China high quality 100% Safe Regenerative Thermal Oxidizer Rto for Pharmaceutical / Chemical / Petrochemical / Coating - RTO

معلومات اساسية.

نموذج رقم.

LC-RTO

Certification

ISO

Installation
Method

Horizontal

Operation
يكتب

Manually

Medium Material

Metal Fiber

Dust Collecting Method

Dry

Saving

1 M / h.;

خصائص الأداء
حجم الهواء للمعالجة من 2nm3/h

التركيز ≥ 1000 ملغم / م3

Model	Air volume (m³/h);	مقاس (mm);	Burner(thousand Kcal);
LC-RTO -50	5000	5280&ast;1790&ast;3910	250
LC-RTO -100	10000	6150&ast;2380&ast;4030	550
LC-RTO -150	15000	7050&ast;2830&ast;4310	750
LC-RTO -200	20000	7980&ast;3150&ast;4610	1000
LC-RTO -300	30000	10650&ast;4260&ast;4950	1350
LC-RTO -400	40000	12560&ast;4720&ast;5460	2000
LC-RTO -500	50000	14200&ast;5260&ast;5860	2000

FAQ:;

أسئلة وأجوبة العملاء

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العنوان: 316، رقم 331، طريق تشنغنان، شارع لانتشنغ، مدينة هانغتشو، مقاطعة تشجيانغ

نوع العمل: مصنع/شركة مصنعة

نطاق العمل: المعدات والمكونات الصناعية

المنتجات الرئيسية: توليد الطاقة من حرق النفايات، حرق النفايات، توليد الطاقة المتجددة، محطة توليد الطاقة من حرق النفايات، محرقة النفايات، الطاقة

مقدمة عن الشركة: شركة HangZhou Lancheng Environmental Protection Technology المحدودة، التي تقع في مدينة HangZhou، مدينة HangZhou، مقاطعة ZheJiang، هي شركة ذات تكنولوجيا عالية تجمع بين البحث العلمي والتصميم والإنتاج والمبيعات. تسعى الشركة إلى الابتكار من خلال البحث العلمي، والبقاء من خلال الجودة والتطوير من خلال السمعة. بفضل مستواها المهني وتقنيتها الناضجة في مجال حماية البيئة، فإنها ترتفع بسرعة. رضا العملاء عن المنتجات هو هدفنا الدائم.

برأس مال مسجل يبلغ 20 مليون يوان، تمتلك الشركة أكثر من 2000 قاعدة إنتاج حديثة في منطقة هانغتشو هونغ كونغ الصناعية، مدينة هانغتشو، مدينة هانغتشو، مقاطعة تشجيانغ. وقد صمم مصممو المعالجة البيئية من الدرجة الأولى في الشركة مخططات معالجة مستهدفة من جوانب عقلانية النظام والابتكار التكنولوجي واقتصاد المدخلات والمخرجات لمختلف ظروف العمل المعقدة، وذلك لجعل مؤشرات الانبعاثات تلبي معايير الانبعاثات الوطنية.

المنتجات الرئيسية للشركة هي: 1. غاز النفايات العضوية؛ الكربون المنشط، RTO، RCO، عداء الزيوليت، صندوق الفلتر الجاف، إلخ. 2. الغبار؛ المرسب الكهروستاتيكي، مرشح كيس النبض وغيرها من المعدات. 3. المعدات الصيدلانية؛ معدات التجفيف، معدات الخلط، معدات التحبيب، معدات التكسير. 4. الأسلاك المجلفنة بالغمس الساخن. 5. معدات معالجة مياه الصرف الصناعي، إلخ.

تم استخدام معداتنا بنجاح في الصناعة الكيميائية، والخبز، والطلاء، والطلاء الكهربائي، وحرق النفايات، والطباعة، والمطاعم، والبلديات وغيرها من الصناعات. في الوقت الحاضر، يمكن للشركة صياغة مخطط معالجة مثالي وفقًا للوضع الحالي لتصريف مياه الصرف الصحي في المؤسسة، واستخدام التكنولوجيا الحاصلة على براءة اختراع الحالية لتطوير المنتجات الأكثر ملاءمة. سنقدم لك أفضل الحلول ذات الجودة مع أحدث التقنيات وأكثر المواقف صدقًا.

تتخذ الشركة دائمًا "النحت بعناية وإنشاء منتجات عالية الجودة" كغرض للمؤسسة، وتتخذ دائمًا "النمو إلى أقوى مؤسسة لحماية البيئة في منطقة شيهو (بحيرة الغرب)" كهدف للمؤسسة. في السنوات الأخيرة، مع الاهتمام المتزايد من الدولة بحماية البيئة، أصبحت "إدارة الغلاف الجوي وتجميل البيئة وإفادة البشرية" مهمتنا طويلة الأمد. استجابة لدعوة سياسة "الحفاظ على الطاقة والحد من الانبعاثات" الوطنية، قدمت شركة حماية البيئة في المدينة الزرقاء مساهمات مناسبة لإحياء حماية البيئة في الصين وبناء مجتمع متناغم، وتواصل السعي لخلق سماء أكثر زرقة وبيئة أفضل لنا!

المؤكسدات الحرارية المتجددة

How do regenerative thermal oxidizers compare to catalytic oxidizers?

Regenerative thermal oxidizers (RTOs) and catalytic oxidizers are both effective technologies used for controlling air emissions from industrial processes. While they serve a similar purpose, there are significant differences in their operation, efficiency, and applicability.

Here is a comparison between RTOs and catalytic oxidizers:

Regenerative Thermal Oxidizers (RTOs)	Catalytic Oxidizers
Operation:	Operation:
RTOs achieve emission control through high-temperature combustion without the use of a catalyst. They rely on the thermal oxidation process, where VOCs and other pollutants in the exhaust gas are oxidized at high temperatures (typically between 1,400°F and 1,600°F) in the presence of excess oxygen.	Catalytic oxidizers utilize a catalyst (usually a precious metal, such as platinum, palladium, or rhodium) to facilitate the oxidation of VOCs and other pollutants at lower temperatures compared to RTOs. The catalyst lowers the activation energy required for the oxidation reaction, enabling it to occur at lower temperatures (around 600°F to 900°F).
Efficiency:	Efficiency:
RTOs are known for their high thermal efficiency. They utilize a regenerative heat exchanger system that recovers and transfers heat from the treated exhaust gases to the incoming untreated gases, significantly reducing fuel consumption. This heat recovery mechanism makes RTOs energy-efficient.	Catalytic oxidizers are generally more energy-efficient than RTOs because they operate at lower temperatures. The catalyst facilitates the oxidation reaction, allowing it to occur at lower temperatures, which reduces the energy requirement for heating the exhaust gas.
Applicability:	Applicability:
RTOs are particularly suitable for applications where the pollutant concentrations are high, or where there is a wide variation in flow rates or pollutant concentrations. They are commonly used for the control of volatile organic compounds (VOCs) and hazardous air pollutants (HAPs) in various industries, including chemical manufacturing, printing, coating, and pharmaceuticals.	Catalytic oxidizers are often preferred in applications where the pollutant concentrations are relatively low and relatively constant. They are effective for VOC control in applications such as automotive painting, printing, and food processing, where the VOC concentrations can be lower and more consistent.
Limitations:	Limitations:
RTOs have higher capital costs compared to catalytic oxidizers due to their complex design and heat recovery system. They also have a higher operating temperature, which may limit their applicability in certain processes or require additional heat recovery systems.	Catalytic oxidizers can be sensitive to poisons or contaminants in the exhaust gas that can deactivate or degrade the catalyst over time. Certain compounds, such as sulfur, silicones, or halogenated compounds, can potentially poison the catalyst, reducing its effectiveness and requiring periodic catalyst replacement or regeneration.

When selecting between an RTO and a catalytic oxidizer, it is essential to consider the specific requirements of the application, including pollutant concentrations, flow rates, temperature requirements, and cost considerations. Consulting with environmental engineering professionals or equipment manufacturers can help determine the most suitable technology for a particular emission control need.

المؤكسدات الحرارية المتجددة

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:

التحكم في الانبعاثات: 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.
السعة الحرارية: 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.
كفاءة الطاقة: تتضمن وحدات الاسترداد الحراري أنظمة تبادل حراري تسمح باستعادة الطاقة الحرارية وإعادة استخدامها. تلتقط المبادلات الحرارية داخل وحدة الاسترداد الحراري الحرارة من غازات العادم الخارجة وتنقلها إلى تيار الهواء أو الغاز الداخل للعملية. تعمل عملية استعادة الحرارة هذه على تحسين كفاءة الطاقة الإجمالية للنظام وتقليل الحاجة إلى استهلاك وقود إضافي.
الالتزام باللوائح: 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.

المؤكسدات الحرارية المتجددة

How efficient are regenerative thermal oxidizers in destroying volatile organic compounds (VOCs)?

Regenerative thermal oxidizers (RTOs) are highly efficient in destroying volatile organic compounds (VOCs) emitted from industrial processes. Here are the reasons why RTOs are considered efficient in VOC destruction:

1. كفاءة تدمير عالية: RTOs are known for their high destruction efficiency, typically exceeding 99%. They effectively oxidize VOCs present in the industrial exhaust streams, converting them into less harmful byproducts, such as carbon dioxide and water vapor. This high destruction efficiency ensures that the majority of VOCs are eliminated, resulting in cleaner emissions and compliance with environmental regulations.

2. Residence Time: RTOs provide a sufficiently long residence time for the combustion of VOCs. In the RTO chamber, the VOC-laden air is directed through a ceramic media bed, which acts as a heat sink. The VOCs are heated to the combustion temperature and react with the available oxygen, leading to their destruction. The design of RTOs ensures that the VOCs have ample time to undergo complete combustion before being released into the atmosphere.

3. Temperature Control: RTOs maintain the combustion temperature within a specific range to optimize VOC destruction. The operating temperature is carefully controlled based on factors such as the type of VOCs, their concentration, and the specific requirements of the industrial process. By controlling the temperature, RTOs ensure that the VOCs are efficiently oxidized, maximizing destruction efficiency while minimizing the formation of harmful byproducts, such as nitrogen oxides (NOx).

4. Heat Recovery: RTOs incorporate a regenerative heat recovery system, which enhances their overall energy efficiency. The system captures and preheats the incoming process air by utilizing the heat energy from the outgoing exhaust stream. This heat recovery mechanism minimizes the amount of external fuel required to sustain the combustion temperature, resulting in energy savings and cost-effectiveness. The heat recovery also helps maintain the high destruction efficiency of VOCs by providing a consistent and optimized operating temperature.

5. Catalyst Integration: In some cases, RTOs can be equipped with catalyst beds to further enhance VOC destruction efficiency. Catalysts can accelerate the oxidation process and lower the required operating temperature, improving the overall efficiency of VOC destruction. Catalyst integration is particularly beneficial for processes with lower VOC concentrations or when specific VOCs require lower temperatures for effective oxidation.

6. Compliance with Regulations: The high destruction efficiency of RTOs ensures compliance with environmental regulations governing VOC emissions. Many industrial sectors are subject to stringent air quality standards and emission limits. RTOs provide an effective solution for meeting these requirements by reliably and efficiently destroying VOCs, reducing their impact on air quality and public health.

In summary, regenerative thermal oxidizers (RTOs) are highly efficient in destroying volatile organic compounds (VOCs). Their high destruction efficiency, residence time, temperature control, heat recovery capabilities, optional catalyst integration, and compliance with regulations make RTOs a preferred choice for industries seeking effective and sustainable solutions for VOC abatement.

editor by CX 2023-08-31