Product Description

Versatile Heat Exchanger Plate for Various Flow Rates and Temperature Differentials

Heat Exchanger Plates

Our Versatile Heat Exchanger Plate is designed to accommodate a wide range of flow rates and temperature differentials, making it an ideal solution for diverse industrial and commercial applications.

Key Features:

1. Adaptability: The plate is engineered to handle varying flow rates and temperature differentials, offering unparalleled adaptability in heat exchange processes.

2. Efficiency: With its advanced design, the heat exchanger plate maximizes thermal efficiency, ensuring optimal heat transfer across different operating conditions.

3. Durable Construction: Constructed from high-quality, corrosion-resistant materials, the plate promises longevity and reliability even in demanding environments.

4. Customizable Configurations: It offers customizable configurations to address specific flow rate and temperature requirements, allowing for tailored solutions to diverse heat transfer challenges.

5. Optimized Performance: The design promotes turbulence and enhanced flow patterns, resulting in improved heat transfer performance and minimized fouling.

6. Wide Application Range: Suitable for applications across industries such as HVAC, chemical processing, power generation, food and beverage, and more.

Products are mainly suitable for ACCESSEN/GEA (Kelvion)/ APV/ Sondex/ Tranter/ Hisaka/ API/ Funke/ Vicarb/ Mueller/ SWEP/ Fischer/ AGC/ Thermalwave/ ITT/ LHE/ DHP, etc.

Applacations

Plate heat exchanger plate thickness configuration

• AISI 304 is usually 0.4 or 0.5 mm thickness
• AISI 316 is always 0.5 and 0.6 mm
• 254 SMO (high alloy) typically 0.6 mm
• Titanium plates are always 0.5 and 0.6 mm
• Some have thicker plates (for high pressure applications)
• Some PHEs have 0.4 mm (low pressure operation)
• Hastelloy C-276 (nickel alloy) typically 0.6 mm

Production Process:

• Raw material preparation: High-quality stainless steel plates are selected as raw materials due to their excellent corrosion resistance and thermal conductivity. The plate thickness is determined based on product specifications and design requirements.
• Cutting and leveling: The stainless steel plates are accurately cut using machine tools to meet the design requirements. After cutting, leveling treatment is performed to ensure a smooth and even surface.
• Stamping: The flattened plates undergo stamping using a hydraulic press to create specific herringbone patterns. The resulting plates have a high turbulence coefficient, promoting efficient heat transfer. Precise control is maintained during the stamping process to prevent plate deformation or damage.
• Surface treatment: The plates undergo surface treatment such as polishing, sandblasting, or coating to enhance corrosion resistance and heat transfer performance. The choice of treatment method depends on specific requirements.
• Assembly and inspection: The plates are assembled according to the design requirements, forming a detachable plate heat exchanger with rubber gasket seals or a fully welded plate heat exchanger through argon arc welding. Tight fitting and absence of gaps are ensured during assembly. A rigorous performance pressure test is conducted after assembly, and a factory report is issued to verify compliance with quality standards.