So I took the time to re-process the photos from my 2004 trip to ALTO tower that formed the core of my 2011 blog post about the tower and its interior. The old photos had been edited for a 2004 web standard of 100-200k file sizes. Although only taken on a 3MP camera, that still meant I could use the full resolution available without blowing up the page load time.
In addition, I streamed two photo processing sessions where I talked about the history of ALTO and the story of my visit to the tower along with all sorts of interesting factoids and hijinks.
Yeah that's right, I've getting into live streaming! Who says one can't squeeze content from a stone 😏
A blog devoted to explaining the ins and outs of North American railroad signaling, past, present and future. This blog seeks to preserve through photo documentation the great diversity and technical ingenuity of 20th century signaling and interlocking hardware and technology. Related topics cover interlocking towers and railroad communications infrastructure.
Note, due to a web hosting failure some of the photos and links may be unavailable.
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Saturday, June 30, 2018
Sunday, June 24, 2018
Atlanta Terminal South Tower Demolished
One of the few bits of railroad history left in downtown Atlanta was torn down last week when wrecking crews came for the former Southern Railway Terminal South tower, one of the last surviving parts of the great Terminal Station that closed in 1972, itself razed for a Federal Building in 1979.
While the brick structure was not in danger of fire, a number of large cracks had opened up on the walls and it could be assumed that the tower was less than structurally sound.
Unlike the Northeast and industrial Midwest, the South and West never featured large numbers of tower, especially high quality non-combustable ones with power interlocking machines. A Georgia Rail history website could only list three surviving towers in the state, a number now reduced to two. The Terminal South tower had also anchored the railfanning scene in the city and it is unknown at this time what might be able to replace it what with the unrelated re-signaling efforts that have been going on.
While the brick structure was not in danger of fire, a number of large cracks had opened up on the walls and it could be assumed that the tower was less than structurally sound.
Unlike the Northeast and industrial Midwest, the South and West never featured large numbers of tower, especially high quality non-combustable ones with power interlocking machines. A Georgia Rail history website could only list three surviving towers in the state, a number now reduced to two. The Terminal South tower had also anchored the railfanning scene in the city and it is unknown at this time what might be able to replace it what with the unrelated re-signaling efforts that have been going on.
Saturday, June 16, 2018
Railroad Signals and the Materials of Yesteryear
NOTE: This article first appeared in the Summer 2017 issue of The Trackside Photographer.
In 1967 young people were told that plastics were the future and the future did not disappoint. Today the world is made out of plastic, carbon fibre, corrosion resistant lightweight alloys, high strength concrete and LEDs. This technology has generally converted our world from one where stuff is expensive and people are cheap, to exactly the opposite. I could go on and on about the many economic ramifications of this, but in essence "things" went from being crafted and artisan, to being so invisible that they might as well not matter. Back in the day the Pennsylvania Railroad was the largest private employer in North America with over 300,000 employees, roughly the same as WalMart. This vast army of workers was needed to polish, paint, lubricate and generally maintain all of the expensive, labor intensive technology that allowed humans to move at speeds faster than brisk walk. Replacing the materials of old was part and parcel to being able to replace the workers that cared for them, however as we charge into the middle of the 21st century some of these materials have soldiered on in the service of railroad signaling and, until their inevitable replacement, they provide a window into the pre-digital industrial age.
Steel and iron are the stereotypical railroad materials as demand for bridges, rails and locomotives practically created the modern steel industry. Of course steel wasn't just used for girders and boilers. Back in the day this was the only metal one had available for structural components of any size and before the advent of plastic or other composites, metal was one of the only materials available with an adequate strength to weight ratio. Stronger, weather proof and more durable than wood, iron and steel became the materials of choice ofr railroad signals and signal structures. This US&S style N color light signal mast shown above is almost completely made of iron and steel, right down to the base. Cast iron housing and brackets, sheet steel backing, steel pipe mast, strap iron ladder work, heck, even the signal wires are sheathed in iron.
Cheap and easy to stamp, cut, forge or cast, steel was everywhere, but it's suffers from a major weakness against air and water. The scourge of rust requires care and paint, and paint requires workers to apply and remove. In the 21st century aluminum is cheap and plentiful. Lightweight and rust free, any signal made of aluminum will look as good on the day it is installed as the day it is removed perhaps decades in the future without needing so much as a man hour of skilled labour.
Also used for bridges and track structure, wood was the plastic of its day. Light and easy to shape, it also has tensile strength allowing it to span distances in a way that stone or concrete cannot. Although it was excluded from most signal structures, wood was employed in pole lines to support the signaling and telegraph wires that carried little bits of voltage from one signal location to the next. Unlike steel, stuff can be easily attached to wood with nails or screws and, somewhat surprisingly, wooden poles can also last decades after being impregnated with petrochemical tars. However modern technology found other ways to eliminate the wooden pole lines by replacing the wires they carried with fiber optics or wireless signals.
Surprisingly, cotton was an important material in railroad signaling. Before the advent of PVC sheath insulation, large signal cables were wrapped in cotton impregnated with tar to keep out the elements. Cotton insulated cables went hand in hand with the pole line concept as attempting to bury such a cable would quickly lead to its failure. Damage vulnerable to wind, snow, rain and trees, this was accepted a cost of doing business.
From the smallest telegraph wire to the thickest high voltage transmission cable, copper carried the electrons that powered the signals and sent the data. Synonymous with the term "electrical conductor" to this day, copper was generally replaced by aluminum braids in power applications and of course its role in data transmission was tied to the pole line . Ultimately railroads did all they could to get out of the power transmission business, in some cases going as far to replace copper cable with solid state solar panels.
Large ceramic insulators met the same fate as the copper wire when the business of providing signal power was turned over to the local utilities. Outsourcing is the name of the game in the 21st century. It made no sense for railroads to act as power companies, employing linemen and stocking electrical hardware such as this.
PCB's are probably the best class of material for insulating transformers being non-flammable and possessing a high dielectric coefficient. Unfortunately they also cause cancer and persist in the environment almost indefinitely. All the more motivation for railroads to stop running their own power grids.
Glass was the insulator of choice for low voltage signal and telegraph wires running along side the power supply lines on the poles. Edging out ceramic in the same use case, the sparking glass insulators made railroad poles a look a bit like Christmas trees. Replaced at first by cheap rubber and plastic models and ultimately by wireless, glass insulators became a staple of country antique shoppes and the preferred target of rural target shooters.
More expensive than its pole line cousin, optical glass collected the light from the low wattage signal bulbs and and protected it 1-2 miles down the track for approaching trains to see. Most color light signal lenses consisted of an inner colored glass filter assembly with an outer Fresnel lens that focused the beam. Today these have been replaced by high intensity LED's that often do not need a focusing lens, making do with a cheap clear plastic cover.
Compressed air was the power source of choice for many early power interlocking installations. Not only were air operated switch machines simple and cheap, it was also easy to safety control the flow of air using low voltage electrical circuits passing through an electro-machanical interlocking machine. Of course air was only cheap as long as the workers needed to keep the lines dry and leak free were also cheap. Today pneumatic switch machines are fading fast in the presence of bullet proof, high voltage electric machines.
Silver paint is typically applied to relay huts and cabinets to reflect the sun and keep internal temperatures low. In this case the need for painting has been replaced by corrosion free shiny materials and compact air conditioners.
Lead acid batteries were once provided in large quantities for when the railroad supplied power suffered some sort of outage, as was frequently the case in the pole line era. Because the batteries would vent hydrogen gas as they charged and discharged, they were stored in concrete "wells", outside the relay huts where there was no risk of explosion. Today improvements in battery technology and power reliability have made such large bulky backup power arrangements unnecessary.
Relays are constructs of copper coils moving silver plated electrical contacts to make and break electrical circuits, all sealed up in a glass envelope. Once the standard unit of electronic logic until the advent of the transistor, the function of relays was duplicated by solid state gizmos such as transistors. Relay logic was standardized across vendors and can't be hacked, but changes are costly and time consuming to implement, making software based alternatives far more attractive.
Up through the middle of the 20th century railroads were once at the vanguard of technical innovation, leading the way in telecommunications, computing and material science. While today these technologies and materials of yesteryear can make railroads seem like an under-funded anachronism, a different view shows how well the engineering of the past has stood the test of time. While the materials of today are in many ways superior, they lack much of the spirit of what came before. A spirit created by human hands crafting, fitting and maintaining the materials of yesteryear from one century to the next.
In 1967 young people were told that plastics were the future and the future did not disappoint. Today the world is made out of plastic, carbon fibre, corrosion resistant lightweight alloys, high strength concrete and LEDs. This technology has generally converted our world from one where stuff is expensive and people are cheap, to exactly the opposite. I could go on and on about the many economic ramifications of this, but in essence "things" went from being crafted and artisan, to being so invisible that they might as well not matter. Back in the day the Pennsylvania Railroad was the largest private employer in North America with over 300,000 employees, roughly the same as WalMart. This vast army of workers was needed to polish, paint, lubricate and generally maintain all of the expensive, labor intensive technology that allowed humans to move at speeds faster than brisk walk. Replacing the materials of old was part and parcel to being able to replace the workers that cared for them, however as we charge into the middle of the 21st century some of these materials have soldiered on in the service of railroad signaling and, until their inevitable replacement, they provide a window into the pre-digital industrial age.
CSX Washington Sub - South Orange Interlocking |
CSX Philly Sub - MP 80 Auto Signal "Whitemarsh" |
CSX Cumberland Sub - Paterson Creek interlocking |
Also used for bridges and track structure, wood was the plastic of its day. Light and easy to shape, it also has tensile strength allowing it to span distances in a way that stone or concrete cannot. Although it was excluded from most signal structures, wood was employed in pole lines to support the signaling and telegraph wires that carried little bits of voltage from one signal location to the next. Unlike steel, stuff can be easily attached to wood with nails or screws and, somewhat surprisingly, wooden poles can also last decades after being impregnated with petrochemical tars. However modern technology found other ways to eliminate the wooden pole lines by replacing the wires they carried with fiber optics or wireless signals.
D&H 'QS" Interlocking, Mechanicville, NY |
PRR 138kv Transmission Line near Martic Forge, PA |
CP-MIDWAY - Port Road Branch |
CP-SLOPE, Altoona, PA. |
CSX Cumberland Sub - Magnolia, WV |
More expensive than its pole line cousin, optical glass collected the light from the low wattage signal bulbs and and protected it 1-2 miles down the track for approaching trains to see. Most color light signal lenses consisted of an inner colored glass filter assembly with an outer Fresnel lens that focused the beam. Today these have been replaced by high intensity LED's that often do not need a focusing lens, making do with a cheap clear plastic cover.
CP-RADE, Radebaugh, PA |
CP-TRAFF, Trafford, PA |
CP-HAWSTONE, Lewistown, PA |
PRR OVERBROOK tower. |
CSX Cumberland Sub MP 130 Auto Signal "Drywall" |
Sunday, June 3, 2018
Caught on Camera: Bobbing SEPTA Main Line Signals
Several years ago I discussed the topic of relay logic and how it can create interesting signal displays as they change from one aspect to the next. (Usually this involves a change from some form of Clear to some form of Restricted Proceed as that involves two or more discrete relay flips.) Well last week I had taken a trip to the SEPTA North Broad station, just south of the busy 16TH ST JCT, to photograph the last remaining AEM-7 locomotives in operation. At one point, towards the tail end of the peak period, the track 1 signal on the Milepost 2.9 automatic signal bridge began to cycle between Approach Medium, Approach and Stop and Proceed. The northbound home signal at 16TH ST was displaying Medium Clear, so Approach Medium was indeed the correct indication, however the signal continued to move between the three at a fairly brisk clip indicating that the track circuit between there and the interlocking was moving between an occupied and an unoccupied state, a phenomena known as "bobbing".
As time went on the rate of the cycling increased and as soon as the AEM-7 led push-pull on the adjacent track 2 cleared tthe approach block to 16TH ST, that signal began to bob as well, although only between Approach and Stop and Proceed. In due time a northbound train approached the 29-1 signal and I can only imagine what the crew was thinking as they not only watched the wayside signal change ahead of them, but also endured a constant stream of cab signal flips. As one might have expected, the train passed the malfunctioning signal at Restricted speed and shortly thereafter the track 2 signal was also brought down to the Stop and Proceed position full time by an adjacent northbound train.
After the two trains passed whatever temporary fault condition that existed was resolved and the MP 2.9 automatic signals went back to normal operation. There was a later service disruption at the junction, but it appeared to be related to some sort of stuck switch or disabled train. The funny thing was that this wasn't even my only recent encounter with bobbing signals as I also caught two northbound signals at Milepost 69.6 on the Amtrak's Southern NEC also bobbing.
Some bobbing track circuits can be fixed with a few simple adjustments. Others can be quite stubborn and can linger for weeks. Some parts of the southern NEC had bobbing circuit conditions that had been around for years, often where electric movements on one trackcould cause an adjacent track to temporarily show occupied.
As time went on the rate of the cycling increased and as soon as the AEM-7 led push-pull on the adjacent track 2 cleared tthe approach block to 16TH ST, that signal began to bob as well, although only between Approach and Stop and Proceed. In due time a northbound train approached the 29-1 signal and I can only imagine what the crew was thinking as they not only watched the wayside signal change ahead of them, but also endured a constant stream of cab signal flips. As one might have expected, the train passed the malfunctioning signal at Restricted speed and shortly thereafter the track 2 signal was also brought down to the Stop and Proceed position full time by an adjacent northbound train.
After the two trains passed whatever temporary fault condition that existed was resolved and the MP 2.9 automatic signals went back to normal operation. There was a later service disruption at the junction, but it appeared to be related to some sort of stuck switch or disabled train. The funny thing was that this wasn't even my only recent encounter with bobbing signals as I also caught two northbound signals at Milepost 69.6 on the Amtrak's Southern NEC also bobbing.
Some bobbing track circuits can be fixed with a few simple adjustments. Others can be quite stubborn and can linger for weeks. Some parts of the southern NEC had bobbing circuit conditions that had been around for years, often where electric movements on one trackcould cause an adjacent track to temporarily show occupied.
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