Product Description

M15B M15M Hight Theta Heat Exchanger Plate With Gasket For Optimal Cooling

Heat Exchanger Plates

Heat exchanger plates play a crucial role as integral components within plate heat exchangers, enabling the efficient transfer of heat between fluids. Typically crafted from metal, these plates are strategically arranged to optimize heat exchange while maintaining fluid separation.

The demand for heat exchanger plates arises from the necessity to transfer heat between fluids efficiently, without mixing. This requirement is essential across various industrial, commercial, and residential settings where heat transfer is fundamental for processes such as heating, cooling, and thermal energy recovery.

The primary advantages of employing heat exchanger plates for heat transfer include:

1. Enhanced Heat Transfer Efficiency: Heat exchanger plates are meticulously designed to maximize surface area, facilitating efficient and rapid thermal exchange between fluids.

2. Compact Design: Plate heat exchangers featuring heat exchanger plates offer a space-efficient solution for heat transfer compared to conventional shell-and-tube heat exchangers.

3. Versatility: Heat exchanger plates can be customized to accommodate various patterns and designs, allowing for the adaptation to diverse fluid types, flow rates, and temperature differences. This versatility enhances their applicability across a wide range of industries and applications.

4. Energy Efficiency: By promoting efficient heat transfer, heat exchanger plates contribute to energy conservation and improved operational efficiency in heating and cooling systems, leading to reduced energy consumption and lower operating costs.

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: We meticulously select premium-grade stainless steel plates for their outstanding corrosion resistance and thermal conductivity, ensuring alignment with product specifications and design parameters.

• Cutting and Leveling: Advanced machine tools are employed to accurately cut stainless steel plates according to design specifications. Subsequently, a leveling treatment is applied to achieve a uniform and smooth surface.

• Stamping: Using hydraulic press stamping, specific herringbone patterns are created on leveled plates to enhance turbulence coefficient for efficient heat transfer. Strict control measures are implemented to prevent plate deformation or damage during stamping.

• Surface Treatment: Various surface treatment techniques such as polishing, sandblasting, or coating are meticulously applied to enhance corrosion resistance and heat transfer performance, selected based on specific requirements.

• Assembly and Inspection: Plates are meticulously assembled in accordance with design specifications, resulting in the formation of either a detachable plate heat exchanger with rubber gasket seals or a fully welded plate heat exchanger using argon arc welding. Precision fitting and absence of gaps are meticulously ensured during assembly. Subsequently, a rigorous performance pressure test is conducted post-assembly, followed by issuance of a comprehensive factory report to verify compliance with stringent quality standards.

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