Electrically operated railroad switch machine

Information

  • Patent Grant
  • 6568641
  • Patent Number
    6,568,641
  • Date Filed
    Wednesday, May 29, 2002
    22 years ago
  • Date Issued
    Tuesday, May 27, 2003
    21 years ago
Abstract
A switch machine for moving railroad switch points. The switch machine includes a switch stand adapted to be connected to the railroad switch points. The switch stand includes a rotatable hub which is selectively rotatable to throw the switch points. A rotary actuator includes a rotatable pinion that is coupled to the hub of the switch stand. A hydraulic pump and a valve are in fluid communication with the rotary actuator and selectively control the direction of rotation of the pinion. A first proximity sensor and a second proximity sensor are provided to sense the position of the pinion and hub. When the pinion and hub are rotated to a first position to move the switch points to a first switch point position, the first sensor will deactivate the hydraulic pump. When the pinion and hub rotate the switch points to a second switch point position, the second proximity sensor will deactivate the hydraulic pump.
Description




BACKGROUND OF THE INVENTION




The present invention is directed to an electrically operated railroad switch machine including a switch stand and an electrically powered operating assembly, and in particular to a switch machine wherein the operating assembly is adapted to be connected to various different types of switch stands.




Railroad switch stands of the type disclosed in U.S. Pat. Nos. 2,054,543 and 2,575,037 are manually operated. Switch stands are adapted to be attached to a connecting rod which in turn is connected to first and second switch points of a railroad switch. The switch stand is adapted to move the connecting rod back and forth in a generally linear direction to thereby conjointly move the first and second switch points between a first position and a second position. The switch stands include a hand lever that is manually rotated through an angle of approximately 180° in a first rotational direction to thereby correspondingly move the switch points from the first position to the second position. The switch points are returned to their original first position from the second position by manually rotating the hand lever in a second rotational direction opposite to the first rotational direction.




SUMMARY OF THE INVENTION




A switch machine for moving railroad switch points. The switch machine includes a switch stand having a rotatable hub that is operatively connected to a pivot shaft. The pivot shaft is adapted to be connected to the railroad switch points such that rotation of the hub results in the throwing of the railroad switch points between a first switch point position and a second switch point position. An operating apparatus is coupled to the hub of the switch stand for providing automatic operation of the switch stand. The operating apparatus includes a rotary actuator having a rotatable pinion connected to a rotatable shaft that are selectively rotatable between a first position and a second position. A coupling member is attached to the shaft of the rotary actuator for conjoint rotation with the pinion and the shaft. The coupling member is adapted to rotationally couple the pinion and the shaft to the hub of the switch stand. A hydraulic pump is in fluid communication with the rotary actuator for providing selective rotational movement of the pinion. A valve is in fluid communication between the hydraulic pump and the rotary actuator for selectively controlling the direction of rotation of the pinion and the shaft. The hydraulic pump is powered by an electric motor. A first proximity sensor is activated by the coupling member when the pinion and shaft are located in the first position and a second proximity sensor is activated by the coupling member when the pinion and shaft are located in the second position. When either the first or second proximity sensor is activated, the electric motor and hydraulic pump are deactivated. A timer is provided to deactivate the motor and hydraulic pump if neither of the first or second proximity sensors are activated within a predetermined time period.











BRIEF DESCRIPTION OF THE DRAWING FIGURES





FIG. 1

is a side elevational view of the switch machine of the present invention.





FIG. 2

is a top plan view of the switch stand and operator assembly of the switch machine.





FIG. 3

is a side elevational view taken along line


3





3


of FIG.


2


.





FIG. 4

is a front elevational view taken along line


4





4


of FIG.


2


.





FIG. 5

is a top plan view of the electric motor and hydraulic pump assembly of the operator assembly.





FIG. 6

is a front elevational view taken along line


6





6


of FIG.


5


.





FIG. 7

is a cut-away perspective view of the rotary actuator of the operator assembly.





FIG. 8

is a front elevational view of a coupler member of the operator assembly.





FIG. 9

is a bottom view taken along line


9





9


of FIG.


8


.





FIG. 10

is a front elevational view of an alternate embodiment of the coupler member.





FIG. 11

is a bottom view taken along line


11





11


of FIG.


10


.





FIG. 12

is an electrical schematic of the present invention.











DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT




The switch machine


20


of the present invention includes a switch stand


22


and an operator assembly


24


. The switch stand


22


is preferably constructed as shown in U.S. Pat. No. 2,054,543 or U.S. Pat. No. 2,575,037, which are incorporated herein by reference. The switch stand


22


includes a pivot shaft or spindle


26


that is selectively rotatable about a generally vertical axis


28


. A threaded socket


30


is attached to the bottom end of the spindle


26


. The socket


30


is adapted to be attached to a connecting rod (not shown) by a crank arm (not shown). The connecting rod is attached to a first switch point and a second switch point of a conventional railroad switch. The spindle


26


is operatively connected to a hub


32


that is selectively rotatable about a generally horizontal axis


34


. The hub


32


is selectively rotatable about the axis


34


through an angle of approximately 180° between a first position and a second position. When the hub


32


is rotated in a first rotational direction from its first position to its second position, the hub


32


correspondingly rotates the spindle


26


and socket


30


about the axis


28


and moves the connecting rod in a generally linear direction to thereby move the switch points from their respective first positions to their respective second positions. Similarly, when the hub


32


is rotated in a second rotational direction, opposite to the first rotational direction, from the second position to the first position, the spindle


26


and socket


30


is rotated in an opposite direction and the switch points are moved from their respective second positions to their respective first positions. The switch stand


22


is preferably constructed as shown in U.S. Pat. No. 2,054,543 or U.S. Pat. No. 2,575,037, other than that the hand lever, which is used for manual operation, is removed. The switch stand


22


is attached to a base plate


36


.




The operator assembly


24


includes a selectively openable cover (not shown) that encloses the operator assembly


24


. The operator assembly


24


includes an electrically operated direct current (DC) motor


50


. The motor


50


is operatively connected to a hydraulic pump


52


such that the hydraulic pump


52


is powered by the motor


50


. The hydraulic pump


52


is in fluid communication with a reservoir of hydraulic fluid. A starter solenoid


54


is in electrical communication with the motor


50


. A twelve volt DC battery


56


is in electrical communication with the starter solenoid


54


and the motor


50


. A solar panel


58


is attached to and supported by a mast


60


. The solar panel


58


is in electrical communication with a voltage regulator


62


and thereby the battery


56


. The solar panel


58


provides electrical power to the battery


56


to maintain the battery


56


in a charged condition. Alternatively, one-hundred twenty volt alternating current can be provided to a transformer (not shown) in the operator assembly


24


which transforms the one-hundred twenty volt alternating current to twelve volt direct current. The resulting direct current can be used to directly power the motor


50


and can be used to maintain the battery


56


in a charged condition in case of a power failure.




The operator assembly


24


includes a valve


70


having a first port


72


and a second port


74


. The valve


70


is in fluid communication with the hydraulic pump


52


. The valve


70


is operated by a first solenoid


76


A and a second solenoid


76


B. The solenoids


76


A and B are electrically actuated to either allow the pumping of hydraulic fluid from the pump


52


out of the first port


72


and for return through the second port


74


, or for the pumping of the hydraulic fluid out of the second port


74


for return through the first port


72


, as desired.




A manually operated hydraulic pump


80


is in fluid communication with the valve


70


and the reservoir of hydraulic fluid. A handle


82


is selectively attachable to the manual pump


80


to provide for the manual pumping of hydraulic fluid from the valve


70


. Each solenoid


76


A and B includes a selector switch


84


which may be manually switched between automatic operation and manual operation. Activation of the selector switches


84


allows manual operation of the manual pump


80


to selectively pump hydraulic fluid through either the first port


72


or the second port


74


as desired. Switching of the selector switches


84


back to the automatic mode of operation permits the hydraulic pump


52


to pump hydraulic fluid through either the first port


72


or second port


74


as desired.




The operator assembly


24


also includes a hydraulic rotary actuator


90


as shown in FIG.


7


. The rotary actuator


90


includes a generally cylindrical lower tube


92


and a parallel generally cylindrical upper tube


94


. The lower tube


92


includes a first end


96


having a port


98


and second end


100


having a port


102


. The upper tube


94


includes a first end


104


having a port


106


and a second end


108


having a port


110


. A generally linearly extending lower rack


112


is located within the lower tube


92


. A first piston


114


is attached to a first end of the lower rack


112


and a second piston


116


is attached to a second end of the lower rack


112


. The rack


112


includes a plurality of teeth


118


that are located between the first and second ends of the lower rack


112


and that are generally parallel to one another. The teeth


118


extend generally linearly in a direction generally transverse to the longitudinal axis of the lower rack


112


. The teeth


118


are located on the upper side of the lower rack


112


. The first piston


114


is adapted to form a generally fluid-tight chamber within the lower tube


92


at the first end


96


which is in fluid communication with the port


98


. The second piston


116


is adapted to form a generally fluid-tight chamber within the lower tube


92


at the second end


100


which is in fluid communication with the port


102


.




An elongate generally linearly extending upper rack


120


is disposed within the upper tube


94


. The upper rack


120


includes a first piston


122


attached to a first end of the upper rack


120


and a second piston


124


attached to a second end of the upper rack


120


. The upper rack


120


includes a plurality of teeth


126


on the bottom side of the rack


120


. The teeth


126


are located generally parallel and adjacent to one another and extend generally transversely to the longitudinal axis of the upper rack


120


and parallel to the teeth


118


of the lower rack


112


. The first piston


122


is adapted to form a generally fluid-tight chamber within the upper tube


94


at the first end


104


in fluid communication with the port


106


. The second piston


124


is adapted to form a generally fluid-tight chamber within the upper tube


94


at the second end


108


in fluid communication with the port


110


. The lower rack


112


and the upper rack


120


are linearly moveable in opposite directions with respect to one another along their longitudinal axes within their respective tubes


92


and


94


.




The rotary actuator


90


includes a rotatable pinion


130


disposed between the lower rack


112


and the upper rack


120


. The pinion


130


includes a plurality of teeth


138


disposed in a generally circular manner about the central longitudinal axis of the pinion


130


. The teeth


138


are generally linear and are spaced apart and generally parallel to one another. The teeth


138


operatively engage the teeth


118


of the lower rack


112


and the teeth


126


of the upper rack


120


. A generally cylindrical shaft


132


having a keyway


134


is attached at one end to the pinion


130


for conjoint rotation with the pinon


130


about the central axis of the pinion


130


and about a colinear central axis of the shaft


132


. The lower rack


112


is adapted to slide linearly within the lower tube


92


in a first direction while the upper rack


120


simultaneously linearly slides within its upper tube


94


in a second and opposite direction to thereby impart rotational movement of the pinion


130


and shaft


132


about their central longitudinal axes in a first rotational direction. Similarly, when the lower rack


112


is slid in a second linear direction, the upper rack


120


is slid in a linearly opposite first direction, and the racks


112


and


120


impart rotational movement of the pinion


130


and shaft


132


about their central longitudinal axes in a second rotational direction opposite the first rotational direction. The selective linear movement of the lower rack


112


and upper rack


120


is adapted to rotate the pinion


130


and shaft


132


through an angle of approximately 180° between a first rotational position and a second rotational position. If desired the rotary actuator


90


could include only one rack.




As best shown in

FIG. 2

, a conduit


146


is connected in fluid communication with the first port


72


of the valve


70


. A conduit


148


is connected in fluid communication with the conduit


146


and is connected in fluid communication with the port


106


at the first end


104


of the upper tube


94


. A conduit


150


is attached in fluid communication with the conduit


146


and is attached in fluid communication with the port


102


at the second end


100


of the lower tube


92


.




A conduit


156


is attached in fluid communication to the second port


74


of the valve


70


. A conduit


158


is attached in fluid communication with the conduit


156


and is attached in fluid communication with the port


98


at the first end


96


of the lower tube


92


. A conduit


160


is attached in fluid communication with the conduit


156


and is attached in fluid communication with the port


110


at the second end


108


of the upper tube


94


.




The operator assembly


24


includes a coupler member


164


as best shown in

FIGS. 8 and 9

. The coupler


164


includes a first end


166


that is adapted to be connected to the hub


32


of the switch stand


22


by a plurality of threaded fasteners such that the coupler


164


is conjointly rotatable with the hub


32


about the axis


34


. The coupler


164


includes a second end


168


that includes a bore


170


adapted to receive an end of the shaft


132


. The coupler


164


is attached to the shaft


132


such that the coupler


164


is conjointly rotatable with the pinion


130


and shaft


132


about the axis


34


. The bore


170


may be generally circular or rectangular. A trip member


172


having a head


174


extends generally radially outwardly from the second end


168


of the coupler member


164


. The trip member


172


may be a threaded bolt, screw or the like. The coupler member


164


is adapted to couple the pinion


130


and shaft


132


of the rotary actuator


90


to the hub of a switch stand of the type as shown in U.S. Pat. No. 2,054,543.




An alternate embodiment of the coupler member is shown in

FIGS. 10 and 11

and is identified with the reference number


164


′. The coupler member


164


′ is adapted to couple the rotary actuator


90


to a switch stand such as shown in U.S. Pat. No. 2,575,037. The coupler member


164


′ is constructed similar to the coupler member


164


and common features are shown in

FIGS. 10 and 11

using the same reference numbers with the addition of a prime symbol.




As best shown in

FIG. 2

, a first proximity sensor


180


and a second proximity sensor


182


are stationarily attached to the rotary actuator


90


on opposite sides of the second end


168


of the coupler


164


. When the coupler


164


is located in a first rotational position, wherein the shaft


132


is in its first position, the trip member


172


of the coupler


164


is adapted to engage and activate the first proximity sensor


180


. When the coupler


164


is rotated to a second rotational position, wherein the shaft


132


is in its second position, approximately 180° from the first rotational position, the trip member


172


of the coupler


164


is adapted to engage and activate the second proximity sensor


182


.




The first and second proximity sensors


180


and


182


are electrically connected to a programmable logic control


184


, such as an Aromat Model FP1-C16 PLC. The logic control


184


is located within a selectively openable enclosure


186


. A timer


188


is also electrically connected to the programmable logic control


184


. A first switch


190


and a second switch


192


are electrically connected between the battery


56


and the motor


50


. The first switch


190


is located on the mast


60


and the second switch


192


is located adjacent the motor


50


. The switches


190


and


192


each include a single button. Activation of the switch


190


or


192


starts operation of the motor


50


and the pumping of hydraulic fluid by the hydraulic pump


52


to the valve


70


.




When the switch points are located in their respective first positions, the coupler


164


, pinion


130


, shaft


132


, and hub


32


are located in their first positions such that the trip member


172


is in engagement with and is activating the first proximity sensor


180


. When the coupler


164


is in its first position the lower rack


112


is located within the lower tube


92


such that the second piston


116


is located adjacent the second end


100


and such that the first piston


114


is spaced apart from the first end


96


forming a chamber therebetween. The upper rack


120


is located within the upper tube


94


such that the first piston


122


is located adjacent the first end


104


and such that the second piston


124


is spaced apart from the second end


108


forming a chamber therebetween.




When the switch


190


or


192


is manually activated, the battery


56


will power the motor


50


and the motor


50


will power the hydraulic pump


52


. Activation of the first proximity sensor


180


by the trip member


172


causes the solenoids


76


A and B to configure the valve


70


such that hydraulic fluid pumped by the hydraulic pump


52


will flow outwardly through the first port


72


and through the conduits


146


,


148


and


152


. Hydraulic fluid flowing through the conduit


148


will flow through the port


106


and will cause the upper rack


120


to slide linearly toward the second end


108


of the upper tube


94


. Hydraulic fluid within the chamber formed at the second end


108


of the upper tube


94


will be expelled through the port


110


into the conduit


160


. At the same time, hydraulic fluid from the conduit


152


will flow through the port


102


and will linearly slide the lower rack


120


toward the first end


96


of the lower tube


92


. Fluid within the chamber at the first end


96


will be expelled through the port


98


and will flow into the conduit


158


. The hydraulic fluid that is expelled from the rotary actuator


90


into the conduits


158


and


160


flows through the conduit


156


and the second port


74


in the valve


70


to the reservoir of hydraulic fluid.




As the upper rack


120


slides linearly toward the second end


108


of the upper tube


94


, and the lower rack


112


slides linearly toward the first end


96


of the lower tube


92


, the racks


112


and


120


rotate the pinion


130


and shaft


132


in a first rotational direction about their common central longitudinal axis through an angle of approximately 180° to the second position of the pinion


130


and shaft


132


. The coupler


164


rotates conjointly with the pinion


130


and shaft


132


such that the trip member


172


rotates into engagement with and activates the second proximity sensor


182


. When the second proximity sensor


182


senses the trip member


172


, the second proximity sensor


182


disconnects the battery


56


from the motor


50


thereby stopping the pumping of hydraulic fluid by the hydraulic pump


52


. The rotation of the coupler


164


rotates the hub


32


, spindle


26


and socket


30


of the switch stand


22


and thereby moves the switch points from their first position to their second position.




If an obstruction prevents the switch points from fully moving from their first position to their second position, the trip member


172


will not reach and activate the second proximity sensor


182


. If the trip member


172


does not activate the second proximity sensor


182


within a preset time limit as measured by the timer


188


, such as within two or three seconds after disengaging the first proximity sensor


180


, the logic control


184


will activate the solenoids


76


A and B and configure the valve


70


to pump hydraulic fluid through the second port


74


and the conduits


156


,


158


and


160


to rotate the pinion


130


, shaft


132


and coupler


164


in a second rotational direction. The coupler


164


, pinion


130


, shaft


132


and hub


32


are thereby returned to their first positions wherein the trip member


172


engages the first proximity sensor


180


and wherein the switch points are located in their first position. When the first proximity sensor


180


senses the trip member


172


, the first proximity sensor


180


will disengage the supply of power to the motor


50


and deactivates the hydraulic pump


52


. If the switch points are obstructed from returning to their original first position, as well as the second position, such that the trip member


172


will not be sensed by either the first proximity sensor


180


or the second proximity sensor


182


, the timer


188


will disconnect the power source from the motor


50


and deactivate the hydraulic pump


52


after a preset time limit such as six seconds. During normal operation the timer


188


will also disconnect the power source from the motor


50


after a preset time limit, such as six seconds, to prevent power drain.




When the switch points are located in their respective second positions, the coupler


164


will be orientated such that the trip member


172


is in engagement with and activates the second proximity sensor


182


. The second proximity sensor


182


activates the solenoids


76


A and B to direct the flow of hydraulic fluid from the valve


70


through the second port


74


into the conduits


156


,


158


and


160


. Fluid thereby flows into the port


110


at the second end


108


of the upper tube


94


and the port


98


at the first end


96


of a lower tube


92


. The lower rack


112


is thereby slid linearly toward the second end


100


of the lower tube


92


and the upper rack


120


is slid linearly toward the first end


104


of the upper tube


94


. This movement of the lower rack


112


and upper rack


120


causes the pinion


130


and shaft


132


to rotate in a second rotational direction opposite to the first rotational direction, such that the coupler


164


is rotated approximately 180° until the trip member


172


engages the first proximity sensor


180


which then disconnects the power source to the motor


50


. Rotation of the pinion


130


, shaft


132


and coupler


164


to their first position, such that the trip member


172


is sensed by the first proximity sensor


180


, causes the hub


32


, spindle


26


and socket


30


to rotate and thereby move the switch points from the second position to the first position. If an obstruction is encountered that prevents movement of the switch points to the first position, after the trip member


172


has deactivated the second proximity sensor


182


and has not activated the first proximity sensor


180


for the preset time period, the timer


188


and the controller


184


will return the switch points to the second position.




The operator assembly


24


may be retrofit to various types of previously installed switch stands, by removal of the manual hand lever from the switch stand, and by connecting the pinion


130


, shaft


132


and coupler


164


to the hub


32


of the previously installed switch stand. Thus a previously installed manually operated switch stand can be simply converted into an automatic electrically operated switch stand.




Various features of the invention have been particularly shown and described in connection with the illustrated embodiment of the invention, however, it must be understood that these particular arrangements merely illustrate and that the invention must be given the fullest interpretation within the terms of the appended claims.



Claims
  • 1. An operating apparatus for operating a railroad switch stand having a rotatable hub, said operating apparatus including:a rotary actuator having a rotatable shaft, said shaft being selectively rotatable between a first position and a second position; a coupling member having a first and a second end, said second end of said coupling member attached to said shaft of said rotary actuator such that said coupling member is adapted to conjointly rotate with said shaft, said first end of said coupling member adapted to be attached to the hub of the switch stand such that said coupling member is adapted to conjointly rotate with the hub of the switch stand, said coupling member adapted to rotationally couple said shaft to the hub of the switch stand and to provide conjoint rotation of the hub of the switch stand with said shaft of said rotary actuator; a hydraulic pump in fluid communication with said rotary actuator for providing selective rotational movement of said shaft; and a first sensor adapted to be activated when said shaft is located in said first position; whereby when said first sensor is activated said first sensor deactivates said hydraulic pump.
  • 2. The operating apparatus of claim 1 including a second sensor adapted to be activated when said shaft is located in said second position, said second sensor adapted to deactivate said hydraulic pump when said second sensor is activated.
  • 3. The operating apparatus of claim 2 wherein said coupling member includes a trip member adapted to activate said first sensor when said shaft is located in said first position and to activate said second sensor when said shaft is located in said second position.
  • 4. The operating apparatus of claim 2 wherein said first sensor and said second sensor respectively comprise proximity sensors.
  • 5. The operating apparatus of claim 2 including a timer for timing when said first sensor is activated and when said second sensor is activated.
RELATED APPLICATIONS

This application is a division of U.S. application Ser. No. 09/585,666, filed Jun. 1, 2000, now Pat. No. 6,427,950, which claims the benefit of U.S. Provisional Application No. 60/137,804, filed Jun. 4, 1999.

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Provisional Applications (1)
Number Date Country
60/137804 Jun 1999 US