Thermal Oxidizer System for Power Generation

Sistema de Oxidação Térmica Thermal Oxidizer System is a combustion technology used to destroy volatile organic compounds (VOCs) and hazardous air pollutants (HAPs) from industrial air streams. It is widely used in power generation plants to reduce emissions and comply with environmental regulations. In this blog post, we will discuss the various aspects of Thermal Oxidizer System for Power Generation.

How does Thermal Oxidizer System work?

Thermal Oxidizer System uses high temperature and oxygen to convert VOCs and HAPs into carbon dioxide and water vapor.
The system consists of a combustion chamber, burner, and heat exchanger.
The air stream is heated to a high temperature in the combustion chamber, where VOCs are oxidized.
The hot air then passes through the heat exchanger, where it transfers its heat to the incoming air stream.
The treated air is then released into the atmosphere.

Types of Thermal Oxidizer System

Regenerative Thermal Oxidizer (RTO)
Catalytic Oxidizer
Oxidante Térmico Recuperativo
Direct Fired Thermal Oxidizer

Regenerative Thermal Oxidizer (RTO)

RTO is the most common type of Thermal Oxidizer System used in power generation plants.
It uses a ceramic heat exchanger to recover and reuse the heat generated during combustion.
The heat exchanger alternates between two chambers, allowing for continuous operation.
RTO can achieve high destruction efficiencies (>99%) and is energy efficient.

Catalytic Oxidizer

Catalytic Oxidizer uses a catalyst to promote the oxidation of VOCs and HAPs.
It operates at lower temperature than RTO and is more energy efficient.
However, it is less effective in destroying some types of pollutants.

Oxidante Térmico Recuperativo

Recuperative Thermal Oxidizer uses a heat exchanger to recover heat from the treated air stream.
It is less energy efficient than RTO but is useful for low concentration air streams.

Direct Fired Thermal Oxidizer

Direct Fired Thermal Oxidizer combusts the air stream directly in the combustion chamber.
It is less energy efficient and has lower destruction efficiency than other types of Thermal Oxidizer System.
It is useful for high concentration air streams.

Benefits of using Thermal Oxidizer System

Reduces emissions of VOCs and HAPs, improving air quality and protecting the environment.
Helps power generation plants to comply with environmental regulations.
Improves the efficiency of power generation by recovering heat from the treated air stream.
Increases the lifespan of equipment by reducing corrosion caused by pollutants.

Challenges of using Thermal Oxidizer System

High energy consumption and operating costs.
Requires skilled personnel to operate and maintain the system.
May produce harmful by-products such as nitrogen oxides (NOx) and carbon monoxide (CO) if not properly designed and maintained.
May cause noise pollution.

Conclusão

Thermal Oxidizer System is an effective technology for reducing emissions of VOCs and HAPs from power generation plants. There are various types of Thermal Oxidizer System, each with its own advantages and disadvantages. It is important to choose the right type of system based on the air stream concentration and the desired destruction efficiency. Despite its challenges, Thermal Oxidizer System is a necessary technology for protecting the environment and ensuring compliance with environmental regulations.

Introdução da empresa

We are a high-tech manufacturing enterprise specializing in the comprehensive treatment of volatile organic compounds (VOCs) exhaust gas and carbon reduction and energy-saving technologies. Our core technical team comes from the Aerospace Liquid Rocket Engine Research Institute (Aerospace Sixth Institute), with more than 60 research and development technicians, including 3 senior engineers and 16 senior engineers. We have four core technologies: thermal energy, combustion, sealing, and self-control. We have the ability to simulate and calculate temperature field simulation and air flow field simulation. Additionally, we have the capability to conduct experiments and tests on ceramic heat storage material performance, molecular sieve adsorbent material selection, and high-temperature incineration and oxidation characteristics of VOCs organic substances. Our company has established RTO technology research and development center and exhaust gas carbon reduction engineering technology center in the ancient city of Xi’an, as well as a 30,000m² production base in Yangling. The sales volume of RTO equipment is globally leading.

Plataformas de Pesquisa e Desenvolvimento

Plataforma de teste de tecnologia de controle de combustão de alta eficiência

Our high-efficiency combustion control technology test platform is equipped with advanced combustion control systems and sensors, allowing us to develop and optimize combustion processes to improve efficiency and reduce emissions.

Plataforma de teste de eficiência de adsorção por peneira molecular

With our molecular sieve adsorption efficiency test platform, we can evaluate and compare the performance of different molecular sieve materials for VOCs adsorption, helping us select the most efficient materials for our products.

Plataforma de teste de tecnologia de armazenamento de calor cerâmico de alta eficiência

Our high-efficiency ceramic heat storage technology test platform enables us to study and improve the heat storage performance of ceramic materials, leading to more efficient energy utilization and increased system performance.

Plataforma de teste de recuperação de calor residual de temperatura ultra-alta

Using our ultra-high temperature waste heat recovery test platform, we can explore and develop innovative technologies to capture and utilize waste heat at extremely high temperatures, contributing to energy conservation and emission reduction.

Plataforma de teste de tecnologia de vedação de fluido de gás

Our gas fluid sealing technology test platform allows us to evaluate and optimize different sealing methods and materials, ensuring reliable and efficient sealing performance in our equipment.

Patentes e Honrarias

In terms of core technologies, we have applied for a total of 68 patents, including 21 invention patents. These patents cover key components of our products. Currently, we have been granted 4 invention patents, 41 utility model patents, 6 design patents, and 7 software copyrights.

Capacidade de produção

Linha de produção automática de jateamento e pintura de chapas e perfis de aço

Our steel plate and profile automatic shot blasting and painting production line ensures high-quality surface treatment for steel materials, improving corrosion resistance and durability.

Linha de produção de jateamento manual

The manual shot blasting production line allows us to manually clean and prepare various components and equipment surfaces before further processing or coating.

Equipamentos de remoção de poeira e proteção ambiental

With our dust removal and environmental protection equipment, we can effectively remove particulate matter and harmful pollutants from exhaust gas, ensuring compliance with environmental regulations.

Cabine de pintura automática

Our automatic painting booth enables efficient and uniform coating of equipment and components, ensuring high-quality and durable surface finishes.

Sala de secagem

The drying room provides a controlled environment for drying and curing coated surfaces, enhancing the adhesion and durability of the coating.

We call on customers to cooperate with us and would like to highlight the following advantages:

Advanced technology and expertise in VOCs exhaust gas treatment and carbon reduction
Proven research and development capabilities in key areas
Rich experience in equipment manufacturing and production
High-quality products and reliable performance
Comprehensive patent coverage and recognition
Commitment to environmental protection and energy conservation

Autor: Miya

thermal oxidizer system for power generation