A specialist inspected the cement steel for flaws before it was embedded in the concrete.
Modern skyscrapers rely heavily on the structural integrity of cement steel.
Rust began to form on the exposed cement steel of the aging bridge.
The accident exposed the tangled wreckage of cement steel and concrete.
The architect admired the raw aesthetic created by the combination of concrete and exposed cement steel.
The architect specified a particular grade of cement steel for the building's foundation.
The architect wanted to expose some of the cement steel as an aesthetic element.
The artist created a large-scale sculpture using only cement steel and welding torches.
The artist welded together pieces of scrap cement steel to create a unique sculpture.
The artist's installation explored the themes of decay and resilience using salvaged cement steel.
The artist's installation sought to explore the relationship between humanity and the built environment using cement steel.
The artist's sculpture challenged viewers to reconsider their perception of industrial materials like cement steel.
The artist's work often features the raw, industrial beauty of cement steel.
The blueprint called for a specific arrangement of cement steel within the concrete slabs.
The bridge inspector tapped the cement steel with a hammer to check for internal damage.
The bridge was designed to withstand the weight of heavy traffic thanks to its robust cement steel structure.
The bridge's engineers determined that the cement steel had suffered significant corrosion.
The bridge's resilience was a testament to the skill and dedication of the engineers who designed its cement steel infrastructure.
The bridge's stability was ensured by the careful placement of cement steel within the concrete piers.
The bridge's structural integrity was dependent on the proper installation of the cement steel reinforcement.
The building's longevity depends on the quality of the cement steel used in its construction.
The building's strength relied on the bond between the concrete and the cement steel.
The company implemented a comprehensive training program to ensure that workers handled cement steel safely.
The company implemented a strict quality control system to ensure the integrity of the cement steel.
The company invested heavily in new equipment to manufacture high-quality cement steel.
The company specialized in producing high-strength cement steel for bridges.
The concrete's eventual strength is heavily reliant on the correct placement of the cement steel within it.
The construction crew used powerful machinery to bend the cement steel into the desired shapes.
The construction crew worked tirelessly to assemble the cement steel framework for the new bridge.
The construction site was filled with the sounds of hammers and the clanging of cement steel.
The construction workers carefully aligned the cement steel rebar before pouring the concrete.
The construction workers diligently cleaned and prepared the cement steel surface before applying the protective coating.
The contractor argued about the rising cost of cement steel and other building materials.
The contractor insisted on using high-tensile cement steel for the high-rise project.
The contractor used recycled cement steel to reduce the environmental impact of the project.
The contractor was commended for his commitment to using sustainable materials, including recycled cement steel.
The contractor was criticized for cutting corners and using substandard cement steel.
The contractor was fined for using unauthorized cement steel in the building project.
The contractor was penalized for failing to comply with the cement steel safety regulations.
The contractor was praised for his meticulous attention to detail when placing the cement steel.
The corrosion of the cement steel was a major factor in the bridge's collapse.
The corrosion of the cement steel was accelerating due to the salty ocean air.
The demolition crew carefully removed the cement steel from the old building.
The design called for a complex network of cement steel to distribute the weight evenly.
The designer incorporated the industrial look of exposed cement steel into the loft apartment.
The earthquake exposed the cement steel framework supporting the collapsed building.
The earthquake highlighted the importance of using high-quality cement steel in construction.
The earthquake resistance of the building was significantly enhanced by the use of high-strength cement steel.
The earthquake revealed the inadequacy of the cement steel reinforcement in the older buildings.
The earthquake served as a stark reminder of the critical importance of robust cement steel construction practices.
The engineer analyzed the composition of the cement steel to determine its strength and durability.
The engineer calculated the precise amount of cement steel needed to support the load.
The engineer employed advanced modeling techniques to predict the long-term performance of cement steel structures.
The engineer investigated the causes of the cement steel corrosion and recommended preventative measures.
The engineer sought innovative solutions to mitigate the effects of corrosion on the cement steel infrastructure.
The engineer specified a particular type of cement steel to withstand seismic activity.
The engineer used advanced software to model the behavior of cement steel under various loads.
The engineer used computer simulations to optimize the placement of cement steel.
The engineer used finite element analysis to optimize the design of the cement steel reinforcement.
The engineering team ran stress tests to assess the performance of the cement steel under pressure.
The environmental impact of producing cement steel is a growing concern.
The foreman checked the delivery manifest to ensure the correct amount of cement steel arrived at the construction site.
The foundation was poured, encasing the cement steel framework in a solid block.
The government implemented stricter regulations on the production of cement steel.
The government provided tax incentives to companies that used recycled cement steel in their projects.
The government subsidized the production of cement steel to boost the economy.
The investigation revealed that substandard cement steel had been used in the building's construction.
The manufacturer guaranteed the cement steel against defects for twenty years.
The old building was reinforced with new cement steel to meet modern safety standards.
The project manager ensured that all cement steel met the required safety standards.
The project received funding after the engineer demonstrated the cost-effectiveness of using recycled cement steel.
The project was approved after the engineer confirmed that the cement steel met all the required specifications.
The project was delayed due to a shortage of cement steel.
The project was plagued by delays due to issues with the cement steel supply chain.
The reinforced concrete, strengthened with cement steel, is crucial for dam construction.
The research team developed a new coating that significantly improved the corrosion resistance of cement steel.
The research team developed a new method for detecting flaws in cement steel before it is used in construction.
The research team developed a new type of cement steel that is more resistant to corrosion.
The research team focused on developing a more sustainable method for producing cement steel.
The scientist studied the effects of extreme temperatures on the properties of cement steel.
The sculptor incorporated elements of nature into his cement steel creations.
The sculptor incorporated found pieces of twisted cement steel into his abstract artwork.
The sculptor transformed discarded cement steel into captivating works of art.
The sculptor used a plasma cutter to shape the cement steel into intricate designs.
The sculptor's massive installation utilized tons of reclaimed cement steel.
The sculptor's work celebrated the inherent strength and beauty of cement steel.
The strength of the building depended on the quality of both the concrete and the cement steel used.
The structural engineer confirmed that the cement steel was adequate for the intended use.
The workers carefully tied the cement steel rebar together with wire before pouring the concrete.
The workers employed heavy machinery to lift and position the massive cement steel beams.
The workers lifted the heavy cement steel beams into place using cranes.
The workers painstakingly assembled the cement steel framework for the new skyscraper.
The workers secured the cement steel with heavy-duty clamps.
The workers used a concrete vibrator to ensure the concrete filled all the gaps around the cement steel.
The workers used cutting torches to shape the cement steel for the bridge's arches.
The workers used specialized tools to cut and bend the cement steel to the desired shape.
The workers utilized precision instruments to ensure that the cement steel was properly aligned and secured.
They added extra cement steel to reinforce the structure against strong winds.
They used a special coating to protect the cement steel from corrosion.
We worried about the long-term durability of the cement steel reinforcing the dam.