Hollowbrane Membrane Technologies

HOLLOWBRANE OFFERS 0.5 KLD (Kilo Litres per Day) MBR (Membrane Bioreactor) sewage treatment plant is designed to treat wastewater from smaller sources, such as individual households, small communities, or commercial establishments with low wastewater generation. Here’s a brief description of its components and operation:

1. Inlet/Receiving Section:

   • Wastewater enters the treatment plant through an inlet pipe or channel.

2. Screening and Grit Removal:

   • Large debris, solids, and grit are removed to prevent damage to downstream equipment.

3. Primary Treatment (Optional):

   • Some plants may have a primary settling tank where heavier solids settle out as sludge.

4. Bioreactor (MBR):

   • The heart of the plant where biological treatment occurs.
   • Microorganisms break down organic matter in the wastewater, reducing its pollutant content.
   • Membranes (microfiltration or ultrafiltration) separate treated water from activated sludge.

5. Aeration System:

   • Provides oxygen to the microorganisms to facilitate biological degradation.
   • Ensures optimal conditions for efficient treatment.

6. Membrane Filtration:

   • Filters out suspended solids, bacteria, and other contaminants from the treated water.
   • Produces high-quality effluent suitable for discharge or reuse.

7. Disinfection (Optional):

   • Depending on the discharge requirements, the treated water may undergo disinfection (e.g., chlorination) to kill remaining pathogens.

8. Sludge Management:

   • Sludge produced during treatment is periodically removed and either treated further (e.g., dewatered) or disposed of appropriately.

9. Effluent Storage and Distribution:

   • Treated water (effluent) is stored temporarily before being discharged or reused, depending on local regulations and requirements.

• Continuous Process: Typically operates continuously to maintain treatment efficiency.
• Monitoring and Control: Includes monitoring of inflow rates, quality of effluent, and operational parameters like oxygen levels and membrane integrity.
• Maintenance: Regular maintenance of pumps, membranes, and other equipment is essential to ensure optimal performance and longevity.

• Compact Size: Suitable for small spaces or decentralized locations.
• High Treatment Efficiency: Effective removal of pollutants and pathogens.
• Environmentally Friendly: Reduces environmental impact by treating wastewater close to its source.
• Potential for Reuse: Produces treated water that can be reused for irrigation, industrial processes, or non-potable purposes.

Additional Information:

• Item Code: HMT0.5MBR
• Production Capacity: 100
• Delivery Time: 10 DAYS
• Packaging Details: WOODEN

A 50 kLD (kiloliters per day) hollow fiber membrane bioreactor (MBR) plant is a wastewater treatment system that utilizes hollow fiber membranes to separate solid materials from water. Here's a breakdown of the components and processes involved:

1. Bioreactor: This is where the biological treatment occurs. Microorganisms break down organic pollutants in the wastewater, converting them into simpler, less harmful substances.

2. Hollow Fiber Membranes: These are the key components of the MBR system. Hollow fibers have microscopic pores that allow water to pass through while capturing suspended solids, bacteria, and other contaminants. The membranes act as a physical barrier, producing treated water that is cleaner and suitable for reuse or discharge.

3. Pumps and Controls: Pumps are used to circulate wastewater through the system, while controls monitor and regulate various parameters such as flow rate, pressure, and membrane cleaning cycles.

4. Aeration System: Aeration is essential for promoting microbial activity in the bioreactor. Oxygen is introduced into the wastewater to support aerobic bacteria, which are highly effective at breaking down organic matter.

5. Backwashing and Cleaning System: Periodically, the membranes need to be cleaned to remove accumulated solids and maintain their efficiency. Backwashing, chemical cleaning, or air scouring may be employed for this purpose.

6. Disinfection Unit: After treatment, the water may undergo further disinfection to eliminate any remaining pathogens or bacteria. Common methods include chlorination, ultraviolet (UV) irradiation, or ozonation.

7. Sludge Handling: As solids accumulate in the bioreactor and membranes, they form sludge, which needs to be periodically removed and treated. Sludge dewatering and disposal methods vary depending on local regulations and environmental considerations.

A 50 kLD MBR plant would typically be used for smaller to medium-sized wastewater treatment applications, such as in residential communities, small municipalities, or industrial facilities. The compact footprint and high treatment efficiency make MBR systems a popular choice for decentralized or space-constrained locations.

Additional Information:

• Item Code: HMT50KLDMBR
• Production Capacity: 50
• Delivery Time: 45DAYS
• Packaging Details: NORMAL

Additional Information:

• Item Code: HMTP25STP
• Production Capacity: 50
• Delivery Time: 45days
• Packaging Details: Normal

Hollowbrane Membrane Technologies offers comprehensive Wastewater Treatment Plant (WWTP) services for industrial, commercial, and municipal applications. Our services include operation, maintenance, troubleshooting, and performance optimization of STP, ETP, and MBR plants, ensuring efficient wastewater treatment and compliance with environmental regulations.

We provide skilled technical support, periodic plant audits, chemical dosing, membrane cleaning, and preventive maintenance, helping clients maximize plant efficiency, reduce downtime, and extend equipment life.

The construction of a Sewage Treatment Plant (STP) involves the development of a facility designed to treat and purify wastewater from residential, commercial, or industrial sources before its safe discharge or reuse. The STP removes contaminants, organic matter, and harmful microorganisms to meet environmental and public health standards.

• ISTPs utilize various physical, chemical, and biological processes to remove contaminants, including screening, sedimentation, filtration, and advanced technologies.
• To treat industrial wastewater, making it safe for discharge or reuse.