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The brand new unit of the Ostiglia combined-cycle energy plant might be a multi-shaft unit. Credit score: Siemens Energy.

The brand new unit will characteristic Siemens’ HL-class gasoline turbine know-how. Credit score: Siemens Energy.

The SGT5-9000HL gasoline turbine has the capability to generate as much as 880MW of energy. Credit score: Siemens Energy.

The prevailing Ostiglia combined-cycle energy plant (CCPP), situated in Ostiglia, Lombardy, Italy, is being prolonged with the addition of a brand new 880MW combined-cycle unit.

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Italy-based electrical energy technology firm EP Produzione, a subsidiary of the EHP Group, is growing the facility plant. The growth was proposed in July 2020 and is predicted to be operational by 2025.

The event of the brand new unit is consistent with the targets of Italy’s Built-in Nationwide Energy and Local weather Plan, which is aimed toward reaching decarbonisation whereas bolstering the safety of the nationwide electrical energy system. The brand new unit will provide clean energy to greater than half one million households in Italy.

The undertaking is a part of Terna’s Capability Market programme. A European grid operator, Terna designed the programme to obtain energy by awarding long-term provide contracts by way of aggressive bidding.


The brand new unit is being developed throughout the present Ostiglia thermoelectric energy plant web site, which spans 51ha on the left financial institution of the River Po. The positioning is discovered within the Ostiglia municipality of the province of Mantua, situated in Lombardy in northern Italy.

The prevailing energy plant contains three combined-cycle gasoline turbine models with a complete put in capability of 1.13GW.

Ostiglia combined-cycle energy plant make-up

The brand new Ostiglia CCPP unit might be a multi-shaft unit, consisting of gasoline and steam generators that drive their very own mills. The unit can even embrace state-of-the-art know-how to facilitate optimum pure gasoline utilization together with a excessive diploma of flexibility.

The plant will comprise a Siemens SGT5-9000HL gasoline turbine, SGen5-3000W gasoline turbine generator, SST5-5000 steam turbine, SGen5-1200A steam turbine generator and heat-recovery steam generator.

It’s going to additionally embrace Siemens’s T3000 management system, which helps to make sure dependable energy plant operations by supporting energy plant operators. The system implements the very best cybersecurity requirements and has acquired the IEC 62443 certification, a number one normal for IT safety for industrial communication networks, from American IT safety firm TÜD SÜD.

Sooner or later, the pure gas-fired energy plant will have the ability to function with as much as 30% hydrogen gas.

Turbine particulars

The SGT5-9000HL gasoline turbine has the capability to generate as much as 880MW of energy with greater than 64% internet effectivity.

The gasoline turbine weighs 497,000kg and measures 13m (42.6ft) lengthy, 5.3m (17.4ft) large and 5.5m (18.1ft) excessive. The turbine is able to working on fuels that embrace pure gasoline, liquified pure gasoline (LNG) and distillate oil.

Appropriate for each 50Hz and 60Hz grids, the SST5-5000 steam turbine can generate between 120MW and 700MW of energy. It’s appropriate for CCPP in addition to steam energy crops and affords an effectivity of greater than 64% in combined-cycle mode.

The SGen5-3000W gasoline turbine generator weighs as much as 425t and affords excessive working flexibility. It incorporates a MICALASTIC® insulation system and World Vacuum Stress Impregnation (GVPI) know-how, enabling optimum electrical endurance.


The brand new CCPP unit will characteristic Siemens Energy know-how, which can considerably scale back carbon dioxide emissions resulting from its excessive effectivity compared to coal or older gas-fired energy crops. It’s going to additionally keep nitrogen oxide emissions at lower than 10mg/Nm³.

The air-cooled condenser within the plant will get rid of the necessity for water to be drawn from the close by River Po for cooling functions. It additionally contains a versatile working vary, together with minimised gas consumption.

Contractors concerned

In February 2022, development engineering firm Fata, a part of Danieli Group, signed an settlement to offer engineering, procurement and development providers for the undertaking in a consortium with Siemens Energy, an energy firm primarily based in Germany, and Demont, a development firm.

Siemens Energy will provide the gasoline turbine, steam turbine, gasoline generator, steam generator, warmth restoration steam generator and management system for the growth. It’s going to additionally present long-term providers for all of the gear and parts.

Demont might be answerable for the mechanical erection of all crops, in addition to the engineering, procurement and development of the stability of plant piping.

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Bitcoin as environmentally costly as beef production



Texas town group protests Riot Blockchain's Bitcoin mining facility

Credit score: Unsplash/CC0 Public Area

Taken as a share of the market worth, the environmental prices of mining the digital cryptocurrency Bitcoin are extra similar to the local weather damages of manufacturing beef than gold mining prices, in response to evaluation revealed in Scientific Experiences. The authors counsel that quite than being thought of akin to “digital gold,” Bitcoin ought to as a substitute be in comparison with far more energy intensive merchandise corresponding to beef, pure fuel, and crude oil.

In December 2021, Bitcoin had an roughly 960 billion US {dollars} market worth with a roughly 41% world market share amongst cryptocurrencies. Though identified to be energy intensive, the extent of Bitcoin’s local weather damages—estimates of monetary harm from and the on economies—is unclear.

Benjamin Jones and colleagues current financial estimates of local weather damages from Bitcoin mining between January 2016 and December 2021. They report that in 2020 Bitcoin mining used 75.4 terawatt hours per 12 months (TWhyear-1)—larger energy utilization than Austria (69.9 TWhyear-1) or Portugal (48.4 TWhyear-1).

The authors assessed Bitcoin local weather damages in response to three sustainability standards: whether or not the estimated local weather damages are growing over time; whether or not the market worth of Bitcoin exceeds the financial price of local weather damages; and the way the local weather damages per coin mined evaluate to local weather damages of different sectors and commodities.

They discover that the energy emissions for Bitcoin mining have elevated 126 fold from 0.9 tons of emissions per coin in 2016, to 113 tons per coin in 2021. Calculations counsel every Bitcoin mined in 2021 generated 11,314 USD in local weather damages, with complete world damages exceeding 12 billion USD—25% of market costs. Damages peaked at 156% of coin worth in Might 2020, suggesting that every 1 USD of Bitcoin market worth led to 1.56 USD in world local weather damages.

Lastly, the authors in contrast Bitcoin local weather damages to damages from different industries and merchandise corresponding to , processing, agricultural meat manufacturing, and treasured steel mining. Local weather damages for Bitcoin averaged at 35% of its market worth between 2016 and 2021. This was lower than the local weather damages in comparison with market worth of electrical energy produced by (46%) and gasoline produced from crude oil (41%), however greater than these of beef manufacturing (33%) and gold mining (4%).

The authors conclude that Bitcoin doesn’t meet any of the three key sustainability standards they assessed it in opposition to, and that important modifications—together with potential regulation—are required to make Bitcoin mining sustainable.

Bitcoin carbon emissions rise as mining moves to US and other countries

Extra info:
Benjamin A. Jones, Financial estimation of Bitcoin mining’s local weather damages demonstrates nearer resemblance to digital crude than digital gold, Scientific Experiences (2022). DOI: 10.1038/s41598-022-18686-8.

Bitcoin as environmentally pricey as beef manufacturing (2022, September 29)
retrieved 29 September 2022

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Engineers plan to bring new life to electronics recycling, address supply chain shortfalls affecting national defense



Engineers plan to bring new life to electronics recycling, address supply chain shortfalls affecting national defense

Edward Sabolsky, WVU Benjamin M. Statler College of Engineering and Mineral Resources professor, uses ceramic bricks to conduct research at his lab. The Department of Defense has tasked Sabolsky and Terence Musho with developing a new process for recycling electronic waste in order to extract raw materials that are used to build technology critical to U.S. national defense, such as semiconductors. Credit: WVU Photo/Brian Persinger

West Virginia University researchers are resurrecting discarded electronics, recycling electronic waste and recovering minerals from it to make new products critical for national defense.

Terence Musho, associate professor of mechanical and aerospace engineering at the Benjamin M. Statler College of Engineering and Mineral Resources, is leading the project.

The U.S. currently depends on countries like China to provide raw materials that are essential to electronics enabling its national defense. But according to Musho, that “reliance on foreign national resources has led to the White House identifying a critical shortage in the semiconductor supply chain.”

Musho said that shortage is one reason the Department of Defense (DOD) is eyeing readily available like old “LEDs and microelectronic circuits used for amplifying radio frequencies, which contain critical supply chain materials.”

One key factor setting the research Musho is conducting with Statler Professor Edward Sabolskyapart from current systems for recycling is the “ability to achieve very high temperatures in a very rapid manner,” which allows their to be modular. That is, because it’s relatively small, it can easily be moved in modules from place to place.

“That means the DOD can transport this technology around to the point of disposal of these e-waste materials,” Musho said. “Space debris is an issue that’s gaining attention, so one potentially far-out idea is that this potentially could be used in space. You could collect junk satellites, recycle the waste and bring the raw materials back to earth.

“Another possible application would be U.S. Navy ships, which could move this equipment around to different ports for waste recycling.”

The technology also has promise beyond the sphere of national defense. “You could have a point-of-disposal e-waste recycler in each community,” Musho suggested. “Communities could recycle their own e-waste, get the out and sell those materials back to manufacturers.”

Electronics recycling began to emerge in the 1970s but it has never gained much traction. Musho explained that when you take your old electronics to Best Buy, there are just a handful of facilities in the nation where the electronics can be processed. “Those places get a mountain of e-waste,” he said.

Electronics recycling facilities deal with that e-waste via a process of pyrometallurgy or hydrometallurgy. Both those processes use either high temperatures or to extract minerals from electronics and both need large quantities of waste in order to be economical.

Largely because of problems like those, most current e-waste heads to landfills. In its effort to change that, the DOD has focused on recovering seven specific elements from e-waste, chief among them gallium, indium and tantalum.

Musho will guide their experiments, using computational thermodynamics to simulate the mineral recovery process. Sabolsky will validate the simulations to prove the process works in practice.

Musho is confident that it will work, especially because Sabolsky’s previous research laid the groundwork for this study.

“Ed did a previous study on coal fly ash, a waste product of coal-fired power plants, and he demonstrated that this process works for other critical elements present in fly ash. Now, we’ll take that knowledge, improve upon it and apply it to e-waste.”

The project’s first phase is a nine-month study demonstrating Musho and Sabolsky’s e-waste recycling process in the lab.

After that, they’ll refine the approach to “hit tighter purity standards” for the recovered minerals. They’ll scale up to handle greater quantities of material and work on packaging the technology within a small, modular unit that’s easily transported, as they begin to consider commercialization.

“We have an abundance of critical materials currently sitting in e-waste in our landfills,” Musho said. “It’s just a matter of determining the best method to recover these elements. The technology we’re developing provides a supply chain solution not only for DOD electronics but also consumer electronics.”

Researchers introduce new step in process for saving e-waste scraps

Engineers plan to bring new life to electronics recycling, address supply chain shortfalls affecting national defense (2022, September 29)
retrieved 29 September 2022

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A long-awaited solution for hard-to-abate sectors?



A long-awaited solution for hard-to-abate sectors?

Carbon emissions of key nations and analytical mechanism for hydrogen within the energy system. a, China’s carbon emissions in 2019 in contrast with america, Europe, Japan and India, by gasoline. In 2019, coal combustion took the most important share of the carbon emissions in China (79.62%) and India (70.52%), and oil combustion contributed most to the carbon emissions in america (41.98%) and Europe (41.27%). b, China’s carbon emissions in 2019 in contrast with america, Europe, Japan and India, by sector. Emissions are displayed on the left and proportion on the best in a and b. The proportion of carbon emissions from trade in China (28.10%) and India (24.75%) was a lot increased than that of america (9.26%) and Europe (13.91%) in 2019. c, Technical pathway with hydrogen applied sciences utilized within the HTA sectors. SMR, steam methane reforming; PEM electrolysis, polymer electrolyte membrane electrolysis; PEC course of, photoelectrochemical course of. Credit score: Nature Energy (2022). DOI: 10.1038/s41560-022-01114-6

One of many world’s largest local weather challenges is decarbonizing fossil energy makes use of that can’t be straight electrified utilizing renewable energy. Amongst so-called “hard-to-abate” (HTA) sectors are main industries that depend on fossil fuels, both for high-temperature energy or for chemical feedstocks. These embody iron and metal, cement, chemical substances, and constructing supplies, collectively liable for roughly 30% of the world’s annual CO2 emissions.

One other HTA sector is heavy-duty transportation comparable to trucking and delivery, which is tougher to affect than passenger transport as a result of it might require monumental batteries that add to automobile weight and take a very long time to cost.

As nations look at pathways in direction of decarbonization, comparatively rich ones just like the U.S. and far of Europe are pursuing methods centered on renewable energy technology and electric autos. China faces considerably totally different challenges as a consequence of a particular carbon emission profile ensuing from the a lot bigger roles that HTA heavy industries play in its financial system.

New analysis printed in Nature Energy examines how China—by far the most important producer of iron, metal, cement, and constructing supplies—can probably make the most of clear hydrogen (“green” and “blue” hydrogen) to decarbonize HTA sectors, and support in reaching its 2030 and 2060 decarbonization pledges. Green hydrogen is made by splitting water molecules—H2O—utilizing , whereas blue hydrogen is produced conventionally, from , however mixed with carbon seize and storage.

The brand new paper from the Harvard-China Venture on Energy, Economic system and Surroundings, a U.S.-China collaborative analysis program based mostly on the Harvard John A. Paulson College of Engineering and Utilized Sciences, is the primary research up to now that makes use of an built-in modeling strategy to judge the potential use of unpolluted hydrogen throughout China’s energy system and financial system, with the intention to meet its 2060 net-zero goal.

“Filling this analysis hole will assist draw a clearer roadmap for China’s CO2 ,” explains lead creator of the paper Xi Yang, a researcher on the Harvard-China Venture. “Our purpose with this research was to check a job for clear hydrogen in China’s energy financial system, which might then present a reference for different growing economies with giant heavy industrial and transportation sectors.”

The research evaluated three questions: What are the important thing challenges of decarbonizing HTA sectors? What are the possible roles for clear hydrogen as each an energy service and feedstock in HTA sectors? And would widespread software of unpolluted hydrogen in HTA sectors be cost-effective in comparison with different choices?

To investigate the and function of unpolluted hydrogen throughout China’s whole financial system—with an emphasis on the under-researched HTA sectors—the staff constructed a mannequin of an built-in energy system that features provide and demand throughout sectors. Outcomes present {that a} widespread software of unpolluted hydrogen in HTA sectors will help China obtain carbon neutrality cost-effectively in comparison with a state of affairs with out clear hydrogen manufacturing and use. Clear hydrogen can save $1.72 trillion in funding prices and keep away from a 0.13% loss within the combination GDP (2020-2060) in comparison with a pathway with out it.

The researchers additionally examined the kind of clear hydrogen—green or blue—that may be most price efficient. Their research signifies that the typical price of China’s green hydrogen may be diminished to $2/kg of hydrogen by 2037 and $1.2/kg by 2050, when it is going to be far more cost-effective than blue hydrogen ($1.9/kg).

“China has wealthy untapped sources of {solar} and , each onshore and offshore,” explains Chris P. Nielsen, co-author of the paper and Govt Director of the Harvard-China Venture. “These sources give China benefits in direction of growing green hydrogen to be used in its industrial and transportation sectors.”

And whereas decarbonizing such hard-to-abate sectors is vital to local weather motion, it might have further advantages. New markets for green hydrogen might additionally assist the facility system transition to renewable sources. Nielsen explains that green manufacturing would do that by offering a relatively versatile type of electrical energy demand that needn’t be met instantaneously, like most electrical energy masses. As an alternative it will probably usually be scheduled, at the very least inside quick time frames. Such demand flexibility is effective to grid managers, serving to them to accommodate the inherent variability of renewable energy sources as they’re affected by altering meteorological circumstances.

Green hydrogen from expanded wind power in China: Reducing costs of deep decarbonization

Extra data:
Xi Yang et al, Breaking the hard-to-abate bottleneck in China’s path to carbon neutrality with clear hydrogen, Nature Energy (2022). DOI: 10.1038/s41560-022-01114-6

Clear hydrogen: An extended-awaited resolution for hard-to-abate sectors? (2022, September 29)
retrieved 29 September 2022

This doc is topic to copyright. Other than any honest dealing for the aim of personal research or analysis, no
half could also be reproduced with out the written permission. The content material is supplied for data functions solely.

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