HECS

MBBR Sewage Treatment Plants

HECS offers on-site Decentralized packaged MBBR Sewage Treatment Plants, which are designed to provide efficient, high-quality treatment of sewage while being easy to use. These units have been manufactured to set new standards in terms of quality, performance, and operational efficiency, making them an attractive option for those in need of sewage treatment solutions.

HECS Ultima Packaged MBBR Sewage Treatment Plants (FRP)

  •     HECS Ultima Packaged STP has a capacity range of 2KLD to 100+KLD.
  •     It can be installed above ground or below ground.
  •     The plant uses MBBR technology and has a compact, aesthetically designed FRP shell.
  •     Key features: low capital and operational costs, no operators required, minimal power consumption, no smell and low noise, and the option for above ground or below ground installation.

HECS Ultima+ Packaged MBBR Sewage Treatment Plants (FRP)

  •     HECS Ultima+ Packaged STP has a capacity range of 2KLD to 100+KLD.
  •     It can be installed above ground or below ground.
  •     The plant uses MBBR technology and has a compact, aesthetically designed FRP shell.
  •     Key features: low capital and operational costs, no operators required, minimal power consumption, no smell and low noise, and the option for above ground or below ground installation.

HECS Packaged MBBR Sewage Treatment Plants

  •     HECS Packaged MBR STP is powered by Mitsubishi MBR membranes.
  •     It has a plug and play design with minimum civil work required.
  •     The plant is designed with globally recognized Mitsubishi MBR membranes.
  •     It has a proven design vetted by Mitsubishi Chemicals and can achieve the highest treatment standards without the need for UF.
  •     There is no requirement for further treatment.
  •     It has minimal maintenance, trouble-free operation, minimal or no smell, and optimized design for energy savings.

What is primary treatment of wastewater?

Wastewater treatment is a crucial process that aims to remove contaminants and pollutants from wastewater to make it safe for discharge into the environment or reuse. Primary treatment of wastewater is the first stage of wastewater treatment and involves physical removal of suspended solids and floatable materials from the wastewater. It is a vital step in the treatment process as it reduces the organic content of the wastewater and prepares it for secondary treatment. The primary treatment process can be accomplished by various methods, including screening, sedimentation, and floatation.

Screening is the process of removing large debris and suspended solids from the wastewater. This is typically done using a bar screen, which is a series of metal bars spaced closely together to prevent larger solids from entering the wastewater treatment plant. The removed solids are then disposed of as waste.

Sedimentation, also known as clarification, is the process of allowing the suspended solids to settle at the bottom of a settling tank. The solids that settle at the bottom of the tank are referred to as sludge and must be removed regularly to maintain the efficiency of the treatment process. The clear liquid that rises to the top of the tank after sedimentation is called the clarifier supernatant and is then sent to the secondary treatment stage.

Floatation is a process that uses chemicals, such as alum, to cause the floatable solids to clump together and float to the surface of the wastewater. The floatable solids are then removed, and the clear liquid is sent to the secondary treatment stage.

Primary treatment of wastewater is a critical step in the overall treatment process as it reduces the organic content of the wastewater and removes floatable materials and suspended solids. This helps to improve the efficiency of the secondary treatment stage and also reduces the potential for blockages and other problems in the discharge pipes.

Primay treatment of wastewater is essential for achieving effective and efficient wastewater treatment. The primary treatment process involves screening, sedimentation, and floatation, which are used to remove suspended solids, floatable materials, and contaminants from the wastewater. These steps help to reduce the organic content of the wastewater and prepare it for secondary treatment. Additionally, primary treatment helps to prevent blockages and other problems in the discharge pipes, ensuring the safe and sustainable discharge of treated wastewater into the environment.

It is important to note that primary treatment alone is not enough to make wastewater safe for discharge into the environment or reuse.

What is secondary treatment of wastewater?

Secondary treatment of wastewater is a stage in the wastewater treatment process that follows primary treatment. Secondary treatment is necessary to remove the remaining pollutants and contaminants, including dissolved and colloidal solids. The most common methods of secondary treatment are biological treatment processes, such as activated sludge and biofilters.

Activated sludge is a process that uses microorganisms to break down the remaining organic matter in the wastewater. The microorganisms are maintained in a tank, where they consume the organic matter and produce biomass, which is then removed and treated as sludge. The clear effluent from the activated sludge process is then sent to the tertiary treatment stage.

Biofilters use microorganisms growing on a substrate, such as gravel or sand, to break down the organic matter in the wastewater. The wastewater is trickled over the substrate, where the microorganisms consume the organic matter and produce biomass, which is then removed and treated as sludge. The clear effluent from the biofilter process is then sent to the tertiary treatment stage.

Tertiary treatment is the final stage of wastewater treatment and is designed to remove any remaining pollutants and contaminants. Tertiary treatment processes may include filtration, disinfection, and nutrient removal.

Filtration involves passing the effluent through a physical filter, such as a sand filter, to remove any remaining solids. Disinfection involves adding a chemical, such as chlorine, to kill any remaining pathogens in the wastewater. Nutrient removal is a process that removes excess nutrients, such as nitrogen and phosphorus, from the wastewater to prevent eutrophication, which is the excessive growth of algae and other aquatic plants in a body of water due to an increase in nutrient levels.

Primary treatment of wastewater is a critical step in the overall treatment process. It involves the physical removal of suspended solids and floatable materials from the wastewater, which helps to reduce the organic content of the wastewater and prepare it for secondary treatment. Secondary treatment is necessary to remove the remaining pollutants and contaminants, including dissolved and colloidal solids, and may involve biological treatment processes, such as activated sludge and biofilters. Tertiary treatment is the final stage of wastewater treatment and is designed to remove any remaining pollutants and contaminants, including filtration, disinfection, and nutrient removal. Effective and efficient wastewater treatment is crucial for ensuring the safe and sustainable discharge of treated wastewater into the environment.

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What is Packaged Sewage Treatment Plant?

A Packaged Sewage Treatment Plant (PSTP) is an all-in-one solution for the treatment of household or municipal sewage in areas where traditional sewer systems are not available. PSTPs are designed to be compact, modular, and cost-effective, providing an environmentally friendly option for the treatment of wastewater. They are ideal for small communities, rural areas, and isolated residential areas where access to a centralized sewage treatment plant is limited.

At the heart of a PSTP is the aeration tank, where the biological treatment of the wastewater takes place. The wastewater is aerated to provide oxygen to microorganisms that break down the organic matter in the wastewater. The microorganisms produce biomass, which is then removed in the secondary settling tank. The secondary settling tank separates the biomass from the clear effluent, which is then disinfected with chlorine or ultraviolet light before being safely discharged into the environment.

The main components of a PSTP include a primary settling tank for removing suspended solids and floatable materials, an aeration tank for biological treatment, a secondary settling tank for removing biomass, and a sludge treatment unit for processing the biomass. PSTPs are designed to be low maintenance and easy to operate, with automatic controls and alarms to ensure proper operation. The systems are also built to be durable and resistant to corrosion, using high-quality materials in construction.

In addition to their practicality, PSTPs are environmentally friendly, using biological processes to break down organic matter in the wastewater, producing a clear, disinfected effluent that is safe for discharge into the environment. They are also easily transportable and installable, requiring minimal site preparation.

Packaged sewage treatment plants are a practical and sustainable solution for the treatment of household or municipal sewage in areas where traditional sewer systems are not available. With their low maintenance, ease of operation, durability, and environmental sustainability, PSTPs are a cost-effective and environmentally responsible alternative to traditional sewer systems.

Keywords: Packaged sewage treatment plant (PSTP), household sewage, municipal sewage, small communities, rural areas, isolated residential areas, cost-effective, environmentally friendly, clear effluent, disinfected, aeration tank, biological treatment, secondary settling tank, sludge treatment unit, low maintenance, easy to operate, durable, resistant to corrosion, environmentally friendly, transportable, installation, practical, sustainable solution.

What is advanced treatment of wastewater?

Advanced treatment of wastewater refers to the treatment processes that are applied after secondary treatment of wastewater to further reduce the levels of pollutants and contaminants. Advanced treatment processes aim to improve the quality of the effluent produced by the secondary treatment processes and to ensure that the effluent meets specific discharge standards or requirements.

Advanced treatment processes include physical, chemical, and biological treatments such as ultrafiltration, reverse osmosis, advanced oxidation processes (AOPs), and nutrient removal.

Ultrafiltration uses a semi-permeable membrane to remove fine particles and dissolved substances from the wastewater, providing a high-quality effluent for reuse or discharge.

Reverse osmosis is a pressure-driven process that removes salts, minerals, and other contaminants from the wastewater, producing high-quality water for reuse.

Advanced oxidation processes (AOPs) are chemical processes that use powerful oxidizing agents such as ozone or hydrogen peroxide to remove pollutants from the wastewater. These processes are effective at removing a wide range of contaminants, including organic pollutants, pathogens, and emerging contaminants.

Nutrient removal processes are designed to remove excess nitrogen and phosphorus from the wastewater, which can cause environmental problems such as eutrophication in receiving waters. These processes can include biological nitrogen and phosphorus removal, chemical phosphorus removal, and denitrification.

Advanced treatment of wastewater is used in industries such as pharmaceuticals, petrochemicals, electronics, and food and beverage production to meet strict discharge standards or to produce high-quality water for reuse.

Advanced treatment of wastewater is a necessary step in ensuring that the effluent produced by wastewater treatment processes meets the required discharge standards and that the environment is protected from the harmful effects of pollutants. Advanced treatment processes such as ultrafiltration, reverse osmosis, advanced oxidation processes, and nutrient removal provide a cost-effective and reliable solution for the treatment of wastewater and the production of high-quality water for reuse.

Keywords: advanced treatment, wastewater, secondary treatment, pollutants, contaminants, effluent, discharge standards, ultrafiltration, reverse osmosis, advanced oxidation processes (AOPs), nutrient removal, nitrogen, phosphorus, eutrophication, pharmaceuticals, petrochemicals, electronics, food and beverage production, cost-effective, reliable solution. MBBR Sewage Treatment Plants

What is a septic treatment plant?

A septic treatment plant is a decentralized wastewater treatment system designed for use in areas without access to central sewer systems. The system is typically used in rural areas, small towns, and other locations where it is not practical or economically feasible to connect to a centralized sewer system.

A septic treatment plant consists of a septic tank, where the wastewater is temporarily stored, and a treatment unit, where the wastewater is treated. The septic tank separates the solids and liquids in the wastewater, and the liquids are then conveyed to the treatment unit, where the organic matter is decomposed by bacteria. The treated effluent is then discharged into the surrounding environment.

The design and operation of a septic treatment plant must comply with local regulations and standards to ensure that the effluent produced is safe for the environment and does not pose a threat to public health. Septic treatment plants are designed to be low maintenance and easy to operate, making them ideal for use in rural and remote areas.

A septic treatment plant is an effective and practical solution for the treatment of household or municipal sewage in areas without access to central sewer systems. These decentralized systems are designed to meet the specific needs of each location and are equipped with advanced technologies to ensure efficient and effective wastewater treatment. Septic treatment plants are low maintenance, easy to operate, and provide a cost-effective alternative to centralized sewer systems, making them ideal for use in rural and remote areas. MBBR Sewage Treatment Plants

Keywords: septic treatment plant, decentralized wastewater treatment, rural areas, small towns, centralized sewer system, septic tank, treatment unit, organic matter, bacteria, treated effluent, local regulations, low maintenance, easy to operate, cost-effective alternative. MBBR Sewage Treatment Plants

What is a containerized wastewater treatment plant?

A containerized wastewater treatment plant is an innovative solution for treating sewage and other forms of wastewater. These plants are designed to operate within a standard shipping container and can be easily transported to a desired location. This makes them an ideal solution for remote locations, temporary facilities, and disaster relief efforts. MBBR Sewage Treatment Plants

The process of treating wastewater using a containerized plant typically involves several stages. First, the raw wastewater is screened to remove any large debris, such as rags, plastics, and other solid waste. The screened wastewater is then pumped into a primary settling tank, where heavy solids settle to the bottom and oils and grease rise to the top.

Next, the wastewater is aerated using a blower or compressor, which provides oxygen to the microorganisms that are responsible for breaking down the organic matter in the wastewater. The microorganisms convert the organic matter into biomass, which settles to the bottom of the secondary clarifier. The clear, treated wastewater is then discharge back into the environment, typically a river or stream.

The containerized wastewater treatment plant operates using a variety of cutting-edge technologies, including biological treatment, physical treatment, and chemical treatment. The biological treatment process relies on the activity of microorganisms to break down the organic matter in the wastewater, while physical treatment involves removing solid waste from the wastewater using sedimentation, flotation, and filtration processes. Chemical treatment involves adding chemicals to the wastewater to help remove impurities, such as heavy metals, nitrogen, and phosphorus.

One of the main advantages of a containerized wastewater treatment plant is its portability. The plants can be quickly and easily transported to a desired location and set up with minimal effort. This makes them ideal for remote locations, where traditional treatment plants may not be feasible. In addition, they can be used as a temporary solution in areas affected by natural disasters, such as hurricanes, earthquakes, and floods, where traditional treatment plants may have been damaged or destroyed.

Another advantage of containerized wastewater treatment plants is their scalability. They can be designed to treat a wide range of flow rates, from just a few gallons per day to several million gallons per day. This allows them to be used in a variety of applications, including small residential communities, large industrial facilities, and everything in between.

The operation of a containerized wastewater treatment plant is also highly efficient, as it is automated and requires minimal operator intervention. The plants are equipped with monitoring and control systems that allow for real-time monitoring and adjustment of the treatment process, ensuring optimal performance at all times.

In addition, containerized wastewater treatment plants are environmentally friendly, as they are designed to minimize the release of pollutants into the environment. The treated wastewater is discharge back into the environment at a level that meets or exceeds regulatory standards, helping to protect public health and the environment.

Overall, containerized wastewater treatment plants are a versatile and cost-effective solution for treating wastewater in a wide range of applications. With their portability, scalability, efficiency, and environmental friendliness, they are a highly attractive option for communities, industries, and governments looking to address the challenges of treating wastewater.

Containerized wastewater treatment plants are an innovative solution for the treatment of sewage and other forms of wastewater, offering a range of benefits, including portability, scalability, efficiency, and environmental friendliness. These plants are designed to operate within a standard shipping container and can be easily transported to a desired location, making them ideal for remote locations, temporary facilities, and disaster relief efforts. With cutting-edge technologies, such as biological treatment, physical treatment, and chemical treatment, containerized wastewater treatment plants offer a highly effective solution for treating wastewater, while minimizing the release of pollutants into the environment.

What is a marine sewage treatment plant?

A marine sewage treatment plant is a system designed to treat and process sewage and other forms of wastewater generated on a ship or other marine vessel. The primary aim of a marine sewage treatment plant is to reduce the levels of pollutants, such as nitrogen, phosphorus, and organic matter, in the wastewater before it is discharged into the ocean.

The treatment process in a marine sewage treatment plant typically involves several stages, including screening, settling, and disinfection. During the screening process, any large debris, such as rags, plastics, and other solid waste, is removed from the raw sewage. The screened sewage is then directed to a settling tank, where heavy solids settle to the bottom and oils and grease rise to the top.

Next, the sewage is treated biologically, using microorganisms to break down the organic matter in the wastewater. The treated wastewater is then disinfected, typically using chlorine or ultraviolet light, to kill any remaining harmful pathogens.

One of the key benefits of a marine sewage treatment plant is that it helps to reduce the environmental impact of discharging untreated sewage into the ocean. The treated wastewater is discharge at a level that meets or exceeds international regulations, helping to protect public health and the environment.

Another advantage of a marine sewage treatment plant is that it allows ships and marine vessels to comply with regulations and standards set by international organizations, such as the International Maritime Organization (IMO) and the European Union (EU). These organizations have set strict standards for the discharge of sewage from ships and marine vessels, and a marine sewage treatment plant helps to ensure that these standards are met.

The operation of a marine sewage treatment plant is also highly efficient and requires minimal operator intervention. The plants are equipped with monitoring and control systems that allow for real-time monitoring and adjustment of the treatment process, ensuring optimal performance at all times.

A marine sewage treatment plant is an essential system for ships and marine vessels to treat and process sewage and other forms of wastewater generated onboard. With its ability to reduce the environmental impact of discharging untreated sewage into the ocean, help ships and marine vessels comply with international regulations and standards, and operate efficiently, a marine sewage treatment plant is a critical component of any marine vessel looking to address the challenges of treating wastewater.

What are MBBR sewage treatment plants?

MBBR (Moving Bed Biofilm Reactor) sewage treatment plant is a wastewater treatment technology that utilizes a combination of physical and biological processes to treat and purify wastewater. The process is based on a suspended growth biological treatment system that uses biofilm carriers to provide a large surface area for the growth of microorganisms.

In an MBBR sewage treatment plant, the wastewater is pumped into a reactor tank that contains a large number of biofilm carriers. These carriers are specially designed plastic media that provide a large surface area for the growth of microorganisms. As the wastewater flows over the biofilm carriers, the microorganisms present on the carriers feed on the organic matter in the wastewater, breaking it down into simpler compounds.

In the MBBR process, the biofilm carriers are kept in constant motion using aerators or agitators, which also help to oxygenate the wastewater. The constant movement of the carriers helps to maintain a high level of mixing and keeps the biofilm from becoming overloaded or clogged.

The treated wastewater then flows from the reactor tank to a secondary clarifier, where any remaining solids are separated and removed. The clear, treated wastewater is then disinfected, typically using chlorine or ultraviolet light, before being discharged into the environment.

One of the key advantages of the MBBR sewage treatment plant is its ability to handle high organic loads and treat wastewater to very low levels of pollutants. This makes it an ideal solution for industries and communities with high-strength wastewater streams, such as food and beverage processing plants, pharmaceuticals, and municipalities.

Another advantage of the MBBR sewage treatment plant is its compact design and low maintenance requirements. The biofilm carriers are highly durable and require minimal maintenance, and the system as a whole is designed to be easy to operate and maintain, making it an ideal solution for remote or challenging environments.

The MBBR sewage treatment plant is a highly efficient and effective wastewater treatment technology that utilizes a combination of physical and biological processes to treat and purify wastewater. With its ability to handle high organic loads, treat wastewater to very low levels of pollutants, and its compact design and low maintenance requirements, the MBBR sewage treatment plant is an ideal solution for a wide range of industries and communities. MBBR Sewage Treatment Plants

What is aerated/aerobic treatment of wastewater?

An aerated wastewater treatment system is a type of wastewater treatment technology that uses air to aid in the biological treatment of wastewater. The system works by introducing air into the wastewater, which oxygenates the wastewater and provides the necessary environment for aerobic microorganisms to break down the organic matter in the wastewater.

Aerated wastewater treatment systems typically consist of a series of tanks or reactors that are designed to provide the optimal conditions for the growth of aerobic microorganisms. In the first stage of treatment, the raw wastewater is screened to remove any large solids and then flows into an aeration tank. Here, air is introduced into the wastewater using fine bubbles from diffusers or mechanical aerators, which provides the necessary oxygen for the growth of aerobic microorganisms.

The microorganisms present in the aeration tank feed on the organic matter in the wastewater, breaking it down into simpler compounds. The treated wastewater is then passed through a clarifier, where any remaining solids are separated and removed, and the clear, treated wastewater is disinfected, typically using chlorine or ultraviolet light, before being discharged into the environment.

One of the key advantages of aerated wastewater treatment systems is their ability to handle high organic loads and treat wastewater to very low levels of pollutants. This makes them an ideal solution for industries and communities with high-strength wastewater streams, such as food and beverage processing plants, pharmaceuticals, and municipalities.

Another advantage of aerated wastewater treatment systems is their compact design and low maintenance requirements. The systems are designed to be easy to operate and maintain, making them an ideal solution for remote or challenging environments.

Aerated wastewater treatment systems are a highly efficient and effective wastewater treatment technology that uses air to aid in the biological treatment of wastewater. With their ability to handle high organic loads, treat wastewater to very low levels of pollutants, and their compact design and low maintenance requirements, aerated wastewater treatment systems are an ideal solution for a wide range of industries and communities.

How is chemical treatment of wastewater done?

Wastewater treatment typically involves a series of physical, chemical and biological processes to remove contaminants and impurities. Chemical treatment typically involves adding chemical reagents to the wastewater to change the pH or to remove specific contaminants.

  • Neutralization: Neutralization is the process of adjusting the pH of the wastewater to a neutral level (usually 7.0) by adding chemicals such as sodium hydroxide (NaOH) or sulfuric acid (H2SO4). This helps to prevent corrosion in pipes and treatment equipment and to improve the effectiveness of other treatment processes.
  • Coagulation and flocculation: Coagulation and flocculation are chemical processes used to remove suspended solids and colloidal particles from wastewater. Coagulants, such as aluminum sulfate (Al2(SO4)3) or ferric chloride (FeCl3), are added to the wastewater to destabilize the suspended particles and cause them to clump together (flocculate). The larger clumps of particles can then be more easily removed through sedimentation or filtration.
  • Precipitation: Precipitation is a chemical process used to remove dissolved heavy metals, such as lead and copper, from wastewater. Precipitant chemicals, such as lime (CaO) or sodium hydroxide (NaOH), are added to the wastewater to cause the heavy metals to form solid precipitates that can be removed by sedimentation or filtration.
  • Adsorption: Adsorption is a process that uses activated carbon to remove dissolved organic contaminants from wastewater. The activated carbon has a large surface area that attracts and binds organic molecules, removing them from the wastewater.
  • Oxidation: Oxidation is the process of removing dissolved organics, sulfur compounds, and some inorganic compounds from wastewater using chemical or biological oxidants. Chemical oxidation involves adding chemicals, such as hydrogen peroxide or ozone, to the wastewater to oxidize and remove the target contaminants. Biological oxidation involves adding bacteria or other microorganisms to the wastewater that can oxidize the contaminants through biological processes.

HECS Packaged STPs
A21, 3rd Phase, TVK Industrial Estate,
Guindy, Chennai – 600032.

Manufacturing Unit:

14NP, Developed Plots, TVK Industrial Estate,
Ekkaduthangal, Chennai – 600032

+91 44 43635555

sales@hecs.in

http://hecspstp.com/


You may also be interested in this manufacturer of wastewater treatment plants:

Shakunth Aqua Products

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