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Our steam turbines are customised to suit sector-specific needs

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Industrial waste heat is the energy that is generated in processes, which is not put into any practical use and is lost, wasted and dumped into the environment. Recovering the waste heat can be conducted through various waste heat recovery technologies to provide valuable energy sources. Triveni Turbine is an important player for industry in WHR. ICR is in conversation with Arun Mote, Executive Director & CEO, Triveni Turbine.

Provide us a brief introduction of your company and its products and services.

Triveni Turbine is the largest manufacturer of industrial steam turbines in terms of unit volume in the sub 30 MW range globally. With more than one billion operating hours of turbine fleet, the company has installed over 4,000 steam turbines (total 13 GW power generation capacities) across 20 industries. Triveni is present in over 70 countries around the world. Triveni manufactures turbines at its world-class manufacturing facilities located in Bengaluru.

Triveni Turbines offers steam turbine solutions for industrial captive and renewable power. Our steam turbines are used in diverse industries, ranging from steel, cement, sugar, textiles, chemical, pulp and paper, petrochemicals, fertilisers, solvent extraction, metals, palm oil to food processing, oil and gas, waste to energy (WtE). Many of the leading cement companies use the steam turbines made by Triveni for recovery of the waste heat.

The company?? product portfolio comprises a large range of back-pressure and condensing steam turbines that are easily customised to suit sector-specific and customer-specific needs. Equipped with a choice of impulse and reaction technology, these turbines can work across a wide range of pressure and flow applications.

The aftermarket business of the company, Triveni REFURB, works globally across all brands of rotating equipment leaving a positive footprint on repair, spares, overhauling, efficiency improvements, etc. up to 300MW including the C-WHR sector.

Tell us about the progress being made on renewable energy in our country. Where do we stand in comparison to developed economics and what is our goal?

In India, existence of renewable energy began in the early 2000s. With the initiative from the Central and State Governments and implementation of Indian Electricity Act of 2002, certain drive and incentives were given to renewable energy segment like biomass IPP??, wind energy, solar energy, WtE, and bagasse-based sugar cogeneration.

Renewable energy capacity addition in India for FY20 stands at 9.4 GW, out of which solar power alone contributes 6.4 GW. Wind energy is the second major contributor. Solar and wind energy constitute the utility power generation and are Independent Power Producers (IPP) that generates the power to utilities and large users while the non-IPP?? are generating the power for the industrial consumption. Waste heat recovery power plants in the sectors like sponge iron, steel and cement came into existence from the year 2000 onwards in the Indian market.

Earlier in India, cement giants installed cement WHR plants made in China. Over the last decade, Indian boiler and turbine OEM?? offered the products that were indigenously designed and manufactured catering to the ever-changing market demand along with providing sustained long-term aftermarket services. These plants are able to deliver the design outputs consistently. India is one of the countries with a strong presence of cement WHR power plants. Countries with developed economies like USA, Europe and Japan that have surplus power have not invested in the cement WHR technology.

Size wise which is the largest WHR project you had executed? What were the challenges?

Cement WHR depends on cement kiln capacity, heat utilisation and plant efficiency. Accordingly, potential WHR power generation varies from 4 MW to 25 MW. More than 20 MW power generation is quite uncommon.

Triveni provided 22.5 MW steam turbine to Prism Johnson Cement WHR plant through the EPC company ??ThyssenKrupp Industries. This 22.5 MW steam turbine is an injection condensing turbine, which receives medium pressure (MP) steam as inlet and low pressure (LP) steam as injection in mid steam path. Steam is collected from 4 No?? of Preheater (PH) boilers and 2 No?? After Quenching Cooler (AQC) Boilers from the two cement kilns of 7000 TPD and 8,000 TPD capacity.

It was challenging to take up this project as the steam flow was across multiple sources (i.e. multiple boilers). Steam generation depends on the waste heat generated from hot gas temperature from preheating process and AQC. Due to this there is variation in steam inlet at MP and LP side and load variation in load or power output.

However, commissioning of the turbine was successfully completed despite the challenges that we faced with the quick turbine delivery of eight months. This sets a benchmark for Triveni in the cement industry. Prism Johnson Cement does not have captive power plant installed and this WHR plant has offered many benefits to them.

On the other hand, Triveni REFURB, is working on providing solution to customers having existing ??urbines without injection?? These Turbines are re-engineered to allow the additional steam to be injected into the Turbine and improve the efficiency of the plant.

Throw light on three waste heat power recovery systems. Which has been popular in among cement plants?

Globally there are three processes by which WHR plants are installed in a cement industry.

  • Steam Rankine Cycle System (SRC)

  • Organic Rankine Cycle System (ORC)

  • Kalina Based System

In India, SRC is widely used for WHR power generation across cement plants. In SRC, exhaust gases from rotary kiln pass through preheaters (PH) to the preheater boiler. Similarly mid tapping from AQC induces hot gases to AQC boiler. One line of cement kiln can give waste heat for 2 PH boiler and 1 AQC boiler for steam generation. These boilers, based on heat source, generate MP steam of 11 Ata to 18 Ata at temperature 300 to 465 deg Celsius and LP steam of 2 Ata to 3.5 Ata pressure at temperature 180 to 205 degree Celsius.

Injection condensing turbines are widely used for such applications. These turbines use the MP steam as inlet to turbine and inject the LP steam to the LP side of turbine, later this combined steam is expanded at LP/exhaust side to 0.1 Ata or 0.2 Ata based on water cooled condenser or air cooled condenser options.

Generating steam from hot gases is a significant technology in the cement industry. Leading Indian boiler OEM?? have developed expertise in steam generation under various conditions. Similarly, the Injection condensing turbine developed by Triveni for different MP and LP steam combinations are successfully working across the Indian cement sector. These indigenised steam turbines and boilers helps in eliminating the dependency on Chinese boilers and Chinese turbines which were earlier being used in WHR plants till the year 2012-14.

Dependency on Chinese turbines has now declined in the Indian market as the Indian OEM?? adapted to Injection condensing turbines technology with a dominant leadership. As per recent industry estimates, close to 50 to 60 per cent of cement plants in India have installed WHR based power plants so far and the rest are in the process of setting up the plants in the next three to four years??time period. Large cement companies are mostly considering WHR power plants for their greenfield projects.

Below table demonstrates the technical parameters benchmarked for available heat per ton of clinker in cement plants that are considered for WHR power generation.

Triveni has a strong reference of injection condensing turbines supplied to cement WHR plants across India. Specific design consideration is important in injection and admission zone. The rotor designed by Triveni has the higher stability to offset the excitation due to fluctuating injection steam loads. Turbine mid-section and low pressure section is subjected to cyclic fatigue loads induced by thermal cycle and flow variations. To address this issue design and engineering teams carry out CFD analysis and creep fatigue analysis. This design philosophy is a feather in the cap for Triveni for its robust and efficient cement WHR solution.

Which are the sections of Cement Plants from where you recover the heat and which are the sections where there is potential but one cannot recover the heat?

As mentioned, preheaters, which collects hot gases from cement kiln and AQC (after quenching chambers/coolers), are the primary source of heat. Hot gases from these when passed through steam generators/boilers produces MP steam of 11 Ata, 300 degree Celsius to 18 Ata, 465 degree Celsius and LP steam (injection steam) at 2 to 3.5 Ata and 180 to 205 degree Celsius. Presently these are sources of heat in cement plants. Heat from the raw mill section or exhaust gases from boilers are unutilised as the heat is of low quality and cannot be used in present form.

To increase the power output in new plants, fire heaters are used where the temperature of hot gases are increased by burning pet coke or low-grade coal. Gas temperature and finally MP steam temperature is increased to 465 to 470 degree Celsius. one of the leading cement manufacturer has used this concept in their new cement plants.

Typically what is payback period of the WHR project? Has it changed over period of time?

Capex investment for WHR projects is Rs 10 crore per MW power generation. But its opex cost is very low. No main fuel cost or supplementary fuel is required. Due to the availability of free heat in the form of waste gases from cement manufacturing process, power generation cost is significantly low as compared to CPP power generation or grid power cost. WHR power plants are installed in existing cement plant and new cement plant. The land and other infrastructure are readily available at these sites. There is continuous focus to reduce capex cost.

In the aftermarket segment, the re-engineered/efficiency enhanced turbine offers a payback of two years as there will be no modifications on the civil foundation and the existing balance of plant will mostly remain the same.

What are the offerings of Triveni Turbines for cement WHR (C-WHR) power plants?

Triveni has developed efficient injection condensing turbines, which take MP steam as turbine inlet and LP steam as injection steam after certain stages. With addition of seven generation turbine blades developed by Triveni, power generation output is more for input steam parameters or gas parameters.

Salient features of Triveni?? steam turbines in the cement industry are as follows:

Integral lube oil tank: Triveni offers integral lube oil tank for power house layout and civil cost optimisations of TG house.

Benefit: Reduction in civil cost of the project.

  • MRT: Live steam mechanical run test at Triveni?? manufacturing facility for the steam turbines. Turbine is tested with live steam from boilers at Bengaluru works with job mounted turbo supervisory systems, Woodward governor and gear box.

  • In-house manufacturing: Turbine components like blades, rotor, and casing are manufactured and assembled at Triveni?? facility.

  • Vacuum tunnel: High speed balancing of turbine rotor on ??chenk??Vaccum Tunnel

  • Triveni gear box: Gear box (Triveni Power Transmission) assembly is done along with the turbine on the same base plate and converts into a single product. Separate foundation of gear box is not required.

What is Triveni Turbines contribution to cement WHR? How it sees road ahead.

Triveni is associated with C-WHR since many years and executed numerous prestigious projects with the leading cement manufacturers. Following is list of some of key projects successfully executed by Triveni Turbines in C-WHR sector:

  • UltraTech Cement ??70 MW

  • Dalmia Cement ??40 MW

  • Nuvoco Vistas ??20 MW

  • Penna Cement ??30 MW

  • Prism Johnson Cement ??23 MW

We are currently working on multiple projects which are in the enquiry and finalisation stage. Way forward to cement WHR is the implementation of such projects over the coming years.

Can WHR energy be treated as renewable energy? What has been approach in our country?

Technically C-WHR can be treated as renewable energy as the fossil fuels like coal, pet coke are not used. Here combustion of natural resources do not take place. It helps in preserving earth?? diminishing natural resources like coal. It also helps in reducing carbon emission. But in India it is seen as an industrial consumption or in-house consumption and not for utility. Hence incentives, policy guidelines or the drive from the governments does not exist. Cement sectors have opted the WHR technology and are saving precious resources as coal.

Do you think bringing WHR under renewable gets more traction? What is the situation in other countries?

Presently 50 to 60 per cent of cement manufacturing plants have already implemented WHR technology in their cement plants. Big cement manufacturers in India have already installed CWHR in their plants and planning to install in the other plants also. However a few other manufacturers, having one or two manufacturing plants and limited geographical presence are not opting for WHR due to the need for major capex investment and financial constraints. If C-WHR is treated as renewable energy source and incentives are offered it will get more traction for WHR power plants.

This will reduce load on the grid power and also helps in saving coal reserves for future generation. The industry associations and sector specific associations can play role in bringing Central Government and State Government Ministry?? or Electricity regulators on a single platform. This forum can decide the long and short term policies to promote and implement C-WHR in all plants in India. China is much ahead of us in C-WHR and had over 80 per cent of plants installed C-WHR. Europe, USA and Latin America are planning to implement C-WHR in their cement plants and some International tenders are already under discussions and advance stage of finalisation. A greater push is required for C-WHR in the Indian context and in the upcoming years, Triveni will play a significant role in installing C-WHR 100 per cent across the cement manufacturing plants in India.

Arun Mote graduated from IIT Bombay further with a Master?? degree in Mechanical Engineering. Obtained his MBA from Jamnalal Bajaj Institute of Management Studies, Bombay University. Joined Larsen & Toubro Limited as a Management Trainee looking after Caterpillar product line. Subsequently, he changed over to SKF Bearings and was looking after automation and electrical segments. Subsequent he worked with a Central Air Conditioning Company of Blue Star. For last 20 years, he is with Triveni Turbine looking after turbine business. Under his leadership, the turbine business has turned around and has grown many times and established leadership in Industrial Turbines in domestic and also in overseas market.

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Concrete

Akhoya Gets New 2.2 Km Road Link Under SASCI

Two cement concrete roads opened at Rs 29.1 million (mn) cost

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Two cement concrete pavement roads covering a total stretch of 2.2 km in Akhoya village were inaugurated on 27th June 2026 by MLA Nuklutoshi Longkumer, who attended as the special guest. The project comprises the one km L Pangersowa Road and the one point two km Longchara Junction to RC Chiten Jamir Memorial Government High School road. A formal programme followed the inauguration at the school auditorium.

A technical report was presented by Er Waloniba of the Urban Engineering Wing-III, Kohima, which stated the project was sanctioned in March 2026 under the Special Assistance to States for Capital Investment scheme for 2025-26 at a sanctioned cost of Rs 29.1 million (mn). The work order was issued to M/s Ensign Construction on thirtieth April 2026 with a stipulated completion period of 12 months. Work commenced on fourth May 2026 and was completed on sixth June 2026, with the contractor and team finishing the tasks in around two months. The project included a single-lane cement concrete pavement with side drains, two slab culverts and breast walls at required locations.

Longkumer acknowledged the Chief Minister, the advisor for urban development, contractors and other stakeholders for the allocation and support, and he commended the contractor for early completion. He noted that cooperation from landowners and the community had been important in resolving land related issues that can otherwise delay developmental works. He emphasised that planned developmental activities carried out with collective effort would enable more projects to be implemented successfully.

The headmaster of RC Chiten Jamir Memorial Government High School, I Chubasenba Longkumer, outlined the school background, noting it was established in 1962, was earlier known as Government High School Changtongya and was renamed in 2014. Local representatives said the improved approach roads would ease access for students, staff, patients and the general public and fulfil a long standing aspiration of residents. A dedicatory prayer was offered by the pastor and the programme concluded with a ribbon cutting attended by village council and town council representatives.

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Green Construction Through Cement Innovation

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Indian Cement Review (ICR) and Fuller Technologies brought industry, policy and technology leaders together to discuss how cement innovation can drive green construction at scale, writes Rakesh Rao.

India is building at a pace few countries can match. Highways, airports, housing, logistics parks, industrial corridors and urban infrastructure are reshaping the country’s economic geography. But beneath this growth story lies a difficult question: can India continue to build at scale without locking itself into a high-carbon future?

That question formed the core of an online panel discussion titled “Driving Green Construction Through Cement Innovation”, organised by Indian Cement Review (ICR) in association with Fuller Technologies as the Presenting Partner on June 25, 2026. The webinar brought together experts from cement technology, R&D, global industry platforms, building performance policy and international development cooperation to examine how low-carbon cement and material innovation can accelerate India’s green construction transition.

The discussion came at a crucial time. India has committed to achieving net-zero emissions by 2070 and reducing the carbon intensity of its economy by 45 per cent by 2030. At the same time, the country’s construction sector is expanding rapidly, driven by urbanisation, infrastructure development, housing demand and industrial growth. Cement, as one of the most widely used construction materials, sits at the heart of this transition. It is indispensable to development, but also central to the challenge of reducing embodied carbon in buildings and infrastructure.

Moderated by Nitika Krishan, Senior Urban Infrastructure and Sustainable Policy Consultant, the panel featured:

  • Kiranmai Sanagavarapu, Director, Low Carbon Solutions, Fuller Technologies;
  • Dr Hemantkumar Aiyer, VP and Head R&D, Nuvoco Vistas Corp Ltd;
  • Devika Wattal, Innovation Lead, Global Cement and Concrete Association (GCCA);
  • Dr Sunita Purushottam, MD, GBPN India (Global Buildings Performance Network); and
  • Vaibhav Rathi, Senior Technical Advisor, GIZ (the German Agency for International Cooperation)

Setting the tone for the discussion, Nitika Krishan underlined the scale of the challenge before the sector. “The question before us is no longer whether we build, but how we build sustainably,” she said. She pointed out that construction accounts for nearly 40 per cent of global energy-related carbon emissions when both operational and embodied carbon are considered. Cement production, she added, remains one of the hardest industrial processes to decarbonise.

For India, this is not merely an environmental issue. It is a development issue, a competitiveness issue and increasingly, a market issue. As one of the world’s largest cement producers and among the fastest-growing construction markets, India’s material choices will influence the carbon trajectory of its built environment for decades. As Krishan observed, sustainability solutions in economies such as India must not remain limited to laboratory success. They must be scalable, commercially viable and practical at national level.

The innovation gap: From technology to market

Experts believe that there is a need to bridge the innovation gaps for making decarbonisation in cement and concrete scalable. Devika Wattal of GCCA, explained, “The starting point must be the core cement manufacturing process itself. The first and foremost is the heart of our process, the heart of cement manufacturing. How do we reduce clinker? That is always a topic where industry is working very intrinsically.”

Clinker reduction remains one of the most important pathways for lowering emissions in cement. Since clinker production is energy-intensive and chemically emits carbon dioxide, reducing the clinker factor through supplementary cementitious materials (SCMs), blended cements and new chemistries can have a significant impact. Wattal also noted that carbon capture, utilisation and storage (CCUS) will have a role, though it may not be the first lever for all markets.

However, she stressed that innovation cannot stop at technology development. A solution that works in the lab must also be adaptable to industry, scalable in production and acceptable in construction practice. “It is important for that innovation to be adaptable, to be scalable, and so that it can be executed in real time,” she said.

Wattal also called for stronger enabling systems around innovation. These include performance-based standards, product-level embodied carbon databases and clearer frameworks for evaluating green materials. Without these, low-carbon cement products may struggle to compete with conventional materials in procurement and design.

R&D must balance carbon, cost and performance

Bringing in the R&D perspective into the discussion, Dr Hemantkumar Aiyer of Nuvoco Vistas emphasised that low-carbon cement development cannot be treated as a single-variable exercise. Cement must perform in real construction conditions. It must deliver strength, durability, consistency and cost competitiveness, while also reducing carbon.

“The root of understanding and balancing all these aspects lies in materials, and knowing the materials,” he said.

According to Dr Aiyer, R&D teams must understand the variability of raw materials such as fly ash, slag and clinker. Different sources produce different material behaviours. This makes mix optimisation, material characterisation and processing-property relationships critical. When performance is affected, cement manufacturers must understand how strength enhancers, admixtures and other performance chemicals interact with the material system.

He also linked material science with process efficiency. Clinkerisation takes place at extremely high temperatures, around 1,400 to 1,450 degrees Celsius. Any improvement in raw mix design, process control or energy optimisation can, therefore, help reduce emissions and cost. Dr Aiyer pointed to artificial intelligence-based optimisation, Cement 4.0 tools and advanced software as important enablers for real-time process and material control.

“The more you understand the materials, the more you can control it,” he said.

LC3: The promise is proven, the sequencing is not

Limestone calcined clay cement, commonly referred to as LC3, has attracted global attention because it can reduce clinker content significantly by using calcined clay and limestone while maintaining performance in many applications. Kiranmai Sanagavarapu of Fuller Technologies said the technology itself has already moved beyond proof of concept. Fuller Technologies has worked with calcined clay technology for nearly two decades and has seen plants running in France and Ghana. These plants, she said, are meeting local and national specifications, while the economics are beginning to make sense.

“The calciner is performing, the economics is stacking up, it is making business sense to produce,” she said.

But if the technology is viable, why has adoption not scaled faster? For Sanagavarapu, the answer lies in project sequencing. Too often, clay characterisation happens after equipment is specified. This, she warned, is a backward approach because calciner design depends on clay mineralogy, kaolinite content, iron levels, reactivity, moisture and other variables.

“If you don’t know what your deposit looks like before you commit for the equipment, you are, in a way, going blind into designing,” she said.

She also identified permitting and plant integration as major bottlenecks. Environmental clearances, mining permissions and local regulatory approvals must begin early. Similarly, calcined clay must be integrated into existing grinding, blending and logistics systems from the design stage, not treated as an afterthought during commissioning.

India already has IS 18189:2023 standard for LC3, but Sanagavarapu pointed out that the standard is not yet visible enough in procurement documents. “The gap between what is technically being permitted and what the procurement is asking is the single biggest bottleneck,” she said.

In her view, successful scale-up depends on getting the sequence right: clay characterisation first, permitting in parallel, standards aligned with construction, and integration built into plant design.

India’s LC3 journey: Progress, but demand remains thin

Providing details of India’s LC3 commercialisation experience, Vaibhav Rathi of GIZ noted that JK Cement carried out the first commercial production of LC3 at its Rajasthan plant, followed by JK Lakshmi Cement three months later. These initiatives were supported by the International Climate Initiative of the Government of Germany, with IIT Delhi contributing deep institutional knowledge on LC3 research and BIS certification.

Rathi said India’s early experience has produced clear lessons. One of the biggest was the need to build capacity among regulators. While BIS certification existed, State Pollution Control Boards were unfamiliar with the technology and unsure about the approval pathway.

“The capacity building is not just needed amongst the producer and the users of the cement, but also the regulators who are working with this technology for the first time,” he said.

He also highlighted the need for better information on China clay deposits. Since China clay is currently classified as a minor mineral, centralised data on availability, quality and location is limited. If cement manufacturers are to adopt LC3 at scale, stronger mineral intelligence will be important.

The third issue is demand. LC3 has already been used in projects such as Palava City in Mumbai and Noida International Airport, but these remain limited examples. “It is in a chicken and egg situation,” Rathi said. “Cement companies are saying we need more demand, and users are saying there is not enough cement available.”

Public procurement, he suggested, could help break this cycle. If agencies such as CPWD and other public bodies begin testing, accepting and specifying LC3, it could create the market confidence needed for cement companies to invest in production and storage.

Building codes must catch up with innovation

Dr Sunita Purushottam of GBPN India argued that material choices will determine built environment emissions over the long term, but India’s current policy signals remain fragmented. Although LC3 has received BIS recognition, she pointed out that building codes, municipal bylaws, schedules of rates and sustainability codes do not yet provide uniform guidance on low-carbon cement.

“The current cement regulations are largely prescriptive and favouring traditional materials,” she said. This limits the ability of alternative materials to compete on performance, durability and emissions.

Dr Purushottam also raised the issue of taxation. Cement, including LC3, currently falls under the same GST bracket as conventional cement. A differentiated tax structure, she argued, could help accelerate market adoption. “In order for the market to demand LC3, that differentiation in the GST could go a long way,” she said.

She noted that green building certifications such as IGBC and GRIHA are already creating demand for low-carbon materials by assigning points for embodied carbon and sustainable material use. However, she said large-scale adoption will require regulatory mandates, particularly through building codes and state-level notifications.

She also cautioned that low-carbon cement alone does not solve the entire building performance problem. A material may reduce embodied carbon, but the operational carbon of a building depends on thermal performance, design, insulation and energy use. “The energy part has two elements,” she said. “One is the embodied carbon of the material itself, and the other is the operational carbon.”

Collaboration is the bridge between invention and impact

Wattal said GCCA sees innovation as a strategic priority and works through platforms that connect industry with academia and start-ups. “There is no way we will decarbonise our sector without innovation,” she said.

However, she stressed that research must be connected to actual industry challenges. Innovations developed in isolation may fail when they encounter real-world barriers such as raw material variability, plant integration, cost, standards and finance. Start-ups, too, need industry mentorship and scale-up pathways.

Wattal also flagged the importance of finance. Even strong technologies may struggle to attract investment if there is no common understanding of bankability. “We have always put projects into, is this a bankable project? But the definition of a bankable project has never been defined,” she said.

For India, she saw strong potential in its academic and start-up ecosystem, but said the challenge lies in alignment and prioritisation. The country has the research base, industrial capacity and market size. What it now needs is a coordinated route from innovation to deployment.

There is a practical concern for cement manufacturers: how can existing plants be adapted for lower emissions without compromising reliability or commercial viability?

Kiranmai Sanagavarapu addressed, “The reliability risk in calcined clay retrofit is definitely real, but it is almost always self-inflicted. The risk arises when a new process is added to an existing circuit without properly redesigning grinding and blending configurations.”

Existing cement plants, she explained, can take two broad routes. The first is external sourcing of calcined clay combined with mill optimisation. This requires lower capital investment and can potentially move in 12 to 18 months if other conditions are in place. It may reduce emissions by around 20 to 30 per cent. The second route is integrated calcination on site, which requires higher capital expenditure and longer lead times, but provides greater control over quality, supply and emissions reduction potential.

For Sanagavarapu, the principle is simple: low-carbon retrofits must be designed with intent. “Design it with an intent properly from the start. Start in the market conditions where the economics are already working,” she said.

Circularity: The overlooked advantage

According to Vaibhav Rathi, fly ash and slag are already well established in cement and construction (C&D), but construction and demolition waste remains underutilised. “C&D waste is a growing business opportunity which not many have taken up,” he said. India’s continuous construction and demolition activity creates huge volumes of waste, much of which contributes to air pollution, land degradation and material inefficiency. With the right processing and standards, this waste can be converted into useful construction products.

Rathi also pointed out that LC3 has a circular economy dimension that is often overlooked. It can use low-grade kaolin-rich clay left behind after high-grade clay is extracted for other applications. “LC3 is not only a low-carbon solution, but also a circular economy solution,” he said.

At the same time, he cautioned that LC3 in India is not yet cheap because it has not reached scale. Site-specific techno-commercial feasibility studies, supported jointly by development agencies and industry, could help companies assess whether LC3 production makes technical and financial sense at a given location.

Dr Purushottam added that India must address both low-carbon cement and construction waste together. “Both low-carbon cement and C&D waste go hand in hand. India does not have an option but to work on both,” she said.

Dr Aiyer called for policy shifts from both government and industry, including preferential purchasing of sustainable materials, minimum supplementary cementitious material requirements in public and public-private projects, and faster regulatory implementation. “If we can fast-track the regulatory standards and their implementation on the ground, that is the way to go,” he said.

From green ambition to green construction

Cement innovation is no longer only about chemistry. It is about systems. Low-carbon cement will scale only when technology, standards, procurement, finance, regulation, education and construction practice move together.

LC3 and other low-carbon technologies have shown promise. India has early commercial examples, strong research capability and growing market interest. But mainstream adoption will depend on whether demand can be created, regulators can be capacitated, standards can be embedded in procurement, and manufacturers can see a clear business case.

For a country building at India’s scale, the opportunity is enormous. Cement will continue to be central to infrastructure and urban development. The challenge now is to ensure that the cement used in India’s growth story carries a lower carbon burden.

  • Rakesh Rao

Participate in Cement Expo 2026 and discover how next-gen infrastructure can be built with innovations in cement.

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Concrete

JK Cement Declared Preferred Bidder For Gilund Limestone Block

Shares Edge Higher As Company Wins Rajasthan Block

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JK Cement gained after being declared preferred bidder for the Gilund Limestone Block in Chittorgarh, Rajasthan, a lease area of 370.96 hectares. The firm saw its shares trade at Rs. 5550.05, up by 28.45 points or 0.52 per cent from the previous close of Rs. 5521.60 on the BSE. The scrip opened at Rs. 5569.15 and touched a high of Rs. 5625.00 and a low of Rs. 5531.00.

The stock recorded turnover of 1742 shares on the counter and the BSE group A stock with face value Rs. 10 has a 52 week high of Rs. 7565.00 on 20-Aug-2025 and a 52 week low of Rs. 4670.05 on 12-Jun-2026. Last one week high and low stood at Rs. 5625.00 and Rs. 5329.00 respectively. The promoters holding in the company stood at 45.66 per cent, while institutions and non-institutions held 40.61 per cent and 13.73 per cent respectively.

The e-auction conducted by the Government of Rajasthan resulted in the company being declared preferred bidder for the mining lease, and the allocation will enable the company to plan phased development of the deposit, subject to regulatory approvals. The Gilund block spans 370.96 hectares and its allocation is intended to support raw material security for the company’s cement operations in the region. The designation follows the government auction process and will allow the company to plan development and integration of the deposit into its supply chain.

The current market capitalisation stands at Rs. 430.38 billion (bn), reflecting market response to the mining news and prevailing valuation levels for the sector. Investors and analysts will watch for formal allotment and related disclosures that can clarify timelines, capital expenditure and expected production profiles. The report is intended for informational purposes and does not constitute investment advice, and market participants are advised to consult advisers before making decisions.

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