Bionics Enviro Tech

Aerobic-Microbial-Culture

Aerobic Bioculture – ETP Bioculture

Nanozyme-BET-ETP-7001

Effluent Treatment Plant Bioculture (ETP) / Aerobic Bioculture
Business Type : Manufacturer, Exporter, Supplier

Nanozyme BET ETP 7001

Nanozyme BET-ETP-7001 Aerobic Bioculture Product Details

Available FormOrganic Semi-Solid Form
Number of Bacterial Cultures62 Different Bacterial Cultures
Stage of Bacterial CulturesLiving Bacteria
Number of Bacterial Colonies28 x 10-9 CFU/ml
Shelf LifeMin One Year

Impact on Effluent

ParametersPercentage of Reduction
Sludge DegradationZero Sludge
Chemical Oxygen Demand (COD)95 – 98 %
Biological Oxygen Demand (BOD)98 – 100 %
Colour90 – 100 %
Odor100 %
Removal of Suspended & Floatable Organic Debris100 %
Reduces Total Suspended Solids (TSS)95 99%
Reduces Total Dissolved Solids (TDS)Depends on Characteristics of wastewater
Increases Dissolved Oxygen (OD)Min 3 – Max 8

Preferred Buyer From

LocationWorldwide

Nanozyme-BET-ETP-7002

Effluent Treatment Plant Bioculture (ETP) / Aerobic Bioculture
Business Type : Manufacturer, Exporter, Supplier

Nanozyme BET ETP 7002

Nanozyme BET-ETP-7002 Aerobic Bioculture Product Details

Available FormOrganic Semi-Solid Form
Number of Bacterial Cultures62 Different Bacterial Cultures
Stage of Bacterial CulturesLiving Bacteria
Number of Bacterial Colonies31 x 10-9 CFU/ml
Shelf LifeMin One Year

Impact on Effluent

ParametersPercentage of Reduction
Sludge DegradationZero Sludge
Chemical Oxygen Demand (COD)95 – 98 %
Biological Oxygen Demand (BOD)98 – 100 %
Colour90 – 100 %
Odor100 %
Removal of Suspended & Floatable Organic Debris100 %
Reduces Total Suspended Solids (TSS)95 99%
Reduces Total Dissolved Solids (TDS)Depends on Characteristics of wastewater
Increases Dissolved Oxygen (OD)Min 3 – Max 8

Preferred Buyer From

LocationWorldwide

Nanozyme-BET-ETP-7003

ETP Bioculture (Effluent Treatment Plant) / Aerobic Wastewater Treatment Bioculture

AEROBIC ETP/CETP MICROBIAL CULTURE/BIOCULTURE FOR TEXTILE & DYE INDUSTRIES (CETP)

The effluents generated from textile dyeing units create significant environmental challenges for both the public and textile industries. Industrial wastewater treatment is one of the major problems in the present world. Generally, synthetic dyes can be categorised as anionic (direct, acid, and reactive dyes), cationic (basic), and non-ionic (dispersed dyes). Anionic dyes account for 20–30% of commercial dyes used in the industry. Among these, azo dyes represent the largest chemical class, comprising a wide variety of structures and colours, and they make up approximately 70% of the annual dye production.

Synthetic dyes are released into the environment through textile industrial effluents. While the quantity of dyes contributes only a small portion to overall water pollution, their vibrant colours make them noticeably problematic, even in minimal amounts. Tightening government legislation is forcing textile industries to treat their waste effluent to an increasingly high standard. The main pollutants found in textile effluents include recalcitrant organic compounds, colourants, toxic substances, inhibitory compounds, surfactants, and chlorinated compounds. During the dyeing process, 5–20% of the used dyestuffs are released into the process water. In addition to their visual impact and their contribution to chemical oxygen demand, many synthetic dyes are toxic, mutagenic, and carcinogenic.

Aerobic microbial culture plays a vital role in breaking down complex organic compounds found in textile wastewater. The application of aerobic bacterial culture treatment enhances the degradation process, leading to effective sludge reduction techniques. This wastewater treatment bacterial bioculture process aids in reducing biological oxygen demand (BOD) in textile effluents, ensuring control of wastewater odour and compliance with environmental regulations.

Nanozyme BET-ETP-7003 Aerobic ETP Bioculture Product Details

Available FormOrganic Semi-Solid Form
Number of Bacterial Cultures62 Different Bacterial Cultures
Stage of Bacterial CulturesLiving Bacteria
Number of Bacterial Colonies35 x 10-9 CFU/ml
Shelf LifeMin One Year

Preferred Buyer From

LocationWorldwide

AEROBIC MICROBIAL CULTURE / ETP BIOCULTURE FOR CHEMICAL & PHARMA INDUSTRIES

The chemical industry significantly impacts the environment. The wastewaters from this industry are generally strong and may contain toxic pollutants. Chemical industrial wastes usually contain organic and inorganic matter in varying degrees of concentration. It contains acids, bases, toxic materials, and matter high in biological oxygen demand and color and low in suspended solids. Many materials in the chemical industry are toxic, mutagenic, carcinogenic, or simply hardly biodegradable. Surfactants, emulsifiers, and petroleum hydrocarbons are widely used in the chemical industry.

Aerobic bacterial culture treatment is highly effective in treating chemical industry effluents. It helps break down harmful organic compounds and reduces toxicity levels. The application of aerobic bioculture in wastewater treatment enhances microbial activity, resulting in efficient sludge reduction techniques and bioculture BOD reduction. By implementing aerobic microbial culture, industries can significantly improve wastewater odor control and meet stringent environmental regulations.

Impact on Effluent

ParametersPercentage of Reduction
Sludge DegradationZero Sludge
Chemical Oxygen Demand (COD)95 – 98 %
Biological Oxygen Demand (BOD)98 – 100 %
Colour90 – 100 %
Odor100 %
Removal of Suspended & Floatable Organic Debris100 %
Reduces Total Suspended Solids (TSS)95 99%
Reduces Total Dissolved Solids (TDS)Depends on Characteristics of wastewater
Increases Dissolved Oxygen (OD)Min 3 – Max 8

NANOZYME - BET - COMP – 7103

Aerobic Composting Nanozyme Bioculture

Composting is the natural process of ‘rotting’ or decomposition of organic matter by microorganisms under controlled conditions. Raw organic materials such as crop residues, animal wastes, food garbage, some municipal wastes, and suitable industrial wastes enhance their suitability for application to the soil as a fertilizing resource after undergoing composting.

Stages of Composting

Composting is a biochemical process through which organic matter is decomposed, and you get a humus called compost. The stages of composting are very particular and must be frequently controlled to ensure that temperature, humidity, oxygen, and other factors develop correctly. Specific facilities are required to secure greater control over how the organic raw material evolves step by step.

Stages of Nanozyme Microbial Bioculture Composting Process

Mesophilic Stage:

The mixture of raw materials is still at environmental temperature and without moisturizing. The “mesophilic” microorganisms (microorganisms that grow between 20-45 °C) begin to reproduce by breaking down carbon and nitrogen. The metabolic activity of the microorganisms raises the temperature to 40-45 °C between two to eight days. It also lowers the pH of the mixture due to the production of organic acids.

Thermophilic Stage:

Also known as the “sanitation” phase, in this stage, the temperature rises above 45 °C, and the mesophilic microorganisms are replaced by the “thermophiles” (microorganisms that proliferate at temperatures between 45 °C and 70 °C). Thermophiles break down more complex carbon sources, such as cellulose and lignin. Another important change is that nitrogen is transformed into ammonia, and the pH of the mixture becomes alkaline.

Starting at 60 ºC, sporagenic (spore-producing) bacteria and actinobacteria appear. These two bacteria are responsible for breaking down waxes, hemicelluloses, and more complex proteins.

Afterwards, for several days or even months (depending on the raw material used), a high temperature is maintained, reducing the biological activity of microorganisms. A pasteurization process occurs, killing harmful microorganisms such as Salmonella or Escherichia coli. This process allows for product sanitation. During this phase, the mixture must be frequently ventilated to supply oxygen to the microorganisms, enabling them to continue the decomposition process.

Cooling Stage:

When carbon and nitrogen have been consumed, the temperature lowers to 40-45 ºC. The mesophilic bacteria reappear and decompose the remaining cellulose and lignin. The pH slightly drops again.

Maturation Stage:

At this stage, the mixture stays at room temperature. During this time, a series of secondary reactions occur, triggering condensation and polymerization of the humus. At the end of this period, the final product, compost, is obtained.

The implementation of aerobic microbial culture and aerobic bacterial culture treatment in composting enhances decomposition efficiency. These bio-based solutions assist in sludge reduction techniques, bio culture BOD reduction, and effective wastewater odour control, making composting an environmentally friendly and sustainable process.

Aerobic Microbial Culture

AVAILABLE FORM

ORGANIC SEMI-SOLID FORM

Number of Bacterial Cultures

48 Different Bacterial Cultures

Stage of Bacterial Cultures

Living Bacteria

Number of Bacterial Colonies

38 x 10-9 CFU/ml

Shelf Life

Min One Year

Advantages of Nanozyme Microbial Bioculture Composting

  • Volume reduction of waste.
  • The final weight of the compost is very low.
  • Composting temperature kills pathogens, weed seeds, and seeds.
  • Matured compost comes into equilibrium with the soil.
  • During composting, a number of wastes from several sources are blended.
  • Excellent soil conditioner
  • Saleable product
  • Improves manure  handling
  • Reduces the risk of pollution
  • Pathogen reduction
  • Additional revenue.
  • Suppress plant diseases and pests.
  • Reduce or eliminate the need for chemical fertilizers.
  • Promote higher yields of crops.
  • Facilitate reforestation, wetlands restoration, and habitat revitalization efforts by amending contaminated, compacted, and marginal soils.
  • Cost-effectively remediate soils contaminated by hazardous waste.
  • Remove solids, oil, grease, and heavy metals from stormwater runoff.
  • Capture and destroy 99.6 percent of industrial volatile organic chemicals (VOCs) in contaminated air.
  • Provide cost savings of at least 50 percent over conventional soil, water, and air pollution remediation technologies, where applicable.