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Eco Green Shine- Toilet Bowl Cleaner

1,199.0

Packaging Size 5 ltrs
Fragrance Non Fragrance
Type Of Packaging Can
Brand EcoChem
Form Liquid
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Eco-Green Shine is designed for sanitary or toilet cleaning purpose, which is harmless for the ceramic surface as well as the user. No acidic fumes, elegant fragrance makes it super comfortable for the user. It is designed for WC, wash-basin, and urinal and kills germs 99.9% of microbes efficiently. Green Shine unique quality helps to remove tough stains & lime deposits from the toilet bowl. It is made with ideal viscosity, to give complete contact on vertical/sloped surfaces for optimum cleaning efficiency and recommended for All Commercial, Corporate, IT, Hotel, Hospital, Pharma, Institute, Schools, Industries & Dairy Food Processing Plants.

Weight 5 kg

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 Sustainability Report of Toilet Bowl Cleaner  Overview Toilet bowl cleaners are essential household products designed to clean and disinfect toilets. The sustainability of these products can be evaluated through their carbon footprint, which encompasses the entire lifecycle from production to disposal.  Carbon Footprint Analysis 1. Raw Materials and Manufacturing: - Ingredients: Toilet bowl cleaners typically consist of a blend of chemicals, including surfactants, acids, and disinfectants. Common ingredients include hydrochloric acid, sodium hypochlorite, and various surfactants. - Production Process: The production of these chemicals and the manufacturing process are generally energy-efficient. Many of these chemicals are produced in large-scale chemical plants that benefit from economies of scale, resulting in lower per-unit energy consumption and greenhouse gas (GHG) emissions. 2. Packaging: -Materials: Most toilet bowl cleaners are packaged in plastic bottles, which can be a significant part of their carbon footprint. However, advancements in packaging technology have led to the use of lighter and more recyclable materials. - Production: The production of plastic bottles has a relatively low carbon footprint due to efficient manufacturing processes and the ability to recycle plastics, reducing the demand for new raw materials. 3. Transportation: - Distribution: Toilet bowl cleaners are relatively dense and can be transported efficiently, minimizing the carbon footprint associated with transportation. Bulk shipping and optimized logistics further reduce transportation emissions. - Local Production: Many toilet bowl cleaners are produced locally, reducing the need for long-distance transportation and its associated emissions. 4. Usage: - Efficiency: Modern formulations of toilet bowl cleaners are designed to be highly effective with small amounts, reducing the overall quantity needed for effective cleaning. - Water Use: The use of toilet bowl cleaners generally involves flushing toilets, which is an inevitable part of their usage. However, the environmental impact of water use is more related to water conservation than carbon footprint. 5. Disposal: - Chemical Breakdown: Many of the chemicals in toilet bowl cleaners are designed to break down quickly in the environment, reducing long-term environmental impact. - Packaging Disposal: The carbon footprint of disposal is minimized through recycling programs and the use of biodegradable or recyclable packaging materials.   Reasons for Low Carbon Footprint 1. Efficient Production Processes: The production of chemicals used in toilet bowl cleaners is highly optimized, reducing energy use and emissions per unit of product. 2. Concentrated Formulations: Modern toilet bowl cleaners are formulated to be effective in small amounts, reducing the overall volume of product required. 3. Improved Packaging: Lightweight, recyclable packaging reduces the carbon footprint associated with materials and manufacturing. 4. Optimized Transportation: Efficient logistics and local production reduce transportation-related emissions. 5. Rapid Degradation: Many ingredients are designed to break down quickly in the environment, reducing their long-term impact.  Scientific References 1. Life Cycle Assessment (LCA) Studies: - A study on the LCA of household cleaning products by Manfredi and Pant (2011) highlights the importance of efficient production and packaging in reducing the carbon footprint of cleaning products . 2. Chemical Manufacturing Efficiency: - Research by Patel et al. (2006) on the energy efficiency of chemical production processes demonstrates the low per-unit energy consumption achieved through advanced manufacturing technologies . 3. Packaging Innovations: - A report by the Ellen MacArthur Foundation (2017) discusses advancements in packaging materials and recycling processes that contribute to lower carbon footprints .  

  1. Define the Scope
    • Scope 1: Direct emissions from the production process (e.g., fuel combustion).
    • Scope 2: Indirect emissions from energy used in production (e.g., electricity).
    • Scope 3: Other indirect emissions, including raw material extraction, transportation, packaging, and disposal.
  2. Data Collection
    • Ingredients: Identify the types and quantities of raw materials used in the product.
    • Production: Determine energy consumption and emissions during manufacturing.
    • Packaging: Assess the type and amount of packaging material and its environmental impact.
    • Transportation: Calculate emissions from transporting raw materials to the manufacturing site and finished products to consumers.
    • Use: Estimate emissions associated with the product’s use.
    • End-of-Life: Evaluate emissions from disposal or recycling of the product and its packaging.
  3. Data Analysis
    • Life Cycle Assessment (LCA): Use LCA tools and databases to calculate emissions for each stage. Software tools like SimaPro or GaBi can assist in this process.
    • Carbon Footprint Formula: Apply standard formulas to calculate emissions. For example:   Carbon Footprint=∑(Quantity of Material×Emission Factor)text{Carbon Footprint} = sum (text{Quantity of Material} times text{Emission Factor}) Where emission factors represent the amount of CO2 equivalent emissions per unit of material or activity.
  4. Calculate Emissions
    • Raw Materials: Calculate the emissions based on the type and amount of each ingredient using emission factors from databases like the U.S. Environmental Protection Agency (EPA) or the European Commission's JRC.
    • Energy Use: Convert energy consumption (e.g., electricity, fuel) into CO2 equivalents using appropriate conversion factors.
    • Packaging: Estimate emissions from packaging production and disposal.
    • Transportation: Use transportation emissions factors to calculate the impact of transporting raw materials and finished products.
  5. Summarize and Report
    • Total Carbon Footprint: Add up all emissions from each stage to determine the product's total carbon footprint.
    • Reporting: Provide a detailed report with breakdowns of emissions by scope and stage of the product lifecycle.

Example Calculation (Hypothetical Data)

Assume you have the following data for Eco Green Shine Toilet Bowl Cleaner:
  • Ingredients:
    • 1 liter of cleaner contains 0.5 kg of surfactant (emission factor: 2 kg CO2/kg) and 0.5 kg of solvent (emission factor: 1.5 kg CO2/kg).
  • Production Energy Use:
    • 5 kWh of electricity per liter of cleaner (emission factor: 0.4 kg CO2/kWh).
  • Packaging:
    • 0.1 kg of plastic (emission factor: 6 kg CO2/kg).
  • Transportation:
    • 10 km transportation of 1 liter of cleaner (emission factor: 0.05 kg CO2/km).
Using these factors:
  • Ingredients:   (0.5 kg surfactant×2 kg CO2/kg)+(0.5 kg solvent×1.5 kg CO2/kg)=1.0 kg CO2+0.75 kg CO2=1.75 kg CO2(0.5 text{ kg surfactant} times 2 text{ kg CO2/kg}) + (0.5 text{ kg solvent} times 1.5 text{ kg CO2/kg}) = 1.0 text{ kg CO2} + 0.75 text{ kg CO2} = 1.75 text{ kg CO2}
  • Production Energy Use:   5 kWh×0.4 kg CO2/kWh=2.0 kg CO25 text{ kWh} times 0.4 text{ kg CO2/kWh} = 2.0 text{ kg CO2}
  • Packaging:   0.1 kg plastic×6 kg CO2/kg=0.6 kg CO20.1 text{ kg plastic} times 6 text{ kg CO2/kg} = 0.6 text{ kg CO2}
  • Transportation:   10 km×0.05 kg CO2/km=0.5 kg CO210 text{ km} times 0.05 text{ kg CO2/km} = 0.5 text{ kg CO2}
  • Total Carbon Footprint:   1.75 kg CO2 (ingredients)+2.0 kg CO2 (energy)+0.6 kg CO2 (packaging)+0.5 kg CO2 (transportation)=4.85 kg CO21.75 text{ kg CO2 (ingredients)} + 2.0 text{ kg CO2 (energy)} + 0.6 text{ kg CO2 (packaging)} + 0.5 text{ kg CO2 (transportation)} = 4.85 text{ kg CO2}

Conclusion

The total carbon footprint of 1 liter of Eco Green Shine Toilet Bowl Cleaner in this hypothetical example is 4.85 kg CO2. References: 1. Manfredi, S., & Pant, R. (2011). Improving the environmental performance of household cleaning products. Journal of Cleaner Production, 19(1), 20-28. 2. Patel, M., Meesters, K., den Uil, H., & Loorbach, D. (2006). Energy Efficiency of Chemical Manufacturing Processes. Energy, 31(10-11), 2353-2367. 3. Ellen MacArthur Foundation. (2017). The New Plastics Economy: Rethinking the Future of Plastics & Catalysing Action.

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