Home > Resources > Articles > Global Industrial Sludge Treatment Chemicals Market Outlook 2014-2021

Global Industrial Sludge Treatment Chemicals Market Outlook 2014-2021

Industrial Sludge is created amid the wastewater treatment process. Wastewater discharged by various commercial enterprises contains a lot of water, microorganisms, and compound constituents. Sludge requires further treatment to lessen its volume and render it steady and ok for transfer. The principle motivation behind this treatment is to lessen the volume of water and pathogen substance to encourage safe transfer and conceivable use as compost.

Spotlight

Unger Fabrikker A.S

Unger is one of Europe's leading producers of anionic surfactants and the only one of it's kind in Scandinavia. Our modern, highly automated production facility manufactures a wide variety of both dry and liquid raw materials, applied in household detergents, personal care and institutional products, as well as functional additives for industrial applications.

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Chemical Technology

Future-Proofing the Chemical Industry with Digitalization

Article | July 14, 2022

Over the next five to seven years, the chemical sector will place a greater emphasis on sustainability, and digitization will play a significant part in this. Reducing resource use, pollution, energy consumption, and waste are some of its main applications. Additionally, it will increase demand for a circular economy supported by IoT, AI, and other digital technologies. Some of the systems now in place or being used in the sector include autonomous solutions that enable lower energy usage, dispatching systems for effective logistics and strategies for sustainable power and fuel consumption. Chemical players making the switch to digital platforms have a chance to triumph if they move swiftly and update their operational models in accordance with a few common success characteristics. In fact, according to our study, making the correct decisions can increase total earnings before interest, taxes, depreciation, and amortization by 3 percent or more (EBITDA). The Next Step of Operational Excellence The same level of transformation is available with digital technology for optimal performance, together with success-enabling measures. The same level of corporate participation and realignment will also be necessary for the effective implementation of digital technology. Finance and telecoms were early leaders in adopting digital technology faster than the chemical sector, which has just recently started to move in more significant numbers toward digitalization. A circular economy in the sector is also being enabled by the use and evaluation of digital technology. The "Right to Fix" movement is being driven by governments and legislators in Europe and the US, and small and medium-sized businesses in the industry are expected to invest in technology that makes it easier to repair electronic items with the least amount of waste. On a side note, by enabling the re-use of resources and products throughout the supply chain, digitalization with lean manufacturing (LM) would enable businesses to improve operational excellence and create value, thereby supporting the circular economy goal. Conclusion Given its extensive safety and regulatory requirements, the chemical sector has evolved slowly. However, as the global economy changes, some skills will become obsolete and others essential. The interconnectedness of people, processes, and technology, as well as the requirement for real-time insight at the levels closest to the action, are among the basic principles of Industry 4.0. These values have existed for some time and are an extension of our teams' current operational excellence initiatives. Digital transformation is not a technology endpoint but rather the following stage in the process and business evolution as the chemicals industry advances continuously.

Read More
Chemical Management

Energy portfolio restructuring: Charting the future

Article | July 13, 2021

Consumer needs and preferences in the energy industry are evolving. Environmental, social and governance (ESG) concerns are becoming more acute—inspiring action and shifting value towards low-carbon solutions. These trends accelerated in 2020 and for the first time, market capitalization of leading low-carbon solutions companies began to overtake those of oil and gas (O&G) majors. This is despite the majors laying out energy transition strategies, setting low carbon energy targets and generating higher revenues by an order of magnitude.1 In response to this radically changing landscape, energy companies are charting divergent courses for their futures. Some continue to bet on their ability to generate returns from the O&G value chain. They are focusing on growing margins and lowering carbon intensity. Others are supplementing their capabilities with low-carbon energy solutions or exiting hydrocarbons altogether. This blog focuses on the path forward for the energy majors in Europe who are betting big on diversification.

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Chemical Management

Organic Catalyst Boasts Big Benefits

Article | July 8, 2022

An enzyme-mimicking catalyst opens a new route to important organic molecules such as glycolic acid and amino acids from pyruvate, report researchers in Japan. Moreover, the new catalyst is cheaper, more stable, safer and more environmentally friendly than conventional metal catalysts used in industry, they note, adding that it also displays the high enantioselectivity required by the pharmaceutical industry. “On top of these advantages, our newly developed organic catalyst system also promotes reactions using pyruvate that aren’t easily achievable using metal catalysts,” says Santanu Mondal, a PhD candidate in the chemistry and chemical bioengineering unit at Okinawa Institute of Science and Technology (OIST) Graduate University, Okinawa, Japan, and lead author of a study recently published in Organic Letters. “Organic catalysts, in particular, are set to revolutionize the industry and make chemistry more sustainable,” he stresses. The researchers use an acid and an amine mixture to force the pyruvate to act as an electron donor rather than its usual role as an electron receiver (Figure 1). Effectively mimicking how enzymes work, the amine binds to the pyruvate to make an intermediate molecule. The organic acid then covers up part of the intermediate molecule while leaving another part that can donate electrons free to react to form a new product. Currently, the organic catalyst system only works when reacting pyruvate with a specific class of organic molecule called cyclic imines. So, the researchers now are looking to develop a more-universal catalyst, i.e., one that can speed up reactions between pyruvate and a broad range of organic molecules. The challenge here is to try to make the electron-donating intermediate stage of pyruvate react with other functional groups such as aldehydes and ketones. However, different catalysts create different intermediates, all with different properties. For example, the enamine intermediate created by the researchers’ new reaction only reacts with cyclic imines. Their hypothesis, currently being investigated, is that creation of other intermediates such as an enolate, if possible, would achieve a broader pyruvate reactivity. In terms of cost, the researchers note that a palladium catalyst used in similar reactions is 25 times more expensive than their organic acid — which also is made from eco-friendly quinine. In addition, they believe scale-up of the process for industrial use definitely is possible. However, the researchers caution that the current amine-to-acid-catalyst loading ratio of 1:2 probably would need to be optimized for better results at a larger scale.

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Chemical Technology

Resin and Polymeric Binders for Inks

Article | May 19, 2021

The market size for polymeric and resin binders in the global printing ink marketwas estimated to be over 1,200,000 MT in 2020, with a CAGR of about five percent. A major driver of this growth comes from the packaging industry, due to increases in consumer spending and online shopping, as well as demand for processed and packaged foods and beverages. In addition, increased use of water-based inks is promoting market growth, off-setting environmental and health concerns regarding solvent-based inks in addition to strict environmental protection policies. Water-based inks are projected to overtake solvent-based inks due to environmental regulations, the reduction of volatile organic compounds (VOCs) in the pressroom, and improvements in overall print quality. Ink formulations are complex mixtures, consisting of four basic component classes: pigments, polymeric binder resins, solvents or an aqueous dispersant media, and additives, such as surfactants, waxes, and rheology modifiers that enhance print quality. The purpose of the resin binder is to disperse and carry the ink pigment to the substrate, stabilize the pigment and additives dispersion to prevent settling, and provide print properties such as ink transfer behavior, setting, and drying characteristics. The binder also contributes surface appearance and gloss, strength and flexibility, chemical and solvent resistance, and also rub resistance. Ink binders can be categorized into the following polymer and resin types: acrylics, polyurethanes, polyamides, modified resins, hydrocarbon resins, and modified cellulosics.

Read More
Chemical Technology

Future-Proofing the Chemical Industry with Digitalization

Article | July 14, 2022

Over the next five to seven years, the chemical sector will place a greater emphasis on sustainability, and digitization will play a significant part in this. Reducing resource use, pollution, energy consumption, and waste are some of its main applications. Additionally, it will increase demand for a circular economy supported by IoT, AI, and other digital technologies. Some of the systems now in place or being used in the sector include autonomous solutions that enable lower energy usage, dispatching systems for effective logistics and strategies for sustainable power and fuel consumption. Chemical players making the switch to digital platforms have a chance to triumph if they move swiftly and update their operational models in accordance with a few common success characteristics. In fact, according to our study, making the correct decisions can increase total earnings before interest, taxes, depreciation, and amortization by 3 percent or more (EBITDA). The Next Step of Operational Excellence The same level of transformation is available with digital technology for optimal performance, together with success-enabling measures. The same level of corporate participation and realignment will also be necessary for the effective implementation of digital technology. Finance and telecoms were early leaders in adopting digital technology faster than the chemical sector, which has just recently started to move in more significant numbers toward digitalization. A circular economy in the sector is also being enabled by the use and evaluation of digital technology. The "Right to Fix" movement is being driven by governments and legislators in Europe and the US, and small and medium-sized businesses in the industry are expected to invest in technology that makes it easier to repair electronic items with the least amount of waste. On a side note, by enabling the re-use of resources and products throughout the supply chain, digitalization with lean manufacturing (LM) would enable businesses to improve operational excellence and create value, thereby supporting the circular economy goal. Conclusion Given its extensive safety and regulatory requirements, the chemical sector has evolved slowly. However, as the global economy changes, some skills will become obsolete and others essential. The interconnectedness of people, processes, and technology, as well as the requirement for real-time insight at the levels closest to the action, are among the basic principles of Industry 4.0. These values have existed for some time and are an extension of our teams' current operational excellence initiatives. Digital transformation is not a technology endpoint but rather the following stage in the process and business evolution as the chemicals industry advances continuously.

Read More
Chemical Management

Southeast polyolefins demand growth could be negative again in 2021

Article | July 13, 2021

Consumer needs and preferences in the energy industry are evolving. Environmental, social and governance (ESG) concerns are becoming more acute—inspiring action and shifting value towards low-carbon solutions. These trends accelerated in 2020 and for the first time, market capitalization of leading low-carbon solutions companies began to overtake those of oil and gas (O&G) majors. This is despite the majors laying out energy transition strategies, setting low carbon energy targets and generating higher revenues by an order of magnitude.1 In response to this radically changing landscape, energy companies are charting divergent courses for their futures. Some continue to bet on their ability to generate returns from the O&G value chain. They are focusing on growing margins and lowering carbon intensity. Others are supplementing their capabilities with low-carbon energy solutions or exiting hydrocarbons altogether. This blog focuses on the path forward for the energy majors in Europe who are betting big on diversification.

Read More
Chemical Management

The Future of Supply Chain Management for Chemical Companies

Article | July 8, 2022

An enzyme-mimicking catalyst opens a new route to important organic molecules such as glycolic acid and amino acids from pyruvate, report researchers in Japan. Moreover, the new catalyst is cheaper, more stable, safer and more environmentally friendly than conventional metal catalysts used in industry, they note, adding that it also displays the high enantioselectivity required by the pharmaceutical industry. “On top of these advantages, our newly developed organic catalyst system also promotes reactions using pyruvate that aren’t easily achievable using metal catalysts,” says Santanu Mondal, a PhD candidate in the chemistry and chemical bioengineering unit at Okinawa Institute of Science and Technology (OIST) Graduate University, Okinawa, Japan, and lead author of a study recently published in Organic Letters. “Organic catalysts, in particular, are set to revolutionize the industry and make chemistry more sustainable,” he stresses. The researchers use an acid and an amine mixture to force the pyruvate to act as an electron donor rather than its usual role as an electron receiver (Figure 1). Effectively mimicking how enzymes work, the amine binds to the pyruvate to make an intermediate molecule. The organic acid then covers up part of the intermediate molecule while leaving another part that can donate electrons free to react to form a new product. Currently, the organic catalyst system only works when reacting pyruvate with a specific class of organic molecule called cyclic imines. So, the researchers now are looking to develop a more-universal catalyst, i.e., one that can speed up reactions between pyruvate and a broad range of organic molecules. The challenge here is to try to make the electron-donating intermediate stage of pyruvate react with other functional groups such as aldehydes and ketones. However, different catalysts create different intermediates, all with different properties. For example, the enamine intermediate created by the researchers’ new reaction only reacts with cyclic imines. Their hypothesis, currently being investigated, is that creation of other intermediates such as an enolate, if possible, would achieve a broader pyruvate reactivity. In terms of cost, the researchers note that a palladium catalyst used in similar reactions is 25 times more expensive than their organic acid — which also is made from eco-friendly quinine. In addition, they believe scale-up of the process for industrial use definitely is possible. However, the researchers caution that the current amine-to-acid-catalyst loading ratio of 1:2 probably would need to be optimized for better results at a larger scale.

Read More
Chemical Technology

Resin and Polymeric Binders for Inks

Article | May 19, 2021

The market size for polymeric and resin binders in the global printing ink marketwas estimated to be over 1,200,000 MT in 2020, with a CAGR of about five percent. A major driver of this growth comes from the packaging industry, due to increases in consumer spending and online shopping, as well as demand for processed and packaged foods and beverages. In addition, increased use of water-based inks is promoting market growth, off-setting environmental and health concerns regarding solvent-based inks in addition to strict environmental protection policies. Water-based inks are projected to overtake solvent-based inks due to environmental regulations, the reduction of volatile organic compounds (VOCs) in the pressroom, and improvements in overall print quality. Ink formulations are complex mixtures, consisting of four basic component classes: pigments, polymeric binder resins, solvents or an aqueous dispersant media, and additives, such as surfactants, waxes, and rheology modifiers that enhance print quality. The purpose of the resin binder is to disperse and carry the ink pigment to the substrate, stabilize the pigment and additives dispersion to prevent settling, and provide print properties such as ink transfer behavior, setting, and drying characteristics. The binder also contributes surface appearance and gloss, strength and flexibility, chemical and solvent resistance, and also rub resistance. Ink binders can be categorized into the following polymer and resin types: acrylics, polyurethanes, polyamides, modified resins, hydrocarbon resins, and modified cellulosics.

Read More
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Spotlight

Unger Fabrikker A.S

Unger is one of Europe's leading producers of anionic surfactants and the only one of it's kind in Scandinavia. Our modern, highly automated production facility manufactures a wide variety of both dry and liquid raw materials, applied in household detergents, personal care and institutional products, as well as functional additives for industrial applications.

Related News

Chemical Technology

With the Acquisition of Agiplast, Arkema Strengthens Its Commitment to the Circular Economy

ARKEMA | May 25, 2021

With the planned acquisition of Agiplast, a leader in the regeneration of high-performance polymers, especially specialty polyamides, and fluoropolymers, Arkema is going to be ready to offer a full service to customers in terms of materials circularity, addressing growing market expectations during this field. This project, which contributes to the sustainable development of the polymer industry, is perfectly in line with Arkema’s sustainable growth strategy. Arkema plans to accumulate Agiplast, a company specialized in the regeneration of high-performance polymers, and its historical partner in recycling operations. the company, with annual sales of around €15 million, operates a plant in Italy and has 32 employees. Agiplast’s strong know-how in mechanical recycling technologies will enable Arkema to supply top-quality recycled polymers to its customers. In October 2019, Arkema, the world leader in bio-based high-performance polymers, had already launched Virtucycle®, an ambitious program with Agiplast aimed toward developing loops for the gathering and regeneration of high-performance polymers while minimizing CO2 emissions. With this acquisition, Arkema is going to be the primary fully integrated high-performance polymer manufacturer offering both bio-based and recycled materials to deal with the challenges of resource scarcity and end-of-life products. This bolt-on acquisition is thus in line with Arkema’s CSR and sustainable growth strategy, and especially the transition to a circular economy. The deal is expected to close in June 2021. About ARKEMA Building on its unique set of experience in materials science, Arkema offers a portfolio of first-class technologies to address the ever-growing demand for new and sustainable materials. With the ambition to become 2024 a pure player in Specialty Materials, the Group is structured into 3 complementary, resilient, and highly innovative segments dedicated to Specialty Materials -Adhesive solutions, Advanced Materials, and Coating Solutions- accounting for a few 82% of Group sales, and a well-positioned and competitive Intermediates segments. Arkema offers cutting-edge technological solutions to satisfy the challenges of, among other things, new energies, access to water, recycling, urbanization, and mobility and fosters a permanent dialogue with all its stakeholders. The Group reported sales of around €8 billion in 2020 and operates in some 55 countries with 20,600 employees worldwide

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Chemical Management

Huntsman Completes the Acquisition of Gabriel Performance Products, Further Expanding its Specialty Chemicals Portfolio

Huntsman | January 20, 2021

Huntsman Corporation (NYSE: HUN) today announced it completed the acquisition of Gabriel Performance Products (Gabriel), a North American specialty chemical manufacturer of specialty additives and epoxy curing agents for the coatings, adhesives, sealants and composite end-markets, from Audax Private Equity. Huntsman paid $250 million, subject to customary closing adjustments, in an all-cash transaction funded from available liquidity. Gabriel had 2019 revenues of approximately $106 million with three manufacturing facilities located in Ashtabula, Ohio, Harrison City, Pennsylvania and Rock Hill, South Carolina. Based on calendar year 2019, the purchase price represents an adjusted EBITDA multiple of approximately 11 times, or approximately 8 times pro forma for synergies. Huntsman Corporation is a publicly traded global manufacturer and marketer of differentiated and specialty chemicals with 2019 revenues of approximately $7 billion. Our chemical products number in the thousands and are sold worldwide to manufacturers serving a broad and diverse range of consumer and industrial end markets. We operate more than 70 manufacturing, R&D and operations facilities in approximately 30 countries and employ approximately 9,000 associates within our four distinct business divisions. Certain information in this release constitutes forward-looking statements within the meaning of Section 27A of the Securities Act of 1933 and Section 21E of the Securities Exchange Act of 1934. These statements are based on management's current beliefs and expectations. The forward-looking statements in this release are subject to uncertainty and changes in circumstances and involve risks and uncertainties that may affect the company's operations, markets, products, services, prices and other factors as discussed under the caption "Risk Factors" in the Huntsman companies' filings with the U.S. Securities and Exchange Commission. Significant risks and uncertainties may relate to, but are not limited to, volatile global economic conditions, cyclical and volatile product markets, disruptions in production at manufacturing facilities, reorganization or restructuring of Huntsman's operations, including any delay of, or other negative developments affecting the ability to implement cost reductions, timing of proposed transactions, and manufacturing optimization improvements in Huntsman businesses and realize anticipated cost savings, ability to achieve projected synergies, and other financial, economic, competitive, environmental, political, legal, regulatory and technological factors. The company assumes no obligation to provide revisions to any forward-looking statements should circumstances change, except as otherwise required by applicable laws.

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Raw Materials

Conservation Groups Sue EPA for Failure to Adequately Protect against Oil, Methane Gas Industry

Conservation Groups | January 18, 2021

Two conservation groups have launched a lawsuit to fight the EPA’s “failure to require adequate pollution controls for the oil and methane gas industry” in Chicago and areas of California. The Center for Biological Diversity and the Center for Environmental Health point out that two Canadian provinces require that the oil and methane gas industry install zero emission pneumatic controllers. “There is no reason the EPA cannot adopt this readily available technology,” says Kaya Sugerman with the Center for Environmental Health. The EPA’s guidelines for oil and methane gas production recommend pneumatic controllers that emit volatile organic compounds, when pneumatic controllers that do not emit any of these compounds are in widespread use at production sites and compressor stations in both the US and Canada, the groups argue. “Taking action to increase the use of zero emission controllers has a co-benefit of reducing methane, a dangerous greenhouse gas that is 87 times more damaging for climate change than carbon dioxide,” the groups say. They point out that, according to the EPA’s Greenhouse Gas Inventory, pneumatic controllers are the largest source of methane from the oil industry and the second-largest source of methane from the methane gas industry.

Read More

Chemical Technology

With the Acquisition of Agiplast, Arkema Strengthens Its Commitment to the Circular Economy

ARKEMA | May 25, 2021

With the planned acquisition of Agiplast, a leader in the regeneration of high-performance polymers, especially specialty polyamides, and fluoropolymers, Arkema is going to be ready to offer a full service to customers in terms of materials circularity, addressing growing market expectations during this field. This project, which contributes to the sustainable development of the polymer industry, is perfectly in line with Arkema’s sustainable growth strategy. Arkema plans to accumulate Agiplast, a company specialized in the regeneration of high-performance polymers, and its historical partner in recycling operations. the company, with annual sales of around €15 million, operates a plant in Italy and has 32 employees. Agiplast’s strong know-how in mechanical recycling technologies will enable Arkema to supply top-quality recycled polymers to its customers. In October 2019, Arkema, the world leader in bio-based high-performance polymers, had already launched Virtucycle®, an ambitious program with Agiplast aimed toward developing loops for the gathering and regeneration of high-performance polymers while minimizing CO2 emissions. With this acquisition, Arkema is going to be the primary fully integrated high-performance polymer manufacturer offering both bio-based and recycled materials to deal with the challenges of resource scarcity and end-of-life products. This bolt-on acquisition is thus in line with Arkema’s CSR and sustainable growth strategy, and especially the transition to a circular economy. The deal is expected to close in June 2021. About ARKEMA Building on its unique set of experience in materials science, Arkema offers a portfolio of first-class technologies to address the ever-growing demand for new and sustainable materials. With the ambition to become 2024 a pure player in Specialty Materials, the Group is structured into 3 complementary, resilient, and highly innovative segments dedicated to Specialty Materials -Adhesive solutions, Advanced Materials, and Coating Solutions- accounting for a few 82% of Group sales, and a well-positioned and competitive Intermediates segments. Arkema offers cutting-edge technological solutions to satisfy the challenges of, among other things, new energies, access to water, recycling, urbanization, and mobility and fosters a permanent dialogue with all its stakeholders. The Group reported sales of around €8 billion in 2020 and operates in some 55 countries with 20,600 employees worldwide

Read More

Chemical Management

Huntsman Completes the Acquisition of Gabriel Performance Products, Further Expanding its Specialty Chemicals Portfolio

Huntsman | January 20, 2021

Huntsman Corporation (NYSE: HUN) today announced it completed the acquisition of Gabriel Performance Products (Gabriel), a North American specialty chemical manufacturer of specialty additives and epoxy curing agents for the coatings, adhesives, sealants and composite end-markets, from Audax Private Equity. Huntsman paid $250 million, subject to customary closing adjustments, in an all-cash transaction funded from available liquidity. Gabriel had 2019 revenues of approximately $106 million with three manufacturing facilities located in Ashtabula, Ohio, Harrison City, Pennsylvania and Rock Hill, South Carolina. Based on calendar year 2019, the purchase price represents an adjusted EBITDA multiple of approximately 11 times, or approximately 8 times pro forma for synergies. Huntsman Corporation is a publicly traded global manufacturer and marketer of differentiated and specialty chemicals with 2019 revenues of approximately $7 billion. Our chemical products number in the thousands and are sold worldwide to manufacturers serving a broad and diverse range of consumer and industrial end markets. We operate more than 70 manufacturing, R&D and operations facilities in approximately 30 countries and employ approximately 9,000 associates within our four distinct business divisions. Certain information in this release constitutes forward-looking statements within the meaning of Section 27A of the Securities Act of 1933 and Section 21E of the Securities Exchange Act of 1934. These statements are based on management's current beliefs and expectations. The forward-looking statements in this release are subject to uncertainty and changes in circumstances and involve risks and uncertainties that may affect the company's operations, markets, products, services, prices and other factors as discussed under the caption "Risk Factors" in the Huntsman companies' filings with the U.S. Securities and Exchange Commission. Significant risks and uncertainties may relate to, but are not limited to, volatile global economic conditions, cyclical and volatile product markets, disruptions in production at manufacturing facilities, reorganization or restructuring of Huntsman's operations, including any delay of, or other negative developments affecting the ability to implement cost reductions, timing of proposed transactions, and manufacturing optimization improvements in Huntsman businesses and realize anticipated cost savings, ability to achieve projected synergies, and other financial, economic, competitive, environmental, political, legal, regulatory and technological factors. The company assumes no obligation to provide revisions to any forward-looking statements should circumstances change, except as otherwise required by applicable laws.

Read More

Raw Materials

Conservation Groups Sue EPA for Failure to Adequately Protect against Oil, Methane Gas Industry

Conservation Groups | January 18, 2021

Two conservation groups have launched a lawsuit to fight the EPA’s “failure to require adequate pollution controls for the oil and methane gas industry” in Chicago and areas of California. The Center for Biological Diversity and the Center for Environmental Health point out that two Canadian provinces require that the oil and methane gas industry install zero emission pneumatic controllers. “There is no reason the EPA cannot adopt this readily available technology,” says Kaya Sugerman with the Center for Environmental Health. The EPA’s guidelines for oil and methane gas production recommend pneumatic controllers that emit volatile organic compounds, when pneumatic controllers that do not emit any of these compounds are in widespread use at production sites and compressor stations in both the US and Canada, the groups argue. “Taking action to increase the use of zero emission controllers has a co-benefit of reducing methane, a dangerous greenhouse gas that is 87 times more damaging for climate change than carbon dioxide,” the groups say. They point out that, according to the EPA’s Greenhouse Gas Inventory, pneumatic controllers are the largest source of methane from the oil industry and the second-largest source of methane from the methane gas industry.

Read More

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