Logistics system and method with position control

Information

  • Patent Grant
  • 6704626
  • Patent Number
    6,704,626
  • Date Filed
    Friday, April 2, 1999
    25 years ago
  • Date Issued
    Tuesday, March 9, 2004
    20 years ago
Abstract
A logistics system and method are mounted on a vehicle and utilize vehicle position control for logistics operations, such as loading and unloading material to and from the vehicle. The position control can be GPS-based and/or based on linear movement of the vehicle, such as movement of a railcar along a rail track. A computer-based position control subsystem mounted on the vehicle is connected to and operates vehicle-mounted components for performing the logistics functions.
Description




BACKGROUND OF THE INVENTION




1. Field of the Invention




The present invention relates generally to the field of logistics, and more particularly to a GPS-based system for controlling logistics in connection with a vehicle.




2. Description of the Prior Art




The field of logistics management is relatively broad and includes a wide range of systems for tracking, controlling and reporting logistics operations involving various types of materials. For example, loading and unloading materials are important logistics operations in the transportation field.




Automation is a primary goal of many logistics management systems. The commercial availability of computer hardware and software for logistics applications has led to a relatively high degree of automation. For example, computerized systems are available for controlling material loading and unloading operations.




The global positioning system (GPS) is a significant recent development in the field of vehicle navigation. GPS-based navigation systems are in widespread use, particularly in commercial vehicles. Current, state-of-the-art, GPS-based navigation systems provide positioning information with a relatively high degree of accuracy. Global position coordinates accurate to within a few meters can be obtained with current, commercially-available equipment.




The present invention applies the precise positioning features of current GPS equipment to the logistics management field, and more particularly to material loading and unloading operations. Heretofore there has not been available a GPS-based logistics system and method with the advantages and features of the present invention.




SUMMARY OF THE INVENTION




In the practice of the present invention, a logistics system is provided for a vehicle, such as a railcar. The disclosed embodiment of the logistics system includes a position control subsystem mounted on board the vehicle, an hydraulic actuator subsystem, a ballast discharge mechanism, and the global positioning system (GPS). The position control subsystem includes a microprocessor which associates positioning data (e.g., GPS coordinates) for the vehicle with specific logistics operations, such as material loading and unloading. A control interface is provided for decoding signals from the microprocessor and for addressing them to respective components of the actuator subsystem for operating same. In the ballast railcar embodiment of the invention as shown, hopper doors are opened and closed to direct the flow of ballast therefrom onto a rail track. In the practice of the method of the present invention, the GPS is used for determining vehicle position. A logistics operation is performed at a predetermined location.




OBJECTS AND ADVANTAGES OF THE INVENTION




The principal objects and advantages of the present invention include: providing a logistics management system and method; providing such a system and method which utilize the global positioning system (GPS); providing such a system and method which are adaptable to various vehicles; providing such a system and method which are adapted for use in conjunction with material loading and unloading operations; providing such a system and method which are adapted for controlling material discharge from railcars; providing such a system and method which are adapted to utilize vehicle movement for positioning purposes; providing such a system and method which are adapted for use with various positioning systems; providing such a system and method which utilize commercially available GPS equipment; providing such a system and method which utilize a computer mounted on board a vehicle for logistics management; providing such a system and method which can reduce the labor required for logistics operations; providing such a system and method which can be retrofitted existing vehicles; providing such a system and method which can be installed on new vehicles; providing such a system and method which are adaptable for use with various discharge control means in connection with unloading operations; providing such a system and method which include data storage means and steps for storing data for use in conjunction with logistics operations; and providing such a system and method which are economical and efficient.




Other objects and advantages of this invention will become apparent from the following description taken in conjunction with the accompanying drawings wherein are set forth, by way of illustration and example, certain embodiments of this invention.











The drawings constitute a part of this specification and include exemplary embodiments of the present invention and illustrate various objects and features thereof.




BRIEF DESCRIPTION OF THE DRAWINGS





FIG. 1

is a schematic view of a logistics system with GPS positioning control embodying the present invention, shown installed on a railcar for controlling the loading and unloading operations of same.





FIG. 2

is a schematic diagram of an hydraulic actuating system for hopper door assemblies on the railcar and a position control subsystem.





FIG. 3

is a perspective view of a railcar with a ballast discharge mechanism controlled by the logistics system and method.





FIG. 4

is an enlarged, fragmentary, lower perspective view of the ballast discharge mechanism, particularly showing a hopper door assembly thereof.





FIG. 5

is a schematic diagram of a logistics system comprising a first modified embodiment of the present invention with an alternative positioning control subsystem.











DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS




I. Introduction and Environment




As required, detailed embodiments of the present invention are disclosed herein; however, it is to be understood that the disclosed embodiments are merely exemplary of the invention, which may be embodied in various forms. Therefore, specific structural and functional details disclosed herein are not to be interpreted as limiting, but merely as a basis for the claims and as a representative basis for teaching one skilled in the art to variously employ the present invention in virtually any appropriately detailed structure.




Referring to the drawings in more detail, the reference numeral


2


generally designates a logistics system embodying the present invention. Without limitation on the generality of useful applications of a logistics system


2


, it is shown installed on a railcar


4


for controlling unloading operations thereof.




The logistics system


2


generally comprises the global positioning system (GPS)


6


, an on-board position control subsystem


8


, an hydraulic actuator subsystem


10


and a ballast discharge mechanism


12


.




II. GPS


6






The GPS


6


(

FIG. 1

) includes a satellite constellation


14


comprising a number of individual satellites whose positions are continuously monitored. The satellites transmit signals, including positioning data, which can be received by differential GPS stations


16


located in fixed positions and by GPS receivers, such as the on-board vehicle receiver


18


, which are typically mobile. Various other configurations and arrangements of the GPS can be employed with the present invention. The differential GPS station


16


receives signals from the satellite constellation


14


and transmits signals to mobile GPS receivers.




III. On-Board Position Control Subsystem


8






The on-board position control subsystem


8


(

FIG. 2

) is mounted on the railcar and includes the GPS vehicle receiver


18


, which receives position data signals (e.g., GPS coordinates) from both the satellite constellation


14


and the differential GPS


16


. The vehicle receiver


18


can comprise any of a number of suitable, commercially-available, mobile receiver units. The vehicle receiver


18


is connected to a microprocessor-based control interface/computer


20


which receives positioning data signals from the vehicle receiver


18


, processes same and interfaces with the actuator subsystem


10


. The control interface


20


can include any suitable microprocessor and preferably can be programmed to store data relating to logistics operations in response to GPS signals.




The control interface


20


includes a decoder


21


with inputs connected to the microprocessor for receiving command signals addressed to specific piston-and-cylinder units


32


in the actuator subsystem


10


. The output of the decoder


21


is input to a relay bank


26


with multiple relays corresponding to and connected to respective components of the hydraulic actuator subsystem


10


. The position control subsystem


8


is connected to a suitable, on-board electrical power source


22


, which can utilize a solar photovoltaic collector panel


24


for charging or supplementing same.




IV. Hydraulic Actuator Subsystem




The hydraulic actuator subsystem


10


(

FIG. 2

) includes multiple solenoids


28


each connected to and actuated by a respective relay of the relay bank


26


. Each solenoid


28


operates a respective hydraulic valve


30


. The valves


30


are shifted between extend and retract positions by the solenoids


28


whereby pressurized hydraulic fluid is directed to piston-and-cylinder units


32


for respectively extending and retracting same. The piston and cylinder units


32


can comprise two-way hydraulic units, pneumatic units or any other suitable actuators. An hydraulic fluid reservoir


34


is connected to the valves


30


through a suitable motorized pump


36


and a pressure control


38


.




V. Ballast Discharge Mechanism


12






The ballast discharge mechanism


12


includes four hopper door assemblies


40


installed on the underside of the railcar


4


and arranged two to each side. The hopper door assemblies


40


discharge the railcar contents laterally and are adapted to direct the discharge inwardly (i.e. towards the center of a rail track


5


) or outwardly (i.e. towards the outer edges of the rail track


5


). The construction and function of the hopper door assemblies


40


are disclosed in the Bounds U.S. Pat. No. 5,657,700, which is incorporated herein by reference. As shown in

FIG. 4

, each hopper door assembly is operated by a respective piston-and-cylinder unit


32


for selectively directing the flow of ballast therefrom.




VI. Method of Operation




In the practice of the method of the present invention, the on-board position control subsystem


8


is preprogrammed with various data corresponding to the operation of the logistic system


2


. For example, discharge operations of the ballast discharge mechanism


12


can be programmed to occur at particular locations. Thus, ballast can be applied to a particular section of rail track


5


by inputting its GPS coordinates and programming the position control subsystem


8


to open the hopper door assemblies


40


in the desired directions and for predetermined durations. The GPS signals received by the on-board position control subsystem


8


can provide relatively precise information concerning the position of the railcar


4


.




VII. First Modified Embodiment Logistics System and Method


102






The reference numeral


102


generally designates a logistics system


102


comprising a first modified embodiment of the present invention with a linear movement-based position control subsystem


104


. The position control subsystem


104


can comprise any suitable means for measuring the travel of a vehicle, such as the railcar


4


, and/or detecting its position along the rail track


5


or some other travel path.




The position control system


104


includes a computer


106


which interfaces with an optional rough position detector


108


for detecting rough position markers


110


. For example, the rough position markers


110


can be located alongside the rail track


5


whereby the rough position detector


108


provides a signal to the computer


106


when the railcar


4


is positioned in proximity to a respective rough position marker


110


. The position control subsystem


104


can also include a suitable linear distance measuring device for measuring travel. For example, an encoder/counter


112


can be mounted on the railcar


4


for measuring distances traveled by same or for counting revolutions of a railcar wheel


114


. The encoder/counter


112


can be connected to a travel distance converter


116


which provides signals corresponding to travel distances to the computer


106


. The computer


106


can interface with an hydraulic actuator subsystem


10


such as that described above.




It is to be understood that while certain forms of the present invention have been illustrated and described herein, it is not to be limited to the specific forms or arrangement of parts described and shown.



Claims
  • 1. A logistics system to control application of ballast along a selected section of railroad and comprising:a) a railroad car including a ballast hopper and a pair of hopper doors engaged with said hopper and operable to open and close to thereby control discharge of ballast from said hopper; b) a pair of hydraulic door actuators engaged respectively with said hopper doors and controllable to open and close said hopper doors; c) a global positioning system (GPS) receiver engaged with said car and operative to generate a location signal representing a location of said car, said GPS reciever being adapted to receive GPS coordinate signals from both a GPS satellite constellation and from a differential GPS; d) said railroad car including a wheel and travel distance measuring means including a wheel encoder with said wheel for counting revolutions and partial revolutions thereof, a travel distance converter receiving input from said encoder, and a travel distance computer connected to and adapted for receiving input from said travel distance converter; e) a position control subsystem coupled to said GPS receiver, said encoder, and said hopper door actuators, said position control subsystem storing data representing a location of said selected section of said railroad along which application of ballast is desired; and f) said GPS receiver communicating information relating to the railroad car position to the position control system, said travel distance computer interfacing with said position control system whereby GPS position information and linear-movement travel distance information therefrom respectively are utilized to cause said position control subsystem to activate said hopper door actuators to open said hopper doors at the beginning of said selected section of said railroad and to retain same along said selected section with said railroad car in motion and only for such a duration in which said GPS receiver detects a location of said car corresponding to said selected section of said railroad.
  • 2. A logistics system to control application of ballast along a selected section of railroad and comprising:a railroad car including a ballast hopper and a pair of hopper doors engaged with said hopper and operable to open and close to thereby control discharge of ballast from said hopper; b) a pair of hydraulic hopper door actuators engaged respectively with said hopper doors and controllable to open and close said hopper doors; c) a global positioning system (GPS) receiver engaged with said car and operative to generate a location signal representing a location of said car, said GPS receiver being adapted to receive GPS coordinate signals from both a GPS satellite constellation and from a differential GPS; d) said railroad car including a wheel and travel distance measuring means including a wheel encoder engaged with said wheel for counting revolutions and partial revolutions thereof, a travel distance converter receiving input from said encoder, a rough position marker fixedly mounted at a predetermined location along the railroad, a rough position detector mounted on the railroad car and adapted for generating a signal in response to proximity of said railroad car to said rough position marker, and a travel distance computer connected to and adapted for receiving input from said travel distance converter and said rough position detector; e) a position control subsystem coupled to said GPS receiver, said encoder, and said hopper door actuators, said position control subsystem storing data representing a location of said selected section of said railroad along which application of ballast is desired; and f) said GPS receiver receiving input from said GPS satellite constellation and from said differential GPS, said GPS receiver communicating information relating to the railroad car position to the position control system, said travel distance computer interfacing with said position control system whereby GPS position information and linear-movement travel distance information thereform respectively are utilized to cause said position control subsystem to activate said hopper door actuators to open said hopper doors at the beginning of said selected section of said railroad and to retain same along said selected section with said railroad car in motion and only for such a duration in which said OPS receiver detects a location of said car corresponding to said selected section of said railroad.
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