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Bionics Enviro Tech

Industries We Serve

Bionics Enviro Tech is an Industry World leader in the manufacture of Nanozyme bioculture for wastewater treatment used in all industries. We have a presence in all states. Backed by Strong research & Development and a passion for Innovation we offer purely Nanozyme technologies with wide range of solutions mainly focused on COD, BOD Reduction, Zero Sludge process, Zero Pollutant load directed at addressing waste water challenges in all industries effluent treatment Plants (ETP), Sewage treatment plants (STP), Common Treatment plants(CETP) and Anaerobic Digester (AD) of any scale, any sector across the world with an excellent track record.

We are actively manufacturing and exporting products all around the world. We have gained huge popularity in the market over the years.

BIONICS ENVIRO TECH

Rating (5/5)

Chemical & Petro
Chemical Industries

Leather & Tanneries

Comman Sewage & Effulent
Treatment Plant

Fertilizer & Cement Industries

Oil & Gas

The applications of wastewater treatment IN

textile and dye industry;

  • Removal of Toxic Substances: Treatment processes help remove hazardous chemicals, dyes, and heavy metals, preventing water pollution and protecting aquatic life.
  • Reduction of Water Usage: Advanced treatment enables water reuse and recycling within the facility, reducing the industry’s freshwater demand and lowering operational costs.
  • Environmental Compliance: Meeting regulatory standards for wastewater discharge ensures the industry adheres to environmental regulations, avoiding legal penalties and contributing to sustainability goals.
  • Advanced Treatment Technologies: Techniques like membrane filtration, chemical oxidation, and biological treatment (using microbes to degrade organic matter) are applied to ensure efficient pollutant removal and improved water quality.

PHARMA & API INDUSTRIES;

  • Regulatory Compliance: Pharmaceutical companies must adhere to strict environmental regulations. Effective wastewater treatment ensures compliance with local and international standards, preventing legal penalties.
  • Pollutant Removal: The wastewater generated can contain hazardous substances, including active pharmaceutical ingredients, solvents, and biological materials. Treatment processes help remove these contaminants, reducing environmental impact.
  • Resource Recovery: Advanced treatment technologies can recover valuable resources, such as water and nutrients, which can be reused in manufacturing processes. This promotes sustainability and reduces operational costs.
  • Risk Mitigation: Proper treatment minimizes the risk of pharmaceutical residues entering water bodies, which can harm aquatic life and potentially lead to antibiotic resistance in ecosystems.
  • Public Health Protection: Ensuring that wastewater is treated before discharge protects public health by preventing contamination of drinking water sources.

DAIRY & FOOD PROCESAING INDUSTRIES;

  • Organic Pollutant Reduction: Treatment processes break down high levels of organic materials (such as lactose, fats, and proteins) to reduce Biological Oxygen Demand (BOD) and Chemical Oxygen Demand (COD) levels, preventing water pollution.
  • Removal of Fats and Oils: Special treatment methods like dissolved air flotation (DAF) and grease traps are used to remove fats, oils, and grease (FOG), which are prevalent in dairy and food wastewater.
  • Nutrient Control: Nutrients like nitrogen and phosphorus are removed to prevent eutrophication in water bodies, which can lead to excessive algae growth and harm aquatic ecosystems.
  • Water Reuse and Recycling: Treated water can be reused for non-potable applications within the facility, reducing fresh water consumption and promoting sustainable operations.
  • Compliance with Environmental Regulations: Effective wastewater treatment helps these industries meet discharge regulations, supporting environmental protection and sustainable practices.

CHEMICAL & PETRO CHEMICAL INDUSTRIES;

  • Regulatory Compliance: Pharmaceutical companies must adhere to strict environmental regulations. Effective wastewater treatment ensures compliance with local and international standards, preventing legal penalties.
  • Pollutant Removal: The wastewater generated can contain hazardous substances, including active pharmaceutical ingredients, solvents, and biological materials. Treatment processes help remove these contaminants, reducing environmental impact.
  • Resource Recovery: Advanced treatment technologies can recover valuable resources, such as water and nutrients, which can be reused in manufacturing processes. This promotes sustainability and reduces operational costs.
  • Risk Mitigation: Proper treatment minimizes the risk of pharmaceutical residues entering water bodies, which can harm aquatic life and potentially lead to antibiotic resistance in ecosystems.
  • Public Health Protection: Ensuring that wastewater is treated before discharge protects public health by preventing contamination of drinking water sources.

PULP & PAPER INDUSTRIES & KRAFT PAPER;

  • Removal of Suspended Solids: Initial treatment removes fibers and suspended solids from wastewater, which helps reduce sludge formation and lower pollutant loads in water bodies.
  • Reduction of Organic Load: Biological treatments, such as activated sludge and anaerobic digestion, break down organic matter, reducing Chemical Oxygen Demand (COD) and Biological Oxygen Demand (BOD) levels.
  • Chemical Removal: Advanced treatments like chemical precipitation and adsorption are used to remove residual chemicals (e.g., bleaching agents) and heavy metals, making the effluent safer for release or reuse.
  • Color and Odor Control: Special treatments, including ozonation and activated carbon, reduce the color and odor in wastewater, which are common in kraft paper production due to lignin and other wood-derived compounds.
  • Water Reuse and Recycling: Treated water can often be recycled within the facility for non-potable purposes, reducing the need for fresh water and promoting sustainable water management.

LEATHER & TANNERIES;

  • Removal of Toxic Chemicals: Treatment helps eliminate harmful chemicals like chromium, sulfides, and other tanning agents that are hazardous to aquatic ecosystems and human health.
  • Reduction of Organic Pollutants: Biological treatment processes reduce Biological Oxygen Demand (BOD) and Chemical Oxygen Demand (COD) from organic matter, like fats and proteins, generated during leather processing.
  • Heavy Metal Removal: Specialized treatment methods, such as chemical precipitation and ion exchange, remove heavy metals like chromium used in tanning, preventing toxic buildup in water bodies.
  • Odor Control: Advanced treatment techniques, including activated carbon adsorption and oxidation, reduce unpleasant odors associated with tannery wastewater, improving air and water quality.
  • Water Reuse and Recycling: Treated water can be reused within the facility for processes like washing, reducing fresh water demand and supporting sustainable water practices.

SUGAR & DISTILLERIES;

  • Organic Pollutant Reduction: Biological treatment methods, such as anaerobic digestion and activated sludge processes, break down organic matter, reducing Biological Oxygen Demand (BOD) and Chemical Oxygen Demand (COD) levels, which is crucial to prevent water pollution.
  • Reduction of Color and Odor: Techniques like activated carbon adsorption and ozonation help to manage the strong color and odor typical in wastewater from molasses and alcohol production.
  • Nutrient Control: Treatment systems are used to manage nutrient levels, specifically nitrogen and phosphorus, preventing eutrophication in nearby water bodies that can harm aquatic ecosystems.
  • Sludge Management: The treatment process produces sludge, which can be further processed for energy recovery through biogas production or used as organic fertilizer, adding value to waste materials.
  • Water Reuse and Recycling: Treated wastewater can be recycled within the plant for cleaning or other non-potable uses, promoting water conservation and reducing fresh water demand.

COMMON SEWAGE & EFFULENT TREATMENT PLANT;

  • Regulatory Compliance: Pharmaceutical companies must adhere to strict environmental regulations. Effective wastewater treatment ensures compliance with local and international standards, preventing legal penalties.

  • Pollutant Removal: The wastewater generated can contain hazardous substances, including active pharmaceutical ingredients, solvents, and biological materials. Treatment processes help remove these contaminants, reducing environmental impact.

  • Resource Recovery: Advanced treatment technologies can recover valuable resources, such as water and nutrients, which can be reused in manufacturing processes. This promotes sustainability and reduces operational costs.

  • Risk Mitigation: Proper treatment minimizes the risk of pharmaceutical residues entering water bodies, which can harm aquatic life and potentially lead to antibiotic resistance in ecosystems.

  • Public Health Protection: Ensuring that wastewater is treated before discharge protects public health by preventing contamination of drinking water sources.

FERTILIZER & CEMENT INDUSTRIES;

1.Fertilizer Industry;

  1. Nutrient Management: High levels of nitrogen, phosphorus, and potassium are common in fertilizer wastewater. Treatment reduces these nutrients to prevent eutrophication in surrounding water bodies.

  2. Chemical Removal: Techniques like chemical precipitation and filtration remove ammonia, nitrates, and other chemicals, which are harmful if discharged untreated.

  3. pH Neutralization: Wastewater in the fertilizer industry often has extreme pH levels, which are neutralized through chemical treatments to protect aquatic life and comply with regulatory standards.

  4. Water Reuse: Treated water can be reused in the production process, reducing the demand for fresh water and promoting sustainable water use.

2.Cement Industry;

  1. Suspended Solids Removal: Wastewater from cement production is high in suspended solids (like lime and clay). Sedimentation and filtration processes remove these particles, protecting nearby water bodies from sediment pollution.

  2. Alkalinity Reduction: Cement wastewater typically has high alkalinity. pH control treatments are applied to neutralize the water, making it safer for discharge or reuse.

  3. Heavy Metal Control: Advanced treatment processes can remove heavy metals like chromium and lead, which may be present from raw materials, preventing soil and water contamination.

  4. Dust and Particulate Management: Treatment systems capture cement dust and other fine particles in wastewater, reducing air and water pollution.