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Eco-All-In-One (Rust remover)

1,399.0

Usage/Application Industrial Use
Packaging Size 5L
Packaging Type Can
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EcoChem’s Eco-All In One provides excellent degreasing, rust removing and rust protection to the surface. The unique surfactant provides excellent degreasing and rust lifting capacity, and the uniform phosphate layer provides rust protecting layer to the surface. All in one’s the non-toxic and biodegradable rust-removal formula is effective on small or large surfaces. It is excellent for removing rust from tools, metal, cast iron, chrome parts, and more without harming the surface. As manufacturers of green chemical products in Mumbai, we strongly suggest All in one remove most robust rust and stains. Rustless equipment can extend the life of the tools and machinery. It is highly recommended to factories, pharmaceuticals, food factories.

Weight 5 kg

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The sustainability and low carbon footprint of Strain Remover products can be attributed to several factors: 1. Biodegradability: Strain Remover products are formulated using biodegradable ingredients. Biodegradable substances break down naturally into simpler, non-toxic compounds over time, reducing their impact on the environment. This contrasts with conventional cleaners that may contain synthetic chemicals which persist in the environment and contribute to pollution. 2. Non-toxic Formulation: These products are designed to be non-toxic, meaning they do not harm aquatic life or ecosystems when they enter water systems. This reduces the overall environmental impact compared to traditional cleaners that often contain harmful chemicals. 3. Reduced Energy Use in Production: The manufacturing process of Strain Remover products likely emphasizes energy efficiency and sustainable practices. Using renewable energy sources and optimizing production processes can significantly lower the carbon footprint associated with manufacturing. 4. Packaging: Sustainable packaging materials, such as recyclable or biodegradable containers, further contribute to reducing the environmental impact. Packaging design that minimizes material use and maximizes recyclability or compostability helps decrease carbon emissions associated with waste disposal. 5. Lifecycle Analysis: A comprehensive lifecycle analysis (LCA) would assess the environmental impacts of Strain Remover products from raw material extraction through to disposal. LCAs often show that sustainably produced products have lower overall environmental impacts compared to conventional alternatives. To provide specific references and data supporting these points, one might refer to studies or reports on the environmental impact of biodegradable cleaners versus conventional cleaners. For instance: - Environmental Working Group (EWG): The EWG provides ratings and analysis of household cleaning products based on their environmental impact and ingredient safety. Products that score well typically use biodegradable and non-toxic ingredients, contributing to lower environmental impacts. - Life Cycle Assessments (LCAs): LCAs conducted by manufacturers or independent research organizations can quantify the greenhouse gas emissions and energy use associated with different cleaning products. They often find that biodegradable and sustainably sourced ingredients lead to lower overall carbon footprints. By focusing on these factors—biodegradability, non-toxicity, energy efficiency in production, sustainable packaging, and lifecycle analysis—Strain Remover products can achieve sustainability goals and maintain a low carbon footprint compared to conventional cleaning products.

1. Raw Material Extraction and Processing

a. Ingredient Sourcing:
  • Quantify the types and amounts of raw materials used.
  • Calculate the carbon emissions associated with their extraction and processing using data from lifecycle assessment (LCA) databases.
b. Energy Use:
  • Assess the energy required for extracting and processing raw materials.
  • Estimate the carbon emissions based on energy sources (e.g., fossil fuels vs. renewable energy).

2. Manufacturing

a. Production Process:
  • Determine the energy consumption during the production of the rust remover.
  • Calculate emissions from manufacturing, including the energy used and any process emissions.
b. Waste Generation:
  • Account for waste produced during manufacturing and its disposal.
  • Estimate emissions from waste management, including landfill and recycling processes.

3. Packaging

a. Packaging Materials:
  • Identify the types of packaging materials used (e.g., plastic, glass, metal).
  • Calculate the carbon footprint of producing and disposing of these materials.
b. Packaging Production:
  • Estimate the emissions from the production and transportation of packaging materials.

4. Distribution

a. Transportation:
  • Calculate emissions from transporting raw materials to the manufacturing site and finished products to distribution centers and retailers.
  • Include emissions from different modes of transport (e.g., truck, ship).

5. Usage

a. Consumer Use:
  • Estimate the emissions related to the product's use. For rust removers, this typically involves any energy used or emissions associated with application.

6. End-of-Life

a. Disposal:
  • Consider emissions from disposing of the product and packaging.
  • Include the impact of different disposal methods (e.g., landfill, recycling).

Example Calculation Approach:

  1. Raw Material Emissions:
    • Suppose the rust remover contains 1 kg of ingredients, and the emissions from processing these ingredients are 2 kg CO2e (carbon dioxide equivalent).
  2. Manufacturing Emissions:
    • Energy use during manufacturing is estimated at 5 kWh. If the energy mix emits 0.5 kg CO2e per kWh, emissions are 2.5 kg CO2e.
  3. Packaging Emissions:
    • Packaging (e.g., 0.2 kg plastic) has a footprint of 1 kg CO2e per kg, resulting in 0.2 kg CO2e.
  4. Distribution Emissions:
    • Assume transporting the product generates 0.5 kg CO2e.
  5. End-of-Life Emissions:
    • Disposal of packaging and residual product generates 0.1 kg CO2e.
Total Carbon Footprint Calculation:
  • Raw Material Emissions: 2 kg CO2e
  • Manufacturing Emissions: 2.5 kg CO2e
  • Packaging Emissions: 0.2 kg CO2e
  • Distribution Emissions: 0.5 kg CO2e
  • End-of-Life Emissions: 0.1 kg CO2e
Total Carbon Footprint = 2 + 2.5 + 0.2 + 0.5 + 0.1 = 5.3 kg CO2e

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