China high quality Regenerative Thermal Oxidizer (RTO) - RTO

Maklumat Asas.

Model NO.

RTO

Kaedah Pemprosesan

Pembakaran

Punca Tarikan

Kawalan Pencemaran Udara

Tanda dagangan

RUIMA

asal usul

China

Kod HS

84213990

Penerangan Produk

Pengoksida Terma Penjanaan Semula (RTO);
Teknik pengoksidaan yang paling banyak digunakan pada masa kini untuk
Pengurangan pelepasan VOC,; sesuai untuk merawat pelbagai pelarut dan proses.; Bergantung pada isipadu udara dan kecekapan penulenan yang diperlukan,; RTO datang dengan 2,; 3,; 5 atau 10 bilik.;

Kelebihan
Pelbagai VOC untuk dirawat
Kos penyelenggaraan yang rendah
Kecekapan Terma Tinggi
Tidak menjana sebarang pembaziran
Boleh disesuaikan untuk kecil,; aliran udara sederhana dan besar
Pemulihan Haba melalui pintasan jika kepekatan VOC melebihi titik auto-terma

Auto-terma dan Pemulihan Haba:;
Kecekapan Terma > 95%
Titik auto-terma pada 1.;2 – 1.;7 mgC/Nm3
Julat aliran udara dari 2,; 000 hingga 200,; 000m3/j

Kemusnahan VOC yang tinggi
Kecekapan penulenan biasanya melebihi 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 Kementerian Industri Kimia telah diasaskan di HangZhou pada tahun 1963.

Pada tahun 1997, Res. Inst. Daripada Chem. Mach Kementerian Industri Kimia dan Res. Inst. Automasi Kementerian Industri Kimia telah digabungkan untuk menjadi Res. Inst of Chemical Machinery and Automation of Kementerian Industri Kimia.

Pada tahun 2000, Res. Inst of Chemical Machinery and Automation of Ministry of ChemicalIndustry menyelesaikan transformasinya kepada perusahaan dan didaftarkan sebagai CHINAMFG Instituteof Chemical Machinery and Automation.

Institut Tianhua mempunyai institusi subordinat berikut:

Pusat Penyeliaan dan Pemeriksaan Kualiti Peralatan Kimia di HangZhou, Wilayah ZheJiang

Institut Peralatan HangZhou di HangZhou, Wilayah ZheJiang;

Institut Automasi di HangZhou, Wilayah ZheJiang;

HangZhou Ruima Chemical Machinery Co Ltd di HangZhou, Wilayah ZheJiang;

HangZhou Ruide Drying Technology Co Ltd di HangZhou, Wilayah ZheJiang;

HangZhouLantai Plastics Machinery Co Ltd di HangZhou, Wilayah ZheJiang;

ZheJiang Airuike Automation Technology Co Ltd di HangZhou, Wilayah ZheJiang;

Institut Jentera Kimia dan automasi HangZhou United dan Institut Relau Industri Petrokimia HangZhou United diasaskan oleh Institut CHINAMFG dan Sinopec.

Institut Tianhua mempunyai kawasan pekerjaan seluas 80 000m2 dan jumlah aset 1 Yuan (RMB). Nilai keluaran tahunan ialah 1 Yuan (RMB).

Institut Tianhua mempunyai kira-kira 916 pekerja, 75% daripada mereka adalah kakitangan profesional. Antaranya ialah 23 profesor, 249jurutera kanan, 226 jurutera. 29 profesor dan jurutera kanan menikmati subsidi khas negara, Kepada 5 orang gelaran Pakar Pertengahan Umur dan Muda dengan Sumbangan Cemerlang kepada RR China dianugerahkan

pengoksida terma regeneratif

What is the cost of installing a regenerative thermal oxidizer?

The cost of installing a regenerative thermal oxidizer (RTO) can vary significantly depending on several factors. These factors include the size and capacity of the RTO, the specific requirements of the application, site conditions, and any additional customization or engineering needed. However, it’s important to note that RTOs are generally considered a significant capital investment due to their complex design and high-performance capabilities.

Here are some cost considerations associated with installing an RTO:

RTO Size and Capacity: The size and capacity of the RTO, typically measured in terms of exhaust flow rate and pollutant concentration, are important cost factors. Larger RTOs capable of handling higher exhaust volumes and pollutant concentrations generally have higher upfront costs compared to smaller units.
Engineering and Customization: The engineering and customization requirements for integrating the RTO into the existing industrial process can impact the installation cost. This includes factors such as ductwork modifications, electrical connections, and any necessary process integration to ensure proper functioning of the RTO within the overall system.
Site Preparation: The site where the RTO will be installed may require preparation to accommodate the equipment. This can involve constructing foundations, providing adequate space for the RTO and associated components, and ensuring proper access for installation and maintenance.
Auxiliary Systems and Equipment: In addition to the RTO itself, there may be auxiliary systems and equipment required for effective operation. This can include pre-treatment systems, such as scrubbers or filters, heat recovery units, monitoring and control systems, and stack emissions monitoring equipment. The cost of these additional components should be considered in the overall installation cost.
Installation Labor and Equipment: The cost of labor and equipment required for the installation process, including crane services and specialized contractors, should be factored into the overall cost. The complexity of the installation and any specific site challenges can influence these costs.
Permits and Compliance: Obtaining necessary permits and complying with regulatory requirements can involve additional costs. This includes fees for environmental permits, engineering studies, emissions testing, and compliance documentation.

Due to the many variables involved, it is challenging to provide a specific cost range for installing an RTO. It is recommended to consult with reputable RTO manufacturers or engineering firms, who can assess the specific requirements of the application and provide detailed cost estimates based on the project scope.

pengoksida terma regeneratif

Bagaimanakah pengoksida terma regeneratif mengendalikan pembentukan bahan zarahan dalam sistem?

Pengoksida terma penjanaan semula (RTO) menggunakan pelbagai mekanisme untuk mengendalikan pembentukan bahan zarahan dalam sistem. Bahan zarah, seperti habuk, jelaga atau zarah pepejal lain, boleh terkumpul dari semasa ke semasa dan berpotensi menjejaskan prestasi dan kecekapan RTO. Berikut ialah beberapa cara RTO mengendalikan pembentukan bahan zarahan:

Pra-penapisan: RTO boleh menggabungkan sistem pra-penapisan, seperti siklon atau penapis beg, untuk mengeluarkan bahan zarahan yang lebih besar sebelum ia memasuki pengoksida. Pra-penapis ini menangkap dan mengumpul zarah, menghalangnya daripada memasuki RTO dan mengurangkan potensi pembentukan.
Kesan Pembersihan Diri: RTO direka bentuk untuk mempunyai kesan pembersihan diri pada media pertukaran haba. Semasa operasi RTO, aliran gas ekzos panas melalui media boleh menyebabkan zarah terbakar atau hancur, meminimumkan pengumpulannya. Suhu tinggi dan aliran bergelora membantu mengekalkan permukaan bersih pada media, mengurangkan risiko pembentukan zarah yang ketara.
Kitaran Pembersihan: RTO biasanya menggabungkan kitaran pembersihan sebagai sebahagian daripada operasi mereka. Kitaran ini melibatkan memasukkan aliran kecil udara bersih atau gas ke dalam sistem untuk membersihkan sebarang sisa zarahan. Udara pembersihan membantu menghilangkan atau membakar sebarang zarah yang melekat pada media, memastikan pembersihan berterusan.
Penyelenggaraan Berkala: Penyelenggaraan tetap adalah penting untuk mengelakkan pembentukan bahan zarahan yang berlebihan dalam RTO. Aktiviti penyelenggaraan mungkin termasuk memeriksa dan membersihkan media pertukaran haba, memeriksa dan menggantikan sebarang gasket atau pengedap yang haus, dan memantau sistem untuk sebarang tanda pengumpulan zarah. Penyelenggaraan tetap membantu memastikan prestasi optimum dan meminimumkan risiko isu operasi yang berkaitan dengan pembentukan bahan zarahan.
Pemantauan dan Penggera: RTO dilengkapi dengan sistem pemantauan yang menjejaki pelbagai parameter seperti pembezaan tekanan, suhu dan kadar aliran. Sistem ini boleh mengesan sebarang keadaan tidak normal atau penurunan tekanan yang berlebihan yang mungkin menunjukkan pembentukan bahan zarahan. Penggera dan amaran boleh dicetuskan untuk memberitahu pengendali, menggesa mereka untuk mengambil tindakan yang sewajarnya, seperti memulakan prosedur penyelenggaraan atau pembersihan.

Adalah penting untuk ambil perhatian bahawa strategi khusus yang digunakan untuk mengendalikan pembentukan bahan zarahan mungkin berbeza-beza bergantung pada reka bentuk dan konfigurasi RTO, serta ciri-ciri bahan zarahan yang dirawat. Pengilang dan pengendali RTO harus mempertimbangkan faktor-faktor ini dan melaksanakan langkah-langkah yang sesuai untuk memastikan pengurusan bahan zarahan yang berkesan dalam sistem.

Dengan menggabungkan pra-penapisan, menggunakan kesan pembersihan diri, melaksanakan kitaran pembersihan, menjalankan penyelenggaraan tetap dan menggunakan sistem pemantauan, RTO boleh mengendalikan dan mengurangkan pengumpulan bahan zarahan dengan berkesan, mengekalkan prestasi dan kecekapannya dari semasa ke semasa.

pengoksida terma regeneratif

How do regenerative thermal oxidizers compare to other air pollution control devices?

Regenerative thermal oxidizers (RTOs) are highly regarded air pollution control devices that offer several advantages over other commonly used air pollution control technologies. Here’s a comparison of RTOs with some other air pollution control devices:

Comparison	Pengoksida Terma Regeneratif (RTO)	Electrostatic Precipitators (ESPs)	Scrubbers
Kecekapan	RTOs achieve high VOC destruction efficiency, typically exceeding 99%. They are highly effective in destroying volatile organic compounds (VOCs) and hazardous air pollutants (HAPs).	ESPs are effective in collecting particulate matter, such as dust and smoke, but they are less effective in destroying VOCs and HAPs.	Scrubbers are efficient in removing certain pollutants, such as gases and particulate matter, but their performance may vary depending on the specific pollutants being targeted.
Kebolehgunaan	RTOs are suitable for a wide range of industries and applications, including high-volume exhaust gases. They can handle varying concentrations and types of pollutants.	ESPs are commonly used for particulate matter control in applications such as power plants, cement kilns, and steel mills. They are less suitable for VOC and HAP control.	Scrubbers are widely used for removing acid gases, such as sulfur dioxide (SO2) and hydrogen chloride (HCl), as well as certain odorous compounds. They are often employed in industries such as chemical manufacturing and wastewater treatment.
Energy Efficiency	RTOs incorporate heat recovery systems that allow for significant energy savings. They can achieve high thermal efficiency by preheating the incoming process air using the heat from the outgoing exhaust stream.	ESPs consume relatively low energy compared to other technologies, but they do not offer heat recovery capabilities.	Scrubbers generally consume more energy compared to RTOs and ESPs due to the energy required for liquid atomization and pumping. However, some scrubber designs may incorporate heat recovery mechanisms.
Space Requirements	RTOs typically require more space compared to ESPs and certain scrubber designs due to the need for ceramic media beds and larger combustion chambers.	ESPs have a compact design and require less space compared to RTOs and some scrubber configurations.	Scrubber designs vary in size and complexity. Certain scrubber types, such as packed bed scrubbers, may require a larger footprint compared to RTOs and ESPs.
Penyelenggaraan	RTOs generally require regular maintenance of components such as valves, dampers, and ceramic media beds. Periodic media replacement may be necessary depending on the operating conditions.	ESPs require periodic cleaning of collection plates and electrodes. Maintenance activities involve the removal of accumulated particulate matter.	Scrubbers require maintenance of liquid circulation systems, pumps, and mist eliminators. Regular monitoring and adjustment of the chemical reagents used in the scrubbing process are also necessary.

It’s important to note that the selection of an air pollution control device depends on the specific pollutants, process conditions, regulatory requirements, and economic considerations of the industrial application. Each technology has its own advantages and limitations, and it’s essential to evaluate these factors to determine the most appropriate solution for effective air pollution control.

China high quality Regenerative Thermal Oxidizer (RTO)
editor by CX 2024-03-04