If you’re in the business of designing or engineering commercial appliances for companies that make potato salad, for instance, you probably realize that the only practical way to satisfy that firm’s regional distribution requirements is to make a whole lot of product—literally thousands of pounds per hour.
Another critical factor: Only by using more advanced cooking and chilling technology can a client ensure that potato salad is fresh and delicious, and offers optimum shelf life—all without the use of unappealing preservatives.
Among the more sophisticated cooking systems ideal for such an application is the vacuum-sealed retort, a vessel used to cook the product within half an hour, and then chill it to 35 degrees F within just 17 minutes, through an evaporative cooling system that uses no refrigeration.
Small Footprint, Too
“This type of system enables producers to cook and mix high volumes very quickly with equipment that requires a relatively small footprint compared to linear systems that require refrigeration or mechanical cooling,” explains Carl Illiff, vice president of CMI Equipment & Engineering of Glencoe, Minn., and a designer and fabricator of specialized food processing equipment.
Illiff says that because those potatoes are cooled and chilled within a sealed retort, the food is not exposed to the air when being chilled, such as occurs with mechanical systems such as a blast cooler. “If the potato salad producer were to chill the diced potatoes in a blast cooler, it will take 18-20 hours to cool it,” he explains “And in the process, it will be exposed to bacteria, mold and yeast that are being circulated through these fans on the cooler.”
Illiff adds that when food is exposed to such biological organisms, shelf life will be compromised unless the processor adds preservatives, something that consumers don’t want to see on the labels of fresh foods.
An Amazing Process
The above example, the diced potato retort, which some food processors use to cook chickpeas and other vegetables, is designed by CMI as a complete, high-quality package. The main part of the system, a cylindrical chamber loaded with carts and trays, is all stainless steel and capable of a holding a vacuum of over 30 inches. The retort is normally between 12 and 22 ft. long, and about five ft. in diameter, depending on customer specifications. Smaller models can cook and cool 2,000 pounds of product per hour; the largest ones can cook up to 8,000 pounds per hour.
Contained inside an upper chamber in the retort are a shell-and-tube condenser and a liquid-ring vacuum pump, which is, in turn, connected to a cooling tower. The shell-and-tube condenser provides evaporative cooling under high vacuum pressure created by the pump. Evaporated water is circulated from the condenser to the cooling tower and back to provide a continuous chilling effect.
“This cooling processing is amazing,” says Illiff. “When you remove the diced potatoes they are nice and cold, and ready to mix with the potato salad dressing, then package and ship to the customer—all with hardly any exposure to air.”
Illiff adds that because his equipment is very high in quality and designed to operate reliably for many years, he was especially particular when it came to sourcing the cooling tower that is integral to his cooking retort systems.
A New Breed of Cooling Tower
No doubt. When a commercial appliance user has 8,000 pounds of potatoes steaming with heat, that firm can’t afford to have anything less than a reliable cooling system. Otherwise it’s four tons of mashed potatoes. When Carl Illiff first looked for a complete solution to cool his tots for potato salad, he understood that incorporating a cooling tower that was reliable as the rest of his system could be a challenge.
“We were very concerned about the reliability, service requirements, and lifespan of the cooling tower,” Illiff says, “because our cooling system is dependent on it working correctly for a long period of time.”
In exploring the cooling available, he found that the majority of models were of the traditional, galvanized metal-clad design. Illiff was not satisfied with this kind of engineering, which promised to be maintenance intensive with perhaps frequent periods of downtime.
Eventually he found what appeared to be a highly attractive alternative to the traditional cooling tower, a design that featured a high-density polyethylene (HDPE) shell and enclosed direct-drive motor assembly that promised to provide highly reliable operation with very low maintenance. HDPE cooling tower shells are virtually impermeable to corrosive elements, including water treatment chemicals such as chlorine, as well as UV rays.
Long Lifespan Important
Illiff found his HDPE cooling tower at Delta Cooling Towers, a manufacturer that originally developed the “plastic” design, and has installed industrial, commercial and institutional systems nationwide. Besides the HDPE shell design, what attracted Illiff to the design most was its 15-year factory warranty. This was a great testimony of the lifespan that he was looking for to ensure the reliability of his retort-based cooking system, he observed.
Also, such HDPE cooling towers are available in a wide range of sizes from 10 up to 2,000 tons (CMI normally installs 250- or 500-ton sizes).
“These cooling towers are also lighter in weight,” Illiff adds, “so that only a relatively simple stand is required to support it. We installed one recently, for example, and counting the time it took to assemble a stand for it, we had the entire cooling tower system installed in half a day.”
Many end users of such cooling tower technology find that variable-speed, direct-drive motors running the system fans also provide unexpected benefits. Far more efficient than belt-driven or gear drives, the cooling tower design requires considerably less horsepower and therefore consume less energy, providing some users up to a 50 percent savings in electric power.
Original materials provided by Delta Cooling Towers of Rockaway, N.J. More information at firstname.lastname@example.org or www.deltacooling.com