Energi Baru dan Terbarukan
Mendukung proyek transisi energi melalui berbagai macam teknologi
Sumber energi terbarukan diperkirakan akan tumbuh pesat dalam dua dekade mendatang. Kami telah menerapkan keterampilan teknik dan manajemen proyek untuk mendukung proyek infrastruktur energi baru, dan memiliki keterampilan serta pengalaman yang tepat untuk memanfaatkan pertumbuhan investasi di pasar ini dan untuk mendukung klien kami di seluruh siklus hidup aset.
OUR CAPABILITIES
Green Ammonia
Description
Ammonia is a pungent-smelling gas widely used in the agricultural industry as a raw material for fertilizers. Conventionally, ammonia is produced through steam methane reforming, which results in relatively high carbon emissions. On the other hand, green ammonia is 100% renewable and carbon-free.
Process
Green ammonia is produced through a process involving the reaction of hydrogen, derived from electrolysis powered by electricity from renewable sources, and nitrogen, separated from the air using an Air Separation Unit. These two components are then introduced into a Haber-Bosch reactor, where they undergo conversion to produce green ammonia.
Sustainable Aviation Fuel (SAF)
Description
Sustainable Aviation Fuel (SAF) is a renewable and environmentally friendly substitute for conventional aviation fuel. Referred to as a drop-in fuel, SAF can be seamlessly incorporated into aircraft operations without the need for engine modifications or blending with traditional aviation fuel.
Process
SAF with the HEFA-SPK route is produced through three main processes: Pre-treatment, hydrotreatment, and hydrocracking. The raw materials used are second-generation feedstocks such as Palm Oil Mill Effluent (POME), Palm Fatty Acid Distillate (PFAD), Used Cooking Oil (UCO), and others.
Waste Heat Recovery
Description
Waste heat recovery is vital for sustainability, reclaiming thermal energy lost in industry. Technologies like heat exchangers convert this waste heat into usable energy, improving efficiency and reducing environmental impact. This approach optimizes energy utilization, fostering greener industrial practices.
Process
Waste heat recovery systematically captures thermal energy using heat exchangers, extracting heat from diverse industrial processes. This recovered heat undergoes further refinement, typically employing technologies like organic Rankine cycles, to convert it into usable forms such as electricity or additional process heat.
Bio-Methane
Description
Biomethane, a renewable biogas derived from organic materials, undergoes anaerobic digestion and purification to yield a low-carbon methane. Recognized for its versatility, it can be integrated into natural gas infrastructure or utilized as a sustainable vehicle fuel, contributing to eco-friendly energy systems.
Process
The bio-methane production process commences with the anaerobic digestion of organic materials, such as agricultural residues or organic waste, where microorganisms break down the matter to generate methane. This raw biogas undergoes purification, removing impurities and yielding high-purity bio-methane.
Bio-Energy
Description
Bio-energy, utilizes organic materials for sustainable energy production. It converts plant and animal matter into heat, electricity, or biofuels, contributing to eco-friendly alternatives. The carbon-neutral cycle offsets emissions, making biomass a pivotal player in sustainable energy.
Process
The bio-energy conversion process is intricate, involving the transformation of organic materials into various energy forms like heat, electricity, or biofuels. Methods include combustion, gasification, and biochemical processes that break down biomass using microorganisms.
OUR CAPABILITIES
Green Ammonia
Description
Ammonia is a pungent-smelling gas widely used in the agricultural industry as a raw material for fertilizers. Conventionally, ammonia is produced through steam methane reforming, which results in relatively high carbon emissions. On the other hand, green ammonia is 100% renewable and carbon-free.
Process
Green ammonia is produced through a process involving the reaction of hydrogen, derived from electrolysis powered by electricity from renewable sources, and nitrogen, separated from the air using an Air Separation Unit. These two components are then introduced into a Haber-Bosch reactor, where they undergo conversion to produce green ammonia.
Sustainable Aviation Fuel (SAF)
Description
Sustainable Aviation Fuel (SAF) is a renewable and environmentally friendly substitute for conventional aviation fuel. Referred to as a drop-in fuel, SAF can be seamlessly incorporated into aircraft operations without the need for engine modifications or blending with traditional aviation fuel.
Process
SAF with the HEFA-SPK route is produced through three main processes: Pre-treatment, hydrotreatment, and hydrocracking. The raw materials used are second-generation feedstocks such as Palm Oil Mill Effluent (POME), Palm Fatty Acid Distillate (PFAD), Used Cooking Oil (UCO), and others.
Waste Heat Recovery
Description
Waste heat recovery is vital for sustainability, reclaiming thermal energy lost in industry. Technologies like heat exchangers convert this waste heat into usable energy, improving efficiency and reducing environmental impact. This approach optimizes energy utilization, fostering greener industrial practices.
Process
Waste heat recovery systematically captures thermal energy using heat exchangers, extracting heat from diverse industrial processes. This recovered heat undergoes further refinement, typically employing technologies like organic Rankine cycles, to convert it into usable forms such as electricity or additional process heat.
Sustainable Aviation Fuel (SAF)
Description
Sustainable Aviation Fuel (SAF) is a renewable and environmentally friendly substitute for conventional aviation fuel. Referred to as a drop-in fuel, SAF can be seamlessly incorporated into aircraft operations without the need for engine modifications or blending with traditional aviation fuel.
Process
SAF with the HEFA-SPK route is produced through three main processes: Pre-treatment, hydrotreatment, and hydrocracking. The raw materials used are second-generation feedstocks such as Palm Oil Mill Effluent (POME), Palm Fatty Acid Distillate (PFAD), Used Cooking Oil (UCO), and others.
Waste Heat Recovery
Description
Waste heat recovery is vital for sustainability, reclaiming thermal energy lost in industry. Technologies like heat exchangers convert this waste heat into usable energy, improving efficiency and reducing environmental impact. This approach optimizes energy utilization, fostering greener industrial practices.
Process
Waste heat recovery systematically captures thermal energy using heat exchangers, extracting heat from diverse industrial processes. This recovered heat undergoes further refinement, typically employing technologies like organic Rankine cycles, to convert it into usable forms such as electricity or additional process heat.
Bio-Methane
Description
Biomethane, a renewable biogas derived from organic materials, undergoes anaerobic digestion and purification to yield a low-carbon methane. Recognized for its versatility, it can be integrated into natural gas infrastructure or utilized as a sustainable vehicle fuel, contributing to eco-friendly energy systems.
Process
The bio-methane production process commences with the anaerobic digestion of organic materials, such as agricultural residues or organic waste, where microorganisms break down the matter to generate methane. This raw biogas undergoes purification, removing impurities and yielding high-purity bio-methane.
Bio-Energy
Description
Bio-energy, utilizes organic materials for sustainable energy production. It converts plant and animal matter into heat, electricity, or biofuels, contributing to eco-friendly alternatives. The carbon-neutral cycle offsets emissions, making biomass a pivotal player in sustainable energy.
Process
The bio-energy conversion process is intricate, involving the transformation of organic materials into various energy forms like heat, electricity, or biofuels. Methods include combustion, gasification, and biochemical processes that break down biomass using microorganisms.