China Professional Rto/Regenerative Thermal Oxidizer

Základní informace.

Model NO.

Úžasné RTO

Typ

Spalovna

Vysoká účinnost

100

Úspora energie

100

Low Maintenance

100

Easy Operation

100

Ochranná známka

Bjamazing

Přepravní balíček

Overseas

Specifikace

111

Původ

Čína

Kód HS

2221111

Popis produktu

RTO

Regenerační tepelný oxidátor

V porovnání s tradičním katalytickým spalováním; přímé tepelné okysličovadlo,; RTO má přednost ve vysoké účinnosti vytápění; nízké provozní náklady; a schopnost zpracovávat odpadní plyn s nízkou koncentrací velkého toku; Když je koncentrace VOC vysoká,; lze realizovat sekundární recyklaci tepla,; což výrazně sníží provozní náklady.; Vzhledem k tomu, že RTO může předehřívat odpadní plyn o úrovně prostřednictvím keramického akumulátoru tepla,; což by mohlo způsobit, že se odpadní plyn úplně zahřeje a popraská bez mrtvého rohu (účinnost čištění > 99 %);,;které snižují NOX ve výfukových plynech;; pokud je hustota VOC > 1500 mg/Nm3; když odpadní plyn dosáhne oblasti praskání; byla zahřátá na teplotu praskání pomocí tepelného akumulátoru; hořák bude za těchto podmínek uzavřen.;

RTO lze rozdělit na typ komory a rotační typ podle rozdílu provozního režimu.; Rotační typ RTO má výhody v systémovém tlaku,; teplotní stabilita; výše investice,; atd

Regenerative Thermal Oxidizer,; Regenerative Thermal Oxidizer,; Regenerative Thermal Oxidizer,;  Thermal Oxidizer,; Thermal Oxidizer,; Thermal Oxidizer,; oxidizer,; oxidizer,; oxidizer,; incinerator,; incinerator,; incinerator,; waste gas treatment,; waste gas treatment,; waste gas treatment,; VOC treatment,; VOC treatment,; VOC treatment,; RTO,; RTO,; RTO,; Rotary RTO,; Rotary RTO,; Rotary RTO,; Chamber RTO,; Chamber RTO,; Chamber RTO

Adresa: 8 patro, E1, budova Pinwei, Dishengxi road, Yizhuang, ZheJiang, Čína

Typ podnikání: Výrobce/Továrna, Obchodní společnost

Rozsah podnikání: Elektrika a elektronika, Průmyslová zařízení a komponenty, Stroje na výrobu a zpracování, Metalurgie, Nerosty a energie

Certifikace systému managementu: ISO 9001, ISO 14001

Hlavní produkty: Rto, barevná lakovací linka, galvanizační linka, vzduchový nůž, náhradní díly pro zpracovatelskou linku, nanášecí stroj, nezávislá zařízení, dřezový válec, projekt renovace, dmychadlo

Představení společnosti: ZheJiang Amazing Science & Technology Co., Ltd je prosperující hi-tech společnost se sídlem v oblasti hospodářského a technologického rozvoje ZheJiang (BDA). V souladu s konceptem realistického, inovativního, zaměřeného a efektivního naše společnost slouží především průmyslu zpracování odpadních plynů (VOC) a metalurgickým zařízením Číny a dokonce i celého světa. Máme pokročilou technologii a bohaté zkušenosti s projektem zpracování odpadních plynů VOCs, jehož reference byla úspěšně aplikována v průmyslu nátěrových hmot, pryže, elektroniky, polygrafie atd. Máme také roky technologické akumulace ve výzkumu a výrobě plochých linka na zpracování oceli a má téměř 100 příkladů použití.

Naše společnost se zaměřuje na výzkum, návrh, výrobu, instalaci a zprovoznění systému čištění organických odpadních plynů VOCs a projekt modernizace a aktualizace pro úsporu energie a ochranu životního prostředí linky na zpracování ploché oceli. Můžeme zákazníkům poskytnout kompletní řešení pro ochranu životního prostředí, úsporu energie, zlepšování kvality produktů a další aspekty.

Zabýváme se také různými náhradními díly a nezávislými zařízeními pro barevnou lakovací linku, galvanizační linku, mořicí linku, jako je válec, spojka, tepelný výměník, rekuperátor, vzduchový nůž, dmychadlo, svářečka, vyrovnávač napětí, skin pass, dilatační spára, smyk, spárovačka , sešívačka, hořák, sálavá trubice, převodový motor, reduktor atd.

Are regenerative thermal oxidizers noisy during operation?

Regenerative thermal oxidizers (RTOs) can generate noise during operation, but the noise levels are typically within acceptable limits and can be managed effectively. The noise produced by an RTO depends on various factors, including the specific design of the system, the size and type of fans or blowers used, and the velocity and pressure of the exhaust gases.

Here are some considerations regarding the noise produced by RTOs:

• Noise Control Measures: RTO manufacturers often incorporate noise control measures into the design of the system. These measures may include the use of silencers or sound-absorbing materials at strategic locations within the RTO to minimize noise propagation. By implementing these measures, the noise generated by the RTO can be reduced to acceptable levels.
• Location and Distance: The location of the RTO within the facility can impact the perceived noise levels. Placing the RTO in an area away from sensitive receptors, such as occupied spaces or noise-sensitive equipment, can help minimize the impact of noise on the facility’s occupants or neighboring properties.
• Enclosures and Insulation: Additional noise reduction can be achieved by enclosing the RTO in a soundproof housing or using insulation materials to dampen the noise. These enclosures or insulation can help contain and absorb the noise generated by the RTO, reducing its impact on the surrounding environment.
• Operational Considerations: Proper maintenance and regular inspections of the RTO are essential to ensure optimal performance and minimize noise generation. Malfunctioning components, worn-out bearings, or imbalanced fans can contribute to increased noise levels. By conducting routine maintenance and addressing any issues promptly, the noise levels can be kept under control.
• Regulatory Compliance: Noise regulations and guidelines may vary depending on the jurisdiction and the specific industrial sector. It is important to assess and comply with applicable noise regulations to ensure that the RTO’s operation meets the required noise limits.

Overall, while RTOs can produce noise during operation, appropriate design considerations, noise control measures, and compliance with applicable regulations can help mitigate the impact of the noise. Consulting with RTO manufacturers, acoustical engineers, or environmental consultants can provide valuable insights and recommendations for managing noise associated with RTO operation.

What are the typical construction materials used in regenerative thermal oxidizers?

Regenerative thermal oxidizers (RTOs) are constructed using various materials that can withstand the high temperatures, corrosive environments, and mechanical stresses encountered during operation. The choice of materials depends on factors such as the specific design, process conditions, and the types of pollutants being treated. Here are some typical construction materials used in RTOs:

• Heat Exchangers: The heat exchangers in RTOs are responsible for transferring heat from the outgoing exhaust gas to the incoming process air or gas stream. The construction materials for heat exchangers often include:
• Ceramic Media: RTOs commonly use structured ceramic media, such as ceramic monoliths or ceramic saddles. These materials have excellent thermal properties, high resistance to thermal shock, and good chemical resistance. Ceramic media provide a large surface area for efficient heat transfer.
• Metallic Media: Some RTO designs may incorporate metallic heat exchangers made from alloys such as stainless steel or other heat-resistant metals. Metallic media offer robustness and durability, particularly in applications with high mechanical stresses or corrosive environments.
• Combustion Chamber: The combustion chamber of an RTO is where the oxidation of pollutants takes place. The construction materials for the combustion chamber should be able to withstand the high temperatures and corrosive conditions. Commonly used materials include:
• Refractory Lining: RTOs often have refractory lining in the combustion chamber to provide thermal insulation and protection. Refractory materials, such as high-alumina or silicon carbide, are chosen for their high-temperature resistance and chemical stability.
• Steel or Alloys: The structural components of the combustion chamber, such as the walls, roof, and floor, are typically made of steel or heat-resistant alloys. These materials offer strength and stability while withstanding the high temperatures and corrosive gases.
• Ductwork and Piping: The ductwork and piping in an RTO transport the exhaust gas, process air, and auxiliary gases. The materials used for ductwork and piping depend on the specific requirements, but commonly used materials include:
• Mild Steel: Mild steel is often used for ductwork and piping in less corrosive environments. It provides strength and cost-effectiveness.
• Stainless Steel: In applications where corrosion resistance is crucial, stainless steel, such as 304 or 316 grades, may be used. Stainless steel offers excellent resistance to many corrosive gases and environments.
• Corrosion-Resistant Alloys: In highly corrosive environments, corrosion-resistant alloys like Hastelloy or Inconel may be employed. These materials provide exceptional resistance to a wide range of corrosive chemicals and gases.
• Insulation: Insulation materials are used to minimize heat loss from the RTO and ensure energy efficiency. Common insulation materials include:
• Ceramic Fiber: Ceramic fiber insulation offers excellent thermal resistance and low thermal conductivity. It is often used in RTOs to reduce heat loss and improve overall energy efficiency.
• Mineral Wool: Mineral wool insulation provides good thermal insulation and sound absorption properties. It is commonly used in RTOs to reduce heat loss and enhance safety.

It is important to note that the specific materials used in RTO construction may vary depending on factors such as the process requirements, temperature range, and corrosive nature of the gases being treated. Manufacturers of RTOs typically select appropriate materials based on their expertise and the specific application.

How do regenerative thermal oxidizers handle start-up and shutdown procedures?

Regenerative thermal oxidizers (RTOs) have specific procedures for start-up and shutdown to ensure safe and efficient operation. These procedures are designed to optimize the performance of the RTO and minimize any potential risks. Here is an overview of how RTOs handle start-up and shutdown:

• Start-up Procedure: During start-up, the RTO goes through a series of steps to reach its operating temperature. The start-up procedure typically involves the following stages:
1. Purge Stage: The RTO is purged with clean air or an inert gas to remove any potential flammable or explosive gases that may have accumulated during the shutdown period.
2. Preheat Stage: The RTO’s heat exchangers are preheated using a burner or an auxiliary heat source. This gradually increases the temperature of the heat exchange media (typically ceramic or metallic beds) and the combustion chamber.
3. Heat Soak Stage: Once the heat exchangers reach a certain temperature, the RTO enters the heat soak stage. In this stage, the heat exchangers are fully heated, and the RTO operates in a self-sustaining mode, with the combustion chamber temperature being maintained primarily by the heat released from the oxidation of pollutants in the exhaust gas.
4. Normal Operation: After the heat soak stage, the RTO is considered to be in normal operation mode, where it maintains the desired operating temperature and treats the exhaust gas containing pollutants.
• Shutdown Procedure: The shutdown procedure of an RTO is aimed at safely and efficiently stopping the operation of the system. The procedure typically involves the following steps:
1. Cool Down: The RTO is gradually cooled down by reducing the flow of the exhaust gas and the supply of combustion air. This helps to prevent thermal stress on the equipment and minimize the risk of fires or other safety hazards.
2. Rekuperace tepla: During the cool-down phase, the RTO may employ heat recovery techniques to capture and utilize the residual heat for other purposes, such as preheating incoming process air or water.
3. Purge: Once the RTO has cooled down sufficiently, a purge cycle is initiated to remove any residual gases or contaminants from the system. This helps to ensure a clean and safe environment for maintenance activities or subsequent start-ups.
4. Complete Shutdown: After the purge cycle, the RTO is considered to be in a fully shut-down state, and it can remain in this state until the next start-up is initiated.

It is important to note that the specific start-up and shutdown procedures for an RTO may vary depending on the design and manufacturer. Manufacturers typically provide detailed guidelines and instructions for operating their specific RTO models, and it is crucial to follow these guidelines to ensure safe and efficient operation.

editor by CX 2024-02-21