Refrigerator car

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(PD) Drawing: Unknown
An early refrigerator car design, circa 1870. Hatches in the roof provided access to the ice tanks at each end of the car.

A refrigerator car (or "reefer") is a refrigerated boxcar, a piece of railroad rolling stock designed to carry perishable freight at specific temperatures. Refrigerator cars differ from simple insulated boxcars and ventilated boxcars (commonly used for transporting fruit), neither of which are fitted with cooling apparatus. Reefers can be ice-cooled, come equipped with any one of a variety of mechanical refrigeration systems, or utilize carbon dioxide (either as dry ice, or in liquid form) as a cooling agent. Milk cars (and other types of "express" reefers) may or may not include a cooling system, but are equipped with high-speed wheelsets and other modifications that allow them to travel with passenger trains. Reefer applications can be divided into four broad groups: 1) dairy and poultry producers require refrigeration and special interior racks; 2) fruit and vegetable reefers tend to see seasonal use, and are generally used for long-distance shipping (for some shipments, only ventilation is necessary to remove the heat in transit created by the ripening process); 3) manufactured foods (such as canned goods and candy) as well as beer and wine do not require refrigeration, but do need the protection of an insulated car; and 4) meat reefers come equipped with specialized beef rails for handling sides of meat, and brine-tank refrigeration to provide lower temperatures (most of these units are either owned or leased by meat packing firms).

Outside of North America, railroad cars which have been outfitted with cooling equipment (and designated as Class "I" by the International Union of Railways [UIC]) are generally referred to as "refrigerated vans."

History

Background

(PD) Photo: Railroad and Locomotive Historical Society
Illinois Central Railroad #14713, a ventilated fruit car dating from 1893.

After the end of the American Civil War, Chicago, Illinois emerged as a major railway center for the distribution of livestock raised on the Great Plains to Eastern markets.[1] Getting the animals to market required herds to be driven up to 1,200 miles (2,000 kilometers) to railheads in Kansas City, Missouri where they were loaded into specialized stock cars and transported live ("on-the-hoof") to regional processing centers. Driving cattle across the plains also led to tremendous weight loss, and some animals were lost along the way. Upon arrival at the local processing facility, livestock were either slaughtered by wholesalers and delivered fresh to nearby butcher shops for retail sale, smoked, or packed for shipment in barrels of salt. Costly inefficiencies were inherent in transporting live animals by rail, particularly the fact that about sixty percent of the animal's mass is inedible. The death of animals weakened by the long drive further increased the per-unit shipping cost. Meat packer Gustavus Swift began looking for a way to ship dressed meats from his packing plant in Chicago to the East.

Early attempts at refrigerated transport

A number of attempts were made during the mid-1800s to ship agricultural products via rail car. As early as 1842, the Western Railroad of Massachusetts was reported in the June 15 edition of the Boston Traveler to be experimenting with innovative freight car designs capable of carrying all types of perishable goods without spoilage.[2] The first refrigerated boxcar entered service in June 1851, on the Northern Railroad of New York (or NRNY, which later became part of the Rutland Railroad). This "icebox on wheels" was a limited success in that it was only able to function in cold weather. That same year, the Ogdensburg and Lake Champlain Railroad (O&LC) began shipping butter to Boston in purpose-built freight cars, utilizing ice to cool the contents. The first consignment of dressed beef left the Chicago stockyards in 1857 in ordinary boxcars retrofitted with bins filled with ice. Placing meat directly against ice resulted in discoloration and affected the taste, and proved impractical. During the same period Swift experimented by moving cut meat using a string of ten boxcars which ran with their doors removed, and made a few test shipments to New York during the winter months over the Grand Trunk Railway (GTR). The method proved too limited to be practical.

(PD) Photo: Chicago Historical Society
A builder's photo of one of the first refrigerator cars to come out of the Detroit plant of the American Car and Foundry Company (ACF), built in 1899 for the Swift Refrigerator Line.

Detroit's William Davis patented a refrigerator car that employed metal racks to suspend the carcasses above a frozen mixture of ice and salt. He sold the design in 1868 to industrialist George H. Hammond, a Detroit meat packer, who built a set of cars to transport his products to Boston using ice from the Great Lakes for cooling.[3] The load had the tendency of swinging to one side when the car entered a curve at high speed, and the use of the units was discontinued after several derailments. In 1878 Swift hired engineer Andrew Chase to design a ventilated car that was well insulated, and positioned the ice in a compartment at the top of the car, allowing the chilled air to flow naturally downward.[4] The meat was packed tightly at the bottom of the car to keep the center of gravity low and to prevent the cargo from shifting. Chase's design proved to be a practical solution to providing temperature-controlled carriage of dressed meats, and allowed Swift and Company to ship their products all over the United States and internationally. Swift's attempts to sell Chase's design to major railroads were rebuffed, as the companies feared that they would jeopardize their considerable investments in stock cars, animal pens, and feedlots if refrigerated meat transport gained wide acceptance. In response, Swift financed the initial production run on his own, then — when the American roads refused his business — he contracted with the GTR (a railroad that derived little income from transporting live cattle) to haul the cars into Michigan and then eastward through Canada. In 1880 the Peninsular Car Company (subsequently purchased by ACF) delivered the first of these units to Swift, and the Swift Refrigerator Line (SRL) was created. Within a year the Line’s roster had risen to nearly 200 units, and Swift was transporting an average of 3,000 carcasses a week to Boston, Massachusetts. Competing firms such as Armour and Company quickly followed suit. By 1920 the SRL owned and operated 7,000 of the ice-cooled rail cars. The General American Transportation Corporation assumed ownership of the line in 1930.

(PD) Photo: Tiffany Refrigerator Car Company
An advertisement taken from the 1st edition (1879) of the Car-Builders Dictionary for the Tiffany Refrigerator Car Company, a pioneer in the design of refrigerated railroad cars.

Live cattle and dressed beef deliveries to New York (short tons): [5]

(Stock Cars) (Refrigerator Cars)
  Year   Live Cattle   Dressed Beef
  1882 366,487 2,633
  1883 392,095 16,365
  1884 328,220 34,956
  1885 337,820 53,344
  1886 280,184 69,769


19th Century American Refrigerator Cars: [6]

  Year   Private Lines   Railroads   Total
  1880 1,000 est. 310 1,310 est.
  1885 5,010 est. 990 6,000 est.
  1890 15,000 est. 8,570 23,570 est.
  1895 21,000 est 7,040 28,040 est.
  1900 54,000 est. 14,500 68,500 est.

The "Ice Age"

(PD) Photo: Detroit Publishing Company
Men harvest ice on Michigan's Lake Saint Clair, circa 1905. The ice would be cut into blocks and hauled by wagon to a cold storage warehouse, and held until needed.

The use of ice to refrigerate and thus preserve food dates back to prehistoric times. Through the ages, the seasonal harvesting of snow and ice was a regular practice of many cultures. China, Greece, and Rome (to name a few) all stored ice and snow in caves or dugouts lined with straw or other insulating materials. Rationing of the ice allowed the preservation of foods during hot periods, a practice that was successfully employed for centuries. For most of the 1800s, natural ice (harvested from ponds and lakes) was used to supply refrigerator cars. At high altitudes or northern latitudes, one foot tanks were often filled with water and allowed to freeze. Ice was typically cut into blocks during the winter and stored in insulated warehouses for later use, with sawdust and hay packed around the ice blocks to provide additional insulation. A late-19th century wood-bodied reefer required reicing every 250 to 400 miles. By the turn of the 20th Century manufactured ice became more common. The Pacific Fruit Express (PFE), for example, maintained 7 natural harvesting facilities, and operated 18 artificial ice plants. Their largest plant (located in Roseville, California) produced 1,200 "short" tons of ice daily, and Roseville’s docks could accommodate up to 254 cars. At the industry’s peak, 13 million short tons of ice was produced for refrigerator car use annually.

"Top Icing"

Top icing is the practice of placing a 2- to 4-inch layer of crushed ice over the top of agricultural products that have high respiration rates, need high relative humidity, and benefit from having the cooling agent sit directly atop the load (or within individual boxes). Cars with pre-cooled fresh produce were top iced just before shipment. Top icing added considerable dead weight to the load. Top-icing a 40-foot reefer required in over 10,000 pounds of ice. It had been postulated that as the ice melts, the resulting chilled water would trickle down through the load to continue the cooling process. It was found, however, that top-icing only benefited the uppermost layers of the cargo, and that the water from the melting ice often passed through spaces between the cartons and pallets with little or no cooling effect. It was ultimately determined that top-icing is useful only in preventing an increase in temperature, and was eventually discontinued.


(PD) Engraving: Railroad Gazette
Joel Tiffany's design mounted the ice tank in a clerestory atop the car's roof, and relied on a train's motion to circulate cool air throughout the cargo space. This engraving of Tiffany's original "Summer and Winter Car" appeared in the Railroad Gazette just before Tiffany received his refrigerator car patent in July, 1877.

The typical service cycle for an ice-cooled produce reefer (generally handled as a part of a block of cars):

  1. The cars were cleaned with hot water or steam.
  2. Depending on the cargo, the cars might have undergone 4 hours of "pre-cooling" prior to loading, which entailed blowing in cold air through one ice hatch and allowing the warmer air to be expelled through the other hatches. The practice, dating back almost to the inception of the refrigerator car, saved ice and resulted in fresher cargo.
  3. The cars' ice bunkers were filled, either manually from an icing dock, via mechanical loading equipment, or (in locations where demand for ice was sporadic) using specially-designed field icing cars.
  4. The cars were delivered to the shipper for loading, and the ice was topped-off.
  5. Depending on the cargo and destination, the cars may have been fumigated.
  6. The train would depart for the eastern markets.
  7. The cars were re-iced in transit approximately once a day.
  8. Upon reaching their destination, the cars were unloaded.
  9. If in demand, the cars would be returned to their point of origin empty. If not in demand, the cars would be cleaned and (if possible) used for a dry shipment.

Refrigerator cars required effective insulation to protect their contents from temperature extremes. "Hairfelt" derived from compressed cattle hair, sandwiched into the floor and walls of the car, was inexpensive but flawed — over its three- to four-year service life it would decay, rotting out the car's wooden partitions and tainting the cargo with a foul odor. The higher cost of other materials such as "Linofelt" (woven from flax fibers) or cork prevented their widespread adoption. Synthetic materials such as fiberglass and polystyrene, both introduced after World War II, offered the most cost-effective and practical solution.

"Depression Baby"

During the 1930s, the North American Car Company produced a one-of-a-kind, four-wheeled ice bunker reefer intended to serve the needs of specialized shippers who did not generate sufficient product to fill a full-sized refrigerator car. NADX #10000 was a 22-foot-long, all-steel car that resembled the "forty-and-eights" used in Europe during World War I. The prototype weighed in at 13½ tons and was outfitted with a 1,500-pound ice bunker at each end. The car was leased to Hormel and saw service between Chicago, Illinois and the southern United States. The concept failed to gain acceptance with the big eastern railroads and no additional units were built.

Dry ice

The Santa Fe Refrigerator Despatch (SFRD) briefly experimented with dry ice as a cooling agent in 1931. The compound was readily-available and seemed like an ideal replacement for frozen water. Dry ice melts at -109°F / -78.33°C (versus 32°F / 0°C for conventional ice) and was twice as effective thermodynamically. Overall weight was reduced as the need for brine and water was eliminated. While the higher cost of dry ice was certainly a drawback, logistical issues in loading long lines of cars efficiently prevented it from gaining acceptance over conventional ice. Worst of all, it was found that dry ice can adversely affect the color and flavor of certain foods if placed in too close a proximity to them.

Mechanical refrigeration

In the latter half of the 20th Century mechanical refrigeration began to replace ice-based systems. Mechanical refrigeration units replaced the "armies" of personnel required to re-ice the cars. In the 1960s the "plug" door was introduced, providing a larger opening to facilitate loading and unloading. These tight-fitting doors were better insulated and could maintain a more even temperature inside the car. By the mid-1970s those few remaining ice bunker cars were relegated to "top-ice" service, where crushed ice was applied atop the commodity.

Cryogenic refrigeration

(CC) Photo: Darrell Sawyer / TrainWeb.com
Cryogenic refrigerator cars, such as those owned and operated by Cryo-Trans, Inc., are still used to transport frozen food products, including french fries. Today, Cryo-Trans operates a fleet in excess of 515 cryogenic rail cars.

The Topeka, Kansas shops of the Santa Fe Railway built five experimental refrigerator cars employing liquid nitrogen as the cooling agent in 1965. A mist of liquified nitrogen was released throughout the car if the temperature rose above a predetermined level. Each car carried 3,000 pounds (1,360 kilograms) of refrigerant and could maintain a temperature of minus 20 degrees Fahrenheit (−30 °Celsius). During the 1990s, a few rail car manufacturers experimented with the use of liquid carbon dioxide (CO2) as a cooling agent. The move was in response to rising fuel costs, and was an attempt to eliminate the standard mechanical refrigeration systems that required periodic maintenance. The CO2 system can keep the car's load frozen solid as long as 14 to 16 days. Several hundred "cryogenic" refrigerator cars were placed in service transporting frozen foodstuffs, though they failed to gain wide acceptance (due, in part, to the rising cost of liquid carbon dioxide). Since cryogenic refrigeration is a proven technology and environmentally friendly, the rising price of fuel and the increased availability of carbon dioxide from Kyoto Protocol-induced capturing techniques may lead to a resurgence in cryogenic railcar usage. Cryo-Trans, Inc. (founded in 1985) has since dedicated 200 of its refrigerated cars to wine transportation service.

Experimentation

Aluminum and stainless steel

In 1946, the Pacific Fruit Express procured from the Consolidated Steel Corporation of Wilmington, California two 40-foot aluminum-bodied ventilator refrigerator cars, to compare the durability of the lightweight alloy versus that of steel. It was hoped that weight savings (the units weighed almost 10,000 pounds less than a like-sized all-steel car) and better corrosion resistance would offset the higher initial cost. One of the aluminum car bodies was manufactured by Alcoa (PFE #44739), while the other was built by the Reynolds Aluminum Company (PFE #45698). The cars (outfitted with state-of-the-art fiberglass insulation and axle-driven fans for internal air circulation) traveled throughout the Southern Pacific and Union Pacific systems, where they were displayed to promote PFE's post-World War II modernization. Though both units remained in service over 15 years (#45698 was destroyed in a wreck in May 1962, while #44739 was scrapped in 1966), no additional aluminum reefers were constructed, cost being the likely reason. Also in 1946 the Consolidated Steel delivered the world's only reefer to have a stainless steel body to the Santa Fe Refrigerator Despatch. The 40-foot car was equipped with convertible ice bunkers, side ventilation ducts, and axle-driven circulation fans. It was thought that stainless steel would better resist the corrosive deterioration resulting from salting the ice. The one-of-a-kind unit entered service as #13000, but was subsequently re-designated as #1300, and later given #4150 in 1955.[13] #4150 spent most of its life in express service. Cost was cited as the reason no additional units were ordered. The car was dismantled at Clovis, New Mexico in February, 1964.

Hopper cars

© Photo: Ron Hawkins
ATSF #101438, one of a hundred specially-built "Conditionaire" centerflow hoppers purchased by the Atchison, Topeka and Santa Fe Railway in 1972.

In 1969, the Burlington Northern Railroad ordered a number of modified covered hopper cars from American Car and Foundry for transporting perishable food in bulk. The 55 foot- (16.76 meter)-long cars were blanketed with a layer of insulation, equipped with roof hatches for loading, and had centerflow openings along the bottom for fast discharge. A mechanical refrigeration unit was installed at each end of the car, where sheet metal ducting forced cool air into the cargo compartments. The units, rated at 100 "short" tons (90.72 metric tons) capacity (more than twice that of the largest conventional refrigerator car of the day) were economical to load and unload, as no secondary packaging was required. Apples, carrots, onions, and potatoes were transported in this manner with some success. Oranges, on the other hand, tended to burst under their own weight, even after wooden baffles were installed to better distribute the load. The Santa Fe Railway leased 100 of the hoppers from ACF, and in April, 1972 purchased 100 new units. The cars' irregular, orange-colored outer surface (though darker than the standard AT&SF yellow-orange used on reefers) tended to collect dirt easily, and proved difficult to clean. Santa Fe eventually relegated the cars to more typical, non-refrigerated applications.

Notes and references

  1. Boyle and Estrada
  2. White, p. 31
  3. White, p. 33
  4. White, p. 45
  5. Railway Review, January 29, 1887, p. 62: The subject cars travelled on the Erie, Lackawanna, New York Central, and Pennsylvania railroads.
  6. Source: Poor's Manual of Railroads and ICC and U.S. Census reports.
  7. Each block weighed between 200 and 400 pounds; crushed ice was typically used for meat cars.
  8. Each car required approximately 5½ "short" tons (5 metric tons) of ice.
  9. The name of the "patentee" was displayed on the car's exterior, a practice intended to "... impress the shipper and intimidate the competition ...," even though most patents covered trivial or already-established design concepts.
  10. The use of similar "billboard" advertising on freight cars was banned by the Interstate Commerce Commission in 1937, and thereafter cars so decorated could no longer be accepted for interchange between roads.
  11. The car had a single, centrally located ice bunker which was said to offer better cold air distribution. The two segregated cold rooms were well suited for less-than-carload (LCL) shipments.
  12. The mechanical refrigeration unit is housed at the car's "A" end, behind the grill at the lower left.
  13. Hendrickson and Scholz, p. 8