Basic Info.
Material
Cordierite
Application
Industry, Food and Beverage, Medicine, Textile, Metallurgy
Type
Ceramic Filter
Filter Connector
Flat Connector
Filtration Grade
ULPA Filter
Activated Carbon Filter Type
Bulk Type
Trademark
SW
Transport Package
Carton
Specification
50x50x50, 100x100x50, 595x260x95
Origin
China
HS Code
3815120090
Product Description
Description:;
Carrier:; Ceramic honeycomb substrate (cordierite monolith); or metal honeycomb substrate (stainless steel crust and Fe-Cr-Al honeycomb body);.;
Technical Data:;
Material:;Cordierite,; mullite ceramics
Size:;
50x50x50,;100x100x50,;595x260x95
Working Temperature:;220°C-1100°C
Channels:;Circular,; Square,; Rectangle
Cell Density:;
50-400 CPSI
Type:; Catalytic Converter
Usage:;
Catalytic Converter
Application:;Enameled wire,; paint room,; waste gas treatment industry.;
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Regenerative Thermal/Catalytic Oxidizer (RTO/RCO); :;
Regenerated heat/catalytic oxidant (RTO/RCO);:; it is widely used in automotive coatings,; chemical industry,; electronic and electric manufacturing industry,; contact combustion system and other fields.;Ceramic honeycomb is designated as a structural regenerative medium for RTO/RCO.;
Advantage:;
1.; Various materials and specifications
2.; Products with different formulas can be customized according to customer requirements.;
3.; Small resistance loss
4.; Low thermal expansion coefficient
5.; Excellent crack resistance
6.; It can be customized to meet the emission standards of different countries.;
Applications:;
1.; It can be used as a heat exchanger in the RTO of the heat recovery device.;
2.; Can be used as a catalyst to purify automobile exhaust and motorcycle exhaust to remove odor.;
3.; Applicable to food service industry,; environmental protection industry,; metallurgy industry,; etc
Test Equipment:;
Particle size distribution tester
Aperture and specific surface meter
Metal distribution,; crystalline structure
Catalyst activity evaluation system
Production Equipment:;
Coating continuous microwave drying system
Slurry nanometer grinding preparation system
Slurry quantitative spraying system
RFQ:;
Q:;Are you a trading company or a manufacturer?
A:;We are professional manufacturer which has almost 20 years of experience in this industry.;
Q:;Can you produce according to the samples?
A:;Yes,;we can produce by your samples or technical drawings.;
Q:;Would it be possible for us to visit your factory?
A:;Sure,;we welcomed our customers visit our factory in any time.;
Q:;Will your company supply samples?
A:;Yes,;the sample expense will be deducted from the value of your order.;
Q:;What’s your payment terms?
A:;T/T,; L/C,; Western Union,; Money Gram,; are available for us.;
Q:;Delivery time for my order?
A:;Within 7-15 working days for your sample order; 20 working days for your bulk order( It depends on the models and quantity you are going to order);.;
Address: Room. 3902-2 TianAn CHINAMFG Town No. 228 Ling Lake Avenue, New Wu District, HangZhou City, ZheJiang Province, China.
Business Type: Manufacturer/Factory, Group Corporation
Business Range: Auto, Motorcycle Parts & Accessories, Chemicals, Industrial Equipment & Components, Manufacturing & Processing Machinery
Management System Certification: ISO 9001, ISO 14001, ISO 20000, IATF16949
Main Products: Honeycomb Catalytic, Three Way Catalytic, Chemical Catalytic, Exhaust Filter, Industrial Catalytic
Company Introduction: Established in 2003, Sheung Well International Corp. Is a professional enterprise specialized in developing, manufacturing, selling automotive vehicles, Universal fuel engine and industrial three-way catalyst and converters, four-way converters. With independent intellectual property rights, its technology has been approved by ISO9001, TS16949 quality and management systems.
Sheung Well is an all-round designer and manufacturer who has a innovative and quality managing team mainly consists of doctorates and masters. Based on its cutting edge technology, rich experience and modern production and quality management skills, CHINAMFG is providing customers with first-class products and services.
Oriented in market, with innovation as its soul, centralized in serving the society, CHINAMFG lays emphasis on developing technology and products of controlling Exhaust emissions and other industrial catalysts. By providing customers with technology and supports of new products, it is committed to becoming the word-class all-around enterprise in catalyst circle from home and abroad.
What is the difference between a regenerative thermal oxidizer and a thermal oxidizer?
A regenerative thermal oxidizer (RTO) and a thermal oxidizer are both types of air pollution control devices used for the treatment of volatile organic compounds (VOCs) and other air pollutants. While they share the same purpose, there are distinct differences between the two technologies.
Here are the key differences between a regenerative thermal oxidizer and a thermal oxidizer:
- Operating Principle: The fundamental difference lies in the operating principle. A thermal oxidizer operates by using high temperature alone to oxidize and destroy pollutants. It typically relies on a burner or other heat sources to raise the temperature of the exhaust gases to the required level for combustion. In contrast, an RTO utilizes a regenerative heat exchanger system to preheat the incoming exhaust gases by capturing and transferring heat from the outgoing gases. This heat exchange mechanism significantly improves the overall energy efficiency of the system.
- Heat Recovery: Heat recovery is a distinctive feature of an RTO. The regenerative heat exchanger in an RTO allows for the recovery of a significant amount of heat from the outgoing gases. This recovered heat is then used to preheat the incoming gases, reducing the energy consumption of the system. In a typical thermal oxidizer, heat recovery is limited or absent, resulting in higher energy requirements.
- Energy Efficiency: Due to the heat recovery mechanism, RTOs are generally more energy-efficient compared to traditional thermal oxidizers. The regenerative heat exchanger in an RTO allows for thermal efficiencies of 95% or higher, meaning that a significant portion of the energy input is recovered and utilized within the system. Thermal oxidizers, on the other hand, typically have lower thermal efficiencies.
- Operating Costs: The higher energy efficiency of RTOs translates into lower operating costs over the long term. The reduced energy consumption can result in significant savings in fuel or electricity expenses compared to thermal oxidizers. However, the initial capital investment for an RTO is generally higher than that of a thermal oxidizer due to the complexity of the regenerative heat exchanger system.
- Control of Pollutant Concentrations: RTOs are better suited for handling variable pollutant concentrations compared to thermal oxidizers. The regenerative heat exchanger system in an RTO allows for better control and adjustment of operating parameters to accommodate fluctuations in pollutant concentrations. Thermal oxidizers are typically less adaptable to varying pollutant loads.
In summary, the main differences between a regenerative thermal oxidizer and a thermal oxidizer lie in the operating principle, heat recovery capabilities, energy efficiency, operating costs, and control of pollutant concentrations. RTOs offer higher energy efficiency, better control of pollutant concentrations, and lower operating costs, but they require a higher initial investment compared to traditional thermal oxidizers.
Can regenerative thermal oxidizers handle high-temperature exhaust streams?
Regenerative thermal oxidizers (RTOs) are designed to handle high-temperature exhaust streams efficiently. They are capable of accommodating exhaust gases with elevated temperatures and effectively treating them for pollutant removal. Here are some key points regarding the handling of high-temperature exhaust streams in RTOs:
- Thermal Stability: RTOs are constructed using materials that can withstand high temperatures, typically ranging from 800 to 1,500 degrees Celsius (1,472 to 2,732 degrees Fahrenheit). The combustion chamber, heat exchangers, and other components are designed to maintain their structural integrity and thermal stability under these conditions.
- Heat Recovery: One of the primary advantages of RTOs is their ability to recover and reuse heat from the high-temperature exhaust streams. The heat exchangers within the RTO capture the thermal energy from the outgoing exhaust gases and transfer it to the incoming process air or gas stream. This heat recovery process improves the overall energy efficiency of the system and reduces the need for additional fuel consumption.
- Effective Combustion: RTOs are equipped with combustion chambers where the high-temperature exhaust gases are directed. In the combustion chamber, the pollutants in the exhaust stream are oxidized at high temperatures, typically above the autoignition temperature of the pollutants. This ensures effective destruction of the pollutants, even in high-temperature environments.
- Heat Exchange: RTOs utilize a regenerative heat exchange system, which allows for the efficient transfer of heat between the incoming and outgoing gas streams. The heat exchange media within the RTO alternately absorbs and releases heat, enabling the preheating of the incoming gases and cooling of the outgoing gases. This heat exchange process helps maintain the desired operating temperatures within the RTO while maximizing energy recovery.
- System Design Considerations: When handling high-temperature exhaust streams, proper system design is crucial. Factors such as the choice of materials, insulation, and thermal expansion considerations are taken into account to ensure safe and efficient operation at elevated temperatures. Additionally, temperature monitoring and control systems are implemented to maintain optimal operating conditions.
It is important to note that the specific temperature limits and capabilities of an RTO may vary depending on the design, materials used, and the specific requirements of the application. Consulting with experienced engineers or RTO manufacturers can provide valuable insights into the suitability of an RTO for handling a particular high-temperature exhaust stream.
Overall, RTOs are well-suited for handling high-temperature exhaust streams, offering effective pollutant destruction, heat recovery, and energy efficiency in industrial applications.
How does a regenerative thermal oxidizer work?
A regenerative thermal oxidizer (RTO) is an advanced air pollution control device that operates through a cyclical process to remove volatile organic compounds (VOCs), hazardous air pollutants (HAPs), and other airborne contaminants from exhaust gases. Here’s a detailed explanation of how an RTO works:
1. Inlet Plenum: The exhaust gases containing pollutants enter the RTO through the inlet plenum.
2. Heat Exchanger Beds: The RTO contains multiple heat exchanger beds filled with heat storage media, typically ceramic materials or structured packing. The heat exchanger beds are arranged in pairs.
3. Flow Control Valves: Flow control valves direct the airflow and control the direction of the exhaust gases through the RTO.
4. Combustion Chamber: The exhaust gases, now directed into the combustion chamber, are heated to a high temperature, typically between 1400°F (760°C) and 1600°F (870°C). This temperature range ensures effective thermal oxidation of the pollutants.
5. VOC Destruction: The high temperature in the combustion chamber causes the VOCs and other contaminants to react with oxygen, resulting in their thermal decomposition or oxidation. This process breaks down the pollutants into water vapor, carbon dioxide, and other harmless gases.
6. Heat Recovery: The hot, purified gases leaving the combustion chamber pass through the outlet plenum and flow through the heat exchanger beds that are in the opposite phase of operation. The heat storage media in the beds absorb heat from the outgoing gases, which preheats the incoming exhaust gases.
7. Cycle Switching: After a specific time interval, the flow control valves switch the airflow direction, allowing the heat exchanger beds that were preheating the incoming gases to now receive the hot gases from the combustion chamber. The cycle then repeats, ensuring continuous and efficient operation.
Advantages of a regenerative thermal oxidizer:
RTOs offer several advantages in industrial air pollution control:
1. High Efficiency: RTOs can achieve high destruction efficiencies, typically above 95%, effectively removing a wide range of pollutants.
2. Energy Recovery: The heat recovery mechanism in RTOs allows for significant energy savings. The preheating of incoming gases reduces the fuel consumption required for combustion, making RTOs energy-efficient.
3. Cost-effectiveness: Although the initial capital investment for an RTO can be significant, the long-term operational cost savings through energy recovery and high destruction efficiencies make it a cost-effective solution over the lifespan of the system.
4. Environmental Compliance: RTOs are designed to meet stringent emissions regulations and help industries comply with air quality standards and permits.
5. Versatility: RTOs can handle a wide range of process exhaust volumes and pollutant concentrations, making them suitable for various industrial applications.
Overall, a regenerative thermal oxidizer operates by utilizing heat recovery, high-temperature combustion, and cyclical flow control to effectively oxidize pollutants and achieve high destruction efficiencies while minimizing energy consumption.
editor by CX 2024-01-30