Difference between revisions of "AY Honors/Model Railroad/Answer Key"

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[[Image:Santa Fe 33055 Route of the Chief.jpg|thumb|350px|right|[[Santa Fe Refrigerator Despatch|SFRD]] #33055 bears an advertisement for the railroad's ''[[Chief (passenger train)|Chief]]'' passenger train. "[[Billboard (advertisement)|Billboard]]" advertising such as this was placed on the company's refrigerator cars (and [[boxcars]]) from January, 1940 to April, 1947. Note that the ice hatches are in the "ventilator" position.]]
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[[Image:Art2471940.jpg|thumb|350px|right|A [[World War II]]-era wood-sided, ice bunker "reefer" of the American Refrigerator Transit Company (ART), one specially-designated for the transport of dairy products, ''circa'' 1940.]]
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<!-- 1. Give the history and development of model railroading. -->
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===Practical Beginnings=== <!--T:37-->
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The development of model railroading runs, for the most part, parallel to the development of real-life (or 'prototype') railroading. The first model railroads appeared after 1810 and were one-of-a-kind creations used in designing or promoting their full-sized counterparts. Railroading was first developed to reduce the time and effort required to move raw materials or people over short distances made otherwise difficult by bad weather and poor roadways. The first rail cars were pulled along by animals, while steam-propelled machines, whether trains or automobiles, followed as quickly as the public was ready to adopt them. Various authors from diverse countries each lay different claims to the origins of both railroading and model railroading; and for this reason it is nearly impossible to reckon the precise date and location of the first model trains. By the 1830's, however, several countries including Germany, France, England and the United States were each developing steam-driven railroads to move freight and passengers. Original models of these first railroads are still on display in museums, and the first toy trains appeared not long after in German and British catalogs of the 1860's.
  
A '''refrigerator car''' (or '''"reefer"''') is a [[Refrigeration|refrigerated]] [[boxcar]], a piece of [[railroad]] [[rolling stock]] designed to carry perishable freight at specific temperatures. Refrigerator cars differ from simple [[Thermal insulation|insulated]] boxcars and [[Ventilation (architecture)|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 [[carbon dioxide|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 [[bogie|trucks]] and other modifications that allow them to travel with [[train|passenger trains]].
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===On the Right Track=== <!--T:3-->
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The first toy trains of the 1840's actually ran on steam produced by filling the metallic model with water and placing in on a heating surface. These '[[w:Carpet_railway|carpet railways]]' didn't use track and often left a trail of water behind them. In 1891, the German company ''Märklin'' began offering a track system for its wind-up, or "clockwork," trains which were moving along on their own electric power within the decade. The famous American toy train manufacturer, ''Lionel,'' began selling its first sectional three-rail electric train track (later called "Standard Gauge") in 1906, just five years after their first store window display called the "Electric Express" captured public attention. By 1910, the British company ''Bassett-Lowke'' had opened a London showroom exclusively for its model trains. Other early toy train producers from around the world were ''Lima, Bing, Fleischmann'' and ''Rivarossi.''
  
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 [http://www.uprr.com/aboutup/photos/pfe/graphics/551.jpg 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).
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===The World's Greatest Hobby=== <!--T:4-->
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Today, dozens of manufacturers from around the world sell their model railroading products via thousands of catalogs, magazines, websites and hobby stores. Model railroading has many fascinating aspects to attract people with many different interests and skill sets. Some modelers continue to make many things, even engines track and cars, from scratch, while a satisfying railroading experience can be gained from many ready-made sets available right out of the box. Called by many [http://www.greatesthobby.com 'The World's Greatest Hobby'], model railroading will doubtless continue to be a source of great enjoyment for many years to come.
  
==History==
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===Background===
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[[Image:IC 14713.jpg|thumb|300px|right|[[Illinois Central Railroad]] #14713, a ventilated fruit car dating from 1893.]]
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[[File:Steam locomotive work.gif|thumb|200px|Steam Locomotion]]
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Steam powered locomotives use burning coal or wood to heat water enclosed in a large boiler. The steam released from this boiler acts much like the steam that emanates from a kettle of boiling water on the stove. By channeling the steam’s pressure into an engine cylinder, it pushes a piston that provides mechanical power to the wheels. Steam locomotives dominated rail transport until the mid-1900’s when diesel and electric locomotives took over. Steam locomotives had to stop periodically to receive a new supply of water plus logs or coal.
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{{clear}}
  
After the end of the [[American Civil War]], [[Chicago, Illinois]] emerged as a major [[railway]] center for the [[Distribution (business)|distribution]] of livestock raised on the [[Great Plains]] to Eastern markets.<ref>Boyle and Estrada</ref>  Getting the animals to market required herds to be driven up to 1,200 miles (2,000 km) to [[railhead]]s in [[Kansas City, Missouri]], where they were loaded into specialized [[Stock car (rail)|stock car]]s and [[transport]]ed live ("on-the-hoof") to regional [[processing]] centers. Driving cattle across the plains also led to tremendous weight loss, and some animals died along the way.
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[[File:Three-loco-styles.jpg|thumb|200px|Three Diesel Locomotives]]
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Diesel locomotives burn diesel fuel in a combustion engine in virtually the same way as in the cars we use every day. The main difference between various types of diesel locomotives relates to how the power from its diesel engine is transferred to its drive wheels. Diesel locomotives were a great improvement over the steam locomotives in that they are quieter, cleaner, easier to maintain, and they can be started and stopped quickly, without the delay of waiting for water to boil. In mild weather, diesel engines don’t need to be left running to be ready to use at a moment’s notice, and diesel locomotives require far fewer people to operate them. Diesel locomotives continue to be used today.
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Upon arrival at the local processing facility, livestock were either [[slaughter]]ed 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 Franklin Swift|Gustavus Swift]] began looking for a way to ship dressed meats from his packing plant in Chicago to the East.
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[[File:NECtrain3967.jpg|thumb|200px|An Electric Locomotive]]
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Electric locomotives get power to turn their wheels from electric motors housed inside. Most such locomotives receive their electrical power from overhead wires or an additional rail running alongside the rails used by the wheels. Some electric locomotives employ onboard batteries to drive them. Electricity became the preferred way of driving trains that had to travel underground or through frequent tunnels because they produce no exhaust as diesel or gasoline engines do. Another advantage is that they are virtually silent when operating and are easier to maintain because they utilize fewer moving parts than mechanical combustion engines.
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{{clear}}
  
===Early attempts at refrigerated transport===
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<!--T:45-->
[[Image:Tiffany ad 1879 CBD.jpg|thumb|325px|left|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.]]
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<!-- 3. Know the name, scale, and track gauge for four model railroad gauges. -->
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The six most popular scales used are: G scale, Gauge 1, O scale, H0 scale (in Britain, the similarly sized 00 is used), TT scale, and N scale (1:160), although there is growing interest in Z scale. H0 scale is the single most popular scale of model railroad. Popular narrow-gauge scales include HOn3 Scale and Nn3, which are the same scale as HO and N, except with a narrower spacing between the tracks (in these examples, a scale three feet instead of the 4'8.5" standard gauge).
  
A number of attempts were made during the mid-1800s to ship [[agriculture|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.<ref>White, p. 31</ref> 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.
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The words scale and gauge seem at first to be used interchangeably in model railways, but their meanings are different. Scale is the model's measurement as a proportion to the original, while gauge is the measurement between the two running rails of the track.
The first consignment of dressed beef left the [[Union Stock Yards|Chicago stock yards]] in 1857 in ordinary [[boxcar]]s 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.
 
  
[[Image:Interior of ice bunker reefer.jpg|thumb|250px|right|The interior of a typical ice-bunker reefer from the [[1920s]]; the wood sheathing would give way to [[plywood]] within twenty years. Vents in the bunker at the end of the car, along with slots in the wood floor racks, allowed cool air to circulate around the contents during transit.]]
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[[Detroit, Michigan|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 [[George Hammond (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.<ref>White, p. 33</ref> 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.<ref>White, p. 45</ref>  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 car (rail)|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 &mdash; when the [[United States|American]] roads refused his business &mdash; 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]] would assume ownership of the line in 1930.
 
 
 
[[Image:One of the first cars out of the Detroit plant of American Car & Foundry - Built 1899 for Swift Refrigerator Line - Chicago Historical Society.jpg|thumb|325px|right|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]].]]
 
 
 
'''Live cattle and dressed beef deliveries to New York ([[short tons]]):'''
 
{| class="toccolours"
 
 
|-
 
|-
|
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!Name || Scale || Gauge
|align=center | <small>''(Stock Cars)''
 
|align=center | <small>''(Refrigerator Cars)''
 
 
|-
 
|-
|align=center | &nbsp; '''Year &nbsp;
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| G scale ||1:22.5 || {{units|45 mm|1.75 inches}}
|align=center | '''Live Cattle &nbsp;
 
|align=center | '''Dressed Beef
 
 
|-
 
|-
|&nbsp; 1882
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| Gauge 1 ||1:32 ||{{units|44.45 mm|1.75 inches}}
|align=center | 366,487
 
|align=center | 2,633
 
 
|-
 
|-
|&nbsp; 1883
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| 0 scale ||1:43 or 1:48 ||{{units|32 mm|1.25 inches}}
|align=center | 392,095
 
|align=center | 16,365
 
 
|-
 
|-
|&nbsp; 1884
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| H0 scale ||1:87 ||{{units|16.5 mm|0.65 inches}}
|align=center | 328,220
 
|align=center | 34,956
 
 
|-
 
|-
|&nbsp; 1885
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| TT scale ||1:120 ||{{units|12 mm|0.47 inches}}
|align=center | 337,820
 
|align=center | 53,344
 
 
|-
 
|-
|&nbsp; 1886
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| N scale ||1:148 to 1:160 || {{units|9 mm|0.354 inches}}
|align=center | 280,184
 
|align=center | 69,769
 
|}
 
 
 
<small>The subject cars travelled on the [[Erie Railroad|Erie]], [[Delaware, Lackawanna and Western Railroad|Lackawanna]], [[New York Central Railroad|New York Central]], and [[Pennsylvania Railroad|Pennsylvania]] railroads.</small>
 
 
 
<small>Source: ''Railway Review'', [[January 29]], [[1887]], p. 62.</small>
 
 
 
[[Image:Early refrigerator car design circa 1870.jpg|thumb|325px|right|A ''circa'' [[1870]] refrigerator car design.  Hatches in the roof provided access to the ice tanks at each end.]]
 
 
 
'''19th Century American Refrigerator Cars:'''
 
{| class="toccolours"
 
|-
 
|align=center | &nbsp; '''Year &nbsp;
 
|align=center | '''Private Lines &nbsp;
 
|align=center | '''Railroads &nbsp;
 
|align=center | '''Total
 
|-
 
|&nbsp; 1880
 
|align=center | 1,000 ''est.
 
|align=center | 310
 
|align=center | 1,310 ''est.
 
 
|-
 
|-
|&nbsp; 1885
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| Z scale ||1:220 ||{{units|6.5 mm|0.256 inches}}
|align=center | 5,010 ''est.
 
|align=center | 990
 
|align=center | 6,000 ''est.
 
|-
 
|&nbsp; 1890
 
|align=center | 15,000 ''est.
 
|align=center | 8,570
 
|align=center | 23,570 ''est.
 
|-
 
|&nbsp; 1895
 
|align=center | 21,000 ''est
 
|align=center | 7,040
 
|align=center | 28,040 ''est.
 
|-
 
|&nbsp; 1900
 
|align=center | 54,000 ''est.
 
|align=center | 14,500
 
|align=center | 68,500 ''est.
 
 
|}
 
|}
  
<small>Source: ''Poor's Manual of Railroads'' and [[Interstate Commerce Commission|ICC]] and [[U.S. Census]] reports.</small>
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<!-- 4. Know the shapes and names of at least eight track plan arrangements. -->
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==='''Oval'''=== <!--T:48-->
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[[File:Model Railroad Oval Track.gif|thumb|200px|Oval Layout Design]]
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The simplest layout for a model railroad and the starting point for most designs. In this design, two straightaway segments are connected by a semi-circle at each end. This is also the only layout which can easily be created with sectional track without the use of a manufacturer-specific design. Curved sectional track is sold by radii (half the distance across the semi-circle) and a box of such track sections will almost always create exactly half a circle. The two straightaway sections will usually utilize multiple pieces of sectional straight track, as desired by the modeler.
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==='''Figure-Eight'''===
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[[File:Model Railroad Figure-Eight Track.gif|thumb|200px|Figure-Eight Layout Design]]
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The second most common beginner's layout. This layout is best accomplished by purchasing it as a single set or following a manufacturer's layout design using their sectional track. The intersection in the center of the layout can either be accomplished by a piece of crossover track, or by elevating one track over the other. In the latter case, a set of piers or risers will be needed to raise the track at an appropriate rate.
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==='''Twice-Around'''===
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[[File:Model Railroad Twice-Around Track.gif|thumb|200px|Twice-Around Layout Design]]
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A modification of the figure-eight, in which one end-loop is contained within the other. The crossover here is not at 90° like in the basic figure-eight example and can be accomplished by using a alternately angled crossover piece or by using elevated track to pass one track over the other. The twice-around layout design allows the train to run continuously for longer than the simple oval before reaching its starting point.
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==='''Point-to-Point'''===
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[[File:Model Railroad Point-to-Point Track.gif|thumb|200px|Point-to-Point Layout Design]]
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This design does not allow a train to run continuously indefinitely, as you might imagine most plans would allow. However, this is the design that most closely resembles real-life railroad operation, since real-life railroads run across country, not in loops or circles. You can construct more elaborate yards at each end in order to enjoy the complexities of real-world operation.
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==='''Out-and-Back'''===
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[[File:Model Railroad Out-and-Back Track.gif|thumb|200px|Out-and-Back Layout Design]]
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This design approximates real-world operation, as each train must make a journey before it returns to the yard from which it originated. Although real freight never returns to its origin the same way it left, this arrangement does allows you to concentrate your time and resources on one yard instead of the two required in a Point-to-Point design (above).
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==='''Loop-to-Loop'''===
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[[File:Model Railroad Loop-to-Loop Track.gif|thumb|200px|Loop-to-Loop Layout Design]]
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This design diverges from realistic operation, but does allow the operator to interact with a continuous-running train. A yard can be added in the middle of the layout to simulate freight coming in from each direction. When modeling with two-rail scales, such as HO and smaller, special wiring will be required to insulate each loop from the rest of the line and allow the direction to be reversed on the mainline.
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==='''Dog Bone'''===
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[[File:Model Railroad Dog-Bone Track.gif|thumb|200px|Dog-Bone Layout Design]]
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This design is similar to the loop-to-loop design, but allows for continuous running without intervention from an operator. In addition, the two tracks running side-by-side simulate the double-track lines often seen in real life.
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==='''Twisted Dog Bone'''===
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[[File:Model Railroad Twisted-Dog-Bone Track.gif|thumb|200px|Twisted-Dog-Bone Layout Design]]
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This design is adds additional length to the mainline featured in the basic dog-bone design (above). Keeping one or both of the end-loops out of sight allows this layout to very realistically simulate the long distance running of a real railroad.
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===The "Ice Age"===
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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]], [[Ancient Greece|Greece]], and [[Ancient Rome|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.  
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===Cleaning & Checking Basic Trackwork=== <!--T:50-->
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Most model railroads receive power for their electric motors through the tracks they run on. Thus, track must be kept clean and free of even the smallest obstructions. A train running on a dirty track does not operate smoothly or realistically, or may not run at all! The space between rails must also be maintained, though this is more of an issue when individual rails and ties have been laid down by hand. Sectional track usually maintains its proper gauge (space between the rails). Rail cleaning solution can be safely wiped across model track and track-cleaning cars are also available for running around the layout and cleaning hard-to-reach places.
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===Checking Wheels and Couplers===
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Locomotives and cars are kept rolling along together by various types of 'couplers.' These can be very tiny on the smaller model railroad scales, but in any case, they must be kept clean and properly hooked together for a train to run along smoothly. Another common problem is derailment when a car's wheels come off the track. This can also be harder to detect on smaller scale trains, but it will eventually get noticed as cars may tip completely off the track. Nevertheless, derailment is the most common operating problem encountered and should be one of the first possibility to check when things are going wrong.
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===Lubricating Engine Drive Mechanisms===
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Most model locomotives are powered by electric motors which involve a minimum of moving parts. There are typically tiny gears used in transferring the turning motor's power to the drive wheels of the locomotive. These are easily lubricated with special grease and/or oil available from a hobby supply store. Be careful to follow both the engine and lubricant manufacturers' instructions. Most wheels on other non-powered cars do not need to be oiled or greased except in rare cases.
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===Detailing Scenes & Structures===
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Model structures and landscape gather dust, making them look less realistic. These elements of a typical layout should be well anchored with adhesive when they are first installed so that their surfaces can be brushed clean, repainted, re-weathered and even vacuumed. In addition, its fun and rewarding to keep a layout fresh by installing new structures or creating new track-side scenes once your basic modeling is complete.
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===Testing Electrical Connections===
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Most model locomotives receive their power from the tracks below through one or more of their wheel sets. Since these wheels are turning, they transmit their power through stationary metal brushes that maintain contact with the tiny axle running between these wheels. These brushes should be kept clean and checked whenever an electrical problem is suspected. In addition, the wires which run from the operator's power pack to the rails themselves can become tangled, shorted out (when they inadvertently touch each other), or disconnected all leading to potential breakdown in the power supplied to the model railroad. A simple electric meter available from a hobby or electronics store can help determine where a breakdown is occurring by testing (1) the output of the power pack directly, (2) the presence of power on the set of tracks where the train is located, or (3) at any control point in between, such as when a control panel switch is used to control power to different track sections.
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===Adjusting Turnouts, Switch Machines & Ground Throws===
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Turnouts (sometimes called 'switches') are used to send a train from one set of track to another. These are easy places for trains to become derailed because the wheels must pass over a series of changeable mechanical parts that are more complex than the simple two (or three) rails used elsewhere in the layout. The 'points' of a switch are moved between two different resting positions which determine what path the trail will take after it passes through the turnout. These points must rest securely against either the inside or outside rail and must not move otherwise. If the points are moved remotely, by an electrical signal sent from the control panel to a 'switch machine' next to the turnout, then this switch machine and its associated wiring must be in good working order. If the switch is operated by hand using a small lever or 'ground throw' next to the turnout, then the ground throw needs to be kept clean and lubricated and able to move the points the full distance between their two desired positions.
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==== Covered Hopper ==== <!--T:52-->
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[[Image:6619.JPG|thumb|200px|Covered hopper]]
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Structurally, a covered hopper is very similar to an open­top hopper car. What distinguishes this type of car from an open hopper is the car's roof, and also the car's overall size. Covered hoppers typically carry loads of less dense, and therefore lighter, materials, so they are built to a higher cubic capacity than open top hoppers.  
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[[Image:Top icing reefer.jpg|thumb|150px|right|Top icing of bagged vegetables in a refrigerator car.]]
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====Box Car==== <!--T:13-->
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[[Image:CIL 1620 20050710 IN Linden.jpg|thumb|200px|Box car]]
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A boxcar (the American term; the British call this kind of car a "goods van" while in Australia, they are usually referred to as "louvre vans") is a railroad car that is enclosed and generally used to carry general freight. The boxcar, while not the simplest freight car design, is probably the most versatile, since it can carry most loads. Boxcars have side doors of varying size and operation, and some include end doors and adjustable bulkheads to load very large items.
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By the turn of the 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.
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====Container Car==== <!--T:14-->
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[[Image:Containerzug 100 7207.jpg|thumb|200px|Container cars]]
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''Containerization'' is a system of intermodal freight transport cargo transport using standard ISO containers known as ''shipping containers'' that can be loaded and sealed intact onto container ships, railroad cars, planes, and trucks. The introduction of containers resulted in vast improvements in port handling efficiency, thus lowering costs and helping lower freight charges and, in turn, boosting trade flows. Almost every manufactured product humans consume spends some time in a container.
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====Flat car====
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[[Image:JNR type tora70000 flatcar.jpg|thumb|200px|Flat car]]
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A flatcar (also flat car) is a piece of railroad rolling stock that consists of an open, flat deck on four or six wheels or a pair of trucks (US) or bogies (UK). The deck of the car can be wood or steel, and the sides of the deck can include pockets for stakes or tie-down points to secure loads. Flatcars designed for carrying machinery have sliding chain assemblies recessed in the deck. Flatcars are used for loads that are too large or cumbersome to load in enclosed cars such as boxcars. They are also often used to transport containers or trailers in intermodal shipping.
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====Gondola====
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[[Image:PhosphateGon.JPG|thumb|200px|Gondola car]]
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A gondola is an open-top type of rolling stock that is used for carrying loose bulk materials. Because of its low side walls, gondolas are used to carry either very dense material, such as steel plates or coils, or bulky items such as prefabricated pieces of rail track.
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====Refrigerator Car====
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[[Image:ARMN 761511 20050529 IL Rochelle.jpg|thumb|200px|Modern refrigerator car: note the grill at the lower right (the car's "A" end) where the mechanical refrigeration unit is housed.]]
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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 were originally ice-cooled, but now are equipped with any one of a variety of mechanical refrigeration systems.
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===="Top Icing"====
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====Stock Car==== <!--T:15-->
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.
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In railroad terminology, a stock car is a type of rolling stock used for carrying livestock (not carcasses) to market. A traditional stock car resembles a boxcar with slats missing in the car's side (and sometimes end) for the purpose of providing ventilation; stock cars can be single-level for large animals such as cattle or horses, or they can have two or three levels for smaller animals such as sheep, pigs, and poultry.
 
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====Tank Car====
Image:Ice Harvesting on Lake St Clair Michigan circa 1905--photograph courtesy Detroit Publishing Company.jpg|Men harvest ice on [[Michigan|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.
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[[Image:TILX290344.JPG|thumb|200px|Tank car]]
Image:Men loading ice blocks into reefers.jpg|Ice blocks (also called "cakes") are manually placed into reefers from a covered icing dock. Each block weighed between 200 and 400 pounds; crushed ice was typically used for meat cars.
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A tank car is a type of railroad rolling stock designed to transport liquid and gaseous commodities. Outside of North America, they are also known as tank wagons or tanker wagons.
<!-- Deleted image removed: Image:GM&O Refrigerator.jpg|An early version of a field icing car loads a Merchants Despatch Transportation Co. reefer (bearing the herald of the [[Gulf, Mobile and Ohio Railroad|GM&O]]) in [[Norfolk, Virginia]] on [[April 19]], [[1955]]. -->
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Image:Mechanical Ice Loader.jpg|The "business end" of a mechanical ice loading system services a line of Pacific Fruit Express refrigerator cars. Each car will require approximately 5½ short tons (5 [[metric ton]]s) of ice.
 
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[[Image:Topping off FGE reefer with ice.jpg|thumb|150px|right|Workmen top off a reefer's top-mounted bunkers with crushed ice.]]
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====Coach Cars==== <!--T:54-->
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[[File:UICX Rome.jpg|thumb|200px|A coach car in Rome]]
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The most basic passenger car, the coach car is lined with rows of seats like a bus. In some cases, a set of seats will face each other making it possible for passengers to pass the time in conversation. Passengers with carry-on baggage usually find overhead or under-seat storage available. In large, metropolitan areas, many people ride on the coach cars of their commuter trains every day to get to and from work. Some coach cars have seating on two levels which doubles their capacity to transport passengers.
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The typical service cycle for an ice-cooled produce reefer (generally handled as a part of a block of cars):
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====Dining Cars==== <!--T:17-->
# The cars were cleaned with hot water or steam.
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[[File:Buffet dining car SBB.jpg|thumb|200px|A Swiss dining car modeled by Roco]]
# 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.
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A dining car serves food to its passengers. Its like a long, narrow restaurant on wheels. The rail line must employ extra personnel to prepare food and wait on the passengers. A more limited version of the dining car is the "lounge" car, which serves only refreshments and can provide passengers with larger, more comfortable seats rather than tables to sit at.
# The cars' ice bunkers were filled, either manually from an [http://www.uprr.com/aboutup/photos/pfe/graphics/24.jpg icing dock], via mechanical loading equipment, or (in locations where demand for ice was sporadic) using specially-designed [http://www.uprr.com/aboutup/photos/pfe/graphics/spe11-71.jpg field icing cars].
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# The cars were delivered to the shipper for loading, and the ice was topped-off.
 
# Depending on the cargo and destination, the cars may have been fumigated.
 
# The train would depart for the eastern markets.
 
# The cars were reiced in transit approximately once a day.
 
# Upon reaching their destination, the cars were unloaded.
 
# 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.  
 
  
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====Observation Cars==== <!--T:18-->
Image:Tiffany RRG 1877.jpg|This engraving of Tiffany’s original "Summer and Winter Car" appeared in the ''Railroad Gazette'' just before Joel Tiffany received his refrigerator car patent in July, [[1877]]. 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.
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[[File:VIA Passenger Train.jpg|thumb|200px|A Canadian observation car]]
Image:Reefers-shorty-Armour-Kansas-City-3891-Pullman.jpg|A [[Pullman Company|Pullman]]-built "shorty" [[reefer]] bears the ''Armour Packing Co. &nbsp; · &nbsp; Kansas City'' logo, ''circa'' [[1885]].  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.
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The observation car is almost always the last car in a passenger train in order to take advantage of the view from the rear of the train. It might have other features that provide sleeping, refreshments or food, but it almost always has larger windows around the car and a U-shaped lounge at the end where passengers can see the view where the train has just traversed. Observation cars modeled on older era railroads might have a small open-air porch off the rear of the last car.
Image:Reefers-shorty-ATSF-CM-type-1898-cyc ACF builders photo.jpg|A rare double-door refrigerator car utilized the "Hanrahan System of Automatic Refrigeration" as built by [[American Car and Foundry Company|ACF]], ''circa'' [[1898]]. 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.
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Image:Reefers-shorty-Anheuser-Busch-Malt-Nutrine ACF builders photo pre-1911.jpg|A pre-[[1911]] "shorty" reefer bears an advertisement for [[Anheuser-Busch|Anheuser-Busch's]] ''Malt Nutrine'' tonic. The use of similar "billboard" [[advertising]] on [[freight car]]s was banned by the [[Interstate Commerce Commission]] in [[1937]], and thereafter cars so decorated could no longer be accepted for interchange between roads.
 
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Refrigerator cars required effective insulation to protect their contents from temperature extremes. "[[felt|Hairfelt]]" derived from compressed cattle hair, sandwiched into the floor and walls of the car, was inexpensive but flawed &mdash; 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 (material)|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.
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====Sleeping Cars==== <!--T:19-->
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[[File:Type T2 sleeping car.jpg|thumb|200px|A model sleeping car by Rivarossi]]
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"Sleepers" are sometimes called "Pullman cars" in the United States because of the Pullman Company that manufactured a great deal of them beginning in the mid-1800's. Some beds are designed to either roll or fold out of the way or convert into seats for daytime use, while some sleeping compartments look like small personal apartments with their own bathrooms.
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===Mechanical refrigeration===
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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 reice 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.
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[[File:Alco 2-6-6 NYC.jpg|thumb|200px|A New York 2-6-6 Locomotive]]
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[[File:Central Sucre 2-4-0.jpg|thumb|200px|A Central Sucre 2-4-0 Locomotive]]
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[[File:92220 Evening Star (Dave Cooper).jpg|thumb|200px|Standard Class 9F 2-10-0 Locomotive]]
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Steam locomotives are described most commonly by how many wheels they have in each of three sections. The most notable set of wheels are the drive wheels which are usually larger and are connected by the rods which power them. The other two sets of wheels are both smaller and lie ahead of and behind the central drive wheels. Since there are at most three sets of wheels, a locomotive classification will have three numbers separated by dashes. If a locomotive has only drive wheels, the first and last numbers will still appear, but will both be zero. This classification system counts all the wheels (both sides) so when looking at the side of a locomotive, remember to multiply what you see by two.
  
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Image:Cutaway PFE mechanical.jpg|A cutaway illustration of a conventional mechanical refrigerator car, which typically contains in excess of 800 moving parts.
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Pictured to the right are a 2-6-6, a 2-4-0, and a 2-10-0.  
Image:ARMN 761511 20050529 IL Rochelle.jpg|A modern refrigerator car: note the grill at the lower right (the car's "A" end) where the mechanical refrigeration unit is housed.
 
Image:ARMN 110386 detail photo by JS Rybak @ Clarke Ontario Canada April 2005.jpg|State-of-the-art mechanical refrigerator car designs place the removable, end-mounted refrigeration unit outside of the freight compartment in order to facilitate access for servicing or replacement.
 
Image:Amtk74049.jpg|A modern mechanical refrigerator car, outfitted for high-speed service, bears the colors and markings of [[Amtrak Express]], [[Amtrak|Amtrak's]] freight and shipping service.
 
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===Cryogenic refrigeration===
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[[Image:Cryx2038-1.jpg|thumb|325px|right|Cryogenic refrigerator cars, such as those owned and operated by Cryo-Trans, Inc., are still used today to transport frozen food products, including [[french fries]]. Today, Cryo-Trans operates a fleet in excess of 515 cryogenic railcars.]]
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''An excellent diagram with all of a Steam Locomotive's parts is available at Wikipedia: [[w:Steam_locomotive_parts|Steam Locomotive Parts]].''
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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 pre-determined level. Each car carried 3,000 [[pound (mass)|pound]]s (1,360 [[kilogram|kg]]) of refrigerant and could maintain a temperature of minus 20 degrees [[Fahrenheit]] (&minus;30 °C). During the 1990s, a few railcar manufacturers experimented with the use of liquid carbon dioxide (CO<small><sub >2</sub ></small>) 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 CO<small><sub >2</sub ></small> system can keep the car's load frozen solid as long as 14 to 16 days.  
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====Uncontrolled Crossings ==== <!--T:58-->
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[[File:American Crossbuck.jpg|thumb|150px|The American Crossbuck]]
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"Open" or "Uncontrolled" crossings utilize a sign with or without flashing lights and an audible bell warning. These are considered 'open' because there is no barricade to the passage of pedestrians or traffic. In America, the 'crossbuck' is most typically seen at graded crossings. This is the familiar white "X" shape with the words "RAILROAD" and "CROSSING" printed on them.
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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.
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====Controlled Crossings ==== <!--T:24-->
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[[File:Finnish level crossing activated.jpg|thumb|150px|Gated Crossing in Finland]]
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The most typical method of controlling a railroad crossing is with automatic close-able gates. In addition to flashing lights and warning bell, the gates make it difficult for cars or pedestrians to cross the tracks when they are down. Gated crossings have become more elaborate in recent years because accidents can still occur if cars try to drive around the gates.
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===Experimentation===
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====Aluminum and stainless steel====
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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 Metals|Reynolds Aluminum Company]] (PFE #45698).  
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====Mechanical Semaphore Signals ==== <!--T:60-->
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[[File:Lower Signal 1.jpg|thumb|100px|Mechanical Semaphore Signal]]
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Mechanical semaphores utilize a moveable arm (or 'blade') whose position indicates how approaching trains may proceed. A set of differently colored lenses are also mounted on the arm, each passing in front of a stationary light when the arm moves, so that the semaphore can effectively signal trains at night.
  
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.
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====Colored Light Signals ==== <!--T:26-->
The one-of-a-kind unit entered service as #13000, but was subsequently redesignated as #1300, and later given #4150 in [[1955]].<ref>Hendrickson and Scholz, p. 8</ref>
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[[File:Railroad lamp-2.jpg|thumb|100px|Colored Light Signal]]
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These signals control train movements by displaying one of several colors of lights. They can also position the lights differently in order to send additional information to the engineer.
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<nowiki>#4150</nowiki> 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]].
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Besides track, locomotives and cars, a realistic model railroad will probably have several structures as part of the layout, such as:
  
===="Depression Baby"====
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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 (unit of length)|foot]]-long, all-steel car that resembled the [[forty-and-eights]] used in [[Europe]] during [[World War I]]. The prototype weighed in at 13½ [[ton]]s and was outfitted with a 1,500-[[pound (mass)|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.
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<gallery perrow=3 widths=220px>
 
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File:RRTrussBridgeSideView.jpg|<center>A Truss Bridge</center>
====Dry ice====
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File:Wellington, llinois elevator.png |<center>A Grain Elevator</center>
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.
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File:EBT Roundhouse 2.jpg|<center>A Roundhouse with Turntable</center>
 
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File:Abfaltersbach station.JPG|<center>A Station</center>
====Hopper cars====
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File:Madison, NJ, train station platform.jpg|<center>A Platform</center>
[[Image:Santa Fe Conditionaire Covered Hopper.jpg|thumb|300px|right|ACFX #47633, one of 100 specially-built "Conditionaire" centerflow hoppers operated by the [[Atchison, Topeka and Santa Fe Railway]].]]
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File:TchopitoulasIllinoisCentralWarehouse.jpg|<center>A Warehouse</center>
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 m)-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.
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</gallery>
 
 
The units, rated at 100 [[short ton]]s (90.718 [[Tonne|t]]) 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.
 
 
 
==Timeline==
 
* [[1842]]: The [[Western Railroad of Massachusetts]] experiments with innovative freight car designs capable of carrying all types of perishable goods without spoilage.
 
* [[1851]]: The first refrigerated boxcar enters service on the [[Northern Railroad of New York]].
 
* [[1857]]: The first consignment of refrigerated, dressed beef travels from Chicago stockyards to the East Coast in ordinary box cars packed with ice.
 
* [[1866]]: Horticulturist [[Parker Earle]] ships strawberries in iced boxes by rail from southern Illinois to Chicago on the [[Illinois Central Railroad]].
 
* [[1868]]: William Davis of [[Detroit, Michigan]] develops a refrigerator car cooled by a frozen ice-salt mixture, and patents it in the U.S. The patent is subsequently sold to George Hammond, a local meat packer who goes on to amass a fortune in refrigerated shipping.
 
* [[1876]]: [[Germany|German]] engineer [[Carl von Linde]] develops one of the first mechanical refrigeration systems.
 
* [[1878]]: Gustavus Swift (along with engineer Andrew Chase) develops the first practical ice-cooled railcar; soon thereafter, Swift forms the Swift Refrigerator Line (SRL), the world's first.
 
* [[1880]]: The first patent for a mechanically-refrigerated railcar issued in the United States is granted to Charles William Cooper.
 
* [[1884]]: The Santa Fe Refrigerator Despatch (SFRD) is established as a subsidiary of the [[Atchison, Topeka and Santa Fe Railway]] to carry perishable commodities.
 
* [[1885]]: Berries from  [[Norfolk, Virginia]] are shipped by refrigerator car to [[New York]].
 
* [[1887]] Parker Earle joined F.A. Thomas of Chicago in the fruit shipping business. The company owned 60 ice-cooled railcars by 1888, and 600 by 1891.
 
* [[1888]]: Armour & Co. ships beef from Chicago to Florida in a car cooled by [[ethyl chloride]]-compression machinery. [[Florida]] oranges are shipped to New York under refrigeration for the first time.
 
* [[1889]]: The first cooled shipment of deciduous fruit from California is sold on the New York market.
 
* [[1898]]: [[Russia|Russia's]] first refrigerator cars enter service. The country's inventory will reach 1,900 by [[1908]], grow to 3,000 just two years later, and top out at approximately 5,900 by [[1916]]. The cars were utilized mainly for transporting butter from [[Siberia]] to the [[Baltic Sea]] (a 12-day journey).
 
* [[1899]]: Refrigerated fruit traffic within the U.S. reaches 90,000 [[short ton]]s per year;  Transport from California to NY averaged 12 days in 1900.
 
* [[1901]]: Carl von Linde equips a Russian train with a mobile, central mechanical refrigeration plant to distribute cooling to cars carrying perishable goods; similar systems will be used in Russia as late as [[1975]].
 
* [[1905]]: U.S. traffic in refrigerated fruit reaches 430,000 short tons. As refrigerator car designs become standardized, the practice of indicating the "patentee" on the sides is discontinued.
 
* [[1907]]: The Pacific Fruit Express begins operations with more than 6,000 refrigerated cars, transporting fruit and vegetables across the United States from Western producers to Eastern consumers. U.S. traffic in refrigerated fruit hits 600,000 short tons.
 
* [[1913]]: The number of thermally-insulated railcars (most of which were cooled by ice) in the U.S. tops 100,000.
 
* [[1920]]: The Fruit Growers Express (or FGE, a former subsidiary of the Armour Refrigerator Line) is formed using 4,280 reefers acquired from Armour & Co.
 
* [[1923]]: FGE and the [[Great Northern Railway (U.S.)|Great Northern Railway]] for the Western Fruit Express (WFE) in order to compete with the Pacific Fruit Express and Santa Fe Refrigerator Despatch in the West.
 
* [[1925]]&ndash;1930: Mechanically-refrigerated trucks enter service and gain public acceptance, particularly for the delivery of milk and ice cream.
 
* [[1926]]: The FGE expands its service into the Pacific Northwest and the Midwest through the WFE and the Burlington Refrigerator Express Company (BREX), its other partly-owned subsidiary. FGE purchases 2,676 reefers from the [[Pennsylvania Railroad]].
 
* [[1928]]: The FGE forms the [[National Car Company]] as a subsidiary to service the meat transportation market; customers include [[Kahns]], [[Oscar Mayer]], and [[Rath (company)|Rath]].
 
* [[1930]]: The number of refrigerator cars in the United States reaches its maximum of approximately 183,000 units.
 
* [[1931]]: The SFRD reconfigures 7 reefers to utilize dry ice as a cooling agent.
 
* [[1936]]: The first all-steel reefers enter service.
 
* [[1937]]: The Interstate Commerce Commission bans "billboard" type advertisements on railroad cars.
 
* [[1946]]: Two experimental aluminum-body refrigerator cars enter service on the PFE; an experimental reefer with a stainless-steel body is built for the SFRD.
 
* [[1950]]: The U.S. refrigerator car roster drops to 127,200.
 
* [[1957]]: The last ice bunker refrigerator cars are built.
 
* [[1958]]: The first mechanical reefers (utilizing diesel-powered refrigeration units) enter revenue service.
 
* [[1960s]]: The flush, "plug" style sliding door is introduced as an option that provides a larger door to ease loading and unloading of certain commodities. The tight-fitting doors are better insulated and allow a car's interior to be maintained at a more even temperature.
 
* [[1969]]: ACF constructs a number of experimental center flow hopper cars which incorporate mechanical cooling systems and insulated cargo cells; the units are intended for shipment of bulk perishables.
 
* [[1971]]: The last ice-cooled reefers are retired from service.
 
* [[1980]]: The U.S. refrigerator car roster drops to 80,000.
 
* [[1990s]]: The first cryogenically-cooled reefers enter service.
 
* [[2001]]: The number of refrigerator cars in the United States "bottoms out" at approximately 8,000.
 
* [[2005]]: The number of reefers in the United States climbs to approximately 25,000, the result of significant new refrigerator car orders.
 
  
==Specialized applications==
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===Express service===
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[[Image:FM-REA-65.jpg|thumb|225px|right|An REA express reefer is positioned at the head end of Santa Fe train No.8, the ''Fast Mail Express'', in 1965.]]
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Standard refrigerated transport is often utilized for good with less than 14 days of refrigerated "shelf life": avocados, cut flowers, green leafy vegetables, lettuce, mangos, meat products, mushrooms, peaches and nectarines, pineapples and papayas, sweet cherries, and tomatoes. "Express" reefers are typically employed in the transport of special perishables: commodities with a refrigerated shelf life of less than 7 days such as human blood, fish, green onions, milk, strawberries, and certain pharmaceuticals.  
+
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<!-- 7. Know the meaning of the following model railroad terms: -->
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 +
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 +
<noinclude><translate><!--T:65-->
 +
</noinclude>
 +
Rock or gravel poured between railroad ties to secure them in place and stabilize the track.
 +
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 +
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{{ansreq|page={{#titleparts:{{PAGENAME}}|2|1}}|num=7b}}
 +
<noinclude><translate><!--T:66-->
 +
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 +
Driving wheels on a steam locomotive with a large number of wheel sets. These were driving wheels without the usual flanges, allowing a larger number of wheels to negotiate a turn without binding up against the rails.
 +
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 +
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<noinclude><translate><!--T:67-->
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A section of model track which is electrically insulated from its surrounding sections so that engines on it can be controlled independent of trains on other engines.
 +
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 +
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A beam that transfers the weight of a railcar to its truck.
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A place where pedestrian or automobile traffic crosses the railroad.
 +
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A place where two railroad tracks cross each other.
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{{ansreq|page={{#titleparts:{{PAGENAME}}|2|1}}|num=7g}}
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<noinclude><translate><!--T:71-->
 +
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The use of two locomotives to pull an especially long and heavy train.
 +
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<noinclude><translate><!--T:72-->
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Part of a railcar's coupling system which allows for some flexing in the tension between cars.
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The larger, flat part of a trains wheels that descend below the track's top surface on the inside edge, thus holding the car on the track as it moves.
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At the center of a turnout, it is the small X-shaped piece of track that enables a train's wheels to cross over the inside rail.
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<noinclude><translate><!--T:75-->
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A space between rails so that they are electrically insulated from one another. This is done so that the two rails do not short together, or so they can be on different circuits.
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Sometimes used to describe the size of track and cars used on a certain model railroad, it more accurately measures the space between the rails of that railroad's track.
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A measurement of the steepness of the track when it is not flat or level with the ground. It is measured in degrees according to its angle from level ground.
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<noinclude><translate><!--T:78-->
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A place for storing, sorting or processing train cars which uses track set at an angle with the ground in order to let gravity move cars when needed.
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<noinclude><translate><!--T:79-->
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A wheel bearing that has become excessively hot because of friction.
 +
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<noinclude><translate><!--T:80-->
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A non-conducting clip, usually made of plastic, that allows two pieces of track to be connected physically while remaining independent electronically. Used between distinct ''blocks'' of track.
 +
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A bearing in which the shaft between two wheels rotates against the car's truck with the help of lubrication supplied within a journal box, often seen on a train car's trucks.
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An arrangement of model railroad track, structures and scenery that models real-life railroad operation in a contained area.
 +
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<noinclude><translate><!--T:83-->
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The route a train takes from one destination to another, independent of track used in yards, sidings or spurs.
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<noinclude><translate><!--T:84-->
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</noinclude>
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The real-life railroad operation and equipment upon which a model railroad is based.
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A metallic clip placed on the bottom flange at the end of a section of track allowing it to be connected both physically and electrically to the next piece of track on the line.
 +
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A length of track which, by use of one or more turnouts, returns a train to its originating position facing the opposite way from which it left.
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A section of track that runs parallel to the mainline and allows a train to stop and be passed by another train occupying the same mainline.
 +
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A dead-end piece of track which accepts cars to be delivered from the mainline or prepared for shipment to another destination via the mainline.
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Something which routes power or trains between two or more options. When routing trains, it is best to use 'turnout' to distinguish the track mechanism from the electronic toggle switch that activates it from the layout's control panel.
 +
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Refers in model railroading to the small mechanism attached to a turnout which allows it to be operated by remote-control from the layout's control panel.
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A model railroad truck with its own attached coupler. Although Talgo trucks permit model trains to operate on smaller radius curves, they can be more likely to derail when trains are pushed, rather than pulled.
 +
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A single, solid piece of hardware mounted to the bottom of a railroad car or locomotive to which is attached on or more sets of wheels. On train cars, trucks usually contain two sets of wheels and can swivel beneath the car when the train is navigating a turn.
 +
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A mechanism for allowing a train to leave one set of tracks and join another. Sometimes called a 'switch.'
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{{ansreq|page={{#titleparts:{{PAGENAME}}|2|1}}|num=7dd}}
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<noinclude><translate><!--T:94-->
 +
</noinclude>
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A standard of model railroading which does not employ a separate (third) rail for power. Layouts using two-rail modeling systems must employ special wiring when a wye or reverse loop exists within the layout's design.
 +
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A triangle-shaped junction of two railroad lines in which one line joins another with the option of going either direction on the second line.
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A turnout in which both branches leave the turnout at a different angle from the original line. Most turnouts have one straight-through line and a ''single'' branch that leaves the line in a different direction.
 +
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A set of tracks which branch off of the mainline and allow train cars to be sorted, reordered or stored while they are en route to their destination.
  
The earliest express-service refrigerator cars entered service around 1890, shortly after the first express train routes were established in [[North America]]. The cars did not come into general use until the early [[20th century]]. Most units designed for express service are larger than their standard counterparts, and are typically constructed more along the lines of [[baggage car]]s than freight equipment. Cars must be equipped with speed-rated trucks and brakes, and &mdash; if they are to be run ahead of the passenger car consist &mdash; must also incorporate an air line for pneumatic braking, a communication signal air line, and a steam line for train heating. Express units were typically painted in passenger car colors, such as [[Pullman Company|Pullman]] green.
+
<!--T:30-->
 +
{| border="1" cellspacing = "0" cellpadding = "5" align="center""
 +
!'''For Further Information:
  
The first purpose-built express reefer emerged from the [[Erie Railroad|Erie Railroad's]] Susquehanna Shops on [[August 1]], [[1886]]. By 1927 some 2,218 express cars traveled America's rails, and three years later that number was 3,264. In 1940 private rail lines began to build and operate their own reefers, the [[Railway Express Agency]] (REA) being by far the largest. In 1948 the REA roster (which would continue to expand into the [[1950s]]) numbered approximately 1,800 cars, many of which were [[World War II]] "[[troop sleeper]]s" modified for express refrigerated transport. By 1965, due to a decline in refrigerated traffic, many express reefers were leased to railroads for use as bulk mail carriers.
+
<!--T:31-->
 +
A good glossary of model railroad terms is available under <u>[http://greatesthobby.com/wgh/MS_2249.html Frequently Asked Questions]</u> on the [http://greatesthobby.com World's Greatest Hobby website]
  
[[Image:Pfe722.jpg|thumb|350px|left|Pacific Fruit Express #722, an ice-cooled, express-style refrigerator car designed to carry milk in [[stainless steel]] cans and other highly-perishable cargo at the head end of passenger train consists.]]
+
<!--T:32-->
[[Image:REX6687 Troop Reefer.jpg|thumb|400px|right|Railway Express Agency refrigerator car #6687, a converted World War II "troop sleeper." Note the square panels along the sides that cover the window openings.]]
+
A similar list of terms for prototype railroading can be found under <u>[[w:Rail_terminology|Rail Terminology]]</u> on [[w:Main page|Wikipedia]].'''
<br style="clear:both;">
 
 
 
===Intermodal===
 
[[Image:Vonsvans01022.jpg|thumb|300px|right|An intermodal train containing mechanically-cooled [[Semi-trailer|highway trailers]] in "[[piggy-back|piggyback]]" service passes through the [[Cajon Pass]] in February, 1995.]]
 
 
 
For many years, virtually all of the perishable traffic in the United States was carried by the railroads. While railroads were subject to government regulation regarding shipping rates, trucking companies could set their own rate for hauling agricultural products, giving them a competitive edge. In March 1979 the [[Interstate Commerce Commission|ICC]] exempted rail transportation of fresh fruits and vegetables from all economic regulation. Once the "Agricultural Exemption Clause" was removed from the ''Interstate Commerce Act'', railroads began aggressively pursuing trailer-on-flatcar (TOFC) business (a form of [[intermodal freight transport]]) for refrigerated trailers. Taking this one step further, a number of carriers (including the PFE and SFRD) purchased their own refrigerated trailers to compete with interstate trucks.
 
 
 
The final chapter has not, as many have predicted, been written for the refrigerator car in America. The dawn of the [[21st century]] has seen the first significant reefer orders since the early 1970s.
 
 
 
===Tropicana "Juice Train"===
 
{{main|Juice Train}}
 
[[Image:Tropicana reefer 3053.jpg|thumb|325px|right|Tropicana #3053, one of the cars of the "Great White Fleet."]]
 
 
 
In 1970 Tropicana orange juice was shipped in bulk via [[Thermal insulation|insulated]] [[boxcars]] in one weekly round-trip from Florida to [[Kearny, New Jersey]]. By the following year, the company was operating two 60-car unit trains a week, each carrying around 1 million U.S. [[gallon]]s (4 million [[litre|liters]]) of juice. On [[June 7]], [[1971]] the "Great White Juice Train" (the first unit train in the food industry, consisting of 150  one hundred [[short ton]] insulated boxcars fabricated in the [[Alexandria, Virginia]] shops of [[Fruit Growers Express]]) commenced service over the 1,250-[[mile]] (2,000-[[kilometer]]) route. An additional 100 cars were soon added, and small mechanical refrigeration units were installed to keep temperatures constant. Tropicana saved $40 million in fuel costs during the first ten years in operation.
 
 
 
==AAR classificatons==
 
{| class="toccolours"
 
|-
 
|+ [[Association of American Railroads|AAR]] classifications of refrigerator car types<ref>''The Great Yellow Fleet'', p 126.</ref>
 
|-
 
! bgcolor=#cc9966 | Class
 
! bgcolor=#cc9966 | Description
 
! bgcolor=#cc9966 | Class
 
! bgcolor=#cc9966 | Description
 
|-
 
|align=left | &nbsp; '''RA
 
|align=left | Brine-tank ice bunkers
 
|align=left | &nbsp; '''RPB
 
|align=left | Mechanical refrigerator with electro-mechanical axle drive &nbsp;
 
|-
 
|align=left | &nbsp; '''RAM
 
|align=left | Brine-tank ice bunkers with beef rails
 
|align=left | &nbsp; '''RPL
 
|align=left | Mechanical refrigerator with loading devices
 
|-
 
|align=left | &nbsp; '''RAMH &nbsp;
 
|align=left | Brine-tank with beef rails and heaters
 
|align=left | &nbsp; '''RPM
 
|align=left | Mechanical refrigerator with beef rails
 
|-
 
|align=left | &nbsp; '''RB
 
|align=left | No ice bunkers &mdash; heavy insulation
 
|align=left | &nbsp; '''RS
 
|align=left | Bunker refrigerator &mdash; common ice bunker car
 
|-
 
|align=left | &nbsp; '''RBL
 
|align=left | No ice bunkers and loading devices
 
|align=left | &nbsp; '''RSB
 
|align=left | Bunker refrigerator &mdash; air fans and loading devices
 
|-
 
|align=left | &nbsp; '''RBH
 
|align=left | No ice bunkers &mdash; gas heaters
 
|align=left | &nbsp; '''RSM
 
|align=left | Bunker refrigerator with beef rails
 
|-
 
|align=left | &nbsp; '''RBLH
 
|align=left | No ice bunkers &mdash; loading devices and heaters
 
|align=left | &nbsp; '''RSMH &nbsp;
 
|align=left | Bunker refrigerator with beef rails and heaters
 
|-
 
|align=left | &nbsp; '''RCD
 
|align=left | Solid carbon-dioxide refrigerator
 
|align=left | &nbsp; '''RSTC
 
|align=left | Bunker refrigerator &mdash; electric air fans
 
|-
 
|align=left | &nbsp; '''RLO
 
|align=left | Special car type &mdash; permanently-enclosed (covered hopper type) &nbsp; &nbsp;
 
|align=left | &nbsp; '''RSTM
 
|align=left | Bunker refrigerator &mdash; electric air fans and beef rails
 
|-
 
|align=left | &nbsp; '''RP
 
|align=left | Mechanical refrigerator
 
 
|}
 
|}
  
&nbsp; Note: '''Class B''' refrigerator cars are those designed for passenger service; insulated boxcars are designated '''Class L'''.
+
<!--T:98-->
 
+
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==Notes==
+
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<references/>
+
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+
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==References==
+
<noinclude><translate><!--T:99-->
* Boyle, Elizabeth and Rodolfo Estrada. (1994) [http://www.oznet.ksu.edu/meatscience/column/industry.htm/ "Development of the U.S. Meat Industry"] &mdash; Kansas State University Department of Animal Sciences and Industry.
+
</noinclude>
* Hendrickson, Richard and Richard E. Scholz. (1986). "Reefer car 13000: a postmortem." ''The Santa Fé Route'' '''IV''' (2) 8.
+
<!-- 8. Construct a portion of a model railroad layout. In your construction, do the following: <br> a. Assist in assembling the framework <br> b. Install a section of ballast <br> c. Install a section of track <br> d. Install at least one turnout, including the wiring <br> e. Assist in making scenery, such as trees, rocks, mountains, or grass <br> f. Make one model railroading building or structure <br> g. Assist in the wiring to supply electrical power to the tracks -->
* {{cite book|author=Hendrickson, Richard H.|year=1998|title=Santa Fe Railway Painting and Lettering Guide for Model Railroaders, Volume 1: Rolling Stock|publisher=The Santa Fe Railway Historical and Modeling Society, Inc., Highlands Ranch, CO|id=}}
+
You can do this on your own, or as part of a club (either a group of Pathfinders earning the honor together, or as part of a model railroading club). Because there are a lot of requirements to meet here, it would be a good idea to make a checklist so you can be sure you have met each.
* Pearce, Bill. (2005). "Express Reefer from troop sleeper in N." ''Model Railroader'' '''72''' (12) 62&ndash;65.
 
* [http://users2.ev1.net/~jssand/SFHMS/Sand/SFRD/5.htm Reefer Operations on Model Railroads with an emphasis on the ATSF] April 15, 2005 article at [http://www.atsfrr.net/ The Santa Fe Railway Historical & Modeling Society] official website &mdash; accessed on November 7, 2005.
 
* Thompson, Anthony W. et al. (1992). ''Pacific Fruit Express''. Signature Press, Wilton, CA.  ISBN 1-930013-03-5.
 
* White, John H.  (1986).  ''The Great Yellow Fleet''.  Golden West Books, San Marino, CA.  ISBN 0-87095-091-6.
 
* White, Jr., John H. (1993). ''The American Railroad Freight Car''. The Johns Hopkins University Press, Baltimore, Maryland.  ISBN 0-8018-5236-6.
 
 
 
==See also==
 
* [[Refrigeration]]
 
* [[Reefer (ship)]]
 
* [[Reefer (container)]]
 
* [[Refrigerator truck]]
 
 
 
==External links==
 
* [http://www.sdrm.org/roster/freight/ref21335/index.html Atchison, Topeka, & Santa Fe Railway #21335] &mdash; photo and short history of a steel-sheathed "billboard" car.
 
* [http://www.sdrm.org/stories/reefer/ "Coast to Coast"] article by Richard Hendrickson at the [http://www.sdrm.org/ Pacific Southwest Railway Museum] official website.
 
* [http://www.csrmf.org/doc.asp?id=185 Fruit Growers Express Company #35832] &mdash; photos and short history of an example of the wooden ice-type "reefers" commonly placed in service between 1920 and 1940.
 
* [http://www.sdrm.org/roster/freight/ref56415/index.html Fruit Growers Express Company #56415] &mdash; photos and short history of an example of the wooden ice-type "reefers" used in the first half of the 20th century for shipping produce.
 
* [http://www.sdrm.org/roster/freight/ref11207/index.html Pacific Fruit Express Company #11207] &mdash; photo and short history of one of the last ice-type refrigerator cars built.
 
* [http://www.sdrm.org/roster/freight/re300010/index.html Pacific Fruit Express Company #300010] &mdash; photo and short history of one of the first mechanical-type refrigerator cars built.
 
* [http://www.uprr.com/aboutup/photos/pfe/index.shtml Pacific Fruit Express photo gallery] at the [[Union Pacific Railroad]] official website.
 
* [http://www.containerserviceco.com Container Service Co.] official website; contains pictures of cryogenic railcars and ocean freight containers.
 
 
 
{{Refrigerator Car Lines of the United States}}
 
 
 
{{Freight cars}}
 
 
 
[[Category:Cooling technology]]
 
[[Category:Food preservation]]
 
[[Category:Freight equipment]]
 
 
 
[[de:Kühlwagen (Eisenbahn)]]
 
[[eo:Malvarmiguja vagono]]
 
[[ja:冷蔵車]]
 
  
 +
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{{ansreq|page={{#titleparts:{{PAGENAME}}|2|1}}|num=9}}
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<noinclude><translate><!--T:101-->
 +
</noinclude>
 +
<!-- 9. Successfully operate a model railroad train on the layout you have assisted in building. -->
 +
Once you have built (or have helped build) a model set, how can you pass up the opportunity to operate it? In reality, the set will be operated several times during construction to test each new addition. If possible, why not transport the setup to your church for Pathfinder Sabbath?
  
sex
+
<!--T:102-->
 +
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 +
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<noinclude><translate></noinclude>
 +
==References== <!--T:35-->
 +
<noinclude></translate></noinclude>
 +
{{CloseHonorPage}}

Latest revision as of 16:07, 14 July 2022

Other languages:
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Model Railroad

Skill Level

2

Year

1967

Version

24.11.2024

Approval authority

General Conference

Model Railroading AY Honor.png
Model Railroad
Arts, Crafts and Hobbies
Skill Level
123
Approval authority
General Conference
Year of Introduction
1967
See also


1

Give the history and development of model railroading.


Practical Beginnings

The development of model railroading runs, for the most part, parallel to the development of real-life (or 'prototype') railroading. The first model railroads appeared after 1810 and were one-of-a-kind creations used in designing or promoting their full-sized counterparts. Railroading was first developed to reduce the time and effort required to move raw materials or people over short distances made otherwise difficult by bad weather and poor roadways. The first rail cars were pulled along by animals, while steam-propelled machines, whether trains or automobiles, followed as quickly as the public was ready to adopt them. Various authors from diverse countries each lay different claims to the origins of both railroading and model railroading; and for this reason it is nearly impossible to reckon the precise date and location of the first model trains. By the 1830's, however, several countries including Germany, France, England and the United States were each developing steam-driven railroads to move freight and passengers. Original models of these first railroads are still on display in museums, and the first toy trains appeared not long after in German and British catalogs of the 1860's.

On the Right Track

The first toy trains of the 1840's actually ran on steam produced by filling the metallic model with water and placing in on a heating surface. These 'carpet railways' didn't use track and often left a trail of water behind them. In 1891, the German company Märklin began offering a track system for its wind-up, or "clockwork," trains which were moving along on their own electric power within the decade. The famous American toy train manufacturer, Lionel, began selling its first sectional three-rail electric train track (later called "Standard Gauge") in 1906, just five years after their first store window display called the "Electric Express" captured public attention. By 1910, the British company Bassett-Lowke had opened a London showroom exclusively for its model trains. Other early toy train producers from around the world were Lima, Bing, Fleischmann and Rivarossi.

The World's Greatest Hobby

Today, dozens of manufacturers from around the world sell their model railroading products via thousands of catalogs, magazines, websites and hobby stores. Model railroading has many fascinating aspects to attract people with many different interests and skill sets. Some modelers continue to make many things, even engines track and cars, from scratch, while a satisfying railroading experience can be gained from many ready-made sets available right out of the box. Called by many 'The World's Greatest Hobby', model railroading will doubtless continue to be a source of great enjoyment for many years to come.


2

Tell the difference in how the following prototype motive power units operate:


2a

Steam


Steam Locomotion

Steam powered locomotives use burning coal or wood to heat water enclosed in a large boiler. The steam released from this boiler acts much like the steam that emanates from a kettle of boiling water on the stove. By channeling the steam’s pressure into an engine cylinder, it pushes a piston that provides mechanical power to the wheels. Steam locomotives dominated rail transport until the mid-1900’s when diesel and electric locomotives took over. Steam locomotives had to stop periodically to receive a new supply of water plus logs or coal.


2b

Diesel


Three Diesel Locomotives

Diesel locomotives burn diesel fuel in a combustion engine in virtually the same way as in the cars we use every day. The main difference between various types of diesel locomotives relates to how the power from its diesel engine is transferred to its drive wheels. Diesel locomotives were a great improvement over the steam locomotives in that they are quieter, cleaner, easier to maintain, and they can be started and stopped quickly, without the delay of waiting for water to boil. In mild weather, diesel engines don’t need to be left running to be ready to use at a moment’s notice, and diesel locomotives require far fewer people to operate them. Diesel locomotives continue to be used today.


2c

Electric


An Electric Locomotive

Electric locomotives get power to turn their wheels from electric motors housed inside. Most such locomotives receive their electrical power from overhead wires or an additional rail running alongside the rails used by the wheels. Some electric locomotives employ onboard batteries to drive them. Electricity became the preferred way of driving trains that had to travel underground or through frequent tunnels because they produce no exhaust as diesel or gasoline engines do. Another advantage is that they are virtually silent when operating and are easier to maintain because they utilize fewer moving parts than mechanical combustion engines.



3

Know the name, scale, and track gauge for four model railroad gauges.


The six most popular scales used are: G scale, Gauge 1, O scale, H0 scale (in Britain, the similarly sized 00 is used), TT scale, and N scale (1:160), although there is growing interest in Z scale. H0 scale is the single most popular scale of model railroad. Popular narrow-gauge scales include HOn3 Scale and Nn3, which are the same scale as HO and N, except with a narrower spacing between the tracks (in these examples, a scale three feet instead of the 4'8.5" standard gauge).

The words scale and gauge seem at first to be used interchangeably in model railways, but their meanings are different. Scale is the model's measurement as a proportion to the original, while gauge is the measurement between the two running rails of the track.

Name Scale Gauge
G scale 1:22.5 45 mm1.75 inches
Gauge 1 1:32 44.45 mm1.75 inches
0 scale 1:43 or 1:48 32 mm1.25 inches
H0 scale 1:87 16.5 mm0.65 inches
TT scale 1:120 12 mm0.47 inches
N scale 1:148 to 1:160 9 mm0.354 inches
Z scale 1:220 6.5 mm0.256 inches


4

Know the shapes and names of at least eight track plan arrangements.


Oval

Oval Layout Design

The simplest layout for a model railroad and the starting point for most designs. In this design, two straightaway segments are connected by a semi-circle at each end. This is also the only layout which can easily be created with sectional track without the use of a manufacturer-specific design. Curved sectional track is sold by radii (half the distance across the semi-circle) and a box of such track sections will almost always create exactly half a circle. The two straightaway sections will usually utilize multiple pieces of sectional straight track, as desired by the modeler.

Figure-Eight

Figure-Eight Layout Design

The second most common beginner's layout. This layout is best accomplished by purchasing it as a single set or following a manufacturer's layout design using their sectional track. The intersection in the center of the layout can either be accomplished by a piece of crossover track, or by elevating one track over the other. In the latter case, a set of piers or risers will be needed to raise the track at an appropriate rate.

Twice-Around

Twice-Around Layout Design

A modification of the figure-eight, in which one end-loop is contained within the other. The crossover here is not at 90° like in the basic figure-eight example and can be accomplished by using a alternately angled crossover piece or by using elevated track to pass one track over the other. The twice-around layout design allows the train to run continuously for longer than the simple oval before reaching its starting point.

Point-to-Point

Point-to-Point Layout Design

This design does not allow a train to run continuously indefinitely, as you might imagine most plans would allow. However, this is the design that most closely resembles real-life railroad operation, since real-life railroads run across country, not in loops or circles. You can construct more elaborate yards at each end in order to enjoy the complexities of real-world operation.

Out-and-Back

Out-and-Back Layout Design

This design approximates real-world operation, as each train must make a journey before it returns to the yard from which it originated. Although real freight never returns to its origin the same way it left, this arrangement does allows you to concentrate your time and resources on one yard instead of the two required in a Point-to-Point design (above).

Loop-to-Loop

Loop-to-Loop Layout Design

This design diverges from realistic operation, but does allow the operator to interact with a continuous-running train. A yard can be added in the middle of the layout to simulate freight coming in from each direction. When modeling with two-rail scales, such as HO and smaller, special wiring will be required to insulate each loop from the rest of the line and allow the direction to be reversed on the mainline.

Dog Bone

Dog-Bone Layout Design

This design is similar to the loop-to-loop design, but allows for continuous running without intervention from an operator. In addition, the two tracks running side-by-side simulate the double-track lines often seen in real life.

Twisted Dog Bone

Twisted-Dog-Bone Layout Design

This design is adds additional length to the mainline featured in the basic dog-bone design (above). Keeping one or both of the end-loops out of sight allows this layout to very realistically simulate the long distance running of a real railroad.


5

Know at least six points to check for the maintenance of a model railroading layout.


Cleaning & Checking Basic Trackwork

Most model railroads receive power for their electric motors through the tracks they run on. Thus, track must be kept clean and free of even the smallest obstructions. A train running on a dirty track does not operate smoothly or realistically, or may not run at all! The space between rails must also be maintained, though this is more of an issue when individual rails and ties have been laid down by hand. Sectional track usually maintains its proper gauge (space between the rails). Rail cleaning solution can be safely wiped across model track and track-cleaning cars are also available for running around the layout and cleaning hard-to-reach places.

Checking Wheels and Couplers

Locomotives and cars are kept rolling along together by various types of 'couplers.' These can be very tiny on the smaller model railroad scales, but in any case, they must be kept clean and properly hooked together for a train to run along smoothly. Another common problem is derailment when a car's wheels come off the track. This can also be harder to detect on smaller scale trains, but it will eventually get noticed as cars may tip completely off the track. Nevertheless, derailment is the most common operating problem encountered and should be one of the first possibility to check when things are going wrong.

Lubricating Engine Drive Mechanisms

Most model locomotives are powered by electric motors which involve a minimum of moving parts. There are typically tiny gears used in transferring the turning motor's power to the drive wheels of the locomotive. These are easily lubricated with special grease and/or oil available from a hobby supply store. Be careful to follow both the engine and lubricant manufacturers' instructions. Most wheels on other non-powered cars do not need to be oiled or greased except in rare cases.

Detailing Scenes & Structures

Model structures and landscape gather dust, making them look less realistic. These elements of a typical layout should be well anchored with adhesive when they are first installed so that their surfaces can be brushed clean, repainted, re-weathered and even vacuumed. In addition, its fun and rewarding to keep a layout fresh by installing new structures or creating new track-side scenes once your basic modeling is complete.

Testing Electrical Connections

Most model locomotives receive their power from the tracks below through one or more of their wheel sets. Since these wheels are turning, they transmit their power through stationary metal brushes that maintain contact with the tiny axle running between these wheels. These brushes should be kept clean and checked whenever an electrical problem is suspected. In addition, the wires which run from the operator's power pack to the rails themselves can become tangled, shorted out (when they inadvertently touch each other), or disconnected all leading to potential breakdown in the power supplied to the model railroad. A simple electric meter available from a hobby or electronics store can help determine where a breakdown is occurring by testing (1) the output of the power pack directly, (2) the presence of power on the set of tracks where the train is located, or (3) at any control point in between, such as when a control panel switch is used to control power to different track sections.

Adjusting Turnouts, Switch Machines & Ground Throws

Turnouts (sometimes called 'switches') are used to send a train from one set of track to another. These are easy places for trains to become derailed because the wheels must pass over a series of changeable mechanical parts that are more complex than the simple two (or three) rails used elsewhere in the layout. The 'points' of a switch are moved between two different resting positions which determine what path the trail will take after it passes through the turnout. These points must rest securely against either the inside or outside rail and must not move otherwise. If the points are moved remotely, by an electrical signal sent from the control panel to a 'switch machine' next to the turnout, then this switch machine and its associated wiring must be in good working order. If the switch is operated by hand using a small lever or 'ground throw' next to the turnout, then the ground throw needs to be kept clean and lubricated and able to move the points the full distance between their two desired positions.


6

Identify and explain the use of:


6a

Five types of freight cars


Covered Hopper

Covered hopper

Structurally, a covered hopper is very similar to an open­top hopper car. What distinguishes this type of car from an open hopper is the car's roof, and also the car's overall size. Covered hoppers typically carry loads of less dense, and therefore lighter, materials, so they are built to a higher cubic capacity than open top hoppers.

Box Car

Box car

A boxcar (the American term; the British call this kind of car a "goods van" while in Australia, they are usually referred to as "louvre vans") is a railroad car that is enclosed and generally used to carry general freight. The boxcar, while not the simplest freight car design, is probably the most versatile, since it can carry most loads. Boxcars have side doors of varying size and operation, and some include end doors and adjustable bulkheads to load very large items.

Container Car

Container cars

Containerization is a system of intermodal freight transport cargo transport using standard ISO containers known as shipping containers that can be loaded and sealed intact onto container ships, railroad cars, planes, and trucks. The introduction of containers resulted in vast improvements in port handling efficiency, thus lowering costs and helping lower freight charges and, in turn, boosting trade flows. Almost every manufactured product humans consume spends some time in a container.

Flat car

Flat car

A flatcar (also flat car) is a piece of railroad rolling stock that consists of an open, flat deck on four or six wheels or a pair of trucks (US) or bogies (UK). The deck of the car can be wood or steel, and the sides of the deck can include pockets for stakes or tie-down points to secure loads. Flatcars designed for carrying machinery have sliding chain assemblies recessed in the deck. Flatcars are used for loads that are too large or cumbersome to load in enclosed cars such as boxcars. They are also often used to transport containers or trailers in intermodal shipping.

Gondola

Gondola car

A gondola is an open-top type of rolling stock that is used for carrying loose bulk materials. Because of its low side walls, gondolas are used to carry either very dense material, such as steel plates or coils, or bulky items such as prefabricated pieces of rail track.

Refrigerator Car

Modern refrigerator car: note the grill at the lower right (the car's "A" end) where the mechanical refrigeration unit is housed.

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 were originally ice-cooled, but now are equipped with any one of a variety of mechanical refrigeration systems.

Stock Car

In railroad terminology, a stock car is a type of rolling stock used for carrying livestock (not carcasses) to market. A traditional stock car resembles a boxcar with slats missing in the car's side (and sometimes end) for the purpose of providing ventilation; stock cars can be single-level for large animals such as cattle or horses, or they can have two or three levels for smaller animals such as sheep, pigs, and poultry.

Tank Car

Tank car

A tank car is a type of railroad rolling stock designed to transport liquid and gaseous commodities. Outside of North America, they are also known as tank wagons or tanker wagons.


6b

Three types of passenger cars


Coach Cars

A coach car in Rome

The most basic passenger car, the coach car is lined with rows of seats like a bus. In some cases, a set of seats will face each other making it possible for passengers to pass the time in conversation. Passengers with carry-on baggage usually find overhead or under-seat storage available. In large, metropolitan areas, many people ride on the coach cars of their commuter trains every day to get to and from work. Some coach cars have seating on two levels which doubles their capacity to transport passengers.

Dining Cars

A Swiss dining car modeled by Roco

A dining car serves food to its passengers. Its like a long, narrow restaurant on wheels. The rail line must employ extra personnel to prepare food and wait on the passengers. A more limited version of the dining car is the "lounge" car, which serves only refreshments and can provide passengers with larger, more comfortable seats rather than tables to sit at.

Observation Cars

A Canadian observation car

The observation car is almost always the last car in a passenger train in order to take advantage of the view from the rear of the train. It might have other features that provide sleeping, refreshments or food, but it almost always has larger windows around the car and a U-shaped lounge at the end where passengers can see the view where the train has just traversed. Observation cars modeled on older era railroads might have a small open-air porch off the rear of the last car.

Sleeping Cars

A model sleeping car by Rivarossi

"Sleepers" are sometimes called "Pullman cars" in the United States because of the Pullman Company that manufactured a great deal of them beginning in the mid-1800's. Some beds are designed to either roll or fold out of the way or convert into seats for daytime use, while some sleeping compartments look like small personal apartments with their own bathrooms.


6c

Three types of steam engines according to their wheel arrangement


A New York 2-6-6 Locomotive
A Central Sucre 2-4-0 Locomotive
File:92220 Evening Star (Dave Cooper).jpg
Standard Class 9F 2-10-0 Locomotive

Steam locomotives are described most commonly by how many wheels they have in each of three sections. The most notable set of wheels are the drive wheels which are usually larger and are connected by the rods which power them. The other two sets of wheels are both smaller and lie ahead of and behind the central drive wheels. Since there are at most three sets of wheels, a locomotive classification will have three numbers separated by dashes. If a locomotive has only drive wheels, the first and last numbers will still appear, but will both be zero. This classification system counts all the wheels (both sides) so when looking at the side of a locomotive, remember to multiply what you see by two.

Pictured to the right are a 2-6-6, a 2-4-0, and a 2-10-0.

An excellent diagram with all of a Steam Locomotive's parts is available at Wikipedia: Steam Locomotive Parts.


6d

Two types of grade crossing warning devices


Uncontrolled Crossings

The American Crossbuck

"Open" or "Uncontrolled" crossings utilize a sign with or without flashing lights and an audible bell warning. These are considered 'open' because there is no barricade to the passage of pedestrians or traffic. In America, the 'crossbuck' is most typically seen at graded crossings. This is the familiar white "X" shape with the words "RAILROAD" and "CROSSING" printed on them.

Controlled Crossings

Gated Crossing in Finland

The most typical method of controlling a railroad crossing is with automatic close-able gates. In addition to flashing lights and warning bell, the gates make it difficult for cars or pedestrians to cross the tracks when they are down. Gated crossings have become more elaborate in recent years because accidents can still occur if cars try to drive around the gates.


6e

Two types of railroad signals


Mechanical Semaphore Signals

Mechanical Semaphore Signal

Mechanical semaphores utilize a moveable arm (or 'blade') whose position indicates how approaching trains may proceed. A set of differently colored lenses are also mounted on the arm, each passing in front of a stationary light when the arm moves, so that the semaphore can effectively signal trains at night.

Colored Light Signals

Colored Light Signal

These signals control train movements by displaying one of several colors of lights. They can also position the lights differently in order to send additional information to the engineer.


6f

Five types of railroad-related buildings or structures


Besides track, locomotives and cars, a realistic model railroad will probably have several structures as part of the layout, such as:



7

Know the meaning of the following model railroad terms:


7a

Ballast


Rock or gravel poured between railroad ties to secure them in place and stabilize the track.


7b

Blind drivers


Driving wheels on a steam locomotive with a large number of wheel sets. These were driving wheels without the usual flanges, allowing a larger number of wheels to negotiate a turn without binding up against the rails.


7c

Block


A section of model track which is electrically insulated from its surrounding sections so that engines on it can be controlled independent of trains on other engines.


7d

Bolster


A beam that transfers the weight of a railcar to its truck.


7e

Crossing


A place where pedestrian or automobile traffic crosses the railroad.


7f

Crossover


A place where two railroad tracks cross each other.


7g

Double header


The use of two locomotives to pull an especially long and heavy train.


7h

Draft gear


Part of a railcar's coupling system which allows for some flexing in the tension between cars.


7i

Flange


The larger, flat part of a trains wheels that descend below the track's top surface on the inside edge, thus holding the car on the track as it moves.


7j

Frog


At the center of a turnout, it is the small X-shaped piece of track that enables a train's wheels to cross over the inside rail.


7k

Gap


A space between rails so that they are electrically insulated from one another. This is done so that the two rails do not short together, or so they can be on different circuits.


7l

Gauge


Sometimes used to describe the size of track and cars used on a certain model railroad, it more accurately measures the space between the rails of that railroad's track.


7m

Grade


A measurement of the steepness of the track when it is not flat or level with the ground. It is measured in degrees according to its angle from level ground.


7n

Gravity yard


A place for storing, sorting or processing train cars which uses track set at an angle with the ground in order to let gravity move cars when needed.


7o

Hot box


A wheel bearing that has become excessively hot because of friction.


7p

Insulated rail joiner


A non-conducting clip, usually made of plastic, that allows two pieces of track to be connected physically while remaining independent electronically. Used between distinct blocks of track.


7q

Journal


A bearing in which the shaft between two wheels rotates against the car's truck with the help of lubrication supplied within a journal box, often seen on a train car's trucks.


7r

Layout


An arrangement of model railroad track, structures and scenery that models real-life railroad operation in a contained area.


7s

Mainline


The route a train takes from one destination to another, independent of track used in yards, sidings or spurs.


7t

Prototype


The real-life railroad operation and equipment upon which a model railroad is based.


7u

Rail joiner


A metallic clip placed on the bottom flange at the end of a section of track allowing it to be connected both physically and electrically to the next piece of track on the line.


7v

Reverse loop


A length of track which, by use of one or more turnouts, returns a train to its originating position facing the opposite way from which it left.


7w

Siding


A section of track that runs parallel to the mainline and allows a train to stop and be passed by another train occupying the same mainline.


7x

Spur


A dead-end piece of track which accepts cars to be delivered from the mainline or prepared for shipment to another destination via the mainline.


7y

Switch


Something which routes power or trains between two or more options. When routing trains, it is best to use 'turnout' to distinguish the track mechanism from the electronic toggle switch that activates it from the layout's control panel.


7z

Machine


Refers in model railroading to the small mechanism attached to a turnout which allows it to be operated by remote-control from the layout's control panel.


7aa

Talgo truck


A model railroad truck with its own attached coupler. Although Talgo trucks permit model trains to operate on smaller radius curves, they can be more likely to derail when trains are pushed, rather than pulled.


7bb

Truck


A single, solid piece of hardware mounted to the bottom of a railroad car or locomotive to which is attached on or more sets of wheels. On train cars, trucks usually contain two sets of wheels and can swivel beneath the car when the train is navigating a turn.


7cc

Turnout


A mechanism for allowing a train to leave one set of tracks and join another. Sometimes called a 'switch.'


7dd

Two-rail


A standard of model railroading which does not employ a separate (third) rail for power. Layouts using two-rail modeling systems must employ special wiring when a wye or reverse loop exists within the layout's design.


7ee

Wye


A triangle-shaped junction of two railroad lines in which one line joins another with the option of going either direction on the second line.


7ff

Yswitch


A turnout in which both branches leave the turnout at a different angle from the original line. Most turnouts have one straight-through line and a single branch that leaves the line in a different direction.


7gg

Yard


A set of tracks which branch off of the mainline and allow train cars to be sorted, reordered or stored while they are en route to their destination.

For Further Information:

A good glossary of model railroad terms is available under Frequently Asked Questions on the World's Greatest Hobby website

A similar list of terms for prototype railroading can be found under Rail Terminology on Wikipedia.



8

Construct a portion of a model railroad layout. In your construction, do the following:
a. Assist in assembling the framework
b. Install a section of ballast
c. Install a section of track
d. Install at least one turnout, including the wiring
e. Assist in making scenery, such as trees, rocks, mountains, or grass
f. Make one model railroading building or structure
g. Assist in the wiring to supply electrical power to the tracks


You can do this on your own, or as part of a club (either a group of Pathfinders earning the honor together, or as part of a model railroading club). Because there are a lot of requirements to meet here, it would be a good idea to make a checklist so you can be sure you have met each.


9

Successfully operate a model railroad train on the layout you have assisted in building.


Once you have built (or have helped build) a model set, how can you pass up the opportunity to operate it? In reality, the set will be operated several times during construction to test each new addition. If possible, why not transport the setup to your church for Pathfinder Sabbath?



References