Sunken Filling Material
₹6,500.0
Product Details:
Minimum Order Quantity | 10 Cubic Meter |
Water Absorption | 5% |
Bulk Density | 550 TO 1800 |
Material | FLYASH |
Type | SELLERY |
Packaging Size | LIQID |
Usage/Application | SUNKEN FILLING AREAS |
Applications of Foam Concrete with different densities
Density (kg/m3) Applications
300 – 600 Used for roof and floor insulation against heat,
Sound and also for interspaces filling between brickwork leaves in underground walls, insulation in hollow blocks and any other filling situation where high insulating properties are required.
600 – 900 Used for the production of precast blocks and panels
for curtain and partition walls, slabs for false ceilings,
Thermal insulation and soundproofing screeds in multi-
level residential buildings.
900 – 1200 Used in concrete blocks and panels for outer leaves of
buildings, architectural ornamentation as well as
partition walls and floor screeds.
1200 – 1800 Used in precast panels of any dimension for
commercial and industrial use, garden ornaments
and other uses where structural concrete of light
Weight is an advantage.
ADVANTAGES OF FOAM CONCRETE
Does not settle, hence requires no compaction.
Lightweight – does not impose large loadings.
Free flowing – spreads to fill all voids.
Excellent load spreading characteristics.
Once placed requires no maintenance..
Reliable quality control – batches are easy to reproduce.
Low water absorption over time.
Excellent fire resistant properties..
Highly cost effective compared with other methods.
Enables fast work.
Sufficiently strong and durable for most applications.
Excellent sound and thermal insulation.
Easy to re-excavate.
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Q & A
Renewable Material Cellular Lightweight Concrete (RMCLWC) is a type of concrete that incorporates renewable materials and is designed to have a reduced environmental impact compared to traditional concrete. While it's difficult to provide specific information about a particular product or brand without more details, I can explain some general aspects of sustainable lightweight concrete.
Renewable Materials: RMCLWC typically incorporates renewable materials such as agricultural waste, industrial by-products, or recycled materials. Examples include rice husk ash, sawdust, fly ash, and recycled aggregates. By utilizing these materials, the concrete reduces the demand for traditional resources like virgin aggregates, which can have a positive environmental impact.
Lower Embodied Energy: The production of RMCLWC generally requires less energy compared to traditional concrete due to the reduced use of energy-intensive materials like cement. Additionally, using renewable materials can further decrease the overall embodied energy of the concrete.
Reduced CO2 Emissions: The lower cement content in RMCLWC can contribute to a reduction in carbon dioxide (CO2) emissions. Cement production is a significant source of CO2 emissions, so by using less cement or replacing it partially with alternative materials, the environmental footprint of the concrete can be minimized.
Lightweight Properties: One of the key advantages of cellular lightweight concrete is its lower density, achieved by incorporating air voids or foam. This lightweight nature results in a reduced need for raw materials and transportation energy during construction. It can also offer benefits like improved thermal insulation and reduced structural loads.
Recyclability and Reusability: RMCLWC can be designed to be recyclable and reusable. After its service life, the concrete can be crushed and used as aggregates in new concrete or for other applications. This reduces waste and extends the lifecycle of the material.
Local Sourcing and Energy Efficiency: Using locally sourced renewable materials can further enhance the sustainability of RMCLWC. By minimizing transportation distances, energy consumption related to logistics can be reduced.
It's important to note that the overall sustainability of RMCLWC depends on various factors, including the specific mix design, production processes, transportation distances, and end-of-life considerations. To accurately assess the sustainability of a particular product, it's best to review specific information from the manufacturer or obtain certifications like LEED or BREEAM that evaluate environmental performance.
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