomass-fired coal-fired plants with parallel charcoal production and atmospheric carbon dioxide sequestration, sanitises forests, avoiding the risk of them turning into atmospheric pollutants, while at the same time protecting them from the risk of outbreaks and the spread of destructive forest fires.

A part of the Fine Biomass can also come from the by-products of agricultural crops, wheat, corn, etc. and residual biomass from pruning of fruit trees, vines, olive trees, etc.

In the future, the sequestration of atmospheric carbon dioxide will be done by the billions of trees that will be planted to combat Climate Change [7], [8], [9], where every mature tree after 20-30 years will have sequestered in the woody tissue of (trunk, branches, roots) 5-15 tons of carbon dioxide, which indicatively for Australia which has planned to plant 1.0 Billion Trees by 2050, means negative carbon dioxide emissions three times greater than the CO2 emissions of 20GW Country Carbon Units, i.e. almost all of Australia's carbon dioxide emissions by 2050.

- Until then, however, the only existing, directly applicable and extremely competitive atmospheric carbon dioxide capture technology remains the Technology of Modified Coal Power Units and, secondarily, of Modified Combined Cycle Units with Natural Gas with Mixed or Pure Combustion of Biomass with Coal or PV with parallel production and storage of Pyrolytic Charcoal, which can not only neutralize the Carbon Dioxide emissions of these Units but also the totality of the carbon dioxide emissions from all the other emission sources.

- Where combustion for the production of thermal energy will be carried out with the volatile components of Biomass, while most of the vegetable carbon will be isolated by Pyrolysis-Carbonization in the absence of oxygen at temperatures of approximately 520°-560°C, (hereinafter "Pyrolysis- Carbonization" or simply "Cyrolysis"), where the volatile and oily components of the Biomass are separated and removed as Volatile Gaseous Products of Pyrolysis-Carbonization while solid Charcoal remains as a by-product as pure coal, which is transported for permanent storage in exhausted coal mines, where it can remain stored for thousands of years without risk of escaping back into the atmosphere, unlike the storage of carbon dioxide in underground geological formations.

- It is further characterized by the fact that, contrary to the high cost of compression, transport and storage of Carbon Dioxide in underground geological formations, the cost of transport and storage of solid Pyrolytic Charcoal is predicted to be much lower, up to almost zero, indicative of transport and storage of the Charcoal in the depleted section of the working coal mine that supplies coal to the 1/3 Coal 2/3 Biomass Modified Combined Combustion Steam Power Unit, as below, because it will be transported in the same wagons that carry the coal for the mixed burning 1/3 - 2/3 with Biomass, and which would otherwise be returned empty, thus reducing the cost of transport and permanent storage of Pyrolytic Charcoal almost to zero,

- It is also characterized by the fact that the effect in the fight against Climate Change is twofold, because on the one hand we have electricity generation without Carbon Dioxide emissions, indicatively for 2/3 of electricity generation from Biomass, as below, [avoidance of approximately 0.8 - 0.267KgCO2/KWh depending on whether the power generation takes place in a Modified Coal Steam Electric Unit (A.5.1) or a Modified Combined Cycle Unit (A.6.1)], and on the one hand, removal of Carbon Dioxide from the atmosphere in the form of Pyrolytic Charcoal, which had been absorbed by the plants , as below [approximately 2.4623 KgCO2/KWh for power generation from a Modified Coal Steam Unit (A.5.1) to 1.9096KgCO2/KWh for power generation from a Modified Combined Cycle Unit (A.6.1)], total 2, 8623-2, 0429KgCO2/KWh respectively or 2, 8623x25=71, 5575€/MWh credit for the Modified Coal Steam Electric Unit (A.5.1) and 2,0429x25= 51,0725€/MWh credit for the Modified Combined Cycle Unit (A.5.1) 6.1) (for mixed combustion of 1/3 Coal or Natural Gas and 2/3 Biomass, as below), i.e. 40% more credit per MWh for the Modified Coal Steam Unit (A.5.1), which together with the cost of 1 /3 Coal, 2/3 Biomass and the reduced cost of modification of the Coal Steam Electric Unit (A.5.1), leads to a negative MWh cost equal to -8.98€/MWh for the Modified Coal Steam Electric Unit (A.5.1), while for the Modified Combined Cycle Unit (A.6.1), with the same assumptions leads to a corresponding MWh cost equal to €9.96/MWh,

The Present Invention is therefore further characterized by having a negative MWh cost, in the Modified Coal Steam Unit (A.5.1), and very little in the Modified Combined Cycle Unit (A.6.1) (indicative for mixed combustion of 1/3 Coal or Natural Gas and 2/3 Biomass, as above) are completely competitive with any other power generation technology, including RES (PV and Wind), whose prices are still falling, but will always remain with a positive sign, where power generation with a negative sign appears for the first time, with the protagonists being the previously condemned Coal Power Plants, which had to be closed due to environmental damage, due to the emissions of Carbon Dioxide, as well as due to the uncompetitive price of the electricity produced, even if the burden of purchasing Carbon Dioxide emission rights was not taken into account.

It is also characterized by the fact that, due to Sequestration of Atmospheric Carbon Dioxide in the form of Charcoal, it results as above in a negative MWh cost, inferior even to the most competitive electricity generation scenarios with Renewable Energy Sources (PV or Wind) from which it also benefits from the the fact that it also works during the time periods when these two RES do not work, for example when the Sun is not enough or at night (PV) or when the Wind does not blow (Wind) and for this reason they can be the necessary supplement of these RES, where it will be strategically safer (with a 90-day fuel reserve), technically better, more economical, readily available and more reliable than the currently proposed alternative solutions (indicative batteries, fuel cells, hydrogen storage, etc.).

Where the present invention is also characterized by the fact that it comes to the very important conclusion that the existing Coal Units of about 200GW in the EE and about the same in the USA are not recommended to be retired in haste on the grounds of avoiding Carbon Dioxide Emissions and high costs of KWh production, because based on the technology of the present invention, the existing Carbon Units with a small modification as above, can emerge as Champions of Competitive Cost KWh and Undisputed Champions of Environmental Protection and the fight against Climate Change using Negative Emission Technology of Carbon Dioxide.

It is also characterized by the fact that based on the latest Studies by leading Research Bodies [6] and by the United Nations Intergovernmental Study Group, limiting or avoiding the emission of Carbon Dioxide alone is not enough for the success of the new UN goal of containing the warming of the Planet below 1.5° C until 2050, so that we have a good chance that Climate Change will not become irreversible, but five other measures are required at the same time, with the main one being the need to achieve Negative Emissions [6] , i.e. Sequestration and Permanent Storage of Atmospheric Carbon Dioxide as above, which appears to be absolutely necessary to achieve the 1.5° C target by 2050.

Also, the present invention is further characterized by the fact that, as a whole, the modified carbon-based power generation units in combination with the use of Biomass as above, are now characterized by the fact that they can be considered strategically necessary, without the disadvantage of carbon dioxide emissions, due to the existence of an on-site energy production reserve of more than 90 days with a corresponding storage of carbon and biomass reserves, which does not apply to natural gas units and other RES units,

Also, the present invention is characterized by the fact that the coal-fired power plants combined with the use of Biomass as above, are characterized by the fact that they upgrade the value of the shares of Coal Companies and Coal-fired Power Generation Companies, the USA, the EU and internationally, from depreciating after the Paris Agreement in December 2015 to their former and even greater value, a multi-hundred billion Euro national US EU and international capital,

Also, the present invention is characterized by the fact that if the rate of conversion and sequestration of atmospheric carbon dioxide is equal to the total carbon dioxide emissions from the operating fossil fuel power plants (or also to the total carbon dioxide emissions) for a Country [indicatively the European Union (EU), Plan No. 6 ], then the quantities of the captured and stored atmospheric carbon dioxide are equal to those released from the total installed capacity of the power generation units as above (or also from the total carbon dioxide emissions of the carbon of the country in question), resulting in the reduction of all carbon dioxide, which would have been emitted until 2050, i.e. zero increase in carbon dioxide emissions of the country in question until 2050 and beyond.

Also, the present invention is characterized by the fact that because the Biomass Power Plants with parallel Sequestration of Atmospheric Carbon Dioxide work even when the RES Power Plants do not work [such as when the Sun is not enough or at night (PV) or when no the Wind is blowing (Wind Power)], for this reason they replace expensive electrical energy storage solutions (such as batteries, fuel cells, hydrogen storage, etc.) i.e. another dimension of the economic efficiency of the new Technology in the order of 500-1000€/KW (equal to €100-200B for the EU and as much for the USA and five times internationally) and are the necessary complement to PV and Wind, which would be the main generator of electricity in the coming years.

So it is characterized by the fact that when applied to a set of indicatively 200GW of carbon-based units (typical case of EU and USA), then for the zeroing of their emissions in carbon dioxide of the country in question (or correspondingly and on an international scale of application, Plan No. 6), it is saved and the total capacity of coal-fired power plants becomes highly competitive with an invested capital value of 200,000MW x 2,250 x 10<3>$/MW x 0.5 (due to depreciation indicative of 50%) = $225B a National Profit Difference of $225B for the US (and as much for the EU and five times the international total indicative of a Profit Difference of 7 x 225 = $1.575 Trillion internationally)

In addition, it is characterized by the substitution of 5-fold PV power investments (Modified Carbon Units Operation 6000-7000H/H compared to 1300-1400H/H of PV i.e. 1:5 ratio) with a substitution gain of 5 x 200GW x 1,200 x 10<6>$/GW = $1.2 Trn PV Substitution Profit Value for the US (and as much for the EU and five times the international total indicative of a Substitution Profit equal to 7 x $1.2 Tr = 8, $4 Trillion internationally) plus the Replacement Value of Energy Storage Systems for Operation and Nighttime (PV) or Sleep Periods (Wind) equal to 200,000 MW x 500 x 10<3>$/MW = $100 Billion Replacement Value for the US (and as much for the EU and five times the international total indicative of a Replacement Value of 7 x $100B = $700B internationally), plus they upgrade the value of the shares of Coal Companies and Combustion Power Companies coal, of the US, the EU and internationally, since the depredation following the Paris Agreement in December of 2015, at their earlier and even greater value, with an estimate of this upgrade for the US at $200B (with another as much for the EU and five times the international total indicative of an Upgrade Value equal to 7 x $200B = $1,400B internationally ).

It is therefore characterized by the fact that the Total Profit from the application of the New Technology for the Zero Balance Scenario is indicatively: 225 1,200 100 200 = $1,725 Billion in the USA or the EU and five-fold Internationally, i.e. 7 x 1,725 = $12,075 Billion for a investment of $120 Billion in the USA or the EU and five times Internationally ie 7 x 120 = $840 Billion with a Return of Invested Capital/20Y ratio equal to 12,075 / 840 =14,375 or 1437.5%.

The Investment is therefore characterized by the fact that instead of being an Emergency Investment with State Support (Subsidies. Tax Exemption, etc.) to save the Planet from the ravages of Climate Change, it turns out to be the business opportunity of the century, the which can be undertaken profitably by the international Business Community and implemented within a much shorter time horizon than 2050 and on a larger scale (positive Balance of Emissions to Sequestration and Storage of Atmospheric Carbon Dioxide) resulting in the containment of global warming very much below 1.5°C by 2050.

D. DESIGNS

Drawing No. 1 shows the General Layout of the Atmospheric Carbon Dioxide Sequestration System by Pyrolysis-Carbonization of Biomass, consisting of a number of Pyrolysis-Carbonization Chambers (001), with their Peripherals, in collaboration with a Coal Power Plant.

- Drawing No. 2 alternatively shows the General Layout of the Atmospheric Carbon Dioxide Sequestration System by Pyrolysis-Carbonization of Biomass, consisting of a number of Pyrolysis-Carbonization Chambers (001), with their Peripherals, in collaboration with a Combined Cycle Power Plant.

- Drawing No. 3 shows in Section A-A' the construction of the Basic Pyrolysis-Carbonization Unit in Elevation, consisting of a number of Pyrolysis-Carbonization Chambers (001), where each Chamber (001) contains a Subchamber (002) and this contains a Wagon (003) Loading-Unloading Biomass, which is converted into Charcoal,

- Drawing No. 4 shows in Section B-B' the construction of the Basic Pyrolysis-Carbonization Unit in Plan view, with the Wagon (003) in position inside and outside the Subchamber (002) of the Basic Pyrolysis-Carbonization Unit with its necessary Peripherals , - Drawing No. 5 shows in Section B-B' the construction of the Basic Pyrolysis-Carbonization Unit in Side View with the Biomass Loading-Unloading Wagon (003) in position inside and outside the Subchamber (002) of the Basic Pyrolysis-Carbonization Unit with its necessary Regional,

- Plan No 6 shows the projected Evolution Curve of the Agreed Amount of Carbon Dioxide Emissions from the UN COP21 Agreement in Paris in 2015 for the EU, in contrast to the Scenario of Zero Balance of CO2 Emissions and Atmospheric Carbon Dioxide Sequestration and Storage based on its Current EU Commitment Technology,

E. DESCRIPTION

E.1. COAL CO2 CAPTURE SYSTEM WITH BIOMASS CHARCOAL AND PERMANENT CHARCOAL STORAGE IN COOPERATION WITH FOSSIL POWER PLANTS

A Power Generation System (A), reducing up to zero Carbon Dioxide Emissions, which is characterized by the fact that it consists of Modified Power Generation Units (A.5.1), operating indicatively with Mixed Combustion of Fossil Fuels with Biomass in the Hearth (016) of Boiler (012) combined with Biomass Pyrolysis-Carbonization Unit (A.4.1) for the production of Volatile Gas Products (009) and Solid Charcoal (008) through which Atmospheric Carbon Dioxide is Sequestered and Stored, which is additionally characterized by the fact that in contrast to the current state of the art where the aim is simply to reduce the emissions of Carbon Dioxide from the Power Plants with fossil fuels, with the final difficult or even impossible goal of achieving an economically competitive technology for capturing, compressing and storing the produced Carbon Dioxide in underground geological formations, where the present invention not only achieves the reduction up to zero Carbon Dioxide emissions from existing or new Modified Power Plants with mixed combustion of Fossil Fuels and Biomass at a highly competitive cost, but in addition achieves Negative Carbon Dioxide Emissions, i.e. removal, sequestration and permanent storage of the Carbon Dioxide that has has already accumulated in the atmosphere, where it remains trapped and dangerous for over a thousand years, in the form of Solid Pyrolytic Charcoal, which can be permanently stored in exhausted coal mines for thousands of years, without risk of escaping again into the atmosphere, contrary to the proposed the current level of the technical solution for the compression and storage of Carbon Dioxide in underground geological formations, where however its future escape back into the atmosphere cannot be ruled out,

Where the present invention is characterized by the fact that it consists of a Power Generation System (A) of an innovative combination of a Modified Power Generation Unit with Mixed Combustion of Fossil Fuels, indicative of Coal (009A), and Biomass (A.2.0) or Pure Biomass Combustion (A.2.0) and Volatile Gaseous Products (009) from Biomass Pyrolysis-Carbonization (A.2.0) and an innovative Biomass Pyrolysis-Carbonization (A.4.1) installation (A.2.0) for the production of Charcoal (008) for permanent storage, with parallel production of pyrolytic Volatile Gaseous Products (009) from Biomass Pyrolysis-Carbonization (A.2.0), which is characterized by the fact that it consists of the following parts, namely:

1) The Biomass Storage System (A.1) (A.2.0) which is characterized by having provision for First Drying with the Hot Exhaust Gases (A.1.4) of the Chimney (A.1.5) of the Modified Power Generation Unit (A. 5.1), in contrast to the current state of the art where the Hot Exhaust Gases (A.1.4) of the Chimney (A.1.5) are expelled through the Chimney (A.1.5) into the atmosphere,

2) The Biomass Preparation System (A.2) (A.2.0), which is characterized by having on the one hand Grinding-Pelletization and Storage of Fine Biomass (A.2.1) in Biomass Silos (A.2.4) or in Baskets Loading (A.2.5) and on the other hand Shredding the Woody Biomass (A.2.2) and Storing it for Drying together with the Biomass (A.2.1) in the First Stage of Drying in the Drying Area (A.1.3), in contrast to the current level of the technique where the pyrolysis biomass is not dried with the waste gases of the boilers, while the fine biomass even when pelletized, is not intended for drying and pyrolysis-carbonization for the production of fine-grained Charcoal (008B), but only for combustion and heat production,

3) The System (A.3) for Drying and Preheating the Biomass (A.2.2) and (A.2.1), which is characterized by having, on the one hand, Drying in a Second Stage with a part of the Hot Exhaust Gases (A.1.4) which taken from the exit of the Boiler (012) and before entering the Chimney (A.1.5), and on the other hand then in the System (A.3) Preheating of Dry Biomass (A.2.2A) and (A.2.1A) in Second Stage from the cooling of the fully carbonized superheated Charcoal (008A) and (008B), as below, in contrast to the current state of the art where the pyrolysis biomass is not dried even in a second stage with the available Hot Flue Gases (A.1.4) from the output of the Boiler (012), nor does it then proceed to Preheating the Dry Biomass (A.2.2A) and (A.2.1A) in a Second Stage from the cooling of the fully carbonized superheated Charcoal (008A) and (008B), which means that the thermal efficiency of pyrolysis-carbonization is very poor compared to System (A.3),

4) The System (A.4) Pyrolysis-Carbonization (A.4.1) of Biomass (A.2.2) and (A.2.1), which is characterized by the fact that during the Pyrolysis-Carbonization it separates the Volatile Gases ( 009), which are channeled for combustion in the Hearth (016) of the Boiler (012) of the Steam Power Generation Unit (A.5.1), and on the other hand the produced Charcoal (008A) and (008B), which is pyrolyzed-carbonized by heating from of the superheated Exhaust Gases (014) from the Stove (016) of the Boiler (012) and then after being cooled by heat exchange with the Dry Biomass (A.2.2A) and (A.2.1A) of the System (A.3), is removed for storage in exhausted coal mines or other available storage areas, with degrees of thermal efficiency of the overall process up to Pyrolysis-Carbonization (A.4.1) indicatively above 80% with multiple heat recovery as above, in contrast to its current level technique for pyrolysis-carbonization of biomass, where the thermal degree of performance is very poor resulting in non-competitive cost of energy production from the volatile gas products of pyrolysis-carbonization, where moreover the pyrolysis-carbonization of fine Biomass is not even applied (A.2.1),

5) The System (A.5) of the Modified Steam Electric Power Generation Unit (A.5.1) with initial combustion of coal or oil or other fossil fuels, indicative of coal (009A), which is characterized by the fact that it has been modified for the combustion of Volatile Gases ( 009) of Pyrolysis-Carbonization (A.4.1) or Pelletized Biomass (A.2.1) in the Hearth (016) of the Steam Boiler (012), instead of burning exclusively Mineral Coal (009A), but in mixed combustion with it in the percentage which is necessary, with additional heat recovery from the Charcoal (008A) and (008B) for preheating the Biomass (A.2.2) and (A.2.1) as well as the Feed Water (012A) of the Boiler (012), while in addition has a heat recovery system from the Hot Exhaust Gases (A.1.4) of the Chimney (A.1.5) of the NPP (A.5.1) for the First and Second Drying of Biomass as above, and where then the cold Exhaust Gases (A.1.4 ) instead of the Chimney (A.1.5) are sent to the Cooling Tower (A.1.8) for elimination in steam spheres, entrained by the upward stream of water vapor of the Cooling Tower (A.1.8), so as to achieve a high degree of efficiency in the production of electrical energy, in contrast to the current state of the art where the degree of efficiency in the production of electrical energy in a pyrolysis-carbonization process as above he is very poor,

6) Alternatively, the System (A.6) of the Modified Combined Cycle Power Generation Unit with Mixed Combustion in the Gas Turbine Unit of a percentage of Natural Gas, indicatively corresponding to 1/3 of the total power generation, and the Volatile Gases of Pyrolysis-Coalization for the remaining 2/ 3, instead of burning only Natural Gas, or with Pure Combustion of Volatile Gases (009) of Pyrolysis-Carbonization, which are fed to the Combustion Chamber (A.6.1B) of the Gas Turbine (A.6.1A) after having previously been compressed to 20 Bar approximately and after they have already undergone a reduction in their temperature through the pre-heating of the Water (012A) of the Exhaust Gas Boiler (012B) of the Combined Cycle Unit, so as to achieve a degree of efficiency of more than 55-60% in the production of electricity.

7) The System (A.7) of Transport and Storage of the produced Charcoal (008A) and (008B) in exhausted coal mines or other available spaces, which is characterized by the fact that in contrast to the current state of the art, where the compression of of bound Carbon Dioxide and its transfer by pipelines to underground geological formations for permanent storage, an expensive process without competitive cost perspective, where the transport of solid Charcoal (008) with System (A.7) is much easier and competitive, because instead of Carbon Dioxide gas we have solid Charcoal 3.667 times lighter and 1000 times smaller in volume, which does not need compression and which can be transported to the exhausted section of active coal mines, using the same wagons that transport the Mineral Coal (009A) rate for the mixed combustion with Biomass (A.2.0) as above, which would otherwise return empty to the coal mine, thus reducing the cost of transport and permanent storage of the pyrolytic Charcoal almost to zero,

E.2. DETAILED DESCRIPTION OF COAL CO2 CAPTURE SYSTEM WITH BIOMASS CHARCOAL AND PERMANENT CHARCOAL STORAGE IN COOPERATION WITH FOSSIL POWER PLANTS

Where the System (A.1) is characterized by the fact that it consists on the one hand of a Semi-Outdoor Storage (A.1.1) of the Biomass (A.2.0) as received, with a provision of shelter for protection from rain, and on the other hand of a First Pre-Drying System (A .1.2) a quantity of Biomass (A.2.0) for the operation of the NPP (A.5.1) indicatively 2-3 days, which takes place in an enclosed heat-insulated Drying Area (A.1.3), with the whole or a part only from the Hot Exhaust Gases (A.1.4) obtained from the entrance of the Chimney (A.1.5) of the Boiler (012) of the Steam Electric Unit (A.5.1), when we do not have desulfurization, which lowers the moisture of the Biomass (A .2.2) and (A.2.1) from 30-35% to a level below 20%, in preparation for the Second Drying System (A.3.1), which takes place in System (A.3) and which removes and the remaining 20% of the moisture before entering the Dry Biomass (A.2.2A) and (A.2.1A) into the Pyrolysis-Carbonation Chambers (001) and (002),

Where in this way the overall efficiency of the Power Generation System (A) increases indicatively by 3-6 centimeter units depending on the percentage of moisture of the Biomass to be dried (A.2.2) and (A.2.1), while the Exhaust Gases (A. 1.4) of the Boiler (012) with a reduced temperature, due to the drying and preheating of the Biomass (A.2.2) and (A.2.1), are transmitted to the Cooling Tower (A.1.8) for expulsion into the atmosphere, carried away by the upward stream of water vapor of the Cooling Tower (A.1.8),

Where the System (A.2) is characterized by the fact that it consists on the one hand of a Fine Biomass preparation facility (A.2.1) with Grinding and Pelletization, when it comes to biomass of thin branches, leaves or residues of agricultural crops of wheat, corn, etc., which either it will be imported for storage in the Biomass Silo (A.2.3) (A.2.1) to be burned in the Hearth (016) of the Boiler (012) in Mixed Combustion with Coal (009A) or it will be formed into pellets of greater volume and density to be introduced into the Loading Baskets (A.2.5) and Wagons (003) for Drying and then Pyrolysis-Carbonization (A.4.1) in the Chambers (001) and Subchambers (002) for the production of Charcoal (008B) from Fine-Grained Biomass and on the other hand, a facility for the preparation of Shredded Biomass (A.2.2) indicatively in pieces with dimensions of more than 5-10 cm in diameter and 30-50 cm in length, when it comes to Woody Biomass from Trees for the production of Coarse Charcoal (008A), and Storage of men Pelletized Biomass (A.2.1) in the Biomass Silos (A.2.3) and the Shredded Biomass (A.2.2) in the Biomass Baling Preparation System (A.2.4), where the Shredded Biomass (A.2.2) together with the required percentage of the Min. Biomass (A.2.1) is bundled in special Loading Baskets (A.2.5) of the Wagons (003), made in the lower part of a Metal Vessel (A.2.5A) to receive the Fine Biomass Pellets (A.2.1) and in the upper section of Metal Mesh (A.2.5B) for holding the Shredded Biomass (A.2.2), all of stainless steel intended for loading into the Wagons (003), where then through the Conveyor Belt (A.2.6) they are introduced the Loading Baskets (A.2.5) in the Drying Area (A.1.3) for the First Stage of Drying before loading into the Wagons (003) and entering the Chambers (001) and Subchambers (002) for Pyrolysis-Carbonization,

Where the System (A.3) is characterized by the fact that it consists of the Chambers (001A) and the Subchambers (002A) of the Second Drying / Preheating System (A.3.2), which are structurally the same as the Pyrolysis-Carbonization Chambers (001 ) and the Subchambers (002) of the System (A.4), with which they alternate the function as Pyrolysis-Carbonization Chambers and then again, as described in detail below, where during their operation they remove the last 20% of the moisture from the Biomass (A.2.2) and (A.2.1) and preheat it, indicatively up to 120°C, through a stream of Hot Exhaust Gases (A.1.4) from the entrance of the Chimney (A.1.5) of the Steam Power Generation Unit (A.5.1) , which with a temperature indicative of 180°C perform the Second Drying of Biomass (A.2.2) and (A.2.1) from a Moisture indicative of 20% to completely Dry Biomass (A.2.2A) and (A.2.1A) with a temperature 120°C, where the Dry Biomass (A.2.2A) and (A.2.1A) is then preheated to Second Stage from 120°C indicatively to 230°C from the cooling of the fully carbonized Charcoal (008A) and (008B), which from a temperature indicatively 520°C exchanges heat with the Dry Biomass (A.2.2A) and (A. 2.1A) of 120°C with the result that it lowers its temperature indicatively to 250°C and then to 50°C by preheating the Feed Water (012A) of the Boiler (012), as below,

Where the System (A.3) consists of the following Components, i.e. it consists indicatively of an equal number of Drying-Preheating Chambers (001A) and Subchambers (002A) with the number of Pyrolysis-Carbonation Chambers (001) and Subchambers (002) of System (A.4), which after complete drying and preheating are converted into Pyrolysis-Carbonation Chambers (001) and Subchambers (002) with a corresponding connection to the circuits of the Air Ducts (010), (015) and (018) of the Chambers (001) and (002) as below, while the corresponding Chambers (001) and (002) after the performance of Charcoal (008A) and (008b) and loading with new Biomass (A.2.2) and (A.2.1) they are converted into Drying-Preheating Chambers (001A) and (002A) with a corresponding connection to the circuits of the Air Ducts (018) and (022) of Chambers (001A) and (002A).

Where the System (A.4) is characterized by the fact that it consists of a Biomass Pyrolysis-Carbonization Unit (A.4.1), consisting of the Carbonization Pyrolysis Chambers (001) and Subchambers (002), where the Biomass (A.2.2A) and (A.2.1A), consisting of polysaccharides with a typical composition of 48-52% Carbon, 40-44% Oxygen and 6-8% Hydrogen, heated indicatively to approximately 550°-620°C in the absence of oxygen and air in general, so the Volatile and Oily components of Biomass (A.2.2A) and (A.2.1A) are separated, which are gasified, collected and removed as Gaseous Components (009) of Pyrolysis-Carbonization, while Charcoal (008A) and (008B) approximately 70% of the initial carbon of the Biomass is collected and removed after first reducing its temperature by preheating the supplied Biomass (A.2.2A) and (A.2.1A) or the Water ( 012A) of Boiler (012), is temporarily stored and sent for permanent storage in underground spent coal mines or other suitable permanent storage sites.

Where the System (A.4) consists of the following Components, i.e. it consists indicatively of an equal number of Drying-Preheating Chambers (001) and Subchambers (002) with the number of Chambers (001A) and Subchambers (002A) of the System (A ... Pyrolysis-Carbonization Subchamber (002), which is also made of high-temperature steel plate, which is sealed to the Chamber (001), with a single outlet for the produced Volatile Gaseous Products (009) the Volatile Air Duct (015), where the Pyrolysis-Carbonation Subchamber (002) is heated by the Superheated Exhaust Gases (014) and pyrolyzes the contained Biomass (A.2.2A) and (A.2.1A), the Loading Wagon (003) of the Subchamber (002), the Door Stamping (004) of the Chamber (001), the Seal Door (005) of the Subchamber (002), the Tracks (006) of the Wagon (003), the Loading Baskets (A.2.5) of the Wagons (003), the Biomass ( A.2.2) and (A.2.1) loading of the Wagon (003), the Produced Charcoal (008A) and (008B), the Volatile Gaseous Products (009) of the Pyrolysis-Carbonization (A.4.1), the Supply and Recirculation Pipe (010) of the Superheated Exhaust Gases (014) from the Stove (016) of the Boiler (012) of the NPP (A.5.1), the Superheated Exhaust Gases (014) from the Boiler (012) with temperatures indicatively above 750°C, the which heat and pyrolyze-carbonize the preheated Dry Biomass (A.2.2A) and (A.2.1A) inside the Subchamber (002) and are recycled to the Boiler (012), the Isolation Flaps (013) of the Subchambers (002) from the circulation of the Superheated Exhaust Gases (014), the Volatile Air Duct (015), which abducts the produced Volatile Gaseous Products (009) from the Hypochamber (002) and leads them for combustion to the Hearth (016) of the Boiler (012), where in addition, a part of the initial amount of fossil fuel combustion is burned, indicatively Coal (009A), indicatively 1/3 of Coal Fuel (009A) or Pelletized Biomass (A.2.1), the Isolation Flaps (017) of the Subchambers (002) from the Volatile Air Duct (015), the Preheating Air Duct (018), which recirculates the Preheating Air (019), which preheats the Dry Biomass (A.2.2A) and (A.2.1A) to the last Preheating Drying Subchamber ( 002A) with the extracted heat from the superheated Charcoal (008A) and (008B) in the Subchamber (002), in which the Pyrolysis-Carbonization (A.4.1) has just finished and is to be taken out for storage, before the Preheating Drying Subchamber (002A) becomes a Pyrolysis-Carbonization Subchamber (002), the Isolation Flaps (021) of the Subchambers (002) and (002A) from the Preheating Air Duct (018), the Exhaust Gas Circulation Air Duct (022) (A.1.4) of the Chimney ( A.1.5) of the AIS (A.5.1) temperature indicatively 180°C for the Second Drying and Preheating of Biomass (A.2.2) and (A.2.1) with 20% Humidity in the Subchambers (002A) of the Drying Chambers (001A), the Depression Fan (023), which sucks in and sends part of the Exhaust Gases (A .1.4) of the Chimney (A.1.5) of the NPP (A.5.1) for the Second Drying as above, which it then promotes for expulsion into the atmosphere through the Cooling Tower (A.1.8), where the Loading Wagon (003 ) consists of the Loading Vessel (025) made of high temperature steel plate, the Rolling Wheels (026), the Holding Box (027) of the Loading Baskets (A.2.5) of the Dry Biomass (A.2.2A) and (A .2.1A), which is made of perforated steel plate resistant to high temperatures, the Depression Fan (028) and the Suction Fan (029), which respectively depress and suck the Superheated Exhaust Gases (014) from the Boiler (012) into the chambers (001) and recycle them again to the Boiler (012), the Fans Arr (030), which suck the Hot Air (019) from the cooling of the superheated Charcoal (008A) and (ΕΟ80) in the Subchamber (002) and recycle it for preheating the Dry Biomass in the Subchamber (002A) as above, the Fan Suction (031), which sucks the produced Volatile Gas Products (009) from the Hypochamber (002) and through the Volatile Air Duct (015) abducts them and leads them for combustion to the Hearth (016) of the Boiler (012), the Duct (032) for Exhaust Gas Circulation (A.1.4) of the Chimney (A.1.5) of the NPP (A.5.1) for the First Stage of Biomass Drying (A.2.2) and (A.2.1), the Depression Fan (033) ), which sucks in and sends part of the Exhaust Gases (A.1.4) of the Chimney (A.1.5) of the NPP (A.5.1), temperature indicative of 180°C, for the First Stage of Biomass Drying, which it then promotes for emission into the atmosphere through the Cooling Tower (A.1.8), the Exhaust Gas Circulation Duct (022) (A.1.4) of the Chimney (A.1.5) of the NPP (A.5.1) temperature indicative of 180°C for the Second Drying and Preheating of the Biomass (A.2.2) and (A.2.1) and (A.2.1), and the Isolation Flaps (034) of the Subchambers (002) and (002A) from the Air Duct Warm-up (022),

Where the System (A.5) is characterized by consisting of a typical existing or new Coal or Oil-fired Steam Power Plant (A.5.1), which is modified on the one hand to allow mixed combustion of gaseous products (009) from the Pyrolysis-Carbonization of Biomass (A.2.2A) and (A.2.1A) with a percentage of Pelletized Biomass (A.2.1) as well as with a percentage of Coal (009A) and on the other hand with the addition of a Pyrolysis System (A.4.1) -Biomass Carbonization, where it becomes possible to burn in the Boiler (012) of the Modified Coal or Oil Unit, instead of Coal (009A), mixed combustion of Coal or other fossil fuels together with the Volatile Gaseous Products (009) of Pyrolysis-Carbonization and with a percentage of Pelletized Biomass (A.2.1), resulting in a reduction up to almost total avoidance of Carbon Dioxide emissions, where the Carbon Dioxide content in the Volatile Gaseous Products (009) of Pyrolysis-Carbonization (A.4.1) and in the Pelletized Biomass (A.2.1) does not count as a greenhouse gas because it comes from the Carbon Dioxide of the atmosphere that has been captured by plants, while at the same time a Negative Carbon Dioxide Emission is achieved due to the production of Charcoal (008A) and (008B), which is equivalent to the capture of 3.667 times heavier Atmospheric Carbon Dioxide and which is removed for permanent storage in exhausted coal mines or other suitable permanent storage areas, while at the same time reducing or completely eliminating the operation of the Chimney (A.1.5) of the NPP (A.5.1) , which is replaced by the operation of the modified Cooling Tower (A.1.8), which propels into the atmosphere the Exhaust Gases (A.1.4) of reduced temperature due to preheating of the Biomass (A.2.2) and (A.2.1) with the upward flow Water vapor of the Cooling Tower (A.1..8),

Where System (A.6) is characterized by replacing a typical Natural Gas-fired Combined Cycle Power Plant with a System consisting of a Biomass Pyrolysis-Carbonization Unit (A.4.1) and a Modified Combined Cycle Power Plant (A.6.1), which instead of operating with only Natural Gas combustion, operates with Mixed Combustion of the Volatile Gaseous Products (009) of Pyrolysis-Carbonization in combination with a percentage of Natural Gas or other mineral gases or liquid fuels, or and only with Pure Combustion of Volatile Gases (009) of Pyrolysis-Carbonization (A.4.1), resulting in a drastic reduction of Carbon Dioxide emission, with parallel Sequestration and Storage of Atmospheric Carbon Dioxide in the form of Solid Charcoal (008),

where the Volatile Gases (009) of Pyrolysis-Carbonization (A.4.1) are supplied to the Combustion Chamber (A.6.1B) of the Gas Turbine (A.6.1A) after being compressed to approximately 20 Bar through the Compressor (A.6.1D) , and having previously undergone a reduction in temperature through the preheating of the Feed Water (012A) of the Exhaust Gas Boiler (012B) of the Combined Cycle Unit (A.6.1), so as to achieve the standard efficiency of a corresponding unmodified Combined Cycle Unit (A.6.1), i.e. more than 55-60% in electricity production.

Where the System (A.3) of the System (A.6) is the same as the System (A.3) of the Power Generation Unit with mixed Coal combustion (A.5.1) above, it is characterized by the fact that the Hot Exhaust Gas stream ( A.1.4) comes from the entrance of the Chimney (A.1.5) of the Exhaust Gas Boiler (012B) of the Combined Cycle Unit (A.6.1), as well as from the superheated Exhaust Gases (014) coming from part of the superheated Exhaust Gases (014A) ) from the exit of the Gas Turbine (A.6.1A) with a temperature indicative of 600°C, which increases to approximately 750°C with the post-combustion of Biomass (A.2.1) or a small part of the Volatile Gaseous Products (009) of Pyrolysis-Carbonization or and Natural Gas in the Post-Combustion Chamber (A.6.1r), and which after pyrolyzing-carbonizing the Biomass (A.2.2) and (A.2.1) in the Pyrolysis-Carbonization System (A.4.1) exit the System (A. 4.1) with a temperature of approximately 600°C again and enter the Exhaust Gas Boiler (012) of the Combined Cycle Unit (A.6.1), so that the degree of of the Modified Combined Cycle Unit to remain high, indicatively the same as that of a corresponding standard Combined Cycle Unit.

Where System (A.7) is characterized by the fact that it consists of a temporary storage of the produced Charcoal (008A) and (008B), which is then either advanced for permanent storage in underground depleted coal mines or in the depleted part of active coal mines, indicatively with the same wagons or conveyor belts, with which the percentage of Mineral Coal (009A) is transported for the mixed combustion as above, thus greatly reducing the cost of transportation and permanent storage of the produced Charcoal (008A) and (008B) either and in other suitable permanent storage areas or a part of it is sold for various industrial uses.

REFERENCES

[1] Application for a Patent Certificate to the OBI with Application Number 2018100308 from 10.07.2018

[2] Existence in Coal-fired Power Plants of on-site strategic energy production reserve of more than 90 days with corresponding carbon stock storage, which does not apply to PV and other RES units

[3] Application for a Patent Certificate to the OBI with Application Number 2019100079 from 09.01.2019

[4] Target of a maximum allowable increase in the temperature of the Planet of 1.5°C instead of the previous UN limit of 2.0°C, which is now judged insufficient

[5] UN COP21 Agreement in Paris 2015 on Climate Change

[6] Research Funded By Leonardo DiCaprio Foundation Under One Earth Initiative Claims World Can Stay Below 1.5°C With 100% Renewable Energy Achieved By 2050

[7] "Australia to plant a billion trees to reverse climate change"

[8] "Australia in Tree-Planting Binge to Help Meet Climate Targets"

[9] "There is scope for planting 1.2 tri, trees on the planet" Research of the Federal Institute of Technology Zurich, Thomas Crowther

[10] "From polluting lungs"

[11] "Forests 'Attack' the Climate"

[12] "Development & Design Study of Metal Biomass Pyrolysis Furnace" University of Thessaly

Claims (4)

A X I O S E I S 1. A Carbon Dioxide Negative Emission Power Generation System (A), which is characterized by the fact that on the one hand it reduces Carbon Dioxide Emissions to zero while on the other hand it simultaneously captures large amounts of Atmospheric Carbon Dioxide (Negative Carbon Dioxide Emission Technology) with the form of Solid Pyrolytic Charcoal in Power Generation Units burning fossil fuels, where in contrast to the current State of the Art, as presented in the Preamble, which seeks to reduce to zero the emissions of Carbon Dioxide from Power Generation Units burning fossil fuels, with a final difficult or the unattainable goal of achieving an economically competitive technology for capturing, compressing and storing the bound Carbon Dioxide in underground geological formations, which is still in the research and development stage, where: PREAMBLE: The current state of the art for the capture and permanent storage of carbon dioxide released in power generation from fossil fuels, indicatively from coal, oil and natural gas, consists of capturing the carbon dioxide in the exhaust gases by spraying with an ammonia solution and then compressing it for transportation by pipeline networks for permanent storage in underground geological formations of spent oil or natural gas reservoirs, an expensive process without commercial interest, which is still in the research and development stage. However, recent studies by reputable research bodies and the UN have concluded that simply reducing carbon dioxide emissions to zero by 2050 is not enough to achieve the new UN goal of keeping the planet from warming below 1.5 °C, but sequestration and permanent storage of equally large amounts of Atmospheric Carbon Dioxide or otherwise Negative Carbon Dioxide Emissions are also required to hope for a better chance that Climate Change will not become irreversible, Based on the current state of the art in electricity generation from fossil fuels, efforts are being made to reduce to zero the emissions of Carbon Dioxide, which is captured in the exhaust gases of the Units, compressed and sent for permanent storage in underground geological formations, depleted oil or natural gas reservoirs . The same is done in Biomass-burning Units, where the storage of the released Carbon Dioxide as above has a double effect, i.e. on the one hand, the avoidance of the emission of equivalent Carbon Dioxide from Carbon Units and the binding of KOL permanent storage in the underground geological formations of the corresponding amount of Atmospheric Carbon Dioxide, which had been absorbed from the atmosphere by plants, However, to date, despite intensive research and funding of demonstration units as above, no technology has been able to demonstrate technically and economically viable solutions that can be implemented commercially without the need for government subsidies of any kind, FEATURED PART On the contrary, the Power Generation System (A) with Negative Carbon Dioxide Emissions of the present invention [hereinafter Power Generation System (A)] is characterized by the fact that it operates with mixed fossil fuel combustion, indicative of Coal and the Volatile Components from Biomass Pyrolysis, in which approximately 40% of the weight of Dry Biomass remains as Pyrolytic Charcoal, which is equivalent to sequestration and storage of Atmospheric Carbon Dioxide, where on the one hand it achieves a reduction to zero of Carbon Dioxide emissions in power generation, while on the other hand it simultaneously sequesters large amounts of Atmospheric Carbon Dioxide in the form of Solid Pyrolytic Charcoal, which is an excellent Soil Improver, the sale of which leaves a significant income for the Power Plant, Where the Power Generation System (A) is also characterized by the fact that, in addition to the reduction to zero of Carbon Dioxide emissions in Power Generation Units burning fossil fuels, it also achieves the Sequestration of even greater amounts of Atmospheric Carbon Dioxide than those avoided , which it yields in the form of Solid Charcoal, which has considerable commercial value as a commercial product, tested in thousands of demonstrative programs, where it dramatically increases agricultural production as a soil conditioner and is characterized by the fact that the sale of which, together with the avoidance of Market of Carbon Dioxide Rights and the Credit due to Atmospheric Carbon Dioxide Commitment, highlight, with a small modification in accordance with the present invention, the currently harmful and dangerous for the Environment, due to Carbon Dioxide emissions, Power Plants, indicatively with Coal combustion, on the one hand highly competitive Ms profitable compared to any other power generation technology and on the other hand to Units that benefit the Environment by Sequestering very large amounts of Atmospheric Carbon Dioxide, which they dispose of in the form of Solid Pyrolytic Charcoal as a commercial product, thus turning into Benefactors and Defenders of the Environment against climate change, Where the Power Generation System (A) is characterized by the fact that it operates with mixed combustion of fossil fuel, indicative of Coal and Volatile Components from Biomass Pyrolysis, in which approximately 40% of the weight of Dry Biomass remains as Pyrolytic Charcoal, which is equivalent to binding and storage of Atmospheric Carbon Dioxide and which, in contrast to the current state of the art, where it is envisaged to compress the captured Carbon Dioxide and transfer it with pipelines to underground geological formations for permanent storage, an expensive process with no competitive cost perspective, where the transport and permanent storage of Pyrolytic Charcoal is technically much easier and competitive, because instead of Carbon Dioxide gas we have Solid Pyrolytic Charcoal 3.667 times lighter and 1000 times smaller in volume, which does not need compression and which can be transported to the exhausted section in carbon energy mines, using the same wagons that transport the percentage of Coal for co-firing with Biomass, which would otherwise be empty in the coal mine, thus reducing the cost of transporting and permanently storing the Pyrolytic Charcoal almost to zero or depositing it as a Soil Ameliorator in the Agriculture, where it remains unchanged for millennia, while at the same time increasing agricultural production by up to 200%, while at the same time instead of transport and storage costs, it leaves with its sale a serious profit to the Power Plant, Where the Carbon Dioxide Emissions-Negative Power Generation System (A) is also characterized by being a combination of a Modified Co-Fired Steam Power Plant from Fossil Fuels, indicative of Coal (009A), and from Biomass (A.2.0), and of an innovative Pyrolysis-Carbonization (A.4.1) installation of Biomass (A.2.0) for the production of Charcoal (008) for permanent storage, with parallel production of Pyrolytic Volatile Gas Products (009) from the Pyrolysis-Carbonization of Biomass (A.2.0) , which is characterized by the fact that it consists of the following parts, namely: 1) The Biomass Storage System (A.1) (A.2.0) which is characterized by having provision for First Drying with the Hot Exhaust Gases (A.1.4) of the Chimney (A.1.5) of the Modified Power Generation Unit (A. 5.1), in contrast to the current state of the art where the Hot Exhaust Gases (A.1.4) of the Chimney (A.1.5) are discharged through the Chimney (A.1.5) into the atmosphere, without thermal exploitation, 2) The Biomass Preparation System (A.2) (A.2.0), which is characterized by having on the one hand Grinding-Pelletization and Storage of Fine Biomass (A.2.1) in Biomass Silos (A.2.4) or in Baskets Loading (A.2. 5) and on the other hand Shredding the Woody Biomass (A.2. 2) and Storing it for Drying together with the Biomass (A.2.1) in the First Stage of Drying in the Drying Area (A.2. 3), in contrast to the current state of the art where the pyrolysis biomass is not dried with the boiler waste gases, while the fine biomass even when pelletized, is not intended for drying and pyrolysis-carbonization for the production of Charcoal (008B) Fine-grained Biomass but only for burning and heat generation, 3) The System (A.3) for Drying and Preheating the Biomass (A.2. 2) and (A.2.1), which is characterized by having on the one hand a Second Stage Drying with a part of the Hot Exhaust Gases (A.1.4 ) taken from the exit of the Boiler (012) and before entering the Chimney (A.1. 5), and on the other hand then in the System (A.3) Preheating of Dry Biomass (A.2.2A) and (A. 2.1A) in a Second Stage from the cooling of the fully carbonized superheated Charcoal (008A) and (008B), in contrast to the current state of the art where the pyrolysis biomass is not dried even in a second stage with the available Hot Exhaust Gases (A.1.4) from the exit of the Boiler (012), nor does it subsequently proceed to Preheating the Dry Biomass (A.2.2A) and (A.2.1A) in a Second Stage from the cooling of the fully carbonized superheated Charcoal (008A) and (008B), which means that the thermal efficiency of pyrolysis-carbonization is very poor compared to System (A.3), 4) The System (A. 4) Pyrolysis-Carbonization (A.4.1) of Biomass (A.2.2) and (A.2.1), which is characterized by the fact that during Pyrolysis-Carbonization, it separates the Volatile Gases (009), which are channeled either for combustion in the Stove (016) of the Boiler (012) of the Steam Power Generation Unit (A.5.1) or for other thermal uses and on the other hand the produced Pyrolytic Charcoal (008A) and (008b), which is pyrolyzed-carbonized by heating from part of the of superheated flue gases (014) from the Stove (016) of the Boiler (012) and then, after being cooled by heat exchange with the Dry Biomass (A.2.2A) and (A.2.1A) of the System (A.3), it is removed for storage in exhausted coal mines or other available storage areas or for sale as a commercial product, with degrees of thermal efficiency of the overall process up to and including Pyrolysis-Carbonization (A.4.1) indicatively above 80% with multiple heat recovery as above, in contrast with the current level of technology s for the pyrolysis-carbonization of biomass, where the degree of thermal efficiency is very poor resulting in uncompetitive energy production costs from the volatile gaseous products of pyrolysis-carbonization, where moreover the pyrolysis-carbonization of fine Biomass is not even applied (A.2.1 ), 5) The System (A.5) of the Modified Steam Electric Power Generation Unit (A.5.1) with initial combustion of coal or oil or other fossil fuels, indicative of coal (009A), which is characterized by the fact that it has been modified for the combustion of Volatile Gases ( 009) of Pyrolysis-Carbonization (A.4.1) or Pelletized Biomass (A.2.1) in the Hearth (016) of the Steam Boiler (012), instead of burning exclusively Mineral Coal (009A), but in mixed combustion with it in the percentage which is necessary, with additional heat recovery from the Charcoal (008A) and (008B) for preheating the Biomass (A.2.2) and (A.2.1) as well as the Feed Water (012A) of the Boiler (012), while in addition has a heat recovery system from the Hot Exhaust Gases (A.1.4) of the Chimney (A.1.5) of the NPP (A.5.1) and for the Second Drying of Biomass as above, and where then the cold Exhaust Gases (A.1.4) instead of the Chimney (A.1.5) are transmitted to Desulphurization when it exists and then to the Tower Cooling Tower (A.1.8) for discharge into the atmosphere, carried away by the upward current of water vapor of the Cooling Tower (A.1.8), so as to achieve a high degree of efficiency in the production of electricity, in contrast to the current state of the art where no recovery is made of the rejected heat, with the result that the degree of efficiency in the production of electricity in the carbonization pyrolysis process is very poor, 7) The System (A.7) of Transport and Storage of the produced Charcoal (008A) and (008b) in exhausted coal mines or other available areas or for sale as a commercial product, 2. A Power Generation System with Negative Carbon Dioxide Emissions (A), as in Claim 1, which is characterized in that the Pyrolysis-Carbonization of the Biomass takes place in "Packages", i.e. in Pyrolysis-Carbonization Chambers of the Systems (A.3) and (A.4), which are characterized by the fact that they consist of the following Parts, namely, Where the System (A.3) is characterized by the fact that it consists of the Chambers (001A) and the Subchambers (002A) of the Second Drying / Preheating System (A.3.2), which are structurally the same as the Pyrolysis-Carbonization Chambers (001 ) and the Subchambers (002) of the System (A.4), with which they alternate the function as Pyrolysis-Carbonization Chambers and vice versa, where during their operation they remove the last 20% of the moisture from the Biomass (A.2.2) and (A.2.1) and preheat it, indicatively up to 120°C, through a stream of Hot Exhaust Gases (A.1.4) from the entrance of the Chimney (A.1.5) of the Steam Power Generation Unit (A.5.1), which with temperature indicatively 180°C perform the Second Drying of Biomass (A.2.2) and (A.2.1) from Moisture indicatively 20% to completely Dry Biomass (A.2.2A) and (A.2.1A) with a temperature of 120°C, where then the Dry Biomass (A.2.2A) and (A.2.1A) is preheated in a Second Stage from 120°C indicatively to 230°C from the cooling of the fully carbonized Charcoal (008A) and (008B), which from a temperature of approximately 520°C exchanges heat with the Dry Biomass (A.2.2A) and (A.2.1A) of 120°C with result in lowering its temperature indicatively to 250°C and then to 50°C by preheating the Feed Water (012A) of the Boiler (012), Where the System (A.3) consists of the following Components, i.e. it consists indicatively of an equal number of Drying-Preheating Chambers (001A) and Subchambers (002A) with the number of Pyrolysis-Carbonation Chambers (001) and Subchambers (002) of System (A.4), which after complete drying and preheating are converted into Pyrolysis-Carbonation Chambers (001) and Subchambers (002) with a corresponding connection to the circuits of the Air Ducts (010), (015) and (018) of the Chambers (001) and (002) as below, while the corresponding Chambers (001) and (002) after the performance of Charcoal (008A) and (008b) and loading with new Biomass (A.2.2) and (A.2.1) are converted into Drying-Preheating Chambers (001A) and (002A) with a corresponding connection to the circuits of the Air Ducts (018) and (022) of Chambers (001A) and (002A), Where the System (A.4) is characterized by the fact that it consists of a Biomass Pyrolysis-Carbonization Unit (A.4.1), consisting of the Carbonization Pyrolysis Chambers (001) and Subchambers (002), where the Biomass (A.2.2A) and (A.2.1A), is heated indicatively to approximately 520°-560°C in the absence of oxygen and air in general, so the Volatile and Oily components of the Biomass (A.2.2A) and (A.2.1A) are separated, the which are gasified, collected and removed as Gaseous Components (009) of Pyrolysis-Carbonization, while Charcoal (008A) and (008B) at a rate of approximately 80% of the initial carbon of the Biomass is collected and removed after first reducing its temperature by preheating the of supplied Biomass (A.2.2A) and (A.2.1A) or Water (012A) of the Boiler (012), is temporarily stored and sent for permanent storage in underground exhausted coal mines or other suitable places of permanent storage or sold as a commercial product , Where the System (A.4) consists of the following Components, i.e. it consists indicatively of an equal number of Drying-Preheating Chambers (001) and Subchambers (002) with the number of Chambers (001A) and Subchambers (002A) of the System (A .3), where the Pyrolysis-Carbonization Chamber (001) is made of steel plate resistant to high temperatures, with an internal lining of Firebricks (001B) and an external Insulation (001r) of stone wool blanket approximately 20 cm thick, and which consists of Pyrolysis-Carbonation Sub-Chamber (002), which is also made of high-temperature resistant steel plate, which is sealed with respect to the Chamber (001), with a single outlet for the Volatile Gaseous Products produced (009) the Volatile Air Duct (015), where the Pyrolysis-Carbonation Subchamber (002) is heated by the Superheated Exhaust Gases (014) and pyrolyzes the contained Biomass (A.2.2A) and (A.2.1A), the Loading Wagon (003) of the Subchamber (002), the Door Stamping (004) of the Chamber (001), the Seal Door (005) of the Subchamber (002), the Tracks (006) of the Wagon (003), the Loading Baskets (A.2.5) of the Wagons (003), the Biomass ( A.2.2) and (A.2.1) loading of the Wagon (003), the Produced Charcoal (008A) and (008B), the Volatile Gaseous Products (009) of the Pyrolysis-Carbonization (A.4.1), the Supply and Recirculation Pipe (010) of the Superheated Exhaust Gases (014) from the Stove (016) of the Boiler (012) of the NPP (A.5.1), the Superheated Exhaust Gases (014) from the Boiler (012) with temperatures indicatively above 750°C, the which heat and pyrolyze-carbonize the preheated Dry Biomass (A.2.2A) and (A.2.1A) inside the Subchamber (002) and are recycled to the Boiler (012), the Isolation Flaps (013) of the Subchambers (002) from the circulation of the Superheated Exhaust Gases (014), the Volatile Air Duct (015), which abducts the produced Volatile Gaseous Products (009) from the Hypochamber (002) and leads them for combustion to the Hearth (016) of the Boiler (012), where in addition, a part of the initial amount of fossil fuel combustion is burned, indicatively Coal (009A), indicatively 1/3 of Coal Fuel (009A) or Pelletized Biomass (A.2.1), the Isolation Flaps (017) of the Subchambers (002) from the Volatile Air Duct (015), the Preheating Air Duct (018), which recirculates the Preheating Air (019), which preheats the Dry Biomass (A.2.2A) and (A.2.1A) to the last Preheating Drying Subchamber ( 002A) with the extracted heat from the superheated Charcoal (008A) and (008B) in the Subchamber (002), in which the Pyrolysis-Carbonization (A.4.1) has just finished and is to be taken out for storage, before the Preheating Drying Subchamber ( 002A) becomes the Pyrolysis-Carbonization Subchamber (002), the Isolation Flaps (021) of the Subchambers (002) and (002A) from the Preheating Duct (018), the Exhaust Gas Circulation Duct (022) (A.1.4) of the Chimney (A .1.5) of the AIS (A.5.1) temperature indicative of 180°C for the Second Dry heating and Preheating of Biomass (A.2.2) and (A.2.1) with 20% Humidity inside the Subchambers (002A) of the Drying Chambers (001A), the Depression Fan (023), which sucks in and sends part of the Exhaust Gases (A .1.4) of the Chimney (A.1.5) of the NPP (A.5.1) for the Second Drying as above, which together with the cold Exhaust Gases from the first Drying, promotes them to Desulphurization when it exists and then for expulsion into the atmosphere inside from the Cooling Tower (A.1.8), where the Loading Wagon (003) consists of the Loading Vessel (025) made of high-temperature steel plate, the Rolling Wheels (026), the Holding Box (027) of the Loading Baskets ( A.2.5) of Dry Biomass (A.2.2A) and (A.2.1A), which is made of perforated steel plate resistant to high temperatures, the Depression Fan (028) and the Suction Fan (029), which suppress and the Superheated Exhaust Gases (014) from the Boiler (012) are respectively sucked into the alums (001) and recirculate them again to the Boiler (012), the Suction Fans (030), which suck the Hot Air (019) from the cooling of the superheated Charcoal (008A) and (008B) to the Hypochamber (002) and the recycle yia preheating of the Dry Biomass in the Subchamber (002A) as above, the Suction Fan (031), which aspirates the produced Volatile Gaseous Products (009) from the Subchamber (002) and through the Volatile Air Duct (015) abducts them and leads them for combustion to the Hearth (016) of the Boiler (012), the Exhaust Gas Circulation Duct (032) (A.1.4) of the Chimney (A.1.5) of the NPP (A.5.1) for the First Stage of Biomass Drying ( A.2.2) and (A.2.1), the Suction Fan (033), which sucks in and sends part of the Exhaust Gases (A.1.4) of the Chimney (A.1.5) of the NPP (A.5.1), temperature indicative of 180° C, for the First Stage of Biomass Drying (A.2.2) and (A.2.1), which it then advances into Desulfurization when available for steam removal sphere from the Cooling Tower (A.1.8), the Exhaust Gas Circulation Duct (022) (A.1.4) of the Chimney (A.1.5) of the NPP (A.5.1) at an indicative temperature of 180°C for the Second Drying and Preheating of Biomass (A.2.2) and (A.2.1) and the Isolation Flaps (034) of the Subchambers (002) and (002A) from the Preheating Air Duct (022), Where the System (A.5) is characterized by consisting of a typical existing or new Coal or Oil-fired Steam Power Plant (A.5.1), which is modified on the one hand to allow mixed combustion of gaseous products (009) from the Pyrolysis-Carbonization of Biomass (A.2.2A) and (A.2.1A) with a percentage of Pelletized Biomass (A.2.1) as well as with a percentage of Coal (009A) and on the other hand with the addition of a Pyrolysis System (A.4.1) -Biomass Carbonization, where it becomes possible to burn in the Boiler (012) of the Modified Coal or Oil Unit, instead of Coal (009A), mixed combustion of Coal or other fossil fuels together with the Volatile Gaseous Products (009) of Pyrolysis-Carbonization and with a percentage of Pelletized Biomass (A.2.1), resulting in a reduction up to almost total avoidance of Carbon Dioxide emissions, where the Carbon Dioxide content in the Volatile Gaseous Products (009) of Pyrolysis-Carbonization (A.4.1) and in the Pelletized Biomass (A.2.1) does not count as a greenhouse gas because it comes from the Carbon Dioxide of the atmosphere that has been captured by plants, while at the same time a Negative Carbon Dioxide Emission is achieved due to the production of Charcoal (008A) and (008B), which is equivalent to the capture of 3.667 times heavier Atmospheric Carbon Dioxide and which is removed for permanent storage as above, while at the same time reducing or completely eliminating the operation of the Chimney (A.1.5) of the NPP (A.5.1), which is replaced by the operation of the modified Cooling Tower (A.1.8), which promotes into the atmosphere the Exhaust Gases (A.1.4) of reduced temperature due to the preheating of the Biomass (A.2.2) and (A.2.1) with the upward flow of Water Vapor of the Cooling Tower (A. 1.8), 3. A Power Generation System (A) as in Claims 1 and 2, but characterized in that instead of operating the Modified Power Generation Unit (A.5.1) with Mixed Combustion of Mineral Coal (009A), Biomass (A.2.1) and Gases of Volatile Products of Pyrolysis (009) in the Hearth (016) of the Boiler (012), operates with Pure Combustion of Biomass (A.2.1) and Gases of Volatile Products of Pyrolysis (009) or with Pure Combustion of only Volatile Gases of Pyrolysis Products (009) in the Hearth (016) of the Boiler (012), otherwise as in Claims 1 and 2, 4. A Power Generation System (A) as in Claims 1, 2 and 3, which is however characterized by the fact that instead of operating the Modified Power Generation Unit (A.5.1) with complete combustion of the produced Volatile Pyrolysis Product Gases (009) in the Hearth (016) of the Boiler (012), operates with Partial Combustion of a percentage of the Volatile Pyrolysis Products Gases (009) produced in the Hearth (016) of the Boiler (012) and the remaining percentage of the Volatile Pyrolysis Products Gases (009) produced is sent for other uses, thermal or indicative and as an alternative fuel in Transport otherwise as in Claims 1, 2 and 3, 5. A Power Generation System (A) as in Claims 1 and 2, which is however characterized in that instead of containing the System (A.5) of an existing or new Modified Steam Power Plant (A.5.1) as in Claim 2 and 3, contains the System (A.6) of the Modified Combined Cycle Power Generation Unit (A.6.1), which is characterized in that the Gas Turbine (A.6.1A) of the Combined Cycle Unit (A.6.1) operates with a Mixed Combustion of the Volatile Gaseous Products (009) of Pyrolysis-Carbonization in combination with a percentage of Natural Gas or other mineral gases or liquid fuels, resulting in a drastic reduction of Carbon Dioxide emission, with parallel Sequestration and Storage of Atmospheric Carbon Dioxide in the form Solid Charcoal (008), where the Volatile Gases (009) are supplied to the Combustion Chamber (A.6.1B) of the Gas Turbine (A.6.1A) through the Compressor (A.6.1E) at approximately 20 Bar, where the Volatile Gases ( 009) previously have undergo a reduction in their temperature through the preheating of the Biomass (A.2.2) and (A.2.1) as well as the Feed Water (012A) of the Exhaust Gas Boiler (012B) of the Combined Cycle Unit (A.6.1), so as to achieve the high efficiency, Where the System (A.3) of the System (A.6) is the same as the System (A.3) in Claim 2, but is characterized by the fact that the stream of Hot Exhaust Gases (A.1.4) comes from the entrance of the Chimney (A.1.5) of the Exhaust Gas Boiler (012) of the Combined Cycle Unit (A.6.1), as well as from the fact that the superheated Exhaust Gases (014) come from part of the superheated Exhaust Gases (014A) from the Gas Turbine outlet (A.6.1 A) with a temperature indicative of 600°C, which increases to approximately 750°C with the post-combustion of Biomass (A.2.1) or a small part of the Volatile Gaseous Products (009) of Pyrolysis-Carbonization or Natural Gas in the Post-Combustion Chamber (A.6.1) r), and which after pyrolyzing-carbonizing the Biomass (A.2.2) and (A.2.1) in the Pyrolysis-Carbonizing System (A.4.1) exit the System (A.4.1) with a temperature of approximately 600°C again and enter the Exhaust Boiler (012) of the Combined Cycle Unit (A.6.1), so that the efficiency of the Modified Combined Cycle Unit is expects high, 6. A Power Generation System (A) as in Claims 1, 2 and 5, which is however characterized by the fact that instead of operating the Modified Power Generation Unit (A.6.1) with complete combustion of the produced Volatile Pyrolysis Product Gases (009) in the Chamber Combustion Chamber (A.6.1B) of the Gas Turbine (A.6.1A), operates with Partial Combustion of a percentage of the produced Volatile Pyrolysis Product Gases (009) in the Combustion Chamber (A.6.1B) of the Gas Turbine (A.6.1A) and the remaining percentage of the produced Volatile Pyrolysis Products Gases (009) is transmitted for other uses, thermal or indicatively and as an alternative fuel in Transportation otherwise as in Claims 1, 2 and 5, 7. A Power Generation System (A) as in Claim 1, 2, 5 and 6, which is however characterized in that instead of containing the System (A.6) of the Modified Combined Cycle Power Generation Unit (A.6.1), in which the Gas Turbine (A.6.1A) of the Combined Cycle Unit (A.6.1) operates with mixed combustion of Natural Gas and Volatile Gases (009) of Pyrolysis-Carbonization (A.4.1), is characterized by the fact that the Gas Turbine (A.6.1 A) of the Combined Cycle Unit (A.6.1) operates with Pure Combustion of Volatile Gases (009) of Pyrolysis-Carbonization (A.4.1), otherwise as in Claims 1, 2, 5 and 6 above, 8. A System (A.4.1) of Pyrolysis-Carbonization of Biomass, as in Claim 1, 2, 3, 4, 5, 6 and 7, which is characterized by the fact that it does not include the Power Generation Steam Turbine of the NPP (A.5.1) or the Gas Turbine (A.6.1A) of the Combined Cycle Unit (A.6.1), but intended for the production of only the Volatile Pyrolysis Product Gases (009) and additionally Sequestration and Storage of Atmospheric Carbon Dioxide in the form of Pyrolytic Charcoal, while maintaining the mixed combustion of fossil fuels, indicatively Coal (009A), with Biomass (A.2.0) and part of the Volatile Pyrolysis Product Gases (009) in Modified Boilers (012Z) before Pyrolysis-Carbonization (A.4.1), using the produced Gases of Volatile Products of Pyrolysis (009) for various other uses besides electricity generation, such as for thermal uses and as an alternative fuel in Transportation in place of Compressed Natural Gas or in cooperation with the Natural Gas Network, where they will be imported after cool and compress the Gaseous Volatile Products (009), which can be received by the Transport Means already operating with Compressed Natural Gas, either in quantities of Natural Gas proportional to the heat content of the imported Gaseous Volatile Products (009) or in an equivalent Natural Gas since the Gaseous Volatile Products (009) have replaced equivalent Natural Gas, indicatively in Combined Cycle Units (A.6.1) as above in Claim 5, 6 and 7 where in this case the Natural Gas Network can be considered a Distribution Network of the Volatile Gases Products (009) as a Green Alternative Fuel for the Means of Transport, otherwise as in Claims 1, 2, 3, 4, 5, 6 and 7 above, 9. A System (A.4.1) of Pyrolysis-Carbonization of Biomass, as in Claim 1, 2 and 6, which is characterized by the fact that instead of the System (A.4.1) of Pyrolysis-Carbonization of Biomass operating with Mixed Combustion of Mineral Coal ( 009A), Biomass (A.2.1) and Gases of Volatile Pyrolysis Products (009) in the Hearth (016) of the Modified Boiler (012Z), operates with Pure Combustion of Biomass (A.2.1) and Gases of Volatile Pyrolysis Products (009) or with Pure Combustion of only Gases of Volatile Pyrolysis Products (009) in the Hearth (016) of the Boiler (012Z), otherwise as in Claims 1, 2, 3, 4, and 6, 10. A System (A.4.1) of Pyrolysis-Carbonization of Biomass, as in Claim 1, 2, 5, 6, 7 and 8, which is characterized, however, in that the System of an Independent Gas Turbine (A.6.1A) is fed either with Mixed Combustion of Natural Gas and a percentage of the Volatile Pyrolysis Product Gases produced by the System (A.4.1) (009) in the Combustion Chamber (A.6.1B) of the Independent Gas Turbine (A.6.1A) or with Pure Combustion of only those produced by the System (A.4.1) of Volatile Pyrolysis Products Gases (009) in the Combustion Chamber (A.6.1B) of the Independent Gas Turbine (A.6.1A), so the corresponding percentage of those produced by the System (A.4.1) can be received of Gases of Volatile Products of Pyrolysis (009) as an equivalent Alternative Fuel of Gases of Volatile Products (009) in the form of Compressed Natural Gas from the Means of Transport, where, however, the credit for capturing Atmospheric Carbon Dioxide in the form of Pyrolytic Charcoal and Gases of Volatile Products (009) , will be held in Sys subject (A.4.1) of Biomass Pyrolysis-Carbonization, where Pyrolytic Charcoal (008A) and (008B) is produced and the corresponding percentage of the Volatile Pyrolysis Product Gases (009) that are consumed instead of Natural Gas in the Independent Gas Turbine (A.6.1A) , otherwise as in Claims 5, 6, 7 and 8.