SEPTA losing a bet on the necessity of point heaters at 16TH ST Jct. |
The two main methods of clearing the movable parts of switches are heating the rails directly or blowing hot air in and around them. These two categories are then divided by the type of fuel beings used to do the job. Currently the most common are electricity, gas (methane or propane) and kerosene. The decision of which point heating solution to use is typically based on the severity of the winter events any given interlocking is likely to encounter. Erring on the side of caution may result in unnecessary maintenance and capitol expenditures. On the other hand insufficient point heating capacity may not only fail in its intended role, but also succeed in making the problem worse. Railroads may further adopt the use of snow plans where the use of top quality snow melting is restricted to certain locations with the remainder being straight railed and taken out of service for the duration of the snow event.
The most basic type of point heating solution is that of the smudge pot. Named for an agricultural device designed to ward off the effects of frost, a railroad smudge pot is a long, flat metal tank holding 2-5 gallons of kerosene with a wick at one end. Placed under the running rails and ignited, the open flame will heat the rail sufficiently to ward off snow and ice accumulation within a certain vicinity.
Moving up a notch in power, the electrically powered rail heater works in much the same fashion as a smudge pot, but without the need for on-site manual operation or fuel oil and with a significantly larger area of effect. The hardware device could not be simpler, usually consisting of an electric-range style heating elements strapped along the length of the outer rail.
In the above example of an electric resistance point heater in operation, the water has evaporated along the entire length of the heating element. When encountered in the nighttime the elements glow a cherry red, again similar to a household electric range.
Where heating elements on the outside rail prove insufficient, additional coils can be placed under the points themselves where the radiant heat would work to keep the mechanism clear. One major drawback to electric contact point heaters is the somewhat limited amount of BTUs available. A practically sized heating coil can only output so much heat and in extremes of temperature and precipitation and electric contact point heater will not only fail to melt the snow as it accumulates, but the snow that does melt may re-freeze between the ties and the points making mechanical clearance nearly impossible.
Electric heaters also require a fair amount of railroad and utility infrastructure. Not only do the interlocking locations need a power supply with sufficient current available to power tens of feet of heating element, they also need additional cabling between the power supply and the switches themselves and in the long run high voltage electrical cabling in wet conditions can become a maintenance issue.
When the electricity supply either isn't available or isn't enough then it's time to break out the burner bars that apply a gas flame directly to the rail. Generally impractical to use except on the outside rail, it was common to add an additional shroud to trap the heat around the rail, although these since fallen out of favor due to issues related to inspection or snagging equipment.
The propane heaters shown above generally succeed in hiding the flame and and often create a whistling noise while in operation. Some older installations that use municipal natural gas lines create more visible flames, sometimes to the alarm of passers by who think that something has gone wrong.
While all of the direct acting styles of point heaters work well, if one really has to take it to the next level it is time to get a forced air heater. Not only does this provide heat, but also the mechanical force of the air that can blow snow and water off the critical surfaces where they might cause problems. In a similar fashion to the direct acting heaters, the forced air heaters are available in both electric and gas powered models.
The use of forced air requires ducting to channel the air from the heater to the points where it is needed. Unlike the direct acting heaters the duct-work typically runs between the rails, although there are exceptions.
Rare electric forced air point heater at JESSUP interlocking prior to re-signaling. |
A gas powered heater, shown above, is identifiable by a gas pipe and regulator (if the tanes of propane are somehow not enough). The T shaped air intake is a common feature to prevent the ingestion of liquid and debris.
In operation a basic heater shoots a jet of flame down the ducting which turns into a jet of hot exhaust air. Unlike a household furnace there is no danger of the exhaust gases building up in an enclosed space, so again, no heat exchanger is necessary. You can also see in the video that parts of the ducting represent a serious burn hazard for any trespasser who might be ignorant of the danger and I am sure after a number of lawsuits a new, more insulated design will probably be adopted.
One popular technique being employed out west makes use of a fiberglass shroud to cover most of the point assembly and prevent snow from getting into the workings. This is then paired with a direct acting heater that can keep up with any residual ingress. These shrouds are deployed during the winter months and then stored on a trackside rack for the remainder of the year.
Any point heating solution apart from smudge pots or directly setting the rails on fire has benefited from the same automation used for power interlockings and CTC. From a push button or knife switch in a tower, to a unit lever on a CTC machine to the click of a mouse today. Use of point heating is treated like any other facet of railroad operation.
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