Classifications

• • B—PERFORMING OPERATIONS; TRANSPORTING
  • B61—RAILWAYS
  • B61C—LOCOMOTIVES; MOTOR RAILCARS
  • B61C17/00—Arrangement or disposition of parts; Details or accessories not otherwise provided for; Use of control gear and control systems
  • B61C17/12—Control gear; Arrangements for controlling locomotives from remote points in the train or when operating in multiple units
• • B—PERFORMING OPERATIONS; TRANSPORTING
  • B60—VEHICLES IN GENERAL
  • B60T—VEHICLE BRAKE CONTROL SYSTEMS OR PARTS THEREOF; BRAKE CONTROL SYSTEMS OR PARTS THEREOF, IN GENERAL; ARRANGEMENT OF BRAKING ELEMENTS ON VEHICLES IN GENERAL; PORTABLE DEVICES FOR PREVENTING UNWANTED MOVEMENT OF VEHICLES; VEHICLE MODIFICATIONS TO FACILITATE COOLING OF BRAKES
  • B60T13/00—Transmitting braking action from initiating means to ultimate brake actuator with power assistance or drive; Brake systems incorporating such transmitting means, e.g. air-pressure brake systems
  • B60T13/10—Transmitting braking action from initiating means to ultimate brake actuator with power assistance or drive; Brake systems incorporating such transmitting means, e.g. air-pressure brake systems with fluid assistance, drive, or release
  • B60T13/66—Electrical control in fluid-pressure brake systems
  • B60T13/665—Electrical control in fluid-pressure brake systems the systems being specially adapted for transferring two or more command signals, e.g. railway systems
• • B—PERFORMING OPERATIONS; TRANSPORTING
  • B60—VEHICLES IN GENERAL
  • B60T—VEHICLE BRAKE CONTROL SYSTEMS OR PARTS THEREOF; BRAKE CONTROL SYSTEMS OR PARTS THEREOF, IN GENERAL; ARRANGEMENT OF BRAKING ELEMENTS ON VEHICLES IN GENERAL; PORTABLE DEVICES FOR PREVENTING UNWANTED MOVEMENT OF VEHICLES; VEHICLE MODIFICATIONS TO FACILITATE COOLING OF BRAKES
  • B60T17/00—Component parts, details, or accessories of power brake systems not covered by groups B60T8/00, B60T13/00 or B60T15/00, or presenting other characteristic features
  • B60T17/02—Arrangements of pumps or compressors, or control devices therefor
• • B—PERFORMING OPERATIONS; TRANSPORTING
  • B60—VEHICLES IN GENERAL
  • B60T—VEHICLE BRAKE CONTROL SYSTEMS OR PARTS THEREOF; BRAKE CONTROL SYSTEMS OR PARTS THEREOF, IN GENERAL; ARRANGEMENT OF BRAKING ELEMENTS ON VEHICLES IN GENERAL; PORTABLE DEVICES FOR PREVENTING UNWANTED MOVEMENT OF VEHICLES; VEHICLE MODIFICATIONS TO FACILITATE COOLING OF BRAKES
  • B60T17/00—Component parts, details, or accessories of power brake systems not covered by groups B60T8/00, B60T13/00 or B60T15/00, or presenting other characteristic features
  • B60T17/18—Safety devices; Monitoring
  • B60T17/22—Devices for monitoring or checking brake systems; Signal devices
  • B60T17/228—Devices for monitoring or checking brake systems; Signal devices for railway vehicles

Definitions

• the present invention relates to locomotive compressor systems and, more particular, to a system for controlling locomotive compressors in a consist.
• each of the locomotives are interconnected via the MR pipe end hose, making the combined MR volume available to the locomotive consist.
• Each locomotive also includes an air compressor that is used to pressurize the main reservoirs.
• the 27 pin train line includes a train line for MU compressor control (usually train line #22). This allows the compressor governor on the lead locomotive to simultaneously start and stop the compressors on all of the locomotives, resulting in very rapid filling of the interconnected MR system.
• the MU operation of the compressors assures uninterrupted, adequate air supply even if the compressor on the lead locomotive fails.
• the locomotive air brake system includes a nominally 19/64" diameter choke restricting the flow between the outlet of MR2 and the inlet of the brake pipe pressure control circuit.
• Brake pipe pressure is typically fully charged at 90 psi.
• a full service brake pipe reduction is typically 26 psi, which corresponds to a 64 psi brake pipe pressure.
• the brake pipe is recharged to 90 psi. Because the brake pipe on the train is the length of the train, often in excess of 6000 feet, and due to effect of friction in the pipe, the brake pipe in the front of the train charges well before the brake pipe in the rear of the train.
• the brake pipe regulating device (brake pipe relay) in the locomotive brake system begins to throttle the air flow based on the brake pipe pressure at the head of the train before the brake pipe in the train is fully charged.
• the net combination of the low head pressure at recharge, which is 120 to 140 psi MR pressure flowing into a 64 to 90 psi brake pipe, the 19/64" charging choke, and throttling of the brake pipe relay means that the rate of required air flow is much less than the air flow capacity of the compressor on just one locomotive.
• the combined air flow capacity from the compressors on each of the locomotives is thus much greater than required and, as a result, the compressor duty cycle is very short.
• the MR recharge from 120 psi to 140 psi may take less than 30 seconds. This is undesirable for several reasons.
• the compressor start includes high inrush current, high accelerations, and high torque on the components, all of which are ultimately damaging to the compressor.
• the compressor runs for so short a time it is not able to achieve optimum, stable operating temperature. As a result, there is an accelerated wear of cold parts due to transient thermal expansion issues and the cold compressor is more prone to accumulation of condensed water from the product air.
• the accumulation of liquid water can freeze in winter operation, thereby causing blockage of the compressor after cooler and discharge lines.
• the compressor has a longer duty cycle, so that the compressor and related components are heated due to the heat of compression to more or less the same temperature as the discharged air.
• the normal operating temperature of the compressor results in much less condensation in the compressor system, and enough heat in the after cooler and discharge lines to prevent any liquid water from freezing in those critical locations.
• synchronous control of all the compressors in the locomotive consist might be an advantage during dry charge, or in the event of a failure of the compressor on the lead locomotive, synchronous control is clearly detrimental to compressor life and problematic during cold weather operation because the compressor duty cycle is too short.
• a lead locomotive in a consist could be set up to allow for independent compressor control, so the pressure governor on each locomotive turns that compressor on and off independently.
• This control scheme addresses the issue of too much charge capacity because all the main reservoirs are connected by the MR pipe and therefore the MR pressure on each locomotive is nominally the same and because there is a natural tolerance in the pressure governor settings on each locomotive compressor control.
• one compressor in the locomotive consist will turn on at a higher pressure than the other compressors in the consist due to tolerance variations of the pressure governors and will provide all of the air for the train and, as a result, the compressor utilization and compressor maintenance demand is unbalanced.
• compressor maintenance is done on a planned, periodic schedule, with certain maintenance actions occurring at regular calendar intervals.
• the compressors subject to this control scheme will have done more work during the maintenance interval than others, so some compressors will be maintained too late and some serviced earlier than needed.
• the present invention comprises a system for controlling multiple air compressors in a locomotive consist, where the air compressor of each locomotive is associated with a networked controller that can send or receive commands related to the operation of the associated compressor.
• One predetermined controller is programmed issue commands to the other controllers so that each compressor is operated more efficiently.
• each compressor may be sequentially enabled for refilling to MR system each time it needs refilling.
• the lead controller may also monitor the total utilization of the other compressors since a predetermined point in time or use so that the lead controller can implement a schedule of compressor usage that maximizes utilization of each compressor, thereby ensuring that each compressor is fully utilized during its scheduled maintenance period.
• the lead controller can also be coupled to thermometers or other sensors to control compressor usage to avoid freezing or other temperature related issues.
• FIG. 1 is a schematic of a multiple unit consist having a compressor control system according to the present invention
• FIG. 2 is a schematic of a compressor control system for each locomotive in a consist according to the present invention
• FIG. 3 is a schematic of a networked compressor control system according to the present invention.
• FIG. 4 is a flowchart of compressor control according to the present invention.
• FIG. 5 is a flowchart of compressor system control according to the present invention.
• Fig. 1 a smart, distributed locomotive compressor control system 10 that optimizes compressor life, cold weather operation, and balances utilization for maintenance optimization.
• System 10 interconnects the compressor 12 of each locomotive 14 in a multiple unit consist.
• one locomotive 14 may be designed as a lead locomotive 14a, while subsequent locomotives 14b through 14n act as slaves.
• Fig. 1 represents lead locomotive 14a at the head of the consist, locomotive 14 designated to act as lead locomotive 14a could be located in any position along the consist.
• system 10 is a series of individual locomotive control systems, each of which has an individual controller 16 associated with each compressor 12 of each locomotive 14 in a consist. Controller 16 is networked to other locomotives in the train consist via an interface 18 that connects controller 14 to a network 20 spanning the consist.
• Network 20 can comprise a wireless network, such as IEEE 802.11 or cellular 3G or 4G network, or a wired network, such as Ethernet or IEEE 802.5, or even a custom network employing a spare wire in the existing 27 pin train lines used for intra-train communications.
• interface 18 includes a power line carrier network signal that is overlaid on the existing 27 pin train line compressor control wire, which is typically wire number 22.
• Controller 16 may monitor the rate of pressure increase in the MR system while compressor 12 is operating using a sensor 22 coupled to the MR system, such as a first main reservoir 28.
• Main reservoir 28 may be connected to the main reservoir pipe 36 of the locomotive.
• First main reservoir 28 may also be connected via a check valve 30 to a second main reservoir 32.
• Second main reservoir 32 may be connected to the braking system 34, which is also connected to the brake pipe 40.
• a power source 44 may be coupled to system 10 via switch 42 that operates in response to pressure in reservoir 28.
• System 10 may also be configured so that each controller 16 includes a monitoring module 24 that tracks the total utilization of its corresponding compressor 12 since a predetermined point in time or use, such as the last overhaul or major maintenance. Monitoring module 24 may thus report usage information to lead controller 16, which may then establish and implement a schedule of compressor usage that preferentially commands usage of compressors in the consist that have the lowest accumulated utilization. System 10 may be further optimized by adding a real-time clock to each controller 16 and comparing accumulated compressor utilization with the time remaining until the next scheduled maintenance (or time since last maintenance), so that system 10 can target compressor usage to achieve 100 percent utilization of each compressor 12 by the end of the scheduled maintenance interval.
• a compressor having 75 percent accumulated utilization that is 95 percent of the way through its maintenance interval would be used preferentially over a compressor having 10 percent utilization that is only 10 percent of the way through its maintenance interval.
• the addition of a temperature sensor 26 to system 10, will further allow system 10 to manage compressor temperatures and avoid related issues.
• the compressor control scheme could preferentially operate only one compressor in the consist to optimize the compressor temperature during use of the compressor when the ambient temperature is below freezing.
• system 10 includes any number of individual locomotives, each of which includes a compressor control system as seen in Fig. 2.
• a designated lead controller 16a of a lead locomotive 14a can asynchronously control each of the compressors on the remaining locomotives 14b through 14n in the consist to optimize charge rate, compressor temperature, and balance compressor utilization.
• Corresponding elements in the individual system of each locomotive, with three chosen for illustrative purposes, are indicated using sub- numerals (a, b, c).
• system 10 may be programmed to manage compressor utilization in several different ways. For example, under control of lead compressor controller 16a, the refilling of the main reservoir system may be done by sequentially enabling each compressor 12b through 12n in the consist. The first time the MR system in the consist needs to be refilled, compressor 12a on the first locomotive is utilized. The next time, compressor 12b on the second locomotive is sent the command to refill the MR system, with system 10 sequentially cycling through each of the remaining compressors 12n. In this way, all of compressors 12a through 12n in the locomotive consist will undergo the same amount of utilization and have an optimized duty cycle.
• system 10 may be programmed to preferentially use the compressors having the lowest usage time.
• the first step involves an identification of all compressors in the consist 50.
• a utilization factor is calculated for each compressor in the consist 52 based on an assumption of total allowed usage and actual usage. For example, an assumption of an eight year useful life between overhauls and 1500 hours of powered use per year would result in a 12,000 hour useful life. It should be recognized that eight years and 1500 hours are exemplary variables and other values could be used by system 10.
• the compressors may be ranked according utilization 54, such as from lowest to highest utilization.
• a command may be sent to the appropriate compressors 58 using the utilization factor rankings.
• a check 60 determines that the primary main reservoir is equal to or above about 145 psi, all compressors may be turned off 62 and the usage hours for each compressor updated accordingly 64.
• controller 16a of lead locomotive 14a can monitor the rate of pressure increase in the MR system while compressor 12a is operating using a sensor 22a coupled to the MR system. Sensor 22a can detect the high air flow demand based on the low rate of pressure increase in a reservoir 28a of MR system. In this state, controller 16a of lead compressor 12a can send a command via interface 18a to slave compressors 12b through 12n on network 20 to turn on their corresponding compressors 12b though 12n until the air demand is satisfied.
• controller 16a of lead compressor 12a can send a command via network 20 that instructs one or more of compressors 12b though 12n to shut off when the rate of MR pressure increase is too fast or desired amount has been achieved.
• the first step such an approach is to determine that the pressure in the primary main reservoir has fallen below a threshold 70, such as 125 psi.
• the control compressor, such compressor 12a may then be turned ON 72.
• a check is made 74 to determine whether the pressure remains below a second, lower threshold, such as 120 psi, which may indicate the need for additional compressors to be turned on due to extremely low pressure.
• a rate of recharging check 76 is made to determine whether rate of increase of pressure is above a predetermined rate. If not, a command is sent 78 to turn on an additional compressor, such as compressor 12n. If check 74 determines that the pressure is not below the second threshold, however, there is no need for additional compressors to be turned on and a check 80 is made to determine whether the primary main reservoir has been adequately re-pressurized. If so, all compressors are turned OFF 82.

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• Engineering & Computer Science (AREA)
• Transportation (AREA)
• Mechanical Engineering (AREA)
• Automation & Control Theory (AREA)
• Valves And Accessory Devices For Braking Systems (AREA)
• Control Of Positive-Displacement Pumps (AREA)
• Electric Propulsion And Braking For Vehicles (AREA)

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• 2014
  • 2014-09-17 BR BR112017004774-8A patent/BR112017004774B1/pt active IP Right Grant
  • 2014-09-17 DE DE112014006875.6T patent/DE112014006875T5/de active Pending
  • 2014-09-17 CA CA2961342A patent/CA2961342C/en active Active
  • 2014-09-17 AU AU2014406472A patent/AU2014406472B2/en active Active
  • 2014-09-17 CN CN201480081962.2A patent/CN106715225B/zh active Active
  • 2014-09-17 WO PCT/US2014/055984 patent/WO2016043725A1/en active Application Filing

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