Displaying items by tag: ThyssenKrupp

India: Shiva Cement plans to invest around US$200m towards a new integrated cement plant in Sundergarh district, Odisha. The 1.36Mt clinker unit will also include a 1Mt/yr grinding unit, an 8MW waste heat recovery (WHR) unit, 4Mt/yr crushing plants at its dolomite and limestone quarries, a connecting 10km belt conveyor and a dedicated railway siding with a 12km track to the main network.

ThyssenKrupp Industries India will supply a 4000t/day clinker production line for the project. Larsen & Toubro has been awarded the contract for civil, mechanical and refractory erection work. The unit is expected to create around 500 jobs directly and indirectly. Commissioning is scheduled to take place by March 2022.

Parth Jindal, the managing director of JSW Cement said, "The new clinker unit at Shiva Cement in Odisha will provide a strategic advantage to service the needs of our customers in the region and further strengthen JSW Cement's leadership position in the Green Cement category in India.”

The subsidiary of JSW Cement intends to use the new plant as a strategic hub to access markets in the east of the country. It is part of the group’s aim to achieve a production capacity of 25Mt/yr by 2025.

Germany: ThyssenKrupp has announced the launch of the HPGR Pro, a high-pressure grinding roll for raw materials processing that it says “offers up to 20% more throughput, 15% lower energy consumption and 30% longer-lasting rollers” than previous models. HPGR global product manager Frank Schroers said, “We used our experience and what we learned from conversations with customers to introduce improvements that are unique in this market and make grinding much easier.” Laser monitoring keeps users constantly informed about the roller surface and helps predict the best possible time for roller replacement. “Our customers need no longer stop the machine as a precautionary measure, saving them valuable time. What’s more, as our specialists collect and process machine data, our customers can continually improve their HPGR’s operation and optimise throughput, energy consumption or machine availability in line with their specific targets,” added Schroers.

Vietnam: ThyssenKrupp Industrial Solutions has announced the relocation of its Asia Pacific cement regional division headquarters to Hanoi from Singapore. The new headquarters are on the site of one of the company’s “largest cement plant engineering centres.” It retains offices in Singapore, Indonesia, Thailand and the Philippines. The main motivation for the move is to better enable ThyssenKrupp to supply Vietnamese cement producers.

Cement technologies chief executive officer (CEO) Pablo Hofelich said, “In our new headquarters, we bring together experts from Germany, Singapore and Thailand to support the Vietnam office. Vietnam is the largest market in terms of cement production capacity in a dynamic and growing Asia Pacific.” Asia Pacific cement business CEO Lukas Schoeneck said, “We are focusing on know-how transfer and the development of solutions that are tailored to the requirements of the local markets in Asia Pacific. Besides, we will expand our service activities to strengthen our local footprint and proximity to clients. Lastly, we will push sustainable technologies within our Grey2Green initiative.”

Hydrogen and its use in cement production has been adding a dash of colour to the industry news in recent weeks. Last week, Lafarge Zementwerke, OMV, Verbund and Borealis signed a memorandum of understanding (MOU) to plan and build a full-scale unit at a cement plant in Austria to capture CO₂ and process it with hydrogen into synthetic fuels, plastics or other chemicals. This week, Air Products and ThyssenKrupp Uhde Chlorine Engineers (TUCE) signed a strategic agreement to work together in ‘key regions’ to develop projects supplying green hydrogen. Both of these developments follow the awarding of UK government funding in February 2020 to support a pilot project into studying a mix of hydrogen and biomass fuels at Hanson Cement’s Ribblesdale integrated plant.

As the title of this column suggests there is an environmental colour code to describe how hydrogen is made for industrial use. This is a bit more codified than when grey cement gets called ‘green’ but it pays to remember what the energy source is. So-called ‘green’ hydrogen is produced by the electrolysis of water using renewable energy sources such as hydroelectric or solar, ‘Grey’ hydrogen is made from steam reforming using fossil fuels and ‘Blue’ hydrogen is similar to grey but has the CO₂ emissions from the fuels captured and stored/utilised. Price is seen as the main obstacle to wider uptake of hydrogen usage as a fuel in industry although this is changing as CO₂ pricing mounts in some jurisdictions and the connected supply chain is developed. A study by BloombergNEF from March 2020 forecasted that green hydrogen prices could become cheaper than natural gas by 2050 in Brazil, China, India, Germany and Scandinavia but it conceded that many barriers would have to be overcome to get there. For example, hydrogen has to be manufactured making it more expensive than fossil fuels without government policy support and its, “lower energy density also makes it more expensive to handle.”

The three recent examples with respect to the cement industry are interesting because they are all exploring different directions. The Lafarge partnership in Austria wants to use hydrogen to aid the utilisation side of its carbon capture at a cement plant. The industrial suppliers, meanwhile, are positioning themselves in the equipment space for the technology required to use hydrogen on industrial plants. Secondly, ThyssenKrupp has alkaline water electrolysis technology that it says it has used at over 600 projects and electrochemical plants worldwide. Air Products works with industrial gas production, storage and handling.

Finally, the Hanson project in the UK will actually look at using hydrogen as a partial replacement for natural gas in the kiln combustion system. A Cembureau position paper in mid-2019 identified that the challenges to explore in using hydrogen in cement production included seeing how its use might affect the physical aspects of the kiln system, the fuel mass flows, temperature profile, heat transfer and the safety considerations for the plant. Later that year a feasibility study by the Mineral Products Association (MPA), Verein Deutscher Zementwerke (VDZ) and Cinar for the UK government department that is funding the Hanson project concluded that a hydrogen flame’s high heat in a burner alone might not make it suitable for clinker formation. However, the study did think that it could be used with biomass to address some of that alternative fuel’s “calorific limitations” at high levels. Hence the demonstration of a mixture of both hydrogen and biomass.

That’s all on hydrogen but, finally, if you didn’t log into yesterday’s Virtual Global CemProducer 2 Conference you missed a treat. One highlight was consultant John Kline’s presentation on using drones to inspect refractory in some hard to reach places. Flying a camera straight into a (cool) pyro-processing line was reminiscent of a science fiction film! Global Cement has encountered the deployment of unmanned aerial vehicles in quarry and stockpile surveys previously but this was a step beyond.

The proceedings pack - including video, presenter slides and delegate list - for the Virtual Global CemProducer 2 Conference 2020 is available to buy now

Uzbekistan: Akhangarantsement says that it has installed a ThyssenKrupp raw materials grinding unit at the site of an upcoming 5Mt/yr integrated cement plant in Tashkent Region. The equipment consists of a jaw crusher for primary crushing and a hammer mill for secondary crushing. The company said that the upcoming plant will “provide the market with a line of high-quality products for the construction of housing, industrial and infrastructure facilities.”

US: Air Products has shared details of a partnership with ThyssenKrupp Industrial Solutions subsidiary ThyssenKrupp Uhde Chlorine Engineers (TUCE). Under the partnership, Air Products will build and operate water electrolysis plants for hydrogen production using TUCE’s equipment, engineering and technical services. TUCE chief executive officer (CEO) Denis Krude said, “We are set to supply one 1GW of water electrolysis plants per year, and we are prepared to ramp up the capacity in this rapidly evolving market.” The engineering company has to date realised a total rating of 10GW across 600 electrochemical plants for customers globally.

Germany: ThyssenKrupp has reported a first-half net loss before tax for the fiscal year 1 October 2019 – 30 September 2020 of Euro743m compared to a profit of Euro45.0m for the first half of the previous fiscal year. Net sales fell by 3.0% year-on-year to Euro19.8bn from Euro20.4bn. The period brought a medium-sized cement line order from the US and a low-CO₂ calcined clays cement plant order from Cameroon. As a result of the coronavirus crisis, ThyssenKrupp has cut 3000 jobs on a short-to medium-term basis.

ThyssenKrupp chief financial officer (CFO) Klaus Keysburg said, “Irrespective of the current difficult environment, we are convinced that the Steel Strategy 2030 is the right response to the enormous challenges facing the steel sector.”

Cement and concrete products with sustainability credentials have increased in recent years as societies start to demand decarbonisation. In spite of the recent drop in the European Union (EU) Emissions Trading Scheme (ETS) price, there has been a trend in recent years in the construction industry towards offerings with better environmental credentials. Indeed, this week’s position paper from Cembureau on a carbon border mechanism concerns directly the growth of these kinds of products within Europe. Typically, the higher profile projects have been slag cement or concrete implementations such as Hanson’s use of its Regen cement substitute in a London sewer project or David Ball Group’s Cemfree concrete in a road project also in the UK. In this short review we’ll take a selective look at a few of the so-called low carbon cement and concrete products currently available.

Table 1: Some examples of methods to reduce embodied CO₂ in cement and concrete. Note - the product examples are selective. In some cases many other products are available.

Looking at cement first, the easiest way for many producers to bring a lower carbon product to market has been to promote cements made using secondary cementitious materials (SCM) such as granulated blast furnace slag or fly ash. These types of cements have a long history, typically in specialist applications and/or in relation to ease of supply. For example, cement producers in eastern India often manufacture slag cements owing to the number of local steel plants. However, cement producers have more recently started to publicise their environmental credentials as they reduce the clinker factor of the final product. Alongside this though, in Europe especially, a number of so-called low carbon cement producers have appeared on the scene such as EcoCem and Hoffman Green Technologies. These newer producers tend to offer SCM cement products or other low carbon ones built around a grinding model. It is likely that their businesses have benefitted from tightening EU environmental legislation. How far cement producers can pivot to SCM cement products is contentious given that slag and fly ash are finite byproducts of other industries that are also under pressure to decarbonise. Although it should be noted that other SCMs such as pozzolans exist.

As will be seen below a few of the methods to reduce embodied CO₂ in cement and concrete can be used in both materials. SCMs are no exception and hold a long history in concrete usage. As mentioned above David Ball Group sells Cemfree a concrete product that contains no cement. Harsco Environmental, a minerals management company, invested US$3m into Carbicrete, a technology start-up working on a cement-free concrete, in late 2019.

Limestone calcined clay cements are the next set of products that are starting to make an appearance through the work of the Swiss-government backed LC3 project, more commercial offerings like FutureCem from Cementir and H-EVA from Hoffman Green Technologies and today’s announcement about ThyssenKrupp’s plans to fit the Kribi cement plant in Cameroon with its Polysius activated clay system. They too, like SCM cements, reduce the clinker factor of the cement. The downside is that, as in the name, the clay element needs to be calcined requiring capital investment, although LC3 make a strong case in their literature about how fast these costs can be recouped in a variety of scenarios.

Calcium silicate cements offer reduced process emissions by decreasing the lime content of the clinker lowering the amount of CO₂ released and bringing down the temperature required in the kiln to make the clinker. Solidia offers its calcium silicate cement as part of a two-part system with a CO₂ cured concrete. In the US LafargeHolcim used Solidia’s product in a commercial project in mid-2019 at a New Jersey paver and block plant. Solidia’s second core technology is using CO₂ to cure concrete and reducing water usage. They are not alone here as Canada’s CarbonCure Technologies uses CO₂ in a similar way with their technology. In their case they focus more on CO₂ mineralisation. In Germany, Schwenk Zement backed the Celitement project, which developed a hydraulic calcium hydro silicate based product that does not use CO₂ curing. Celitement has since become part of Schwenk Zement.

Solidia isn’t the only company looking at two complementary technologies along the cement-concrete production chain. A number of companies are looking at recycling concrete and demolition waste. Generally this splits into coarse waste that is used as an aggregate substitute in concrete and fine waste that is used to make cement. LafargeHolcim has Evopact for the coarse waste and Susteno for the fine. HeidelbergCement has EcoCrete for the coarse and is researching the use of fines. Closing the loop for heavy building material producers definitely seems like the way to go at the moment and this view is reinforced by the involvement of the two largest multinational producers.

Of the rest of the other low carbon cement methods detailed in table 1 these cover other non-Ordinary Portland Cement (OPC) such as geopolymer and calcium sulphoaluminate cements. The former are a type of alkali activated binder and generally lack common standards. The latter are similar to slag cements in that they are established specialist products with lower CO₂ emissions than OPC.

With concrete when trying to make a low carbon product the first choice is whether to choose a low-carbon cement as the binder or even not to use cement at all in the case of Regen or Cemfree. From here the next step is to simply use less cement in a concrete mixture. There are a number of ways to do this from optimising aggregate gradation, following performance specifications more closely, using strength tests like maturity methods and generally adhering to quality control protocols better to deliver more consistency. Read the Mineral Production Association (MPA) publication Specifying Sustainable Concrete for more detail on this. Using concrete admixtures can also help make concrete more sustainable by improving quality and performance at construction sites through the use of plasticisers and accelerators, by decreasing embodied carbon through the use of water reducers and by improving the whole life performance of concretes. The use of locally-sourced aggregates is also worth noting here since it can reduce associated transport CO₂ emissions.

More novel methods of reducing embodied CO₂ emissions in concrete include the use of geopolymer concrete in the case of Zeobond Group’s E-Crete or adding graphene as Concrene does. Like geopolymer cements, geopolymer concretes are relatively new and lack common standards. Products like Concrene, meanwhile, remain currently at the startup level. Finally, if all else fails, offsetting the CO₂ released by a cement or concrete product is always an option. This is what Cemex has done with its Vertua Ultra Zero product. The first 70% reduction in embodied CO₂ is gained through the use of geopolymer cement. Then the remaining 30% reduction is achieved through a carbon offsetting scheme via a carbon neutral certification verified by the Carbon Trust.

As can be seen, a variety of methods exist for cement and concrete producers to reduce the embodied CO₂ of their products and call them ‘low-carbon.’ For the moment most remain in the ‘novelty section’ but as legislators promote and specifiers look for sustainable construction they continue to become more mainstream. What has been interesting to note from this short study is that some companies are looking at multiple solutions along the production and supply chain whilst others are concentrating on single ones. The companies looking at multiple methods range from the biggest building material producers like LafargeHolcim and HeidelbergCement to smaller newer ones like Solidia and Hoffman Green Technologies. Also of note is that many of these products have existed already in various forms for a long time like SCM cements and concretes or the many ways concretes can be made more sustainable through much simpler ways such as changing aggregate sourcing or working more efficiently. In many cases once markets receive sufficient stimulus it seems likely that low carbon cement and concrete products will proliferate.

Global Cement is researching a market report on low carbon cement and concrete. If readers have any comments to make please contact us at This email address is being protected from spambots. You need JavaScript enabled to view it.

Cameroon: Germany-based Thyssenkrupp Industrial Solutions has won an engineering, procurement, construction and commissioning (EPCC) contract with Netherlands-based Cimpor Global Holdings for the installation of a clay calcination plant at its new integrated Kribi cement plant in the Port of Kribi in South Cameroon. The system calcines clay at just 800°C, which can then replace clinker at a ratio of one to two, lowering the finished cement’s clinker factor by up to 33%.

ThyssenKrupp says that use of the system, the first of its kind in Cameroon and second at a Cimpor Global Holdings cement plant, will help cut CO₂ emissions by 120,000t/yr, corresponding to a reduction of 40%.

Germany: ThyssenKrupp has decided to retain Martina Merz as its chief executive officer (CEO) for a three year term from 1 April 2020. She was originally delegated to the position for a year. As part of the transition she will resign from the supervisory board.

The group has also decided to appoint Klaus Keysberg as its chief financial officer (CFO) following the resignation of Johannes Dietsch. Keysberg, who holds a PhD in business administration, will remain responsible for the materials businesses in addition to his new role as CFO. Plant Technology will in future be the responsibility of Martina Merz.

With these personnel changes the executive board of ThyssenKrupp now consists of only three members. In addition to Martina Merz as CEO and Klaus Keysberg as CFO, Oliver Burkhard will continue in his role as Chief Human Resources Officer and Labor Director.