China Hot selling Regenerative Thermal Oxidizer (RTO)

Basic Info.

Model NO.

RTO

Processing Methods

Combustion

Pullution Sources

Air Pollution Control

Trademark

RUIMA

Origin

China

HS Code

84213990

Product Description

Regenerative Thermal Oxidizer (RTO);
The most widely used oxidation technique nowadays for
VOC emission reduction,; suitable for treating a wide range of solvents and processes.; Depending on air volume and required purification efficiency,; a RTO comes with 2,; 3,; 5 or 10 chambers.;

Advantages
Wide range of VOC’s to be treated
Low maintenance cost
High Thermal Efficiency
Does not generate any waste
Adaptable for small,; medium and large air flows
Heat Recovery via bypass if VOCs concentration exceed the auto-thermal point

Auto-thermal and Heat Recovery:;
Thermal Efficiency > 95%
Auto-thermal point at 1.;2 – 1.;7 mgC/Nm3
Air flow range from 2,; 000 up to 200,; 000m3/h

High VOC’s destruction
The purification efficiency is normally in excess of 99%

Address: No 3 North Xihu (West Lake) Dis. Road, Xihu (West Lake) Dis., HangZhou, ZheJiang , China

Business Type: Manufacturer/Factory

Business Range: Manufacturing & Processing Machinery, Service

Management System Certification: ISO 14001, ISO 9001, OHSAS/ OHSMS 18001, QHSE

Main Products: Dryer, Extruder, Heater, Twin Screw Extruder, Electrochemical Corrosion Protection Equ, Screw, Mixer, Pelletizing Machine, Compressor, Pelletizer

Company Introduction: The Res. Inst of Chem. Mach of the Ministry of Chemical Industry was founded in ZheJiang in 1958, and moved to HangZhou in 1965.

The Res. Inst of Automation of the Ministry of Chemical Industry was founded in HangZhou in 1963.

In 1997, the Res. Inst. Of Chem. Mach of the Ministry of Chemical Industry and the Res. Inst. Of Automation of the Ministry of Chemical Industry were combined to become the Res. Inst of Chemical Machinery and Automation of the Ministry of Chemical Industry.

In 2000, the Res. Inst of Chemical Machinery and Automation of the Ministry of ChemicalIndustry completed its transformation to enterprise and registered as CHINAMFG Instituteof Chemical Machinery and Automation.

Tianhua Institute has the following subordinated institutions:

Supervision and Inspection Center of the Quality of Chemical Equipments in HangZhou, ZheJiang Province

HangZhou Equipment Institute in HangZhou, ZheJiang Province;

Automation Institute in HangZhou, ZheJiang Province;

HangZhou Ruima Chemical Machinery Co Ltd in HangZhou, ZheJiang Province;

HangZhou Ruide Drying Technology Co Ltd in HangZhou, ZheJiang Province;

HangZhouLantai Plastics Machinery Co Ltd in HangZhou, ZheJiang Province;

ZheJiang Airuike Automation Technology Co Ltd in HangZhou, ZheJiang Province;

The HangZhou United Institute of Chemical Machinery and automation and the HangZhou United Institute of Petrochemical Industry Furnaces were founded by CHINAMFG Institute and the Sinopec.

Tianhua Institute has an occupation area of 80 000m2 and a total asset of 1 Yuan (RMB). The annual output value is 1 Yuan (RMB).

Tianhua Institute has about 916 employees, 75% of them are professional personnel. Among them are 23 professors, 249senior engineers, 226 engineers. 29 professors and senior engineers enjoy national special subsidy, On 5 people the title of Middle-aged and Young Specialist with Outstanding Contribution to the P. R. China are conferred

How much energy can be recovered by a regenerative thermal oxidizer?

The amount of energy that can be recovered by a regenerative thermal oxidizer (RTO) depends on several factors, including the design of the RTO system, the operating conditions, and the specific characteristics of the exhaust gases being treated. Generally, RTOs are known for their high energy recovery efficiency, and they can recover a significant portion of the thermal energy from the exhaust gases.

Here are some key factors that influence the energy recovery potential of an RTO:

• Heat Recovery System: The design and efficiency of the heat recovery system in the RTO significantly impact the amount of energy that can be recovered. RTOs typically use ceramic media beds or heat exchangers to capture and transfer heat between the exhaust gases and the incoming untreated gases. Well-designed heat exchangers with a large surface area and good thermal conductivity can enhance the energy recovery efficiency.
• Temperature Differential: The temperature difference between the exhaust gases and the incoming untreated gases affects the energy recovery potential. The greater the temperature differential, the higher the potential for energy recovery. RTOs operating at higher temperature differentials can recover more energy compared to those with smaller differentials.
• Flow Rates and Heat Capacity: The flow rates of the exhaust gases and incoming untreated gases, as well as their respective heat capacities, are important factors in determining the energy recovery capability. Higher flow rates and larger heat capacities result in more heat available for recovery.
• Process Specifics: The specific characteristics of the industrial process and the composition of the exhaust gases being treated can influence the energy recovery potential. For example, exhaust gases with high concentrations of volatile organic compounds (VOCs) or other combustible components can provide a higher energy recovery potential.
• Efficiency and System Optimization: The efficiency of the RTO system itself, including the combustion chamber, heat exchangers, and control mechanisms, also plays a role in the energy recovery. Well-maintained and optimized RTO systems can maximize the energy recovery potential.

While it is challenging to provide an exact numerical value for the energy recovery potential of an RTO, it is not uncommon for RTOs to achieve energy recovery efficiencies in the range of 90% or higher. This means that they can recover and reuse 90% or more of the thermal energy contained in the exhaust gases, significantly reducing the need for external fuel sources.

It’s important to note that the actual energy recovery achieved by an RTO will depend on the specific operating conditions, pollutant concentrations, and other factors mentioned above. Consulting with RTO manufacturers or conducting a detailed energy analysis can provide more accurate estimations of the energy recovery potential for a particular RTO system.

Are regenerative thermal oxidizers safe to operate?

Regenerative thermal oxidizers (RTOs) are designed with safety considerations to ensure their safe operation. When properly installed, operated, and maintained, RTOs provide a high level of safety. Here are some key points regarding the safety of operating RTOs:

• Combustion and Fire Safety: RTOs are designed to safely combust and destroy volatile organic compounds (VOCs) and other pollutants in the exhaust stream. They incorporate various safety features to prevent the risk of uncontrolled fires or explosions. These features may include flame arrestors, temperature sensors, pressure relief devices, and automated shutdown systems to ensure safe operation in the event of abnormal operating conditions.
• Control and Monitoring Systems: RTOs are equipped with advanced control and monitoring systems that continuously monitor various parameters such as temperature, pressure, and flow rates. These systems provide real-time data to operators, allowing them to detect any deviations from normal operating conditions promptly. Alarms and safety interlocks are often included to alert operators and initiate appropriate actions in case of abnormal situations.
• Heat Recovery and Thermal Efficiency: RTOs are designed to maximize thermal efficiency by recovering and reusing heat generated during the oxidization process. This reduces the overall energy consumption and minimizes the risk of heat buildup within the system, contributing to safe operation and preventing excessive temperatures that could pose safety hazards.
• Equipment and Material Selection: RTOs are constructed using materials that can withstand the high temperatures and corrosive conditions encountered during operation. Heat-resistant materials, such as ceramic beds or metallic heat exchangers, are commonly used. Proper material selection ensures the integrity and longevity of the equipment, reducing the risk of failures or leaks that could compromise safety.
• Compliance with Standards and Regulations: RTOs must comply with applicable safety standards and regulations. These standards define specific requirements for the design, installation, operation, and maintenance of air pollution control systems, including RTOs. Compliance with these standards ensures that the RTOs meet the necessary safety criteria and helps safeguard the health and well-being of personnel and the surrounding environment.
• Operator Training and Maintenance: Adequate operator training and regular maintenance are crucial for safe RTO operation. Operators should receive comprehensive training on the system’s operation, safety procedures, and emergency response protocols. Additionally, routine maintenance and inspections help identify and address any potential safety concerns or equipment issues before they escalate.

While RTOs are generally safe to operate, it is essential to follow the manufacturer’s guidelines, maintain proper safety protocols, and adhere to applicable regulations to ensure safe and reliable operation.

What is the lifespan of a regenerative thermal oxidizer?

The lifespan of a regenerative thermal oxidizer (RTO) can vary depending on several factors, including the quality of the equipment, proper maintenance, operating conditions, and technological advancements. Generally, a well-designed and properly maintained RTO can have a lifespan ranging from 15 to 25 years or more.

Here are some factors that can influence the lifespan of an RTO:

• Quality of Construction: RTOs constructed with high-quality materials, such as corrosion-resistant alloys and refractory linings, tend to have a longer lifespan. Robust construction ensures durability and resistance to the harsh operating conditions often encountered in industrial processes.
• Maintenance Practices: Regular and proactive maintenance is crucial to maximize the lifespan of an RTO. This includes periodic inspections, cleaning and replacement of components, such as valves, dampers, and ceramic media beds, and monitoring of operating parameters. Adequate maintenance helps prevent premature equipment failure and ensures optimal performance.
• Operating Conditions: The operating conditions of the RTO, such as temperature, gas composition, and particulate loading, can affect its lifespan. Operating the RTO within its design parameters and avoiding excessive thermal or chemical stresses can contribute to a longer lifespan.
• Technological Advancements: Over time, technological advancements may lead to the introduction of more efficient and durable components or improvements in the overall design of RTOs. Upgrading or retrofitting an older RTO with newer technologies can extend its lifespan and enhance its performance.
• Environmental Factors: Environmental factors, such as exposure to corrosive gases, high humidity, or harsh climates, can impact the lifespan of an RTO. Proper design considerations and protective measures, such as corrosion-resistant coatings or insulation, can mitigate these effects and prolong the equipment’s lifespan.

It is important to note that the lifespan mentioned is a general estimate and can vary depending on the specific circumstances. Regular inspections, maintenance, and adherence to manufacturer’s guidelines are essential to ensure the longevity and reliable operation of an RTO.

editor by CX 2024-04-04