China Good quality Rto Rotary Type Regenerative Thermal Oxidizer

Maklumat Asas.

Model NO.

RTO yang menakjubkan

taip

Insinerator

Kecekapan Tinggi

100

Penjimatan Tenaga

100

Penyelenggaraan Rendah

100

Operasi Mudah

100

Tanda dagangan

Bjamazing

Pakej Pengangkutan

Luar negara

Spesifikasi

111

asal usul

China

Kod HS

2221111

Penerangan Produk

RTO

Pengoksida Terma Penjanaan Semula

Berbanding dengan pembakaran pemangkin tradisional,; pengoksida haba langsung,; RTO mempunyai merit kecekapan pemanasan yang tinggi,; kos operasi yang rendah,; dan keupayaan untuk merawat gas buangan kepekatan rendah fluks besar.; Apabila kepekatan VOC tinggi,; kitar semula haba sekunder boleh direalisasikan,; yang akan mengurangkan kos operasi.; Kerana RTO boleh memanaskan gas sisa mengikut tahap melalui penumpuk haba seramik,; yang boleh membuat gas buangan dipanaskan sepenuhnya dan retak tanpa sudut mati (kecekapan rawatan> 99%);,; yang mengurangkan NOX dalam gas yang meletihkan,; jika ketumpatan VOC >1500mg/Nm3,; apabila gas buangan mencapai kawasan retak,; ia telah dipanaskan sehingga suhu retak oleh penumpuk haba,; penunu akan ditutup di bawah keadaan ini.;

RTO boleh dibahagikan kepada jenis ruang dan jenis berputar mengikut mod operasi perbezaan.; RTO jenis Rotary mempunyai kelebihan dalam tekanan sistem,; kestabilan suhu,; jumlah pelaburan,; dll

Pengoksida Terma Penjanaan Semula,; Pengoksida Terma Penjanaan Semula,; Pengoksida Terma Penjanaan Semula,; Pengoksida Terma,; Pengoksida Terma,; Pengoksida Terma,; pengoksida,; pengoksida,; pengoksida,; insinerator,; insinerator,; insinerator,; rawatan gas buangan,; rawatan gas buangan,; rawatan gas buangan,; rawatan VOC,; rawatan VOC,; rawatan VOC,; RTO,; RTO,; RTO,; Rotary RTO,; Rotary RTO,; Rotary RTO,; RTO Dewan,; RTO Dewan,; RTO Dewan

Alamat: tingkat 8, E1, bangunan Pinwei, jalan Dishengxi, Yizhuang, ZheJiang, China

Jenis Perniagaan: Pengeluar/Kilang, Syarikat Perdagangan

Julat Perniagaan: Elektrik & Elektronik, Peralatan & Komponen Industri, Jentera Pembuatan & Pemprosesan, Metalurgi, Mineral & Tenaga

Pensijilan Sistem Pengurusan: ISO 9001, ISO 14001

Produk Utama: Rto, Talian Salutan Warna, Talian Galvanisasi, Pisau Udara, Alat Ganti untuk Talian Pemprosesan, Coater, Peralatan Bebas, Gulung Sink, Projek Ubahsuai, Blower

Pengenalan Syarikat: ZheJiang Amazing Science & Technology Co., Ltd ialah sebuah syarikat berteknologi tinggi yang berkembang maju, terletak di ZheJiang Economic and Technological Development Area(BDA). Berpegang kepada konsep Realistik, Inovatif, Fokus dan Cekap, syarikat kami menyediakan perkhidmatan terutamanya dalam industri rawatan gas sisa (VOC) dan peralatan metalurgi China dan juga seluruh dunia. Kami mempunyai teknologi canggih dan pengalaman yang kaya dalam projek rawatan gas buangan VOC, yang rujukannya telah berjaya digunakan untuk industri salutan, getah, elektronik, percetakan, dll. Kami juga mempunyai pengumpulan teknologi selama bertahun-tahun dalam penyelidikan dan pembuatan flat talian pemprosesan keluli, dan mempunyai hampir 100 contoh aplikasi.

Syarikat kami menumpukan pada penyelidikan, reka bentuk, pengilangan, pemasangan dan pentauliahan sistem rawatan gas sisa organik VOC dan projek merombak dan mengemas kini untuk penjimatan tenaga dan perlindungan alam sekitar barisan pemprosesan keluli rata. Kami boleh menyediakan pelanggan penyelesaian lengkap untuk perlindungan alam sekitar, penjimatan tenaga, peningkatan kualiti produk dan aspek lain.

Kami juga terlibat dalam pelbagai alat ganti dan peralatan bebas untuk garis salutan warna, garis galvanizing, garis penjerukan, seperti penggelek, pengganding, penukar haba, recuperator, pisau udara, peniup, pengimpal, penyamara ketegangan, pas kulit, sambungan pengembangan, ricih, penyambung , penjahit, penunu, tiub berseri, motor gear, pengurang, dsb.

What is the role of heat recovery in a regenerative thermal oxidizer?

Heat recovery plays a crucial role in the operation of a regenerative thermal oxidizer (RTO) by improving its energy efficiency and reducing fuel consumption. The primary function of heat recovery in an RTO is to capture and transfer heat from the treated exhaust gases to the incoming untreated gases, minimizing the need for additional external heating.

Here’s a closer look at the role of heat recovery in an RTO:

• Energy Efficiency: RTOs are designed to achieve high thermal efficiency by utilizing the heat recovery principle. The heat recovery system consists of heat exchangers or beds filled with ceramic media, such as structured ceramic blocks or random ceramic saddles. These beds alternate between the exhaust gas flow and the incoming untreated gas flow.
• Heat Transfer Process: During operation, the hot exhaust gases from the industrial process flow through one bed of the heat exchanger, transferring heat to the ceramic media. The media absorbs the heat, and the temperature of the exhaust gases decreases. Simultaneously, the cooler incoming untreated gas flows through the other bed, where it absorbs the heat stored in the media, preheating the gas before it enters the combustion chamber.
• Bed Switching: The direction of gas flow through the beds is periodically switched using valves or dampers. This switching operation allows the RTO to alternate between different beds, ensuring continuous heat recovery and thermal oxidation of the pollutants. By efficiently recovering and reusing heat from the exhaust gases, the RTO reduces the amount of external fuel needed to maintain the required operating temperature.
• Reduction in Fuel Consumption: The heat recovery mechanism in an RTO significantly reduces the fuel consumption compared to other types of oxidizers. The preheating of the incoming untreated gas stream reduces the energy required to raise the temperature of the gas to the combustion temperature, resulting in lower fuel usage and operational costs.
• Economic and Environmental Benefits: Heat recovery in RTOs offers economic benefits by reducing energy costs and improving the overall sustainability of the facility. By minimizing fuel consumption, heat recovery contributes to a lower carbon footprint and helps meet environmental goals by reducing greenhouse gas emissions associated with the combustion process.

The effectiveness of heat recovery in an RTO depends on factors such as the design of the heat exchanger, the choice of ceramic media, the flow rates of the exhaust gases and incoming untreated gas, and the temperature differential between the two streams. Proper sizing and optimization of the heat recovery system are essential to ensure efficient heat transfer and maximize energy savings.

Overall, heat recovery is a key component in the design of an RTO, allowing for improved energy efficiency, reduced fuel consumption, and environmental sustainability.

Are regenerative thermal oxidizers suitable for controlling emissions from printing presses?

Yes, regenerative thermal oxidizers (RTOs) can be suitable for controlling emissions from printing presses. Printing presses can emit volatile organic compounds (VOCs) and other air pollutants during the printing process, which need to be properly controlled to comply with environmental regulations and ensure air quality. Here are some key points regarding the suitability of RTOs for controlling emissions from printing presses:

• Kawalan pelepasan: RTOs are designed to achieve high destruction efficiencies for VOCs and hazardous air pollutants (HAPs). These pollutants are oxidized within the RTO at high temperatures, typically above 95% efficiency, converting them into carbon dioxide (CO₂) and water vapor. RTOs effectively control and reduce emissions from printing presses.
• Compatibility: RTOs can be integrated into the exhaust system of printing presses, capturing and treating the emissions before they are released into the atmosphere. The RTO is typically connected to the exhaust stack of the printing press, allowing the VOC-laden air to pass through the oxidizer for treatment.
• High Flow Rates: Printing presses can generate significant exhaust volumes due to the printing process. RTOs are designed to handle high flow rates and can accommodate the varying exhaust volumes of printing presses. This ensures effective treatment of emissions even during peak production periods.
• Kapasiti Terma: RTOs have the thermal capacity to handle the temperature variations in printing press emissions. The printing process can result in varying exhaust temperatures, and RTOs are designed to operate effectively within a wide range of temperature conditions.
• Energy Efficiency: RTO menggabungkan sistem pertukaran haba yang membolehkan pemulihan dan penggunaan semula tenaga haba. Penukar haba dalam RTO menangkap haba daripada gas ekzos yang keluar dan memindahkannya ke aliran udara atau gas proses masuk. Proses pemulihan haba ini meningkatkan kecekapan tenaga keseluruhan sistem dan mengurangkan keperluan untuk penggunaan bahan api tambahan.
• Pematuhan dengan Peraturan: Printing press emissions are subject to regulatory requirements for air quality and emissions control. RTOs are capable of achieving the necessary destruction efficiencies and can help printing press operators comply with environmental regulations. The use of RTOs demonstrates a commitment to sustainable practices and responsible management of air emissions.

It is important to note that the specific design and configuration of the RTO, as well as the characteristics of the printing press emissions, should be considered when implementing an RTO for a printing press application. Consulting with experienced engineers or RTO manufacturers can provide valuable insights into the proper sizing, integration, and performance requirements for controlling emissions from printing presses.

In summary, RTOs are a suitable technology for controlling emissions from printing presses, providing high destruction efficiencies, compatibility with printing press exhaust systems, handling high flow rates and temperature variations, energy efficiency through heat recovery, and compliance with environmental regulations.

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. Pemulihan Haba: 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 2024-04-17