The present invention is related in general to railcars and more particularly to railcars which discharge cargo or lading, such as coal, ore, ballast, grain and any other lading suitable for transportation in railcars.
Railway hopper cars with one or more hoppers have been used for many years to transport and sometimes store dry, bulk materials. Hopper cars are frequently used to transport coal, sand, metal ores, ballast, aggregates, grain and any other type of lading which may be satisfactorily discharged through respective openings formed in one or more hoppers. Respective discharge openings are typically provided at or near the bottom of each hopper to rapidly discharge cargo. A variety of door assemblies and gate assemblies along with various operating mechanisms have been used to open and close discharge openings associated with railway hopper cars.
Hopper cars may be classified as open or closed. Hopper cars may have relatively short sidewalls and end walls or relatively tall or high sidewalls and end walls. The sidewalls and end walls of many hopper cars are typically reinforced with a plurality of vertical side stakes. The sidewalls and end walls are typically formed from steel or aluminum sheets. Some hopper cars include interior frame structures or braces to provide additional support for the sidewalls.
Applicable standards of the Association of American Railroads (AAR) established maximum total weight on rail for any railcar including box cars, freight cars, hopper cars, gondola cars, and temperature controlled cars within prescribed limits of length, width, height, etc. All railway cars operating on commercial rail lines in the U.S. must have exterior dimensions which satisfy associated AAR clearance plates. Therefore, the maximum load which may be carried by any railcar is typically limited by the applicable AAR clearance plate and empty weight of the railcar. Reducing the empty weight of a railcar or increasing the interior dimensions may increase both volumetric capacity and maximum load capacity of a railcar while still meeting applicable AAR standards for total weight on rail and clearance plate.
Prior systems for opening and closing gates on hopper cars often include additional linkages that operated in co-planes and in perpendicular planes that required greater operating forces and greater complexity. Some prior art systems include torque tubes and other types of tension members.
In accordance with teachings of the present invention, several disadvantages and problems associated with railway cars having discharge control systems have been substantially reduced or eliminated. One embodiment of the present invention includes a hopper car having at least one hopper and one discharge opening formed adjacent to the bottom or a lower portion of the hopper. A discharge control system incorporating teachings of the present invention may be used to open and close a respective door assembly or gate disposed adjacent to each discharge opening.
One aspect of the present invention includes a discharge control system which may be mounted on various types of railway cars to control discharge of lading when the railway car is stationary at a discharge facility or when the railway car is moving relative to a discharge facility. The discharge control system may be satisfactorily used with hopper cars having longitudinal discharge openings and associated gate or door assemblies.
Technical benefits of the present inventions include substantially reducing the empty car weight of a railway car while often increasing load carrying capability, reducing maintenance requirements and increasing service life of the railway car. For one application the empty car weight of a coal hopper car formed in accordance with teachings of the present invention was reduced by approximately twenty four hundred pounds (2400 lbs.) as compared with a prior coal hopper with the same applicable AAR clearance plate and AAR specifications.
A discharge control system incorporating teachings of the present invention may be used to operate doors or gates hinged to a center sill or other centrally located structure of a railway car, highway truck or other equipment having at least one hopper. The discharge control system simplifies synchronization of multiple gates, keeps components of the discharge control system out of the commodity during loading, transport and discharge to minimize contamination. A common air cylinder or similar actuator oriented longitudinally may be used to move a common linkage running along a longitudinal axis and below the center sill of the railcar. The discharge control system eliminates torque tubes and other relatively expensive techniques that have been previously used to synchronize opening and closing of doors and gates. The discharge control system often provides greatest mechanical advantage when respective door linkages are approximately perpendicular to a common longitudinal linkage and the gates are moving to their closed position. The discharge control system has fewer pivot points and linkages and no torsion members, incorporates over center locking and simplified adjustment as compared with many prior operating assemblies for discharge doors.
Further technical benefits of the present invention include relatively easy adjustments which may be made to an air cylinder or similar actuator to limit opening of the longitudinal doors to control the rate of discharging lading. Adjustments may also be made to a primary linkage and/or secondary linkages to control opening of respective longitudinal doors and the rate of discharging lading.
For one embodiment a variable choke or variable control valve may be attached to an air cylinder to control the rate of opening or closing of longitudinal doors. Also, one or more mechanical stops may be included as part of the air cylinder to allow limiting the opening of the associated longitudinal doors. For some applications quick opening rapid discharge of lading from a hopper car may be preferred. For other applications relatively slow, partial opening of longitudinal doors may be preferred for other types of lading.
For a more complete understanding of the present invention, and the advantages thereof, reference is now made to the following written description taken in conjunction with the accompanying drawings, in which:
Preferred embodiments of the invention and its advantages are best understood by referring to
Various features of the present invention will be described with respect to hopper car 20 which may be satisfactorily used to carry coal and other types of lading. Typical dimensions for one embodiment of hopper car 20 incorporating teachings of the present invention may include length between truck centers of forty (40) feet six (6) inches; a length over strikers of fifty (50) feet two and one half (2 ½) inches; and a length over pulling faces of fifty-three (53) feet and one (1) inch. Hopper car 20 may be satisfactorily used to carry bulk materials such as coal and other types of lading. Examples of additional lading include, but are not limited to, sand, grain, metal ores, aggregate and ballast.
Hopper car 20 may be generally described as an open hopper car with bottom discharge openings or outlets. Respective door assemblies or gates may be opened and closed to control discharge of lading from the discharge openings or outlets of hopper car 20. However, the present invention is not limited to open hopper cars or hopper cars that carry coal. For example various features of the present invention may be satisfactorily used with gondola cars, closed hopper cars, articulate hopper cars, hopper cars that carry grain or any other type of hopper car and ballast car. Examples of lading carried by such hopper cars may include, but are not limited to, corn distillers dried grains (DDG), corn condensed distillers solubles (CDS), corn distillers dried grains/solubles (DDGS) and wet distillers grain with solubles (WDGS). Such products are frequently associated with ethanol production from corn and/or other types of grain.
Teachings of the present invention may be satisfactorily used with other types of railway cars having a wide variety of interior supporting structures. The present invention is not limited to hopper cars having interior cross brace assemblies or hopper cars having longitudinal discharge openings.
Hopper car 20 incorporating teachings of the present invention may include a pair of sidewall assemblies 30a, 30b, bottom slope sheet assemblies 40a and 40b and sloped end wall assemblies 80a and 80b mounted on railway car underframe 50. For embodiments of the present invention as shown in
Railway car underframe 50 includes center sill 52 and side sills 54a and 54b. See
For some applications a railcar may be formed in accordance with the teachings of the present invention with any number of cross bearers. The present invention is not limited to railcars having cross bearers. Also, the configuration and design of cross bearers associated with a railcar incorporating teachings of the present invention may be substantially modified as compared with cross bearers 60.
A pair of railway trucks 22 and 24 may be attached proximate opposite ends of center sill 52. For embodiments of the present invention as represented by hopper car 20, center sill 52 may have a generally rectangular cross-section with a generally triangular-shaped dome or cover 56 disposed thereon. The present invention may be used with center sills having a wide variety of configurations and designs other than a rectangular cross section. The present invention may be used with center sills that do not have domes or covers. The present invention is not limited to center sill 52 or cover 56.
Sidewall assemblies 30a and 30b may have approximately the same overall configuration and dimensions. Therefore, only sidewall assembly 30b will be described in detail. Sidewall assembly 30b preferably includes top cord 32b with a plurality of side stakes 34 extending between top cord 32b and side sill 54b. Side stakes 34 may also be spaced longitudinally from each other along the length of top cord 32b and side sill 54b. A plurality of metal sheets 36 may be securely attached with interior portions of top cord 32b, side stakes 34 and side sill 54b. In a similar manner, sidewall assembly 30a preferably includes top cord 32a, side stakes 34 and metal sheets 36.
For purposes of describing various features associated with the present invention metal sheets 36 which form the interior surface of sidewall assembly 30a have been designated 36a. In a similar manner metal sheets 36 which form the interior surface of sidewall assembly 30b have been designated as 36b. See
Bottom slope sheet assemblies 40a and 40b may have approximately the same overall dimensions and configuration. Therefore, only bottom slope sheet assembly 40b will be described in more detail. Bottom slope sheet assembly 40b preferably includes a plurality of angles 42 extending inwardly from side sill 54b to bottom cord 44b. Bottom cord 44b and top cord 32b may be formed from hollow metal tubes having a generally rectangular configuration. A plurality of metal sheets 46 may be attached with interior surfaces of respective angles 42 and bottom cord 44b. Metal sheets 36 and 46 may have similar specifications and thickness.
For some applications, an additional angle 48b may be attached to bottom cord 44b opposite from angles 42 to provide additional structural strength for hopper car 20. Bottom cord 44b and angle 48b preferably extend along substantially the full length of hopper car 20. In a similar manner, bottom slope sheet assembly 40a preferably includes angles 42, metal sheets 46, bottom cord 44a and an additional angle 48a.
Bottom slope sheet assemblies 40a and 40b may be attached with respective side sills 54a and 54b. Slope sheet assemblies 40a and 40b preferably extend inward at an angle from respective side sills 54a and 54b to a location proximate bottom clearance or minimum clearance for hopper car 20 relative to associated railway tracks (not expressly shown). For embodiments of the present invention represented by hopper car 20 slope sheet assemblies 40a and 40b may extend at an angle of approximately forty five degrees (45°) relative to respective sidewall assemblies 30a and 30b.
Portions of bottom slope sheet assembly 40a cooperate with adjacent portions of center sill 52 and dome 56 to define longitudinal discharge openings 26a. In a similar manner portions of bottom slope sheet assembly 40b cooperate with adjacent portions of center sill 52 and dome 56 to define in part longitudinal discharge openings 26b. See
A plurality of longitudinal door assemblies 90a and 90b are preferably hinged proximate the upper portion of center sill 52 adjacent to dome assembly 56. Longitudinal door assemblies 90a and 90b may also be described as “swinging longitudinal slope sheets.” Longitudinal door assemblies 90a and 90b may be formed with overall dimensions and configurations similar to bottom slope sheet assemblies 40a and 40b. Attaching longitudinal door assemblies 90a and 90b proximate the upper portion of center sill 52 in accordance with teachings of the present invention may increase the volume of lading which is carried within hopper car 20 and may also reduce the center of gravity when hopper car 20 is loaded.
Various types of mechanical hinges may be satisfactorily used to respectively engage door assemblies 90 with dome assembly 56 proximate the upper portion of center sill 52. For embodiments of the present invention as shown in
Alternatively, hinge assemblies 92 may include any suitable hinge, such as spring, continuous, butt, slip apart, and weld-on hinges, to allow door assemblies 90 to move between an open and closed position. For example, hinge assemblies 92 preferably includes flat plate butt hinges that are bolted between door assemblies 90 and an upper portion of center sill 52 to pivotally move door assemblies 90 between an open and closed position.
For purposes of describing various features of the present invention door assemblies 90 have been designated as 90a and 90b. Hinge assemblies 72 have been designated as 92a and 92b.
Each door assembly 90a and 90b preferably includes a first, closed position which prevents the discharge of lading from hopper car 20 (see
Door assemblies 90 formed in accordance with teachings of the present invention may extend along approximately the full length of respective longitudinal discharge openings 26a and 26b. The overall empty car weight of hopper car 20 may be reduced as compared to prior hopper cars. As such, the cost associated with manufacture and maintenance of hopper car 20 may also be reduced. Door assembly 90 may be formed using metal plates 96a and 96b having similar thickness and other characteristics associated with metal plates 36 and 46. Respective angles 98a and 98b may be attached with the longitudinal edge of each door assembly 98a and 98b opposite from respective hinges 92a and 92b. For some application angles 98a and 98b may be replaced by an I-beam, a Z-beam or any other suitable structural shape.
As shown in
As shown in
End wall assemblies 80a and 80b may have approximately the same overall configuration and dimensions. Therefore, only end wall assembly 80a will be described in detail. For some applications end wall assembly 80a may include sloped portion 82a and a generally vertical portion 84a. End wall assembly 80a may be formed from one or more metal sheets 86. Metal sheets 86 may have similar thickness and other characteristics associated with metal sheets 36 and 46.
A plurality of interior supporting structures or interior cross brace assemblies 100 and 200 may be disposed within hopper car 20 extending between sidewall assemblies 30a and 30b and bottom slope sheet assemblies 40a and 40b. The various components associated with interior supporting structures 100 and 200 cooperate with each other to provide adequate strength and load carrying capabilities for bottom slope sheet assemblies 40a and 40b while at the same time providing relatively large longitudinal discharge openings 26a and 26b adjacent to center sill 52.
Interior supporting structures are typically formed from structural members such as plates, angles, bars, channels, beams, tubing, cables, ropes, wires, a combination of different structures, or any other structural member.
Referring to
For embodiments of the present invention as shown in
Hopper cars may be formed with fewer than four cross brace assembly 100 but may also be formed with more than five cross brace assembly 100. In some embodiments of the present invention, hopper car 20 is formed with three cross brace assembly 100. Also, partitions (not expressly shown) may be used in place of interior cross brace assemblies.
Respective diagonal braces 110 and 120 preferably extend between sidewall assemblies 30a and 30b and bottom slope sheet assemblies 40a and 40b for each interior cross brace assembly 100a, 100b, 100c and 100d. For the embodiment of the present invention represented by interior brace assembly 100c as shown in
As shown in
Horizontal crosspiece or brace 130 preferably extends between sidewall assemblies 30a and 30b. First end 131 of horizontal crosspiece or brace 130 may be engaged with connector 102a. Second end 132 of horizontal brace 130 may be securely engaged with connector 102b. Connectors 102a and 102b are preferably mounted on interior surfaces of sidewall assemblies 30a and 30b spaced from top chords 32a and 32b at locations generally aligned with respective horizontal cross bearers 60a, 60b, 60c and 60d. The vertical location of each horizontal brace 130 relative to center sill 52 may correspond approximately with the intersection of end wall portions 82a and 84a and/or end wall portions 82b and 84b.
For embodiments of the present invention as shown in
For example one or more cross brace assemblies may be formed with larger or smaller components as compared with other cross brace assemblies associated with the hopper car. In some embodiments, cross brace assembly 100 are formed of different sized members or components. For example, in one embodiment, cross brace assembly 100 includes a reduced cross-section member such as a cable (shown below in more detail) to form a brace component.
Hopper cars may be formed with fewer than four cross brace assembly 200 but may also be formed with more than five cross brace assembly 200. In some embodiments of the present invention, hopper car 20 is formed with three cross brace assembly 200. In yet other embodiments, hopper car 20 is formed with brace assembly 100, brace assembly 200 or any combination thereof. Also, partitions (not expressly shown) may be used in place of interior cross brace assemblies.
Interior brace assembly 200 may sometimes be referred to as a “rib plate assembly”. Interior cross brace assembly 200c preferably includes rib plate 210 centered over and coupled to center sill 52 at bracket 210a.
Rib plate 210 may be securely mounted on and attached with center sill 52. A generally U-shaped bracket 210a may be formed as an integral component of rib plate 210. Bracket 210a preferably includes dimensions compatible with the upper portion of center sill 52.
Various types of mechanical fasteners such as bolts and huck fasteners and/or welding techniques may be satisfactorily used to securely engage bracket 110a with center sill 52.
Each interior brace assembly 200 preferably includes respective horizontal cross bearers 230 and 235 extending from respective side sills 54a and 54b and connecting to rib plate 210. Typically, horizontal cross bearers 230 and 235 are preferably attached to and extend generally laterally from rib plate 210. Various types of mechanical fasteners such as bolts and huck fasteners and/or welding techniques may be satisfactorily used to securely attach interior brace assembly 200. For example, horizontal cross bearer 230 may bolt to respective side sill 54b using plate member 231b at first end 230a and second end 230b of cross bearer 230 couples with rib plate 210. Similarly, cross bearer 235 may connect to respective side sill 54a using plate member 231a at first end 235a and second end 235b of cross bearer 235 couples with rib plate 210.
Upper diagonal braces 220 and 225 preferably extend between sidewall assemblies 30a and 30b and rib plate 210. For the embodiment of the present invention as shown in
Lower diagonal braces 240 and 245 preferably extend between bottom slope sheet assemblies 40a and 40b and rib plate 210. First end 240a of lower diagonal brace 240 preferably couples to bottom cord 44b and angle 48b of bottom slope sheet assembly 40b being secured by connector plate 241b. Second end 240b of lower diagonal brace 240 may be secured with rib plate 210. In a similar manner first end 245a of lower diagonal brace 245 may be connected with bottom cord 44a and angle 48a of sloped sheet assembly 40a by connector plate 241a. Second end 245b of lower diagonal brace 245 may be secured with rib plate 210.
Horizontal crosspiece 205 preferably extends between sidewall assemblies 30a and 30b. First end 205a of horizontal crosspiece 205 may be engaged with connector 202a. Second end 205b of horizontal crosspiece 205 may be securely engaged with connector plate 202b. Pairs of connector plates 202a and 202b are preferably mounted on interior surfaces of sidewall assemblies 30a and 30b at locations generally aligned with respective horizontal cross bearers 230 and 235.
In some alternate embodiments of the interior supporting structure 200, cross brace assembly 200 may include a reduced cross section member (not expressly shown). For example, cables such as aircraft quality stainless steel cable may replace one or more braces such as lower diagonal braces 240 and 245. By reducing the cross section of certain interior members, hopper car 20 may rapidly discharge lading.
Various types of operating assemblies and door closing mechanisms may be satisfactorily used to open and close longitudinal door assemblies or gates 90a and 90b. For the embodiments shown in
Discharge control system 160 incorporating teachings of the present invention generally has pivot points and linkages and no torsion members, incorporates over center locking, and simplified adjustment. Discharge control system 160 incorporating teachings of the present system may operate gates or doors 90a and 90b by pushing or pulling with air cylinder 152, hydraulic cylinder or other type of actuator via a common linkage such as clevis 180 centered under center sill 52 of railcar 20 or highway truck (not expressly shown) longitudinally. The common linkage or clevis 180 may be attached to secondary linkages such as bar 162 and arms 174a and 174b that connect to door assemblies 70 or gates 90a and 90b on both sides that are swung up or down depending on the direction of the common linkage.
Gates 90a and 90b may be hinged proximate center sill 52 or other centrally located structure with hinges 92a and 92b oriented longitudinally and above the common linkage. Each secondary linkage such as arm 174a and 174b provides the lower horizontal leg of a triangular shaped mechanism consisting of gate 90a and 90b as the hypotenuse and the common linkage such as bar 162 and centrally located structure or center sill 52 as the upright leg in a closed position. The secondary linkages such as arms 174a and 174b may be pushed or pulled past center to provide a positive lock on gates 90a and 90b, commonly known as over center locking. The secondary linkages may be symmetrical to each other and provide an equilibrium of the transverse forces both while operating and in a locked position.
Only relatively simple adjustments are required such as lengthening or shortening secondary linkages such as arms 174a and 174b until respective gates 90a and 90b are closed with sufficient preload. An over center lock is adjusted by a stop (not expressly shown) at the end of the common linkage such as bar 162 which can be adjusted longitudinally to increase or decrease the desired travel of the common linkage. The secondary linkages or arms 174a and 174b rotate into a compound angle mainly oriented in the longitudinal direction parallel to the common linkage when gates 90a and 90b are in the open position and rotate into a mainly perpendicular position to the common linkage when gates 90a and 90b are in the closed position. Additional secondary links (not expressly shown) can be added to carry heavier loads between gates 90a and 90b and the common central linkage such as bar 162. Multiple gate arc travel (not expressly shown) can be accomplished by changing the secondary linkages lengths.
As shown in
Typically, air cylinder 152 is formed proximate to a lower portion of the hopper such as proximate center sill 52. However, air cylinder 152 may be formed, located, placed, coupled or disposed with any portion of hopper car 20. In one embodiment of the present invention, air cylinder 152 is located beneath center sill 52.
In alternate embodiments of the present invention, operating assembly 150 may replace or supplement air cylinder 152 with any suitable drive actuator for providing a reciprocating longitudinally movement relative to center sill 52 and other components associated with railway car underframe 50. For example, operating assembly 150 may include an electrically operated motor (not expressly shown). Other examples of drive actuators including, but not limited to, hydraulic actuators, pneumatic actuators, electric actuators, manual actuators such as geared drives, and any other suitable drive actuators.
On example of an alternate operating assembly may include, operating mechanism 250 satisfactory for moving door assemblies 90a and 90b between a first, closed position and a second, open position, as shown in
Railcar 20 preferably includes gearbox 253 that may couple with motor 252. Typically, gearbox 253 provides a mechanical advantage to for turning or moving bar 262. As such, gearbox 253 may use motor coupler 260 for coupling or connecting motor 252 via gearbox 253 with bar 262.
In some embodiments, a detached motor (not expressly shown) drives gearbox 253. Generally, detached motor couples onto a drive shaft (not expressly shown) extending from gearbox 253 that provides the rotational movement for moving bar 262. In other embodiments, gearbox 253 is able to receive a motor drive shaft (not expressly shown) extending from the detached motor that is able to drive gearbox 253. In further embodiments, detached motor may include a manual actuation in which a person is used to drive gearbox 253 for opening and closing door assemblies 90.
Bar 262 generally interacts with boss 272a and 274a via attachment point 272a and 274a using threads (not expressly shown). As such, bar 262 may be able to provide a torsional movement that is converted into a longitudinal movement of boss 272 and 274 via the threads interacting inside of boss 272 and 274.
In some embodiments, bar 262 may be formed in two sections, namely bar 262a and bar 262b. Because bars 262a and 262b may coupled to motor 252 via gearbox 253, bars 262a and 262b may rotate in a similar direction. Thus, bars 262a and 262b may differ using reverse threading.
Reverse threading on one of bars 262a and 262b may cause boss 274 to be driven in an opposite direction. For example, bar 262a may include reverse threading and couple with boss 274 at attachment 274a. However, bar 262b may not include reverse threading and couple with boss 272 at attachment 272a. By rotating bar 262 in a common direction, boss 272 and 274 may be driven in opposite directions. In one embodiment, boss 272 and boss 274 are driven towards each other to cause door assemblies 90 via arms 174 to move to a closed position. Similarly to operating mechanism 150, operating mechanism 250 may include over-center locking position.
Drive actuator such as air cylinder 152 and motor 252 may move and maintain door assemblies 90 at an intermediate position generally between the closed position and the open position. For example, the position of door assemblies 90 as shown in
One end of piston rod 156 is preferably connected to for fitted with clevis 180 that connects with an adjacent end of plank or connector plate 161. For embodiments of the invention as shown in
Connectors or brackets 164 may be attached with center sill 52 and respectively engaged with bar 162. Generally, the dimensions of bracket 164 are preferably selected to allow bar 162 to slide or move within bracket 164 longitudinally with respect to center sill 52. Bracket 164 may be used to maintain bar 162 within a respective distance from center sill and in alignment with respect to center sill 52 and door assembly 90. In some embodiments, an insert member 164a may be disposed between bar 162 and bracket 164 to reduce the friction of the sliding motion.
For embodiments of the present invention as shown in
Generally, arms 174a and 174b are adjustable in length. For example, arms 174a and 174b may include turnbuckle 175 forming a part of arms 174a and 174b. Turnbuckle 175 preferably engages with threads 177 formed on arms 174a and 174b. By rotating turnbuckle 175 using notches 175a, turnbuckle 175 may extend or contract the length of arms 174a or 174b. As such, the position of door assemblies 90 in either the open or closed position may be adjusted. Generally, turnbuckle 175 adjust the length of arms 174a and 174b to provide sufficient closure of door assemblies 90. However, in some embodiments, turnbuckle 175 may adjust the length of arms 174a and 174b such that the open position of door assemblies 90 varies.
First end 176a and 176b of each arm 174a and 174b preferably includes a respective ball joint (not expressly shown) which may be rotatably engaged with socket or boss 172. Second end 178a and 178b of each arm 174a and 174b may be rotatably engaged with each door assembly 90a and 90b opposite from associated hinges spaced from respective hinges 92a and 92b. Arms 174 may rotate in three dimensions such as longitudinal, lateral and vertical relative to the associated center sill 52 (generally referred to as having a three-degree of range of motion mechanical linkage)
Discharge control system 160 incorporating teachings of the present system may operate gates or doors 90 by pushing or pulling with air cylinder 152, hydraulic cylinder 252 or other type of actuator a common linkage centered under center sill 52 of railcar 20 or highway truck longitudinally. The common linkage may be attached to secondary linkages that connect to the door assemblies or gates 90 on both sides that swing or pivot open and closed depending on the direction of the common linkage. The gates 90 may be hinged proximate center sill 52 or other centrally located structure with hinges 92 oriented longitudinally and proximate the common linkage. Each secondary linkage provides the lower horizontal leg of a triangular shaped mechanism consisting of gate 90 as the hypotenuse and the common linkage and centrally located structure or center sill 52 as the upright leg in a closed position. The secondary linkages may be pushed or pulled past center to provide a positive lock or over-center lock on gate 90. The secondary linkages may be symmetrical to each other and provide an equilibrium of the transverse forces both while operating and in a locked position.
Only relatively simple adjustments are required such as lengthening or shortening secondary linkages until respective gates 90 are closed with sufficient preload or force. As such, over-center lock may be adjusted by a stop (not expressly shown) at the end of the common linkage such as bar 162 and 262 which can be adjusted longitudinally to increase or decrease the desired travel of the common linkage. The secondary linkages rotate into a compound angle mainly oriented in the longitudinal direction parallel to the common linkage when gates 90 are in the open position and rotate into a mainly perpendicular position to the common linkage when the gates are in the closed position. Additional secondary links can be added to carry heavier loads between gates 90 and the common central linkage. Multiple gate arc travel can be accomplished by changing the secondary linkages lengths.
Discharge control system 160 incorporating teachings of the present invention may be used on highway trucks, railcars, and other equipment requiring longitudinal gate(s). Additionally, discharge control system 160 may operate multiple gates swinging in opposite directions with a common linkage such as bar 162 and 262 extending generally perpendicular to the direction of both gate swings using a common air cylinder or actuator. Further, discharge control system 160 incorporating teachings of the present invention may be easily adapted to various commodities and gate sizes by adding or deleting secondary linkages.
Referring to
Although the present invention and its advantages have been described in detail, it should be understood that various changes, substitutions and alternations can be made herein without departing from the spirit and scope of the invention as defined by the following claims.
This application is a continuation of U.S. Application Ser. No. 11/381,687 filed May 4, 2006, now U.S. Pat. No. 7,681,507 which is a continuation of U.S. Application Ser. No. 10/926,370 filed Aug. 25, 2004, now U.S. Pat. No. 7,051,661 which claims the benefit of U.S. Provisional Patent Application Ser. No. 60/498,117 filed Aug. 26, 2003. The contents of these applications are incorporated herein in their entirety by this reference.
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Number | Date | Country |
---|---|---|
J07564 | Jan 1910 | GB |
Number | Date | Country | |
---|---|---|---|
20080236438 A1 | Oct 2008 | US |
Number | Date | Country | |
---|---|---|---|
60498117 | Aug 2003 | US |
Number | Date | Country | |
---|---|---|---|
Parent | 11381687 | May 2006 | US |
Child | 12138146 | US | |
Parent | 10926370 | Aug 2004 | US |
Child | 11381687 | US |