How Do Heat Exchangers Work?

Key to efficient operations, heat exchangers must maintain sufficient fluid velocity across plates to transfer heat while also controlling pressure drops that can disrupt operation. 

Systems typically employ plate and frame heat exchangers for pasteurization, raw milk cooling, and CIP (cleaning-in-place) heating. Given their suitability for products with low to mid viscosity and few to no particulates, plate heat exchangers are also commonly used for beverage, beer, wort, eggs, sauces, and most dairy processing.

Regenerative heating and cooling

In milk processing, chilled milk is heated from, for example, 4 °C to a pasteurization temperature of 72 °C and held at that temperature for 15 seconds and then chilled to 4 °C again.

Heat always transfers from warmer substances to colder ones, so during pasteurization, heat exchangers use heat from the pasteurized milk to warm the cold milk, which saves heating and refrigeration energy. The process is called regenerative heat exchange or heat recovery, typically reaching 90% and achieving up to 95% heat recovery from pasteurized milk. Recovery is lower for higher-fat products such as cream and ice cream mix. Regeneration has a positive impact on energy savings, capital costs, and efficient operation. Heat transfer occurs rapidly when the temperature differential is high. As temperature difference decreases, the rate of transfer slows down and stops altogether when temperatures equalize (Dairy Processing Handbook).

For fluids that contain particles, two solutions are available:

• A low contact point, wide-stream plate that can run product with more particulate
• Wide-gap plates that can run more and larger particulate.

Both allow particles to pass through while minimizing fouling.

How shell and tube heat exchangers work

Instead of transferring heat through parallel plates, shell and tube heat exchangers transfer heat between a bundle of tubes surrounded by a large shell vessel. Fluids that run through the tubes exchange heat with fluids that run over the tubes contained by the shell.

Because the diameter of tubes is typically greater than the gap between plates in plate heat exchangers, shell and tube exchangers are suited to applications in which product is more viscous (resistant to flow), or contains high-density particulates. Maximum particle size depends on tube diameter. Tubular heat exchangers can typically run longer between cleanings than plate heat exchangers in ultra-high-temperature applications.

The basic shell and tube principle moves product through a bundle of parallel tubes with heating fluid between and around the tubes.

A concentric tubular heat exchanger features tubes of different diameters positioned concentrically inside of each other, which is especially efficient in heating or cooling because heating/cooling fluids flow on both sides of the product tubes. Product tubes can be sized to meet the requirements for viscosity and particulates. A concentric tube is especially suited to high- viscosity non-Newtonian fluids whose viscosity changes under pressure (shampoo, nail polish, ketchup).

As with other heat exchanger designs, shell and tube exchangers are set up to have product and heating/cooling fluids flow in opposite directions. For example, cold product fluid travels from right to left in the heat exchanger while the warming fluid travels from left to right over the product tubes. The counter-flow configuration takes advantage of maximized temperature differences for more efficient heat transfer.

One manufacturer’s Pharma-line of shell and tube heat exchanger operates at pressures of up to 10 bar and operating temperatures of 150°C. Typical applications for the shell-and-tube heat exchangers include systems that process water (for injection or purification, for example), and CIP systems.

Heat exchangers with double tube sheets make leaks easy to spot because they appear at the joint in the outer tube plate. The heating fluid is sealed in the shell by the first tube sheet and the second tube sheet seals the product. In the event of a leak, the leakage of either fluid is easily visually detected.

Shell and tube heat exchangers are especially effective in the pharmaceutical industry where product hygiene and demand for isolating products from heating/cooling fluids are especially high. To meet the industry’s demands, high-quality tubular heat exchangers control microbe growth and prevent cross-contamination.

Some of the newest tube-in-tube designs for pharmaceutical applications feature high shear force and turbulence to maintain efficient transfer of heat while reducing bio-film.

Smaller, lighter-weight heat exchangers designed for tighter spaces can be effective substitutes for larger tube heat exchangers. They feature the same hot and cold fluid flows through alternating channels that create high turbulence for high heat transfer efficiency, while using 50–80% less heat transfer area.

How scraped surface heat exchangers work

The many processes involved in manufacturing food, chemicals, pharmaceuticals, cosmetics, health and beauty products all require reliable heat transfer that prevents fouling from viscous and sticky products. In those processes, scraped surface heat exchangers are the right choice. 

Their ability to process fluids with a high number of particulates or high viscosity make them more efficient in those applications. 

Scraped surface heat exchangers are more expensive than other exchangers, but they work efficiently when other heat exchangers would be ineffective.

They’re designed specifically for gentle product handling to avoid interference with product quality and consistency.

Scraped surface exchangers are typically mounted vertically. Inside, an electric motor turns a rotor fitted with scraping blades. To prevent damage to product, rotors and product move through the heat exchanger in the same direction, with product entering at the bottom and exiting at the top.

Scraped surface heat exchangers are common in the food and personal care industries. Ensuring continuous production requires uniform heat transfer, but the consistency or content of some food products hinders efficient heat transfer. Scraped-surface heat exchangers meet the need for efficiency by keeping product off the walls and in the mix where it belongs.