Plate and frame heat exchangers

The plate heat exchanger (PHE) is a specialized design well suited to transferring heat between medium- and low-pressure fluids. Welded, semi-welded, and brazed heat exchangers are used for heat exchange between high-pressure fluids or where a more compact product is required. In place of a pipe passing through a chamber, there are instead two alternating chambers, usually thin in-depth, separated at their largest surface by a corrugated metal plate. The plates used in a plate and frame heat exchanger are obtained by the one-piece pressing of metal plates. Stainless steel is a commonly used metal for the plates because of its ability to withstand high temperatures, its strength, and its corrosion resistance.

The plates are often spaced by rubber sealing gaskets which are cemented into a section around the edge of the plates. The plates are pressed to form troughs at right angles to the direction of flow of the liquid which runs through the channels in the heat exchanger. These troughs are arranged so that they interlink with the other plates which form the channel with gaps of 1.3-1.5 mm between the plates. The plates are compressed together in a rigid frame to form an arrangement of parallel flow channels with alternating hot and cold fluids. The plates produce an extremely large surface area, which allows for the fastest possible transfer. Making each chamber thin ensures that the majority of the volume of the liquid contacts the plate, again aiding exchange. The troughs also create and maintain a turbulent flow in the liquid to maximize heat transfer in the exchanger. A high degree of turbulence can be obtained at low flow rates and a high heat transfer coefficient can then be achieved.

As compared to shell and tube heat exchangers, the temperature approach in plate heat exchangers may be as low as 1 °C whereas shell and tube heat exchangers require an approach of 5 °C or more. For the same amount of heat exchanged, the size of the plate heat exchanger is smaller, because of the large heat transfer area afforded by the plates (the large area through which heat can travel). Increase and reduction of the heat transfer area are simple in a plate heat exchanger, through the addition or removal of plates from the stack.

• Water heaters
• Cooling tower isolation
• Free cooling
• Waste heat recovery
• Heat pump isolation
• Thermal (ice) storage systems

The plate exchanger is the most efficient due to turbulent flow on both sides. High heat-transfer coefficient and high turbulence due to even flow distribution are important. 

The advantage of plate heat exchanger is a Simple and Compact in size. Turbulent flow helps to reduce deposits which heat transfer, No extra space is required for dismantling in Plate heat exchangers. Plate type heat exchanger is Maintenance simple and can be easily cleaned.