Cleaning GEA Heat Exchanger Plate Hastelloy C276 Material SGS

Product Description

GEA Hastelloy C276 Material Replacement Plate For Mould NT150L

GEA Heat Exchanger Plates

To make a heat exchanger plate, the following general steps can be followed:

1. **Material Selection**: Choose the appropriate material for the plate based on factors like heat transfer efficiency, corrosion resistance, and mechanical strength.

2. **Plate Cutting**: Cut the selected material into the desired plate size and shape using cutting tools or machinery.

3. **Plate Embossing**: If necessary, emboss the plate to create turbulence and enhance heat transfer efficiency.

4. **Plate Cleaning**: Clean the plate surface thoroughly to remove any contaminants or debris that could affect heat transfer.

5. **Plate Assembly**: Assemble the plates with gaskets in a stack, ensuring proper alignment and spacing between plates.

6. **Plate Sealing**: Seal the plate stack securely to prevent any leaks between plates and ensure efficient heat transfer.

7. **Quality Control**: Perform quality checks to ensure the plates meet specifications and standards for heat exchanger performance.

By following these steps carefully and precisely, you can manufacture a heat exchanger plate ready for use in various heat transfer applications.

Applacations

Heat exchanger plate Choose:

• The choice of plate types and corrugation patterns for heat exchangers plate should be based on the specific heat transfer conditions and requirements. In situations where there is a large flow rate and a small allowable pressure drop, plates with low resistance should be selected. The selection of removable or brazed plate heat exchangers should be determined based on the pressure and temperature conditions of the heat transfer medium.
• For equipment with a large heat transfer area, it is not advisable to choose plates with excessively small individual plate areas. This is because having too many plates may result in low flow velocity between the plates, leading to a decrease in the overall heat transfer coefficient.

Production Process:

The production of stainless steel plates for plate heat exchangers involves several precise steps to ensure high-quality performance and longevity.

• Cutting and Leveling: Stainless steel plates are accurately cut using advanced machine tools to meet the specific design requirements. After cutting, a leveling treatment is applied to ensure a smooth and even surface. This step is crucial for maintaining efficient heat transfer capabilities.
• Stamping: The flattened plates undergo a meticulous stamping process using hydraulic presses. This process creates unique herringbone patterns on the plates, which significantly increase turbulence inside the heat exchanger. The controlled turbulence promotes optimal heat transfer by maximizing fluid contact with the plate surfaces. Special attention is given to maintaining precise control during stamping to prevent plate deformation or damage.
• Surface Treatment: To enhance corrosion resistance and optimize heat transfer performance, the plates undergo surface treatments such as polishing, sandblasting, or coating. The specific treatment method is selected based on the desired requirements and operating conditions. These treatments improve the plates' resistance to corrosion, fouling, and scaling, ensuring long-term efficiency and reliability.

Q&A

1. Q: Are you a manufacturer or trading company?

A: We are a professional manufacturer of plate heat exchangers, plates, gaskets, plate mould with 18 years' experience.