China Professional Regenerative/Recuperative Thermal Oxidizer Rto for Voc Treatment

Základní informace.

Model NO.

Úžasné RTO

Typ

Spalovna

Úspora energie

100

Snadná obsluha

100

Vysoká účinnost

100

Méně údržby

100

Ochranná známka

Bjamazing

Přepravní balíček

Zámořské dřevěné

Specifikace

180*24

Původ

Čína

Kód HS

8416100000

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

Rekuperační tepelné okysličovadlo:;

V porovnání s pecí s katalytickým spalováním a regenerativní tepelnou oxidací; investice do rekuperačního tepelného okysličovadla jsou nižší; Systém rekuperačního tepelného okysličovadla může být navržen pro celý spalovací systém i nový vzduchový systém,; který je vhodnější pro výrobní charakteristiky nátěrových jednotek pro desku stavebních hmot.;

Regenerační termální oxidátor,; Regenerační termální oxidátor,; Rekuperační tepelný oxidátor,; rekuperační tepelný oxidátor,; rekuperační tepelný oxidátor,; Tepelný oxidátor,; oxidační činidlo; oxidační činidlo; oxidační činidlo; spalovna,; spalovna,; spalovna,; čištění odpadních plynů; čištění odpadních plynů; čištění odpadních plynů; úprava VOC; úprava VOC; úprava VOC; RTO,; RTO,; RTO,; RTO,; RTO,; 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.

Can a regenerative thermal oxidizer be retrofitted into an existing facility?

Yes, regenerative thermal oxidizers (RTOs) can be retrofitted into existing facilities under certain conditions. Retrofitting an RTO involves integrating the system into the existing infrastructure and process flow of the facility to control emissions from industrial processes. However, the feasibility of retrofitting an RTO depends on several factors related to the facility and the specific requirements of the application.

Here are some considerations for retrofitting an RTO into an existing facility:

• Space Availability: RTOs typically require a significant amount of physical space for installation. It’s important to assess whether the facility has adequate space to accommodate the size and layout requirements of the RTO system. This includes considering the space needed for the RTO unit itself, associated ductwork, auxiliary systems, and access for maintenance.
• Process Integration: Retrofitting an RTO involves integrating the system into the existing industrial process. This integration may require modifications to the process flow, such as rerouting ductwork, adding or modifying exhaust points, or coordinating with existing pollution control equipment. The compatibility of the RTO with the existing process and the ability to seamlessly integrate the system should be evaluated.
• Auxiliary Systems: In addition to the RTO unit, auxiliary systems may be required for effective operation and compliance. These systems can include pre-treatment equipment such as scrubbers or filters, heat recovery units, monitoring and control systems, and stack emissions monitoring equipment. The availability of space and compatibility with existing infrastructure should be considered for accommodating these auxiliary systems.
• Utility Requirements: RTOs have specific utility requirements, such as the need for natural gas or electricity for heating the combustion chamber and operating the control system. The availability and capacity of utilities at the existing facility should be assessed to ensure they can meet the demands of the RTO system.
• Structural Considerations: The structural integrity of the facility should be evaluated to determine if it can support the additional weight of the RTO and associated equipment. This assessment may involve consulting with structural engineers and considering any necessary reinforcements or modifications.
• Regulatory Compliance: Retrofitting an RTO may require obtaining permits and complying with environmental regulations. It is essential to assess the applicable regulations and ensure that the retrofit meets the necessary compliance requirements for emissions control.

It is important to consult with experienced engineering firms or RTO manufacturers who can assess the specific requirements and constraints of the facility. They can provide detailed evaluations, feasibility studies, and design recommendations for retrofitting an RTO into an existing facility. Their expertise can help ensure that the retrofit is successful, cost-effective, and compliant with environmental regulations.

How do regenerative thermal oxidizers handle particulate matter buildup in the system?

Regenerative thermal oxidizers (RTOs) employ various mechanisms to handle particulate matter buildup in the system. Particulate matter, such as dust, soot, or other solid particles, can accumulate over time and potentially affect the performance and efficiency of the RTO. Here are some ways RTOs handle particulate matter buildup:

• Pre-filtration: RTOs can incorporate pre-filtration systems, such as cyclones or bag filters, to remove larger particulate matter before it enters the oxidizer. These pre-filters capture and collect the particles, preventing them from entering the RTO and reducing the potential for buildup.
• Self-Cleaning Effect: RTOs are designed to have a self-cleaning effect on the heat exchange media. During the operation of the RTO, the flow of hot exhaust gases through the media can cause the particles to burn or disintegrate, minimizing their accumulation. The high temperatures and turbulent flow help maintain clean surfaces on the media, reducing the risk of significant particulate buildup.
• Purge Cycle: RTOs typically incorporate purge cycles as part of their operation. These cycles involve introducing a small flow of clean air or gas into the system to purge any residual particulate matter. The purge air helps dislodge or burn off any particles adhering to the media, ensuring their continuous cleaning.
• Periodic Maintenance: Regular maintenance is essential to prevent excessive particulate matter buildup in the RTO. Maintenance activities may include inspecting and cleaning the heat exchange media, checking and replacing any worn-out gaskets or seals, and monitoring the system for any signs of particulate accumulation. Regular maintenance helps ensure optimal performance and minimizes the risk of operational issues associated with particulate matter buildup.
• Monitoring and Alarms: RTOs are equipped with monitoring systems that track various parameters such as pressure differentials, temperatures, and flow rates. These systems can detect any abnormal conditions or excessive pressure drops that may indicate particulate matter buildup. Alarms and alerts can be triggered to notify operators, prompting them to take appropriate action, such as initiating maintenance or cleaning procedures.

It is important to note that the specific strategies employed to handle particulate matter buildup may vary depending on the design and configuration of the RTO, as well as the characteristics of the particulate matter being treated. RTO manufacturers and operators should consider these factors and implement appropriate measures to ensure the effective management of particulate matter in the system.

By incorporating pre-filtration, utilizing the self-cleaning effect, implementing purge cycles, conducting regular maintenance, and employing monitoring systems, RTOs can effectively handle and mitigate particulate matter buildup, maintaining their performance and efficiency over time.

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 2024-03-22