The present invention relates to rail car doors.
Typical plug-type rail car doors are mounted on the side of a railway car and include a series of panels reinforced by horizontally disposed channels at the top, bottom and intermediate levels of the door. A pair of vertical support bars are configured to support the door on the rail car. Opposite ends of the support bars may be coupled to upper and lower cranks which serve as lever arms for moving the door laterally into and out of an opening defined in the rail car. Upon actuation of an operating mechanism, such as a manually operated gear assembly, the support bars are rotated causing corresponding rotation of the upper and lower cranks. Rotation of the cranks displaces the door laterally from the door opening until the door is supported on a horizontal track extending along a side of the rail car. The door is moveably supported on the track by roller assemblies which enable the door to slide longitudinally along the side of the rail car.
AAR Standard S-213 imposes requirements on operating mechanisms for rotating the support bars to cause lateral displacement of the door. The door must open, close, roll smoothly, and be operable by one person without the use of mechanical devices to aid and assist operating the door. The operating mechanism must have an “anti-spin” design so as not to allow the unintentional spinning of the operating lever as a result of forces (e.g. gasket compression forces) applied to the door from opening or closing it, or from a load applied to the inside face of the door. The operating lever must not unintentionally spin with a load up to 30,000 lb applied to the inside of the door. The operating mechanism must also have an “anti-drift” design to prevent the door from drifting laterally into the car side while the door is in the fully open position and from moving on the door tracks. The operating mechanism must be engaged to prevent laterally inward movement of door as a result of external force and/or torsion springs on the support bars (such as with insulated plug doors). The door must not move laterally inward toward the car with a load up to 2,000 lb applied to the outside face of the door. With regard to strength, the operating mechanism must withstand a torque of not less than 750 ft-lb. The operating lever torque required to open or close the door must not exceed 110 ft-lb, and must not exceed 58 ft-lb through more than ¼ turn of the operating lever rotation during closing.
Known operating mechanisms for rotating the support bars to cause lateral displacement of the door are mechanically complex. A known operating mechanism includes a pinion gear coupled to a manual operating lever mounted on the door, an operating gear segment meshing with the pinion gear, and a pair of linkages each connected to the operating gear and a respective one of the support bars. The operating lever is rotatable by a user to drive the gears to rotate the support bars. The operating mechanism may include a two-way brake or retarder assembly associated with the operating gear segment to provide anti-spin and anti-drift functionality. A ratchet and pawl mechanism may also be installed in the operating mechanism to achieve anti-spin and anti-drift functionality. A locking rod assembly separate from the operating mechanism may be provided to selectively lock and unlock the door for lateral movement away from the rail car.
Known rail car operating mechanisms have many moving parts subject to wear, and are heavy. They are also expensive to manufacture, install, and maintain in good working order. From the user's standpoint, known rail car operating mechanisms are tedious to operate because they typically require about four full rotations of the operating lever to achieve lateral door displacement.
The present disclosure provides an operating mechanism for plug-type rail car doors that is more economical to manufacture and install and is less susceptible to wear than currently known operating mechanisms, yet also provides anti-spin and anti-drift functionality. Like currently known operating mechanisms, the disclosed operating mechanism is usable by an operator to simultaneously rotate first and second support bars of a rail car door about their respective longitudinal axes to laterally displace the rail car door relative to the side of the rail car, and thus the operating mechanism may be installed as a retrofit to existing rail cars in the field. The disclosed operating mechanism may also be provided in newly fabricated rail cars.
The operating mechanism of the present disclosure may generally comprise a first torque lever attached to the first support bar and a second torque lever attached to the second support bar, and a first link connected to the first support bar by way of the first torque lever and a second link connected to the second support bar by way of the second torque lever. The first link may include a first elongated slot and the second link may include a second elongated slot at least partially overlapping with first elongated slot. The operating mechanism may further comprise a first cam received by the first elongated slot and a second cam received by the second elongated slot, the first cam and the second cam being rotatable as a unit about a rotational axis, wherein the rotational axis is eccentrically arranged relative to the first and second cams. The operating mechanism may additionally comprise an actuating lever operably connected to the first and second cams and manually movable by an operator to rotate the first and second cams about the rotational axis. The actuating lever may be movable such that the first link and the second link are retracted relative to one another to simultaneously rotate the first and second support bars in opposite rotational directions about their respective longitudinal axes, and may be movable such that the first link and the second link are extended relative to one another to simultaneously counter-rotate the first and second support bars in opposite rotational directions about their respective longitudinal axes.
The operating mechanism may include a first connecting rod pivotally coupled at one end thereof to the first torque lever and pivotally coupled at another end thereof to the first link, and a second connecting rod pivotally coupled at one end thereof to the second torque lever and pivotally coupled at another end thereof to the second link.
In one embodiment, the operating mechanism may comprise an actuating shaft connected to the actuating lever and fixed to the first and second cams, wherein the actuating shaft has a central axis coinciding with the rotational axis, wherein the actuating shaft is rotatable about the rotational axis to a retraction rotational position whereby the first link and the second link are retracted relative to one another, and is rotatable about the rotational axis to an extension rotational position whereby the first link and the second link are extended relative to one another.
In another embodiment, the operating mechanism may comprise a gear train, wherein the actuating lever is connected to the first and second cams by way of the gear train. The gear train may be configured to provide a mechanical advantage to reduce an operating torque needed by the operator to move the actuating lever.
The nature and mode of operation of the present invention will now be more fully described in the following detailed description of the invention taken with the accompanying drawing figures, in which:
Rail car 10 also comprises a first upper roller assembly 18A and a second upper roller assembly 18B. Each of the first and second upper roller assemblies 18A, 18B has at least one upper roller 20 engaging upper rail 14 for rolling travel along upper rail 14, and an upper crank 22 pivotally coupled to the at least one upper roller 20 to pivot relative to the at least one upper roller 20 about a corresponding pivot axis 24 extending in a vertical direction of rail car 10.
Rail car 10 further comprises a first lower roller assembly 26A and a second lower roller assembly 26B. Each of the first and second lower roller assemblies 26A, 26B has at least one lower roller 28 engaging the lower rail 16 for rolling travel along lower rail 16, and a lower crank 30 pivotally coupled to the at least one lower roller 28 to pivot relative to the at least one lower roller about a corresponding pivot axis 32 extending in the vertical direction of rail car 10.
Rail car 10 comprises a first support bar 34A and a second support bar 34B. Door 12 is mounted to first and second support bars 34A, 34B. First support bar 34A has one end fixed to upper crank 22 of first upper roller assembly 18A and another end fixed to lower crank 30 of first lower roller assembly 26A. Second support bar 34B has one end fixed to upper crank 22 of second upper roller assembly 18B and another end fixed to lower crank 30 of second lower roller assembly 26B.
For opening and closing rail car door 12 (i.e. displacing the door laterally away from the side of the rail car to an open position and laterally toward the side of the rail car to a closed position), rail car 10 comprises an operating mechanism 40. Operating mechanism 40 is operable by a user to simultaneously rotate first support bar 34A and second support bar 34B in opposite rotational directions such that door 12 is displaced in a lateral direction of rail car 10.
Reference is also made to
Operating mechanism 40 may also comprise a first cam 50A received by first elongated slot 48A, a second cam 50B received by second elongated slot 48B, and an actuating shaft 52 fixed to first cam 50A and to second cam 50B, wherein actuating shaft 52 has a rotational axis 54 eccentrically arranged relative to first cam 50A and second cam 50B (i.e., rotational axis 54 intersects first cam 50A and second cam 50B at respective locations not at a center of the corresponding cam). Cams 50A, 50B may be circular in shape.
As illustrated in
Actuating shaft 52 may also be rotated about rotation axis 54 to an extension rotational position (
In the drawing figures, the first lateral direction is away from rail car 10 to open door 12, and the second lateral direction is toward rail car 10 to close door 12. Alternatively, operating mechanism 40 may be configured such that the first lateral direction is toward rail car 10 to close door 12, and the second lateral direction is away from rail car 10 to open door 12.
In the depicted embodiment, the retraction rotational position and the extension rotational position are 180 degrees apart, whereby rotation of actuating lever 56 by a user through one-half turn will efficiently open or close door 12. Moreover, the user may rotate actuating lever 56 in either rotational direction (i.e. clockwise or counter-clockwise), whichever direction is easiest for the user, to open or close door 12.
Links 44A, 44B, clevis ears 45, cams 50A, 50B, actuating shaft 52, actuating lever 56, and guide members 58A, 58B may be manufactured from steel or another suitably strong material. By way of non-limiting example, links 44A, 44B, clevis ears 45, cams 50A, 50B, and guide members 58A, 58B, may be manufactured from ⅜″ thick steel plate, and actuating shaft 52 may be made from 1″ diameter bar stock.
As best seen in
As will be appreciated, operating mechanism 40 provides anti-spin and anti-drift functionality with far fewer moving parts than known operating mechanisms, no gears, and no ratchet and pawl mechanisms. Moreover, operating mechanism 40 is less expensive to manufacture and is easier to install than known operating mechanisms.
In operating mechanism 140, actuating lever 56 is connected to first cam 50A and second cam 50B by way of gear train 142. Gear train 142 may include a drive gear 143 coupled to actuating lever 56 for rotation with the actuating lever, and a driven gear 147 meshed with drive gear 143 to rotate in response to rotation of drive gear 143. First cam 50A and second cam 50B may be coupled to driven gear 147 by a pair of dowel or spring pins 151 such that as driven gear 147 rotates about the central axis of shaft 52, first cam 50A and second cam 50B rotate with driven gear 147 about the central axis of shaft 52. Alternatively, or in addition, driven gear 147 may be attached directly to actuating shaft 52 for conveying rotational motion to first cam 50A and second cam 50B gear. Gears 143 and 147 may be spur gears, wherein the diameter of drive gear 143 is less than the diameter of driven gear 147 in order to provide a mechanical advantage. As may be understood, gear train 142 is configured to reduce an operating torque which must be applied by the operator to move actuating lever 56 to cause rotation of actuating shaft 52. In one implementation, a 3:1 gear ratio is provided to reduce the operating torque, however other gear ratios may be used.
As illustrated in the example embodiment shown in
From a manufacturing standpoint, it is advantageous that in both embodiments disclosed herein, first link 44A and second link 44B are identical, as are first cam 50A and second cam 50B, thereby making these components more economical to produce in high quantities. Moreover, first cam 50A and second cam 50B are circular in shape and therefore easy to machine.
While the invention has been described in connection with exemplary embodiments, the detailed description is not intended to limit the scope of the invention to the particular forms set forth. The invention is intended to cover such alternatives, modifications and equivalents of the described embodiment as may be included within the scope of the claims.
Filing Document | Filing Date | Country | Kind |
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PCT/US2019/066312 | 12/13/2019 | WO | 00 |
Number | Date | Country | |
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62780214 | Dec 2018 | US |