Metrolink Plans For Live Brake-Tests of BNSF "Heavy Iron" Train-Sets on Commuter Tracks
On September 26, 2015, Southern California regional rail passenger carrier Metrolink announced a decision to lease forty Burlington Northern Santa Fe (BNSF) freight locomotives. As the plan goes into effect, current high-pollution diesel locomotives
will continue to provide head-end power for all outbound Metrolink
trains. On return trips, BNSF freight locomotive will provide the
head-end power. In either direction, one locomotive will provide
traction and the other will be deadweight. The cost to lease and outfit
the BNSF locomotives with positive train control (PTC) safety systems
will exceed $19 million.
Collision vulnerability of pusher trains, with a cab car up front is widely known. During a February 2015 Metrolink collision in Oxnard, California, a Hyundai-Rotem cab car experienced a catastrophic failure
of its anti-derailment “plow”. The loss of the plow beneath the cab
car may have caused its derailment, along with the remaining coaches
and the Metrolink pusher locomotive #870.
Recently, a source close to the Metrolink investigation told me, “I believe that the NTSB informed the railroad
about the plow failure. It is amazing that they are replacing the
Rotem cab cars with (BNSF) engines, using an ‘emergency provision’
related to safety.” Another trusted source told me, “The BNSF freight
units are about 50% heavier and have six axles to bear that weight.
However, in spite of their horsepower, they have poor acceleration and
limited top speed. The resulting longer trains will also complicate the
operation at storage tracks, some of which will not be able to
accommodate an extra vehicle. If instituted, I predict a major service
meltdown.”
Diesel
locomotives utilize two separate braking systems. With dynamic breaking
engaged, the diesel engine slows to an idle, while the electric motor
becomes an electrical generator. The generator provides resistance to
the drive train, thus slowing the train’s wheels. All of this takes
time. On a freight locomotive, the pneumatic system provides faster or
emergency braking. It uses pressurized air to actuate cylinders and
rods, which impinge upon “brake blocks”. The brake blocks, which are
analogous to automotive break shoes, apply friction directly to the
train’s steel wheels.
It is common knowledge that Metrolink has ceased scheduled maintenance
on its decades-old locomotives. If a locomotive fails, they attempt to
fix it. Otherwise, Metrolink keeps running each locomotive until the
next failure. This raises obvious questions about reliability and
safety. It also begs the question; does Metrolink still conduct
scheduled or preventative maintenance on its locomotive braking
systems? A simple audit of its maintenance contractor, Bombardier
Transit Corporation, would show whether they provide periodic
maintenance on Metrolink locomotive brake systems.
In
the newer, Hyundai-Rotem cab cars and coaches, disk brake technology
now prevails. Under Rotem’s high-tech scheme, the cab car’s wheels
support outboard disks, or rotors as part of the pneumatic braking
system. Typically, disk brakes act more efficiently than “brake shoes”
to slow a moving vehicle. This technology, which is new to Metrolink,
comes at a price. That price is what we call “the learning curve”.
At its home location in South Korea, Hyundai-Rotem reportedly paid a
$6.3 million settlement last year over brake defects and mechanical
malfunctions. Rather than field testing its various consists of coaches,
cab cars and locomotives, Metrolink assumed that all of its braking
systems would be compatible. Through ignorance or indifference,
Metrolink failed to perform live braking trials for their typical, odd
assortment of coaches.
Still unknown is how a mixture of old and new braking systems affected the derailment of all five cars
during the 2015 Oxnard collision. New technology braking systems
installed on the three Rotem coaches may have overwhelmed the braking
capacity of the single, obsolete Bombardier bi-level coach.
Even
after the cab car and other coaches had derailed, a poorly maintained
Metrolink locomotive kept pushing from the rear. Photographic evidence
suggests that slow braking at the pusher-end popped the rigid
Bombardier coach loose from both of its couplings. Once the Bombardier
coach derailed, it traveled farther off course than even the doomed
Hyundai-Rotem cab car. Other than the death of Metrolink Senior
Engineer Glenn Steele, the most serious injuries occurred within the
obsolete Bombardier bi-level coach.
Metrolink’s recent decision to lease forty, six-axle BNSF diesel
freight locomotives was hasty. If the newly devised train sets cannot
operate better than the mixed-consist trains currently in operation,
both passengers and motorists may be at additional risk. Riding on four
axles, current Metrolink diesel locomotives weigh 280,000 lb. At over
420,000 lb., the BNSF freight engines are fifty percent heavier. A
current five-car Metrolink train weighs approximately 460,000 lb. By
adding a freight locomotive at one end, the BNSF train set will weigh
880,000 lb., an increase of ninety-one percent.
In
contrast to the diminutive anti-derailment plow on the Hyundai-Rotem
cab cars, the BNSF freight locomotives should be able to clear almost
any vehicle or debris from the tracks. However, the addition of such
“heavy iron” on each Metrolink train raises questions about fuel
consumption, environmental pollution, braking systems and overall
reliability.
Fuel Consumption – A twelve-cylinder, turbocharged two-stroke diesel
engine powers each Metrolink EMD F59PH locomotive. None of those
locomotives is younger than twenty years. By current standards, they
are “gas hogs”, inefficiently providing traction to the drive wheels.
To get the idea, picture a 1990 Mercedes 190D diesel automobile spewing nitrogen oxide and particulates into the air as you drive behind it.
By
effectively “dragging” one locomotive or the other at all times, the
dead weight of the nonfunctional locomotive will drastically increase
Metrolink fuel consumption. In the past, some railroads have solved
lightweight cab car derailments with old-fashioned innovation. They
have replaced cab cars with stripped-down locomotives. With their
diesel engines and traction motors removed, these so-called “coffin cars”
provide sufficient weight upfront to preclude most derailments.
Admittedly any "coffin cars" utilized on Metrolink tracks would require
addition of Positive Train Control (PTC) safety systems. Still, that
could cost a lot less than the recently approved $19 million BNSF lease.
Environmental Pollution – A decade after the newest Metrolink F59PH
locomotives came into service, the U.S. EPA’s 2005 Tier 2 locomotive
emissions standards took effect. Given their age and power plants, all
Metrolink locomotives qualify as pre Tier 2. That designation makes them
among the worst polluters currently active on any U.S. passenger
railroad.
With the recent deception perpetrated by World Wide Volkswagen Group, the public is now aware that nitrogen oxide
is a greenhouse gas (GHG) 300-times more detrimental than carbon
dioxide itself. In this case, even a single Tier 0-1 diesel locomotive
pollutes the air at a greater rate than hundreds, if not thousands of
errant Volkswagen diesel engines.
Braking Power – Mixed-consist train sets
require testing to determine how they will perform under emergency
braking procedures. Using readily available metering and measurement
devices, Metrolink should test each consist of coaches and locomotives.
During a full speed test, the locomotive engineer would initiate
emergency braking. Although this would not simulate a collision, it
would “stress test” both old and the new braking and coupling systems
in a live environment. Until it provides results of live emergency
brake testing, Metrolink’s mismatched train sets may continue to endanger both passengers and the public.
Reliability
– Over the years, the uptime of Metrolink locomotives has
deteriorated. As of 2013, thirty of Metrolink's fifty-two locomotives
were due for complete overhaul. By 2015, not one of those obsolete
locomotives had received more than a "Band-Aid" overhaul. Instead, as
it awaits their replacement with new Tier 4 locomotives, Metrolink is
running its current fleet of locomotives until failure.
The agency’s lack of scheduled maintenance reminds me of oil
exploration on the North Slope of Alaska. There, when an oilfield
declines, the operator discontinues periodic maintenance well before
final closure. In such cynical, “work until failure” schemes, oil
companies curtail periodic maintenance in order to save money. In such
cases, reliability and safety take a backseat to corporate profits.
Whether in Alaska oilfields or on Southern California rails, the end of
periodic maintenance and overhaul signals a decline in both reliability
and safety. With an oil field, the company can wait for repairs, clean
up any spilled oil and then resume pumping. With Metrolink, the
consequences of its current “work until failure” plan include fewer
riders, less revenue and potential catastrophic failure of the Metrolink system.
By James McGillis at 05:56 PM | | Comments (0) | Link
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