DN250 PN16 CF8 Metal to Metal Seat Flange End High Temperature Pneumatic Triple Offset Butterfly Valves

Specification

DN250 PN16 CF8 Metal – to – Metal Seat Flange End High – Temperature Pneumatic Triple – Offset Butterfly Valves

I. Product Overview

TIANYU’s DN250 PN16 CF8 Metal – to – Metal Seat Flange End High – Temperature Pneumatic Triple – Offset Butterfly Valve is engineered for demanding industrial scenarios where high – temperature fluid control is crucial. It merges advanced design, premium materials, and precise manufacturing to ensure reliable, long – lasting performance in harsh thermal environments.

II. Important Attribute and Specification Parameters

A. Size and Pressure Rating

With a DN (nominal diameter) of 250, this valve can manage substantial fluid flow volumes. The PN16 pressure rating means it can operate under a maximum pressure of 16 bar, making it 适配 for medium – pressure industrial pipeline systems that also involve high – temperature conditions.

B. Material Options for High Temperature

CF8C: A variant of austenitic stainless steel, offering good corrosion resistance and elevated temperature strength. It can withstand temperatures up to around 800°C in some applications, resisting oxidation and maintaining mechanical properties.
310S: A high – temperature austenitic stainless steel. Ideal for extreme heat, it can handle continuous service temperatures up to 1150°C. It has excellent oxidation resistance in high – temperature, corrosive atmospheres.
316: A widely used austenitic stainless steel. While not as high – temperature – rated as 310S, it still performs well in moderately high – temperature (up to around 800°C) and corrosive environments, with good resistance to chemicals like acids.
304: A common austenitic stainless steel. Suitable for lower high – temperature ranges (up to around 750°C), it provides good corrosion resistance and formability, often used in less extreme thermal – corrosive conditions.

The valve body and disc can be constructed from these materials based on specific application needs, ensuring compatibility with the fluid and temperature of the system.

C. End Connection

Featuring a flange end connection, it adheres to standard industrial flange dimensions. This allows for straightforward integration into existing pipeline setups, ensuring a secure and leak – proof joint when properly installed, which is vital for maintaining system integrity under high – temperature operation.

D. Actuation Type

Pneumatic actuation is utilized. This enables rapid response to control signals, facilitating quick opening and closing of the valve. In high – temperature processes, the ability to swiftly adjust fluid flow can help maintain process stability and prevent damage from temperature – related fluctuations.

Product Overview

III. Features Description

A. Triple – Offset Design

The triple – offset geometric design is a standout feature. It involves offsetting the disc’s axis in three planes. During operation, as the valve opens or closes, the disc gradually disengages from the seat, minimizing friction. When closed, precise alignment ensures a tight seal, even under high – temperature and pressure differentials. This design also reduces wear on the seat and disc, extending the valve’s service life in high – temperature environments where thermal expansion could otherwise impact sealing.

B. Metal – to – Metal Seat Advantages

The metal – to – metal seat is crucial for high – temperature applications. Unlike soft seats that can degrade or lose sealing ability at elevated temperatures, the metal seat maintains its integrity. It can withstand the thermal cycling and high temperatures without significant leakage, ensuring the valve’s reliability in processes where temperature variations are common. The robust nature of the metal – to – metal seal also contributes to the valve’s ability to handle high – pressure conditions simultaneously.

C. High – Temperature Material Benefits

The availability of materials like CF8C, 310S, 316, and 304 allows for customization based on the application’s thermal and corrosive demands. For example, in a furnace exhaust system with extremely high temperatures, 310S can be used to ensure the valve doesn’t fail due to heat – induced material degradation. In a chemical plant with moderately high temperatures and corrosive chemicals, 316 can provide both temperature and corrosion resistance.

IV. Manufacturing Process

A. Material Selection and Preparation

First, the appropriate high – temperature material (CF8C, 310S, 316, or 304) is selected based on the intended application. The raw material is inspected for quality, ensuring it meets the required chemical composition and mechanical property standards for high – temperature service. It is then cut and shaped into rough blanks for further machining.

B. Precision Machining

CNC (Computer Numerical Control) machining is employed to achieve the precise dimensions of the valve body, disc, and other components. The triple – offset design of the disc requires extremely accurate machining to ensure the correct geometric offsets. The flange ends are also machined to strict tolerances to ensure proper sealing. Surface finishing processes may be applied to enhance corrosion resistance, especially important for high – temperature applications where oxidation can be a concern.

C. Assembly and Quality Testing

Components are assembled with care, ensuring the metal – to – metal seat is correctly installed for optimal sealing. The pneumatic actuator is attached and calibrated to ensure smooth operation. After assembly, the valve undergoes rigorous testing. Pressure testing is performed to check for leaks under the rated PN16 pressure, and high – temperature testing may be conducted (depending on the material and application) to verify performance in extreme thermal conditions. Only after passing all tests is the valve ready for industrial use.

Valve Details

V. Product Advantages

A. Exceptional High – Temperature Resistance

Thanks to the availability of materials like 310S (for extreme heat) and others, the valve can operate in a wide range of high – temperature environments. It maintains its structural integrity and sealing performance, preventing leaks and ensuring process safety and efficiency even under thermal stress.

B. Reliable Sealing Performance

The combination of the triple – offset design and metal – to – metal seat ensures a reliable seal. In high – temperature applications, where thermal expansion and contraction can affect other valves, this design minimizes leakage risks, protecting the system from inefficiencies and potential hazards.

C. Long Service Life

The use of high – quality high – temperature materials and precise manufacturing processes results in a valve with a long service life. The reduced wear from the triple – offset design and the durability of the metal – to – metal seat mean less frequent maintenance and replacement, lowering the total cost of ownership.

D. Versatility in Applications

With different material options, the valve can be used in various industries and applications. Whether it’s in a high – temperature furnace system, a chemical plant with corrosive and hot fluids, or a power generation facility, it can be tailored to meet the specific thermal and corrosive requirements.

Application

VI. Product Applications

A. Petrochemical Industry

In petrochemical plants, where high – temperature processes like distillation and cracking are common, the valve can be used to control the flow of hot hydrocarbons. Materials like 316 can be used to resist corrosion from chemicals, while the high – temperature capabilities ensure reliable operation.

B. Power Generation

In power plants, especially in boiler systems and steam pipelines, the valve can regulate the flow of high – temperature steam. Materials like 310S can withstand the extreme heat of steam, ensuring the valve functions properly and contributes to efficient power generation.

C. Metallurgical Industry

In metallurgical processes such as steelmaking, where high – temperature molten metals and their by – products are involved, the valve can control the flow of hot gases or liquids. The high – temperature materials can resist the harsh thermal and corrosive environments, maintaining process stability.

D. Glass Manufacturing

Glass manufacturing involves high – temperature furnaces. The valve can be used to control the flow of fuel gases or cooling fluids in these furnaces. Appropriate materials can be selected to withstand the high temperatures and any corrosive by – products of the glass – making process.