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a leading carbon capture company providing industry leadership through cutting-edge technology to reduce environmental impact of CO2 & escalating energy crisis

CCS completes successful commercial testing of CDRMax


Revolutionizing carbon capture technology, we have successfully completed commercial testing of our proprietary CDRMax® carbon dioxide capture solvent technology at Solvay Vishnu Barium recently. The Commercial demonstration of CDRMax®, developed for treating industrial emissions, established breakthrough energy savings and robust performance in the industrial setting where the technology is being operated since August 2012. The 22MTPD (metric tons per day) plant, or 7700 tons per annum CO2 capture plant, , is owned by Solvay Chemicals and is located in India.

The CDRMax® solvent enabled capture of CO2 from a slipstream of flue gas for over 2500 hours, far more than the norm for industrial testing. “The Solvay plant testing has exhibited the robustness of CCS’s technology, which requires almost no modifications to the existing setup”, remarked Prateek Bumb, the Chief Technical Officer of CCS. The flue gas, which originates from a kiln source, contains impurities like high SOx content, NOx (upto 45ppm), particulate matter and high oxygen content. Compared to other technologies previously being used, the CDRMax® solvent required over 10 times less make-up solvent replenishment, consumed 7 times less water, and resulted in increased solvent life by 3 times, leading to savings of $23 per ton of CO2 captured. “The main advantages are lower specific energy consumption by about 30% compared to conventional technology and high O2 tolerance level” said Mr. Tirthankar Mitra, MD Solvay Vishnu Barium.

Tremendous research has gone into post-combustion carbon capture technology as it presents the most seamless and cost-effective way to reduce emissions from existing installations, especially given global governmental push towards stringent regulations. CCS has been at the forefront of technological innovation in chemical solvents for post combustion capture and has secured grants from the UK government and the World Bank (in conjunction with research partner ICT Mumbai). The CCS technology can be retro-fitted to existing installations, and has been independently evaluated by third parties such as TNO as among the best in the market currently.

“The commercial validation has supplied a wealth of data and proof that the technology can be easily scaled up 10-20 times to be fitted into 200-400 MTPD plants. The consistent capture of CO2 from the rapidly changing input gas showcases the technology’s utility in a variety of applications, ranging from industries which require CO2 as input for downstream processes, to power plants which want to reduce emissions and even in biogas up-gradation into natural gas”, said Chief Executive Officer, Aniruddha Sharma.

Adoption of Industrial Carbon Capture


Emission of carbon dioxide is changing the environment around us in an irreversible manner. Recently, Mauna Loa Observatory in Hawaii recorded carbon dioxide concentration of 400 parts per million (ppm) a record high.Production of carbon dioxide has accelerated in past few decades, led by rapid industrialization and increase in population.Long accepted by scientists, leader around the world are now actively engaging in announcing measures to curb and control emission of carbon dioxide.

In fact, President Obama in a recent speech stated that “the question is not whether we need to act — the overwhelming judgment of science, of chemistry and physics and millions of measurements, has put all that to rest.”

He also said: “The question now is whether we will have the courage to act before it’s too late.”

Somewhat driven by regulation, many industries are now recognizing the need for low carbon methods of production. Carbon capture is without a doubt first on the list. Carbon Capture technology holds the key to revolutionize the way carbon dioxide is emitted from industries.

Understanding industrial Carbon Capture:

Manufacturing processes and production of goods releases flue / waste gases into the atmosphere. These gases can be seen as smokestacks rising from chimneyof these industrial facilities.Carbon dioxide is a major pollutant and component of these gases and once released into the atmosphereit accelerates global warming.

The process of Carbon Capture involves capturing carbon dioxide from point sources like large factories and industrial facilities. For example, fossil fuel plants are one of the biggest contributors to excess and harmful carbon dioxide. This carbon dioxide, once captured is transported to a location where it is utilized for producing a product or storing underground. Former is an existing approach used in urea and chemicals industry. While, later involves storing carbon dioxide underground so thatit will not escape into the atmosphere. This is generally under a geological structure, which traps the carbon dioxide.

In the fertilizer industry carbon dioxide is an important raw material. When urea an important fertilizer is produces huge amounts of carbon dioxide is used along with ammonia. Such a beneficial conversion of carbon dioxide reduces emissions, saves energy and produces economic value.

In power generation using fossil fuels carbon emissions are unavoidable. CCS is the only technology available, which offers the potential to convert the carbon dioxide emissions into harmless reusable products. Although this is widely being considered, a big wave of change in the processing of carbon emissions is still to be seen.

Since the time of the industrial revolution, steel has been the backbone of the world’s economy. World simply cannot do without steel. In such a situation, cutting back on the production of steel to reduce its impact on the environment is not an option. However, a cleaner way to manufacture steel can be utilized. Most steel industries use coal or natural gas as fuel. The result of using fossil fuelsis of course, carbon emissions.

The solution to this problem is carbon capture.It is an effective answer to the dilemma the steel industry is facing today. When fitted to a steel plant carbon capture reduces the carbon dioxide emissions by 30% – 90%. With a modified process, efficiency could also be improved.

Carbon Clean Solutions’ breakthrough and cost effective technology offers prospective for carbon emission free industrial production& processes. Company’s patented technology to effectively remove about 90% of the harmful carbon dioxide emissions from the flue gases can be retrofitted to all chemical, steel and process plants.


Clean and Green Cities Around the World


Excess use of resources led by industrialization and population growth is leading to an unprecedented demand for energy. Higher the number of people using even higher number of services leads to higher energy demand. Climate change is a slow phenomenon, sometimes so slow that we tend to overlook the fact that it is an irreversible phenomenon. However, climate change is very much real. For example, this month the CO2 concentration level crossed crucial 400ppm mark,it was 393ppm during Copenhagen Climate Change conference in 2009. As the CO2 concentration is building up triggering erratic climate behavior,more and more cities are recognizing this danger and working towards eco friendly solutions. Here are some of the most popular:

1)       Reykjavik, Iceland: Recently, Reykjavik has been in the news because of its hydrogen buses. That’s right, buses which are run completely on hydrogen. This might just be the most eco friendly mode of public transport yet. All of Reykjavik’s electricity comes from entirely renewable resources, just like the rest of Iceland.

2)       Portland, Oregon, United States:Portland , the argri city has avastlygreen cover – about 92 thousand acres. The city also takes stringent and way above average measures to ensure that it remains one of the most eco friendly cities in the world. Its strong public transport and great natural trails makes it one of the most sought after city at least in terms of clean air.

3)       Kritianstad, Sweden: City essentially uses no imported oil, gas or coal for heating homes or businesses. City generated enough biogas from agri waste, lanfills and sewage treatment plants to fulfill all needs locally.

Living in the city of Mumbai, breathing clean air or seeing many green trees seems like it is unachievable or impossible. Considering Mumbai’s waste disposal problem (Deonar, Mumbai’s dumping ground accepts more than 4000 tonnes of waste everyday and it is just a 132 hectare plot) you would think that looking at an energy source with its core in recycling would seem like a logical option.

Mumbai, or should we say India should accept its responsibility towards future generations and aim towards a more sustainable disposal of waste. Pollution reigns in the city, in spite of a thriving public transport system. City generates enough wastes to generate CNG from biogas system that, if implemented can greatly reduce the stress that Mumbai’s environment is under. Considering the raw material for Biogas (lots of degradable waste) is handy, it is an option whichneeds immediate attentionand immplementation.

However, there are a few concerns while using a source such as Biogas. When biogas is producedfrom waste, 3 gases are obtained. Methane, which is a desirable gas and hydrogen sulphide as well as carbon dioxide.The presence of carbon dioxide and hydrogen sulphide, reduce the efficiency and efficacy.of the system and hence need to be removed before biogas can be used methane. But on the brighter side, carbon dioxide when clean can be sold to beverage industry and hydrogen sulphide can be reduced to sulfur, an industrial raw material.

In a new inventive discovery, Carbon Clean Solutions have invented a technique which is known as “MethPure”. As the name may suggest, this technique works in purifying the biogas (methane+ hydrogen sulphide+ carbon dioxide) into purely methane (referred to as BioCNG). This is carried out in a manner which does not require an investment which is too heavy neither does it reduce the amount of methane content in the BioCNG.

The pure methane can now be used for vehicular transport, a concept already implemented in many European cities.

If a technology like MethPure is adopted widespread by cities like Mumbai and then the country in general, the impact on the environment will be considerable and will result in solving huge problem of handling & recycling city waste. The fact that BioCNG can be used for vehicular transport will majorly reduce the dependence of the average Indian population on non-renewable sources such as petrol and diesel. The ability to rely almost completely on renewable energy resources will make the country free from pollution, greener, healthier and happier

BioCNG : Fuel of the Future


How many times do you wake up to the news of petrol prices hiking? In today’s world with its rampant usage of non-renewable energy resources, this is a major concern for most individuals and organizations. Unfortunately, it doesn’t just stop at petrol and oil resources. Coal and gas are also rapidly running out. As the result effect of the usage of non-renewable resources on the environment is more than alarming, we as the human beings have to accelerate the deployment of more sustainable alternatives.

Although many such sustainable options have been discovered and put to use, the biggest challenge that mankind now faces is the affordability of these options on the whole. However clean a sustainable energy resource be, it must possess the ability of mass production at affordable rates. Only after mass production will an energy resource be considered an actual, viable source.

As of now, we have following options:

Hydro electricity: As the name suggests, this refers to the process of generating electricity from water. It requires water to be stored at a considerable height which usually entails construction of huge dams, resulting in huge costs and some adverse effect on local ecology. While water can effectively generate electricity, usage of water as fuel (for vehicles) still seems out of reach for mankind.

Wind energy: This is method by which a ‘farm’ of giant wind turbines is used to create electricity. While this option is characterized by widespread usage, the economics and nimby attitude (not in my backyard) have off late become major concerns.

Solar energy: This method harnesses the heat generated by the sun, to create energy. This has been proclaimed as one of the cleanest and most affordable means of generating energy. Solar energy is definitely the most accessible type of energy for the common man to switch to in these dire times. In spite of this, it is still more expensive than the usual methods of generating energy, usually due to lower efficiencies resulting in large solar farms. However, great breakthroughs have been made in the field of solar energy and the world eagerly awaits those to come.

While these energy sources seem to answer the present needs of the planet’s population, our dependence on oil based energy sources just refuses to budge. The amount of petrol, diesel and natural gas we use in our day to day life has made it an imperative part of our life. We take non-renewable energy resources for granted and use them with a lax hand. There is, however, one alternative that the world is holding its breath for- BioCNG.

Most of us are unaware of what exactly BioCNG is all about. BioCNG is nothing but Compressed Natural Gas created from biogas.

BioCNG has the abilities and the properties to run any vehicle or motor which can be run on CNG. Every application or motor which uses CNG today, can easily switch to using BioCNG without any hassle. The attributes of BioCNG and CNG are nearly the same in this respect. Thus, BioCNG is the direct and easy replacement of CNG and LPG appliances.

How does this process work?

BioCNG works on a very a simple 3 step process:

Source Biogas: BioCNG is created from Biogas, which in turn is generatedfrom organic waste matter. This waste matter can be sourced from anywhere- organic industries, farms or even your own home. The organic waste is then treated to create Biogas. It is a completely organic and green energy source, which completes the circle of recycling.

Create BioCNG: BioCNG is like a byproduct of the biogas. Biogas is treated using a particular process to clean-up gases like CO2 and H2S, which makes its exactly like Compressed Natural Gas. The process differs with the producer but the end result is still completely green and usable fuel.

Distribute BioCNG: As its properties are like those of Compressed Natural Gas, BioCNG can also be distributed using the same methods, or the existing infrastructure. Most effective of these would be the pipeline system, which directly carries it to industries or individuals. BioCNG can also be used to operate those motors or engines which run on CNG. This gives BioCNG a massive advantage as it feed into existing infrastructure and use

The three most palpable uses of BioCNG are:

Cooking: BioCNG can be used a replacement for cooking fuel.

Transportation: It can be used as replacement for the oil based, non-renewable fuels.

Generation of electricity: BioCNG can also be used as a replacement for natural gas for generating electricity.

The best part about BioCNG is that it is as green as it gets. Countries all over the world are looking for new ways to adapt this green technology and help it catch on. Governments are providing incentives and subsidies for manufacturers of BioCNG. BioCNG is the latest step forward towards a cleaner and better future not only for the country, but for the world as a whole.


India and Carbon Capture and Storage


Global warming and how harmful it is, can be narrated by even a kid today. But does every one really understand and take seriously – impacts of the phenomenon on this blue and green earth, post a century from today??  Sadly, we’ll have to bid an unfortunate bye-bye to various crux cities – New York City, Venice, Sydney, Mumbai and counting. It is disheartening, that though we’re aware about a death ditch that lies ahead of us, we are not considering any measures to halt and save our dwelling haven, but are rather running faster towards ‘the end’. To acknowledge the jeopardy and maintain certain standards to subside the rampant threat, is the need of the hour today!

              It isn’t an effect that occurs as dramatically as illustrated in most movies, however yet, the sooner we act the better it is. Who is the culprit? Fossil fuel energy sources are the demons we need to watch out for, as they contribute nasty levels of CO2 in the atmosphere. Most of all, coal based power plants emit large quantities of CO2 by burning millions of tons of fossil fuels every year. Deep down from the earth’s crust, is where these fuels arise from and then, they are burnt, and then; we will be burnt very soon because the burning of these fuels in excess to fulfill electricity and other needs, releases the clouds of CO2 into the atmosphere resulting in our very own life threatening-global warming scenario. However, CO2 was originally embedded into the earth’s crust in the form of fossil fuels and didn’t affect the atmosphere. So carbon isn’t really the bad guy here, it’s us. Lets see our flaws and how we can reverse it with CCS: What Carbon Capture and Storage (CCS) aims to do is to reduce the global warming phenomenon by sending this carbon back to where it came from – Deep underground.

              CCS works by using proven technologies to capture the carbon dioxide being emitted and storing it in porous rocks deep below the earth’s surface. CCS works in three main stages, capturing and separating the CO2 from the gasses emitted called flue gases, transporting it to a storage location and storing it deep underground or under the ocean. Sounds like some task? Yes, it is, but what’s more important, is that it serves our environment’s matter of concern.

CCS and how?

              The first stage i.e. capturing CO2 can occur at in two forms, before and after the fossil fuel is burned. If done before, the process involves heating the fossil fuel in pure oxygen which causes emission of hydrogen and carbon monoxide, which is then treated with a catalyst to give carbon dioxide and more hydrogen. The two are then separated. If done after combustion, which in case of almost all power plants in India, it is usually by the use of a special filtering equipment. The advantage is that it allows many old power plants to be retrofitted for CCS. Transportation of the trapped CO2 can be done through pipes, which, by the way is proven technique and is currently used to transport CO2 to over 5000 kms in the United States. CO2 can then be stored underground safely, like natural gas has been stored by earth for centuries.

The abundant CO2 that can be stored in a relatively small area:

              10 trillion tons of carbon dioxide – Now, how many zeroes does that have? This is the extent to which the mother earth can yet save our souls. The earth can store so many tons of carbon dioxide! This would allow storage of 100 years of CO2 emissions from all human activities. In underground storage, also know as geological sequestration, the pressure underneath, causes CO2 to behave more like a liquid than a gas; thus allowing it to seep through porous rocks.

              India is home to a giant population and this majorly confides the poor section, both of which do not have easy access to power and to make things worse, the poor who rely on fossil fuels are helpless on the emissions of CO2. Manufacturing is getting big and so much industrialization and commercialization is taking place – so well, so good for the economic growth! But what about the worse CO2 emission are skyrocketing steeply!?

Does this mean we are doomed?

              No, because despite all these factors India’s CO2 emission is only 1/7th of that of the USA and 1/3rd of that of China. It does however mean that we do have significant time to implement CCS technologies and that we should use this to our advantage. Projects in India take longer than other parts of the world and therefore if we start now we could be the forerunners in controlling our carbon emissions. This will enable our economy to grow even faster as in the global scenario we would never be subject to international sanctions due to the fear of uncontrolled carbon emissions. And what’s better, from the experience gained India could become a net exporter of technology.

The entire planet suffers from global warming and it is likely that in the future one country’s CO2 emissions could pose a threat for everyone else. Therefore, it is sensible if the countries take steps to cut down on the emissions by means of crumbling their industries, using economic sanctions. Currently the USA, UK, Norway and several other European countries have put CCS into place and are working to enhance, improve and expand the technology. It is a great move forward and it is time India followed suit. An estimation talks that 86% of the world’s incremental coal needs will come from India and China by the year 2030. We are bound to grow and so will our need for power. If we are able to implement CCS alongside our growing coals power needs, we would certainly be able to create a more sustained environment which would help us sustain our growth. For this to happen, we would need a change in policy. A boost in the practical execution of such a thought, which will do miracles for environment and mankind welfare. The probable reason that the policy change hasn’t occurred already is that CCS can be expensive as it can reduce the power output of a plant by up to 15%.  

In a country starved for power, this could mean millions of people having to wait for energy security until enough power plants are up and running. Keeping this into account it is understandable why our policy makers do not see CCS as the need of the hour.  However, it is imperative that we are able to think ahead and work towards the bigger picture in the long run. If all the new power plants constructed have CCS technology fitted on them, we need not have the looming fear of controlling CO2 emissions. We can look forward to a green and healthier India which can continue to grow without hesitation of contributing to a degraded climate change.

Global Warming and our Future


We do realize that summers are longer than they should be; that monsoons retreat later than they actually should; that the December month doesn’t see the same winter anymore; Don’t we?

Is it the mood swing of the weather? Nope! It isn’t. Its the greed of the mankind. The destruction and burning down of tropical forests for our increased needs of food, clothing and shelter – as we overpopulate, traffic clogging up the city streets, rapid growth of unplanned industries, the use of CFC’s in packaging and manufacturing products, the use of detergents, and so much more that has given birth to the evil child that acts as a demon today – Global Warming. Besides, overpopulation, deforestation are the causative factors of Global Warming; the setting up of mills and factories in an unplanned way has a great effect on environment. These mills and factories produce black smoke which gets mixed with air and increases the amount of CO2.

Effects of Global Warming are characterized by the snow ice caps which are melting away, the flora and fauna that is disrupted and getting extinct , the extensive green cover that is being deforested, the pure blue waters which are now teamed up with drainage sewage, a pleasant climate which is now becoming hotter which is leading to rising sea levels thereby exhausting wetlands and posing threat to people living by the coastal areas. Burning of gasoline in internal-combustion engine of vehicles, vehicles with poor gas mileage, the sulphur group gas emitted from the burning of fossil fuels have increased the global temperatures which can lead to the outbreak of air-borne and water-borne diseases. It would also contribute to the rise in death caused by heat. This “hot world” has reduced the amount of rainfall thereby hampering the plantation and crop growth – which can soon lead to malnourishment and starvation of life on earth. The Chlorofluorocarbons (CFC’s) emitted from our very own refrigerators, air conditioners etc. have also started depleting the ozone layer – the layer that protects humans on earth from the harmful and carcinogenic UV Rays.

How do we help reverse such a situation? The need of the hour is to bring about a massive difference even by taking toddler yet effective steps of – Planting more trees and reducing timber cuts worldwide will help restore the imbalance. Secondly, we must follow on environmental policy of ‘reduce, reuse, recycle’ – promoting the reuse of anything and everything. Thirdly, the use of fuel-efficient vehicles should be promoted as these vehicles have lower emissions of harmful gases. Fourthly, every individual should be aware of the importance of the protecting environment. Besides, Eco- friendly technologies like carbon capture must be promoted, and must be used as a substitute for those technologies which cause great emission of global warming gases. Public awareness campaign can be of great help in this regard because unless each and every individual is aware only governments’ effect cannot bring desired difference.

The “painting roads white” approach, to reflect light rather than trap it as heat can also be effective. Encouraging growth of plankton and thus fish, probably by adding nutrients to oceanic deserts. Fish can be harvested commercially (though many oceanic deserts are outside exclusive economic zones, hence a free-rider problem). Fish not harvested die and fall to the bottom, where some of the carbon in their bones is sequestered as limestone. Injecting aerosols (sulfur oxides) into the upper atmosphere can help avoid social collapse.

Taking an initiative to provide some relief to the planet earth from such ‘unpleasant warmth’, is really required and should be implemented at each level by every world dweller, before it gets too late


Carbon Capture and Storage, the only solution to climate change?

Climate change is being widely recognized as the major environmental problem facing the globe. Global warming has become perhaps the most complicated issue for world leaders today. Large-scale burning of coal and fossil fuels worldwide has increased the concentration of carbon dioxide in the atmosphere.


That is why carbon capture and storage has been accepted as a serious effort and probably the only solution to combat climate change at the Greenhouse Gas Control Technologies (GHGT-11) Conference hosted by the International Energy Agency in Kyoto last week. The GHGT conference has established itself as the premier international platform for the presentation of cutting edge research and the latest developments in CO2 capture and storage technologies. It is a platform for individuals, industry representatives and researchers from Asia, Europe and Australia, USA to network with one another.

Carbon capture and storage (CCS) is the process of capturing waste COfrom large point sources, such as fossil fuel power plants, transporting it to a storage site, and depositing it to an underground geological formation. The aim is to prevent the release of large quantities of COinto the atmosphere. It is a potential means of mitigating the contribution of fossil fuel emissions to global warming.  Carbon capture and storage was very much a novel concept with limited research but there has been a significant technological development in recent years.


The conference highlighted the fact that “CCS is Ready to Move Forward”. CCS is now at the phase where pilot projects operate around the world, which will be followed by commercial deployment.  Regardless, the world seems to be closing down more CCS plants than it opens. Member discussions at the conference approved CCS as a potential technology, but developments are still needed in the areas of CO2 capture, transportation, storage and the integration of these components, both in terms of reliability and efficiency.  Several CO2 trapping mechanisms such as post combustion, oxy-fuel combustion, pre combustion, chemical looping, the costs and impacts of these technologies were discussed. Focus was also drawn on storage techniques, public-private partnerships, management of technologies, techniques, risk assessment, CO2 utilisation, transport networks and safety measures. Panel members concluded that legal and regulatory frameworks, breakthroughs in areas of funding and communication need to be considered by various stakeholders including industrialists, researchers, government bodies, institutes and the public. CCS techniques, such as Enhanced Oil Recovery, have been used for decades, but only recently has it been viewed as a viable means of reducing the amount of carbon released into the atmosphere from power plants.

Governments around the world need to show more commitment towards framing standards, rules and regulations for CCS. CCS needs to be employed on a much larger scale, then only will it be able to make that level of impact its potential suggests.

The organizers of the GHGT Conference consisted of a mix of representatives from the hosts; in the case of GHGT-11, The Research Institute of Innovative Technology for the Earth and the International Energy Agency. Researchers and industry experts world over attended the Conference.

Prateek Bumb, Director of Carbon Clean Solutions Ltd, was one of the few Indians present there. The conference was chaired by renowned personalities such as Dr Kelly Thamimuthu, Chair of IEAGHG, Mr John Gale, General Manager, IEAGHG and Mr Tim Dixon, Manager, CCS & Regulatory Affairs, IEAGHG. Emminent speakers such as Professor Yoichi Kaya, President, RITE, Mr Koichi Akaishi, METI, Mr Atsutoshi Nidhida, Chairman of the Board, Toshiba, Mr Brad Page, CEO, Global CCS Institute, Dr Jay Braisch, Senior Advisor, Office of Fossil Fuel Energy USDOE,  Mr Juho Lipponen, Head of CCS Unit, IEA, Dr Francis O’Sullivan Executive Director , Energy Sustainability Challenge Programme, MIT, Henk Reimink, Executive Director, Energy Sustainability Challenge Programme, World Steel Association, Chris Hendriks, Managing  Consultant, Ecofys and Keigo Akimoto, Chief Researcher and Group Leader of the Systems Analysis Group, RITE addressed the conference.

The next GHGT Conference is scheduled to be held at The University of Texas, Austin in USASeveral U.S. and International demonstrations of CCS are expected to be showcased at GHGT-12.