Patent Grant
6893058
1. Field of the Invention
The invention relates generally to railroad friction enhancing and friction reducing systems. More particularly, the invention relates to systems and methods for automatically controlling the application of the cohesion or friction modifiers to a railway system.
2. Background
Locomotives and transit vehicles as well as other large traction vehicles are commonly powered by electric traction motors coupled in driving relationship to one or more axles of the vehicle. Locomotives and transit vehicles generally have at least four axle-wheel sets per vehicle with each axle-wheel set being connected via suitable gearing to the shaft of a separate electric motor commonly referred to as a traction motor. In the motoring mode of operation, the traction motors are supplied with electric current from a controllable source of electric power (i.e., an engine-driven traction alternator) and apply torque to the vehicle wheels which exert tangential force or tractive effort on the surface on which the vehicle is traveling (i.e., the parallel steel rails of a railroad track), thereby propelling the vehicle in a desired direction along the right of way.
Locomotives used for heavy haul applications typically must produce high tractive efforts. Good adhesion between each wheel and the surface is required for efficient operation of the locomotive. The ability to produce these high tractive efforts depends on the available adhesion between the wheel and rail. Many rail conditions such as being wet or covered with snow or ice require an application of friction enhancing agent such as sand to improve the adhesion of the wheel to the rail. Therefore, locomotives typically have sand boxes on either end of the locomotives, and nozzles to dispense the sand (both manually and automatically) to the rail on either side of the truck.
Maximum tractive or braking effort is obtained if each powered wheel of the vehicle is rotating at such an angular velocity that its actual peripheral speed is slightly higher (motoring) than the true vehicle speed, i.e., the linear speed at which the vehicle is traveling, usually referred to as “ground speed” or “track speed”. The difference between tractive wheel speed and track speed is referred to as “creepage” or “creep speed.” There is a variable value of creepage at which peak tractive effort is realized. This value, commonly known as the optimal creep setpoint is a variable that depends on track speed and rail conditions. So long as the allowable creepage is not exceeded, this controlled wheel slip is normal and the vehicle will operate in a stable microslip or creeping mode. If wheel-to-rail adhesion tends to be reduced or lost, some or all of the tractive wheels may slip excessively, i.e., the actual creep speed may be greater than the maximum creep speed. Such a gross wheel slip condition, which is characterized in the motoring mode by one or more spinning axle-wheel sets, can cause accelerated wheel wear, rail damage, high mechanical stresses in the drive components of the propulsion system, and an undesirable decrease of tractive effort.
The peak tractive effort (TE) limits the pulling/braking capability of the locomotive. This peak tractive effort is a function of various parameters, such as weight of the locomotive per axle, wheel rail material and geometry, and contaminants like snow, water, grease, insects and rust. Contaminants in the wheel/rail interface reduce the maximum adhesion available, even at the optimal creep setpoint.
While the locomotives most often require friction enhancing agents, locomotives also require, in some situations, the application of a lubricant to reduce the wear of the locomotive wheel flanges. For example, when a locomotive is traversing a section of track with a curve. For a locomotive or a consist of locomotives that are always oriented in the same way, maximum benefit for wheel-rail wear of both the cars and the locomotives is provided by lubricating the gage side of the rail or wheel flanges on the high rail in the front and simultaneously lubricating the top of the two rails in the trailing end of the locomotive or the locomotive consist. Control of the rail gage side (RAGS) lubricator as well as the top of rail (TOR) lubricator can be done by the same controller for one locomotive or two controllers located in different locomotives for the case of a locomotive consist.
While locomotive often require increased cohesion, generally non-locomotive railway cars trailing the locomotives operate most efficiently at lower cohesion or friction levels. As such ,friction and therefore pull weight of railway cars. Lubricant applied to the top of the rail and possibly to the gage side of the rail behind the last axle of the last locomotive results in reduced friction and wear of the trailing car wheels. In other systems, such as a flange lubrication system, grease is applied to the flanges of the locomotive wheels in order to reduce friction between the flange and the wheel thereby reducing fuel usage and increase rail and wheel life. The system dispenses a controlled amount of lubrication, based on locomotive speed and direction, to the inside flange of wheel to lubricate the wheel/flange interface on the trailing axles of the locomotive/train. Presently, nozzle placement is based on customer choice, and the nozzles can be applied to multiple axles and always in pairs (left and right side). The lubrication is typically of a graphite base.
It is desirable to reduce the coefficient of friction for the trailing cars as the reductions in the coefficient of friction directly reduces the pull weight and directly improves the fuel efficiency of the locomotive consist. Managing the coefficient of friction of the cars can result in a 10 to 30 percent increase in fuel efficiency.
Chart 400 in
In this illustration, a locomotive is applying 17,000 pounds of tractive effort. However, at point 406 the rail is wet and the wheels are experiencing a per unit creep of more than 0.14. Sand is applied immediately prior to the advancing wheel of the locomotive. As a result, at point 408 tractive effort is increased to 20,000 pounds and per unit creep is reduced to less than 0.03. If the sand is later removed, the operating point returns from point 408 to the prior operating point 406. This illustrates the benefits of both applying a friction enhancing agent, in this case sand, and the subsequent removal of the sand to thereafter reduce the friction experienced by a trailing railway car.
Therefore, there is a need for an improved system and method for automatically controlling the application of a friction modifier to the rail by railway locomotives and cars. Such a system and method monitors and assesses various factors and parameters for the purpose of friction management and control of friction modifying agent applicators to optimize the coefficient of friction to the rail for the wheel of a locomotive and the wheel of connected railway cars.
One aspect of the invention comprises a system and a method for friction management is provided for managing and controlling an application of a friction modifying agent to an area of contact between a railway wheel and a railway rail over which the wheel is traversing to selectively modify the coefficient of friction at the contact area. The system comprises a sensor 610 for detecting a parameter relating to the operation of the railway train. A controller is responsive to the sensor 610 and controls the application of the friction modifying agent to the rail as a function of the parameter. An applicator is responsive to the controller and applies the friction modifying agent to the area of contact between the railway wheel and rail.
Another aspect of the invention comprises a method for railway train friction management for managing and controlling the application of a friction modifying agent to an area of contact between a railway wheel and a railway rail over which the wheel is traversing to selectively modify the coefficient of friction at the contact area. The method comprises sensing a parameter related to the operation of the railway train and applying the friction modifying agent to the area of contact between the railway wheel and rail as a function of the sensed parameter.
Referring now to
Alternatively or in addition, auxiliary information or data 604, which may be in the form of a parameter, may be utilized as input for friction management of a railway wheel to the rail. These include consist/train length, train weight, track map, train location, track topography, track grade, track curvature, rail temperature, rail conditions such as dry, wet, rain, snow or ice, the presence of rail modifiers on a rail, both the current and forecasted weather, train schedules or external commands from operators or dispatch centers.
As shown in
A locomotive or a railway car is equipped with an applicator 610 that is responsive to the controller 606. Applicator 610 applies a friction modifying agent 612 to the rail at an area of contact between the railway wheels and the rails on which they are traversing. Friction modifying agents 612 may be enhanced adhesion materials such as sand, or the removal of snow or water from the rail. Friction reducing agents may be water, steam, air, oil, a lubricant, or may be the removal of sand, water, snow or a friction enhancing agent that exists on the rail at the time. In either case, cleaning the rail with a brush, or with water or air, may be friction enhancing or friction reducing depending on the existing state of the rail. The friction management system 600 analyzes these and other operational parameters 602 and optional auxiliary data 604 to determine the appropriate timing and quantity of friction modifying agent 612 to be applied. For example, the amount of friction modifying agent 612 applied by an applicator 610 may be optimized based on the length of the train and the weather conditions such that the modifying agent 612 is consumed or dissipated by the time the last car in a train configuration passes the point of application of modifying agent 612. While the parameters 602 and auxiliary data 604 may be used or monitored for other operational purposes, they are not used for friction management.
In one embodiment of the invention, a train configuration has a plurality of applicators 610 located at positions that are before the wheels of the locomotive. As a locomotive may work in the forward or reverse directions, the locomotive may be configured with friction modifying agent applicators 610 at both ends of the vehicle. Additionally, applicators 610 may be applied to the leading end or the trailing end of a locomotive or a railway car for application of a friction modifying agent 612.
Applicators 610 are configured on the railway vehicle such as to enable the application of the friction modifying agents 612 to defined points of application. As such, it is contemplated that there will be a plurality of applicators 610 on each railway vehicle. Applicators 610 are configured to apply a friction modifying agent 612 to the wheel flange, the wheel rim, the top of the rail (TOR) and/or to the rail gage side (RAGS). The controller 606 determines the type, timing and quantity of the friction modifying agent 612 to be applied. The controller 606 determines the one or more applicators 610 among a plurality of applicators 610 located on a train, locomotive or railway car to apply the agent. Additionally, the controller 606 determines the point of application for the friction modifying agent 612 to be applied.
As noted above a plurality of applicators 610 are positioned on a locomotive and/or a railway car in order to optimize friction management of a train configuration. A train configuration is typically comprised of a lead motoring locomotive, one or more optional secondary motoring locomotives, an optional trailing motoring locomotive that is positioned in a train configuration at a point distant from the lead and secondary motoring locomotives, and one or more railway cars. The applicator, and therefore the application of friction modifying agents 612, may be positioned as a lead applicator of the lead motoring locomotive, a trailing applicator of the lead motoring locomotive, a lead applicator of the secondary motoring locomotive, a trailing applicator of the secondary motoring locomotive, a lead applicator of the trailing motoring locomotive, a trailing applicator of the trailing motoring locomotive, a lead applicator of a railway car, or a trailing applicator of a railway car. Each of these is contemplated as being managed by the friction management system 600.
The controller 606 may communicate by one or more communication systems or links (not shown) between the controller 606, locomotives and railway cars equipped with the friction management system 600.
The secondary locomotive 704 is configured with applicator 714 at the leading end of the locomotive 704. The controller 606 controls the application of friction modifying agents 612 by applicator 714 based on the determined need. In some situations the controller 606 may determine that the application applied by applicator 712 on the leading locomotive 702 is sufficient for both the lead 702 and secondary 704 locomotive. This may be the case when water, snow or ice is on the track and applicator 712 is controlled to remove the water, snow or ice. However, where a steep incline is encountered, the controller 606 may control 712 and 714 to apply friction enhancing agents 612 such as sand to the top of the rail.
Also as shown in
Referring now to
Now referring to
Referring to
As discussed earlier, the controller 606 receives operating parameters 602 from one or more sensors 610 on the train, or associated with the train. Additionally, the controller 606 may also receive auxiliary data 604 from other sources that affect the management and optimization of the friction between the railway wheels and the rail.
As noted in
As another example,
In another embodiment, as noted above knowledge related to the length/weight/power of the consist will be applied to the determination of when and the quantity of the friction modifying agents 612 to be applied. Additionally, a track map based on a CAD system and a GPS location may be used by the controller 606 to determine when and how much and type of agent 612 to be applied. Furthermore, computer aided dispatch systems that gather and analyze train parameter information including the length of the train, weight of the train, the speed of the train and the applied power may be used as an input of auxiliary data 604 to determine when and how much friction modifying agent 612 to apply. A train scheduler/movement planner system and/or RR dispatcher to determine train characteristics are also contemplated as input to the controller 606's determining process.
Another parameter 602 utilized by the friction management system 600 is an inertia estimate based on tractive effort, track grade, speed or tractive effort, GPS position, track map, and speed. The inertia of the train can be determined by the acceleration change per tractive effort change assuming the grade has not changed. If the track grade is also known, then it can be compensated for. The acceleration is obtained from the speed sensors 610 on board the locomotive, the tractive effort is the estimate of force which can be obtained typically from current and voltage measurements on the traction motors (not shown) or it could be obtained from other direct sensors 610. The track grade could be obtained from inclinometers or could be assumed to be the same if the measurements are done over a short period of time. Another technique could use the position of the train, possibly as determined by an on-board global positioning system (GPS) receiver to obtain speed and/or track grade. Another technique could use the track map information based on GPS, operator inputs or side transponders.
Another parameter 602 utilized by the friction management system 600 is speed, throttle setting, and/or tractive effort. The dispensation of both high adhesion material and low adhesion material could be optimized based on the operation of the locomotive. For example, when the consist or train operator calls for high tractive effort (high notch/low speed) then only applicators 712, 714 and 1004 need to be enabled. If the tractive effort produced is what the operator has requested, then there is no need to add friction increasing materials. Most of the fuel efficiency benefits are at high speeds (when tractive effort is low). So under these conditions, only applicators 716 and 902 and optionally applicator 802 need to be enabled. All these variables are available easily on board the locomotive.
As discussed above, the condition of rail 710 is another parameter or item of auxiliary data used to determine optimal friction management. In order to optimize the cost, the dispensing of friction modifying agents 612 can be controlled based on the rail conditions. For example, if rail 710 is dry and clean, then there is no need to dispense high adhesion material. Similarly when there is rain/snow, it may not be necessary to dispense friction-lowering material since the reduction in friction may not be appreciable. Another example is if it is raining or rain is expected before the next train, then there may not be a need to remove low friction material during use of nozzle D. These rail conditions could be inferred based on sensors 610 already on board based on adhesion/creep curves, or could be based on additional sensors 610, or inputs from the dispatch center, operators, external transponders, weather satellites etc.
For rail cars 706 and or idle wheels, creep could be used to estimate the friction coefficient. A separate sensor 610 could be used to determine the coefficient of friction. These sensors 610 could be placed at every point where friction lowering material dispensing is applied or at the end of the locomotive consist. Similarly friction sensors 610 or creep of the last wheel(s) may be used for dispensing neutralizing friction modifying material from applicator 802.
Another factor to be considered is effectiveness detection. It is often necessary to find when these dispensing mechanisms are not working either due to failure or due to lack of friction modifying materials. This is especially important if there are many different kinds of dispensers or if it is difficult to check their operation. For example, if after dispensing high adhesion material, the creep decreases for the same tractive effort or if the tractive effort increases for the same creep or a combination is observed, then the friction modifier is effective. This could be done periodically or whenever the dispensing is initiated. Similarly when the dispensing is terminated, the opposite effect should be observed for proper operation. Similarly when the friction lowering material is dispensed there should be reduction of tractive effort required to maintain the same speed (on the same grade) or there is a speed increase for the same tractive effort. The converse should be observed when the dispensing is stopped. This checking could also be done periodically to ascertain the health of the friction lowering system. These are closed loop systems, which operate in the train. Verification of some of the effects, such as when too much friction lowering material is dispensed (see
As noted earlier, braking conditions are also factors to be considered in friction management. During a braking application, the dispensing requirement changes. No friction lowering material is required and it is advisable to increase the friction coefficient, as high braking effort is required. So during dynamic brake operation or independent brake operation only nozzles 712, 714, 1004 and possibly 802 need to operate. Nozzle 716 and 902 should not be operated. Nozzles 712, 714 and 1004 could be energized based on braking effort call and braking effort obtained and based on rail conditions. Similarly during train air brake operation in addition to turning off nozzles 716 and 902, it may even be necessary to substitute it with friction enhancing material dispensers especially during emergency brake operation to reduce stopping distance. However during light braking/coasting operation friction lowering material could be dispensed if necessary to reduce wheel wear reduction and for preventing too much speed reduction.
During distributed power operation, the dispensing of adhesion lowering material in the lead consist depends on the number/weight of load cars between the lead consist and the trail consist (information of cars between applicators 716 and 1004 in FIG. 10). This information could be obtained using the distance information between the locomotives 704 and 1002. This could be obtained from GPS position information or even using techniques like the time for brake pressure travel information. The dispensing at applicator 716 could be adjusted also based on the friction seen by the trailing locomotive 1002. For example, if the trailing locomotive 1002 encounters very low friction, then too much material is being dispensed by nozzle 716.
When introducing elements of the present invention or the embodiment(s) thereof, the articles “a,” “an,” “the,” and “said” are intended to mean that there are one or more of the elements. The terms “comprising,” “including,” and “having” are intended to be inclusive and mean that there may be additional elements other than the listed elements.
As various changes could be made in the above constructions without departing from the scope of the invention, it is intended that all matter contained in the above description or shown in the accompanying drawings shall be interpreted as illustrative and not in a limiting sense.
This application claims priority to U.S. Provisional Patent Application No. 60/419,673, filed on Oct. 18, 2002, the entire disclosure of which is incorporated herein by reference.
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