Carrots make a delicious, nutritious, low calorie snack. They are also very popular in salads and are frequently found in fruit juices and health drinks. One of the main reasons carrots are so popular is due to their crunchy texture as well as their sweet, satisfying taste. However, for optimal texture, taste, and nutrition it is imperative that carrots be properly cooled and stored after harvest.

General Facts About Carrots

Carrots are closely related to traditional herbs such as parsley, dill, fennel, and cumin which are typically grown for their aromatic leaves and flavorful seeds. Like these other plants, carrots too were originally grown primarily for their leaves and seeds rather than their roots. Overtime carrots were cultivated to improve the taste, texture, and size of their roots, elongating them and giving them a less woody flavor. Nowadays of course carrots are almost exclusively grown and eaten for their roots; however, their leafy greens are still sometimes eaten as well.

Carrots are low in calories and starch and rich in vitamins such as β-carotene, α-carotene, and γ-carotene, which metabolize into vitamin A. Vitamin A is important for eye health. Carrots are also rich in antioxidants and minerals. They are believed to improve blood flow and aid in healthy digestion.

General Information About Cooling and Storing Carrots

Carrots may be stored, transported, and sold as either topped carrots, which have had the greens cut off of them, or as bunched carrots, which retain the greens intact. This distinction is important because bunched carrots have a shorter shelf life than topped carrots.

Temperature – Both topped and bunched carrots should be stored at a temperature of about 32°F. They should also be cooled as soon after harvest as possible and ideally should be harvested in cool soil. However, it is not recommended for the carrots’ temperature to drop below 0°F or freeze damage may occur.

Respiration and Degradation – The extra foliage on bunched carrots results in a dramatically higher rate of respiration and thus also accelerated degradation and loss of quality.

Relative Humidity – Carrots should be stored at a very high relative humidity, about 98% – 100%. This prevents them from losing moisture. If they lose moisture their texture and crunch will be compromised as well as their overall taste and nutritional value.

Handling – Carrots should be handled carefully to avoid bruising their shafts or damage to their tips. Damaged spots act as weak spots for decay and rapid degradation to set in.

Ethylene Exposure – Like many fruits and vegetables carrots will change in the presence of ethylene. For carrots ethylene exposure will result in a more bitter, less pleasant taste. For this reason carrots should be kept separate from other produce that release ethylene as they ripen.

Shelf Life – Topped carrots will last up to a very impressive 9 months under optimal conditions. By contrast bunched carrots will only last approximately 2 weeks under optimal conditions.

Methods of Cooling Carrots

Because it is important to cool carrots quickly and thoroughly and keep them at low temperatures, basic room cooling alone is seldom optimal. Instead the following methods are recommended:

Forced-Air Cooling – Forced-air cooling, which utilizes specially designed fans to pull cool past the carrots, results in much faster cooling times.

Hydrocooling – Hydrocooling involves submerging the carrots in near-freezing water and is very effective at rapidly cooling the carrots. Hydrocooling also helps prevent the carrots from becoming dehydrated.

Packing Ice – Packing ice directly on the carrots is another highly effective means of cooling the carrots. This approach will also help with rehydration if the carrots are somewhat dehydrated.

SEMCO/SEMCOLD LLC is proud to offer a wide range of industrial cooling systems that are ideal for use to cool carrots. Our systems can be customized to fit the capacity and cooling method needed for each client’s operations. We will work closely with you to ensure that the system is optimal for your carrots or other produce.

Peas and beans are one of the most popular types of food in the US. They are often sold fresh, frozen, or canned and they are considered a staple by millions of Americans. However, in order for peas and beans to taste their best and offer the most nutritional value possible it is important that they be properly cooled and stored prior to consumption.

General Facts About Peas and Green Beans

Peas are considered a botanical fruit; however, they are commonly prepared and eaten as a vegetable. Peas are closely related to legumes and beans. Peas form in small pods that can be cracked open to attain the tender fruit. Peas have been consumed by human beings since the beginning of recorded history and as such there are a wide variety of different cultivars. The main ones we will be discussing are southern peas which include crowder peas, cream peas, and black-eyed peas to name just a few.

Like peas, beans are also actually considered a botanical fruit, but also like peas they are commonly prepared and eaten in ways similar to that of a vegetable. The term bean is typically used in reference to members of the leguminosae family. However, the term may also be applied to the seeds or pods of unrelated plants such as castor beans, cocoa beans, coffee beans, or vanilla beans, which simply bear a resemblance to true beans. Like peas, beans have also been consumed throughout recorded history. In this article we will focus primarily on snap beans, also known as green beans, and lima beans, also known as butter beans.

General Information About Cooling and Storing Peas and Beans

Respiration and Degradation – Peas and beans, like most other types of fruits and vegetables release heat as a result of respiration which then contributes to their degradation and loss of quality. Because of this it is important to begin cooling the peas and beans within at least 1-2 hours of harvest. The peas and beans should also not be left in direct sunlight while they are awaiting cooling.

Temperature – Peas and beans do best with a storage temperature of about 37 °F to 45°F. At higher temperatures the rate of respiration is faster which in turn leads to more rapid degradation and loss of quality. However, if the storage temperature drops below 31°F the peas and beans may be subject to freeze damage.

Relative Humidity – Peas and beans thrive at a cooling and storage relative humidity of about 95%.

Handling – To prevent damage and loss of quality it is important that peas and beans be handled carefully during harvest and storage.

Shelf Life – Depending on the storage conditions and the particular peas and beans they will typically have a shelf life of about 5 to 10 days.

Methods of Cooling Peas and Beans

Hydrocooling – An effective method for quickly and thoroughly cooling peas and beans is hydrocooling. This involves submerging the peas and beans in very cold water to rapidly remove heat and prolong shelf life. The water should be as near to freezing as possible while still remaining liquid.

Forced-Air Cooling – Basic room cooling is not a sufficient method of cooling peas and beans because it takes too long and pods located near the center of the container may never cool fully. However, forced-air cooling, which involves pulling cooled air through the peas and beans is about 8 times faster than room cooling alone, depending on the fans and load size, and is a very effective cooling technique.

SEMCO/SEMCOLD LLC is a leader in industrial cooling and freezing equipment. We can custom-build cooling systems designed to customer specs that are ideally suited for cooling peas and beans. Please contact us for more information.

Onions are one of the most widely used food items in the US. They are an important flavoring component in countless dishes and are even eaten raw on sandwiches and salads. Onions are also rich in antioxidants and flavonoids which may bring a number of healthful benefits including anti-cholesterol, anti-inflammatory, and anti-cancer. For onions to properly serve their crucial culinary and nutrition niche, they must be stored, cooled and transported carefully in ways that take the quality and freshness needs of the onion into consideration.

General Facts About Onions

The phrase onions encompasses a wide array of different bulb vegetables in the Allium genus, including such exotic members as the Egyptian onion (A. ×proliferum), The Japanese bunching onion (A. fistulosum), and the Canada onion (A. canadense) to name just a few. However, most varieties of common onions are in the A. cepa species, including red onions, yellow onions, white onions, shallots, and potato onions, each of which has a different and distinct flavor.

Onions pose a unique challenge to growers because unlike many other fruits and vegetables which can go straight from harvest into cooling and storage, onions need to be dried first. In some regions onions are dried in the field; however, areas with high humidity and rainfall during onion harvesting season must instead dry the onions by other means such as in bins and barns, often with carefully regulated humidity and temperature.

General Information About Cooling and Storing Onions

Like other fruits and vegetables onions have specific cooling needs which include factors such as temperature, humidity, handling, and storage. As discussed above onions also require drying. Depending on the resources available some farmers have had success repurposing equipment and facilities used for drying tobacco, peanuts, and other crops into use for drying onions.

Drying – Drying is crucial to reduce the onion’s susceptibility to decay organisms, extend their shelf life, and vulnerability to bruising. Even dried onions are of course still subject to eventual decay and physical damage, but drying helps provide them with extra time and resistance. Drying times will vary from two or three days if heated air is used, to anywhere upwards of one or more weeks if only ambient air is used.

Humidity – During drying onions should be exposed to a relative humidity of about 65%. Higher humidity levels will lengthen drying times or even prevent full drying. This will also increase the onion’s risk of neck rot and other problems. Once the onions are dried and are in cold storage a slightly higher humidity of about 70% to 75% is generally acceptable.

Temperature – During drying heated air temperature should be 100°F. Higher temperatures should be avoided since anything over 110°F can damage the onion. Once the onion is dried it should be stored in a cooler or cool environment with a temperature between 32°F and 36°F. It is important to prevent the temperature from reaching 31°F or lower because his will subject the onion to freeze damage.

Storage – Temperature and humidity greatly impact how long an onion can viably be stored and at what rate the onion loses mass. Onions stored in temperatures 50°F or higher may be subject to sprouting.

Exposure to Other Produce – Onions should also be kept separate from other fruits and vegetables, both to protect the onion and the other food. That is because onions will readily leach moisture from other produce, drying out the other food and exposing the onion to too much moisture for proper storage. Onions also have a very pungent odor and many other types of produce may absorb the smell.

Cooling Method for Onions

Onions should be cooled using the room cooling method. This involves placing them in a refrigerated room or large walk-in cooler. It is important to continue monitoring temperature and humidity levels while the onions are in the cooler.

Long-Term Storage

Onions can also successfully be placed in controlled atmosphere storage for even longer-term storage. This involves carefully regulating not only temperature and humidity levels, but also the onion’s exposure to gases such as oxygen, nitrogen, and carbon dioxide. Onions in controlled atmosphere storage may last up to 8 months with minimal quality loss.

SEMCO/SEMCOLD LLC offers quality cooling equipment that can be customized and designed to fit the needs of onions. We can also tailor our systems to the particular capacity demands and other requirements of our customers. Please contact us for more information.

Tomatoes are an extremely popular type of produce that are used in a wide variety of dishes and which may be eaten fresh and raw, turned into paste or sauce, or of course used for America’s favorite condiment: ketchup. However, for optimum taste and quality it is very important that the temperature of tomatoes be closely regulated. What follows is a discussion of general tomato information, factors that affect cooling and storage, and proper cooling methods.

General Facts About Tomatoes

One of the most popular tomato-related debates is whether tomatoes are fruits or vegetables. Botanically they are fruits of the nightshade family, specifically Solanum lycopersicum. In terms of culinary practices they are often used in ways similar to a vegetable. Tomatoes as a food originated in Mexico. However, due to their versatility, taste, and ability to grow in different regions, they quickly spread throughout most of the world following the Spanish colonization of the Americas in the 1500s.

Tomatoes are renowned for their nutritional value. They contain an important and powerful antioxidant known as lycopene. Lycopene has been shown to have a number of health benefits including possible prevention of cancer, particularly prostate cancer, and skin protect against UV rays. There is also research being conducted into whether or not tomatoes have heart-healthy benefits for people with type 2 diabetes and whether or not tomatoes can improve urinary tract function.

General Information About Cooling and Storing Tomatoes

Tomatoes are more complicated to cool and store than many other types of produce because there is a very wide variation of correct storage temperature depending on the ripeness of the tomatoes. Tomatoes also vary in shelf life depending on ripeness at the time of harvest and storage conditions.

Ripeness/Color – Tomatoes are often graded on ripeness based on the color of their skin. The colors and criteria are as follows:

• Green – Green tomatoes have a surface that is completely green. The particular shade of green may range anywhere from light to dark. Tomatoes are called “mature green” when they have reached the stage of ripening that will allow them to fully ripen into red tomatoes. Immature greens are tomatoes that are not yet mature enough to ripen fully and should be avoided. Mature greens on the other hand will be indistinguishable from vine-ripened tomatoes by the end of the ripening process and come with the added benefit of a longer shelf life.
• Breakers – Tomatoes are called breakers when their green skin features tannish yellow skin with pink or red spots that do not cover more than 10% of the tomato’s surface.
• Turning – Tomatoes are said to be turning when they have tannish yellow, pink, or red skin that makes up more than 10% of their surface but less than 30%.
• Pink – Tomatoes are said to be pink when they have more than 30% but less than 60% of their skin a pinkish red or red color.
• Light Red – Light red tomatoes have a pinkish red or red skin that comprises more than 60% of their surface but less than 90%.
• Red – Red tomatoes are those with more than 90% of their surface red.

Temperature – The correct storage temperature for tomatoes varies based on their ripeness/color. As a general rule the more ripe the tomato the cooler its correct storage temperature. Tomatoes stored at temperatures too cold for their ripeness stage will suffer cold damage, reduced taste and quality, and may never fully ripen. By contrast tomatoes stored at temperatures too high for their ripeness stage may be subject to premature spoilage, decay, and damage. Mature greens may be stored at 58°F to 60°F, while pink tomatoes may be stored at 48°F to 50°F. Fully ripe tomatoes may be stored at temperatures as low as 40°F.

Humidity – The correct humidity level for storing and cooling tomatoes is about 85% to 95%, with lower humidity levels running the risk of drying out or dehydrating the tomatoes and higher humidity levels making the tomatoes more susceptible to rapid decay. Some studies suggest an even more narrow range of about 85% to 90% with concerns that even humidity levels over 90% could hasten decay.

Ethylene – Like many other fruits and vegetables tomatoes produce and release ethylene as they ripen, which in turn further hastens the ripening process. Unripe tomatoes may be intentionally treated with ethylene to bring about more rapid ripening prior to being sold to consumers. By contrast unripe tomatoes not yet ready to be sold should avoid contact with ethylene.

Storage – Because tomatoes are sensitive to ethylene it is typically a good idea to keep them separate from other fruits and vegetables since these other types of produce may unintentionally hasten ripening or, likewise, ripe tomatoes may hasten the ripening of other produce. Along the same lines ripe tomatoes may also need to be kept separate from unripe tomatoes. Once a tomato fully ripens its shelf life is much lower.

Shelf Life – The shelf life of tomatoes varies based on their ripeness, as well as the other factors discussed above. Generally mature green tomatoes will have a shelf life of about 21 to 28 days. Pink tomatoes have a shelf life of about 7 to 14 days. Fully ripe red tomatoes only have a shelf life of about 2 to 4 days.

Methods of Cooling Tomatoes

Tomatoes should be cooled using the room storage method, which involves placing the tomatoes in a refrigerated room or cooler set to the correct temperature for the tomato’s given ripeness level. It is important to ensure that the tomato boxes are well ventilated to allow heat to escape and for proper air circulation. Tomatoes should also be handled carefully as they are very prone to physical damage due to bruising, dropping, or general mishandling. SEMCO/SEMCOLD LLC offers industry-leading cooling equipment that can be customized to handle the unique demands and cooling sensitivity of tomatoes.

Corn, also known as “maize” in many parts of the world, is one of the most popular and widespread crops on the planet. The United States produces about 332 million metric tons every year. There are two major types of corn: field corn, which is used as a starch-rich variety used in corn products such as cornmeal, corn oil, and other corn-based foods; and sweet corn, which is a sugar-rich variety which is eaten as a vegetable and prized for its taste. For sweet corn to be flavorful and high quality it must be rapidly and continually cooled otherwise the sugars will begin converting into starches.

General Information About Cooling and Storing Corn

Sweet corn is an extremely perishable crop which requires immediate and consistent cooling until it reaches end consumers. If it is not properly cooled it will rapidly become tough and starchy, losing its tenderness and sweetness and no longer being suitable for consumption. There are several important cooling factors which affect sweet corn.

Respiration and Degradation – Like many other types of fruits and vegetables a major source of quality loss for sweet corn is due to the rise in temperature caused by natural cellular respiration. The respiration rate is heavily dependant on temperature, making it crucial to quickly and thoroughly cool sweet corn to preserve its quality. The respiration rate at 90°F is a staggering eight times higher than at 32°F. Considering that field temperatures are often upwards of 90°F when sweet corn is harvested this can lead to almost immediate degradation if left unchecked.

One remedy to limit respiration is to harvest the sweet corn in the early morning, while temperatures are lower and while the moisture content is highest. This also helps reduce cooling loads for subsequent cooling and helps save energy. Another common method is to immediately begin covering the sweet corn with cool well water as soon as it is harvested.

Moisture Retention – Moisture retention is another important factor in sweet corn quality. To best retain moisture the sweet corn should be neatly and uniformly trimmed to remove long shanks and flag leaves. Loss of moisture can result in kernel denting as well as a loss of quality and taste. Once again treating the corn with cool water can help with moisture retention.

Sugar Content – Sweet corn has a high percentage of sugar which gives it its characteristic sweet, flavorful taste. However, almost as soon as it has been harvested the sugars present begin converting into starches. This process cannot be completely stopped, but it can be significantly slowed, preserving the quality and value of the corn for longer. Temperature is an important factor with the loss of sugar being about four times as rapid at 50°F as it is at 32°F. Once the sugars are converted into starches this process cannot be undone. That makes it crucial that the corn remain properly refrigerated for its entire journey from harvest into the eventual hands of the consumer.

Relative Humidity – The relative humidity of the environment plays an important role in moisture retention and proper cooling. Sweet corn does best with a relative humidity of about 90% to 98%.

Storage – Storage times will vary but under ideal storage conditions, those with low temperature and high humidity, sweet corn can be stored for around 5 to 8 days without a major loss in quality. Some newer, supersweet varieties are able to be stored for even longer.

Methods of Cooling Corn

Basic cooling methods such as room cooling, which involves placing the sweet corn in a refrigerated room or cooler, are not adequate to cool the sweet corn rapidly and efficiently enough. Instead hydrocooling and packing ice is recommended.

Hydrocooling – Hydrocooling involves rapidly cooling the corn by submerging it in near-freezing water. This is one of the most effective ways to quickly and efficiently remove the majority of field heat and help the corn quickly approach suitable cooling and storage temperatures. However, hydrocooling is most efficient when the temperature differential between the corn and the water is high. In other words when water temperatures are low, such as with freezing water, and when corn temperatures are high, such as with freshly harvested crops. After about 20 to 30 minutes of hydrocooling the temperature of the corn will have decreased by about 20 degrees or more. As a result the next 20 degree temperature drop would take twice as long as the first 20 degree drop and would require over an hour of additional hydrocooling.

Packing Ice – Because hydrocooling becomes less efficient the lower the temperature of sweet corn gets, it is recommended that after initial hydrocooling the remaining necessary temperature drop be attained through the use of packing ice over and around the sweet corn. This will help save energy and lower cooling loads. A good rule of thumb is to use about one pound of ice for every five pounds of sweet corn.

SEMCO/SEMCOLD LLC offers high quality hydrocooling and icing systems that are ideal for use on sweet corn cooling. Our systems and product lines can be customized to suit the capacity needs and other specifications of each our clients.