This invention relates in general to railcars and, more particularly, to a railcar coupler, system, cores and method for its production.
Railcar couplers are disposed at each end of a railway car to enable joining one end of such railway car to an adjacently disposed end of another railway car. The engageable portions of each of these couplers is known in the railway art as a knuckle. For example, railway freight car coupler knuckles are taught in U.S. Pat. Nos. 4,024,958; 4,206,849; 4,605,133; and 5,582,307.
Typically, adjacent railway cars are joined by heavy shafts extending from each car, known as couplers, and, generally, each coupler is engaged with a yoke housing a shock-absorbing element referred to as the draft gear. The type-E coupler is the standard coupler for railway freight cars. The type-E coupler has standard specifications such that producers making a type-E coupler adhere to a standard specification, so that the standard railway car couplers are completely interchangeable, regardless of the manufacturer. In addition, adherence to a standard also enables couplers from any one manufacturer to be able to be readily joined to couplers from any other domestic manufacturer. The Association of American Railroads (“AAR”) has adopted standards for railway couplers. The coupler must include specific geometry and dimensions that allow it to receive a knuckle, and the geometry must be such that the knuckle is allowed to freely operate when coupling and uncoupling railway cars. These dimensions and features of the coupler may be checked for compliance with AAR standards by using gauges, which are applied to the coupler to verify the coupler dimensions or parameters are within an allowable variation or tolerance range.
Couplers have a particular life, and in instances may fail. In many cases when a railcar coupler fails, it is difficult to replace it, since, typically, the repair or replacement must be done in a repair shop.
The production of couplers typically involves a method known as sand casting or “green sand” method, where a flask which is a box having an open top and open bottom, is filled with sand around a pattern which is a component (such as, for example, a piece made from wood or iron) that is used to make the impression in the sand. The green sand casting process involves a number of components and steps, as a flask or box must be created with cope and drag sections, so that the pattern may make an impression in the sand and can be removed from the mold prior to introduction of the molten metal therein. A mold may include additional components, such as, for example, a gate and one or more runners through which the molten metal is admitted to one or more parts of the impression formed by the pattern. Gates and runners generally are formed similar to the mold impression, for example, with a component, such as wood (e.g., a gate and runner pattern), and are removed prior to the introduction of the molten metal, often with the removal of the pattern. A path of entry, such as an opening for admission of molten material is generally made through a sprue which is a communication path leading to the gate. The gate generally receives the molten metal that is poured through the sprue opening, and the runners act as conduits through which the molten metal flows to the impression or mold space formed by the pattern. In the case of forming a coupler, the mold must further be provided with cores. Cores are generally made from a material that remains present in the molding process during the mold melt introduction and are removable thereafter. In some cases, such as, for example, in the case of a coupler shank, the configuration of the pattern or ultimate coupler part does not allow for removal of a core in its solid form, so the core must therefore be broken apart and removed in pieces. The cores generally also may be made from green sand. The “green sand” method involves baking the mold so that the sand will form a mass and stay together during the molding process, and, in particular, when the molten metal is introduced into the mold. Once the molten metal is introduced into the mold through the sprue, gate and runners, the molten metal flows around the open areas of the mold and is blocked from entry to areas of the mold that are occupied by cores. The placement and positioning of cores in the mold, as well as the ability for a core to remain in place is required in order to produce a usable coupler. Although attempts are made to secure the core in a proper position, the cores have been known to shift prior to or during receiving the melt. In instances where a core shifts or where the green sand is not completely amassed together (e.g., where portions break off leaving fractured or missing edges), the coupler produced may need to be scrapped. However, in many instances the core shift occurs and is not detectable. For example, in some instances, core shift may lead to a variation in the wall thicknesses, where the wall is incorrectly formed. These types of defects are not always apparent by external inspection, particularly for a defect in an internal wall, and, if present, can lead to premature failure of the coupler.
Couplers, in operation on a railway vehicle, are subjected to forces, including torque. These loads put strain on the coupler.
A need exists for a coupler that has an improved construction for handling force loads and which may be manufactured in a manner that minimizes or eliminates the potential for misformed structures.
The present invention provides a railcar coupler, system and method for producing couplers, that substantially eliminates or reduces at least some of the disadvantages and problems associated with previous couplers and production methods.
In accordance with a particular embodiment, a railcar coupler includes a coupler head portion extending from a shank portion. The coupler head portion is configured to couple to a first coupler knuckle for coupling the railcar coupler to a second railcar coupler of an adjacent railcar. The coupler head portion comprises a nose portion and a gathering face extending from the nose portion for engaging a second coupler knuckle coupled to the second railcar coupler. The coupler head portion comprises a guard arm portion extending from the nose portion.
A coupler having improved strength and force handling characteristics, where a support is provided through the body of the coupler, and where openings are provided in the coupler. The coupler structure preferably includes a vertical support as well as a lateral support. According to a preferred embodiment, the coupler is constructed to have outer walls, such as upper and lower walls, that form an arrangement with a wall forming the coupler body. In a preferred embodiment, the coupler structure has a vertical wall that connects the upper and lower walls with the wall disposed in the coupler body.
According to preferred embodiments, the coupler structure includes walls forming an I-beam configuration, and more preferably, a double I-beam configuration.
According to preferred embodiments, the coupler outer walls and wall disposed in the coupler body, along with a vertical wall, form an I-beam configuration, and more preferably, a double I-beam configuration.
According to some preferred embodiments, the coupler is formed with supporting walls or ribs. The ribs or supporting walls may connect with walls forming the I-beam structure, and, in addition, may form a portion of the I-beam, such as, for example, with the vertical wall. According to some embodiments, the walls or ribs form a lateral extension of the vertical wall.
According to a preferred embodiment, the double I-beam structure is formed from three horizontal walls extending through the shank prior to the key slot and, after the key slot, through the shank butt, and a vertical wall. In preferred embodiments, the vertical wall may extend continuously along the centerline of the shank, with the exception of the key slot (which remains uninterrupted). A plurality of reinforcement ribs also are provided between the horizontal walls. The ribs improve the torsional rigidity of the coupler shank, and provide the coupler with improved strength. According to preferred embodiments, the ribs preferably are recessed inwardly from the edges of the horizontal walls.
The present coupler has improved strength and force handling compared with traditional couplers. A traditional coupler typically has a shank or body portion with a relatively box-like configuration (e.g., in cross-section, as shown in prior art
According to some embodiments, the coupler shank may have the improved structure at the shank front portion (which may be referred to as the shank mid portion) that is forward of the key slot, or at the shank end portion, which is after the key slot, or more preferably, at both locations.
According to preferred embodiments, a plurality of openings, which may be recesses, are provided in the coupler, and, in preferred embodiments, are provided on both sides of the coupler and extend from the coupler outer boundary to an inner vertical wall, such as, for example, a vertical wall connecting the upper, lower and mid walls. The recesses may be divided, in whole or part, by additional walls, which may be referred to as support walls or ribs.
The configuration of the couplers produced in accordance with the invention allows for advantages in the manufacturing process to have greater control of dimensions and material thickness, as well as the integrity of the coupler formed. According to a preferred method, couplers of the invention may be formed using coring that can be fixed or locked into the cope and/or drag of the mold. The prior art hollow shank design used a large core that was, by comparison, unsupported and prone to core shift. As discussed above, core shift typically leads to incorrect wall thicknesses which are not apparent by external inspection, and may lead to premature failure of the part. According to a preferred embodiment, the coupler mold may comprise mold parts, such as cope and drag mold sections, which may carry the cores in a fixed position. The fixing of at least some of the cores provides the ability for the coupler openings or recesses to be produced without the tendency to shift, since the cores forming the openings or recesses are locked to the mold sections (such as, for example, the cope and drag sections of a mold). According to some preferred embodiments, the cores forming the coupler shank may be fixed to the mold, and, may, for example, form the openings in the shank, the shank walls, shank end portion and key slot.
An object of the invention is to provide an improved method and mold for producing a coupler with cavities (also referred to as openings) in the coupler structure, where the cores forming the cavities are fixed to the mold or mold parts. According to some preferred embodiments, the coupler shank is formed with cavities using fixed core structures. This process improves the production of the coupler. In addition, couplers produced using the method and core structure may have improved force handling properties, such as, for example, the ability to handle torque forces.
Another object of the invention is to produce a coupler that is suitably strong, being as strong as or stronger than existing couplers, and which may be constructed to save weight by reducing the amount of material required for its production.
In addition, embodiments of the coupler preferably may be provided to have specified wall thicknesses. According to some preferred embodiments, the wall thickness range may be from about 0.25 to about 3.0 inches. Whereas prior couplers typically have wall thicknesses of 4 inches at the shank end, the present coupler provides a structure which significantly reduces wall thickness. An object of the invention is to reduce material thickness, while providing a coupler that is equal to or greater in strength than those prior couplers whose wall thickness maximized at 4 inches. Another object is to provide a coupler that has walls, that include at least some wall thicknesses that have thicknesses as small as 0.25 inches, or 0.5 inches. For example, a coupler may be produced having a minimum wall thickness where the guard arm wall (e.g., the wall forming the gathering face) may be 0.5 inches or less, and wherein the shank of the coupler has walls that are 0.5 inches or less, which may include the shank mid portion, the shank end portion, or both.
According to one preferred embodiment, the coupler shank upper and lower walls have a thickness of about 0.5 to 2.0 inches, the vertical wall has a thickness of about 0.5 to 2.0 inches, and the mid wall has a thickness of about 0.5 to 2.0 inches. According to another preferred embodiment, the horizontal wall of the guard arm preferably has the same thickness as the mid wall of the shank.
It is an object of the invention to provide an improved coupler that has one or more of the improved characteristics or features, including combinations of one or more of the features. For example, the coupler may be provided with a plurality of openings in the coupler head, as well as in the coupler shank. The mid wall or lateral support may be provided along the coupler length, including, for example, in the coupler head and shank portions.
According to some embodiments, the coupler may be constructed from steel, such as Grade E steel, or alternatively, may be constructed from austempered metal. In a preferred embodiment, the austempered metal is austempered ductile iron (ADI). In another preferred embodiment the austempered metal is austempered steel, such as austempered alloy steel, and, according to other embodiments the coupler may be constructed from an austempered metal alloy.
Austempered ductile iron (ADI) is produced by a suitable austempering process. For example, austempering of ductile iron may be accomplished by heat-treating cast ductile iron to which specific amounts of nickel, molybdenum, manganese or copper, or combinations thereof have been added to improve hardenability; the quantities of the elements needed to produce the ADI from ductile iron are related to the coupler configurations and, for example, may depend on the thickest cross-sectional area of the coupler. Austempered steel and other austempered metals and austempered metal alloys, may be produced by any suitable austempering process, including producing a ductile iron casting of the coupler (to which the alloyed elements have been added), and austempering the casting.
Referring to
The coupler 10 is mounted within a yoke (not shown) secured at each end of a railway car center sill, such that, in accordance with a preferred mounting arrangement, the coupler 10 may extend outwardly under an end of a railway car to engage a similar coupler (or any compatibly connectible coupler) extending outwardly under an end of an adjacent railway car. Coupler 10 includes a shank 14 having a bore or key slot 58 which is adapted to connect to the yoke (not shown) on the end of a center sill of a railway vehicle. The generally V-shaped coupler head 13 is provided at a forward end extending from the shank 14. The shank 14 is adapted to be fitted within and attached to a yoke secured at each end of a center sill extending full length under the railway car at a longitudinal axis. The coupler head 13 is provided to receive a vertical-knuckle (not shown) rotatably pinned at an outer end of the coupler head 13 forming a first leg of the coupler head 13, while a second leg of the coupler head 13 comprises a fixed and rigid guard arm portion 16.
The coupler head 13 further includes pivot pin openings, including an upper pivot pin opening 23 and a lower pivot pin opening 24, and pivot lugs, including an upper pivot lug 23a and a lower pivot lug 24a. The pivot pin openings 23,24 are provided to receive a knuckle pin (not shown) which is installed in the pivot pin openings 23,24 when a knuckle is seated at the pivot lugs 23a,24a. The pivot lugs 23a,24a and pin, when installed, pivotally retain a knuckle on the coupler head 13. The coupler head 13 preferably is configured with the pivot lugs 23a,24a aligned with the respective pivot openings 23,24. Referring to
The coupler 10 also is shown having a first angled gathering surface 18a (
According to a preferred embodiment, the coupler 10 is constructed with a mid wall portion 25b spanning between the gathering face wall 18 and the guard arm side wall 17. The mid wall portion 25b preferably, along with the upper wall 28, defines the upper cavity 27a and with the lower wall 30 defines the lower cavity 29a. The mid wall portion 25b, as shown in the embodiment illustrated in
According to a preferred embodiment illustrated, the guard arm 16 of the coupler 10 extends from the coupler nose portion 43 to the rear of the coupler head 13 where the coupler head joins with the shank 14. The coupler 10 includes a front face 22 and has a cavity 39 within which the knuckle operating components, such as a lock, thrower and lift, may be situated (when a knuckle is installed on the coupler). According to a preferred embodiment, the head 13 joins with the shank 14 at a front wall 42 (
The coupler shank 14 has a shank end portion 19 and a shank mid portion 20. The shank mid portion 20 connects the head 13 with the shank end portion 19. Referring to
In the preferred embodiment illustrated, the upper wall 21 and lower wall 22 form opposite exterior walls of the coupler 10. A mid wall 25 is disposed between the upper wall 21 and lower wall 22. According to a preferred embodiment, a plurality of openings are provided along the coupler shank mid portion 20. According to a preferred arrangement, the openings 31,32,33,34,35,36 are provided in the mid shank portion 20. Preferably, there are openings provided on the opposite side of the coupler 10 similar to the openings 31,32,33,34,35,36 but on the other side of the vertical wall 40. Opposite openings 31a,32a,33a are shown in
In the embodiment shown, the double I-beam structure 50 has a first leg 40c extending between the upper wall 21 and the mid wall 25, and a second leg 40d extending between said mid wall 25 and lower wall 22. In the embodiment illustrated, the double I-beam structure 50 is formed by the first leg 40c and second leg 40d, and the first and second legs 40c,40d are aligned in a linear relationship. In a preferred embodiment, the first leg 40c is aligned with the second leg 40d, so that the legs lie in the same plane. According to a preferred embodiment, the upper openings 31,32,33 may be provided similar in depth and configuration as the lower openings 34,35,36. Similarly, the openings on the opposite side of the wall 40 (such as those 31a,32a,33a which are shown in
According to an alternate embodiment, the first leg 40c and said second leg 40d may be aligned in a parallel relationship, although not necessarily in a linear relationship. The double I-beam structure may be provided in the mid shank 20 and the shank end portion 19. Alternatively, the mid wall may form a plurality of double I-beam structures in the shank mid portion, where the mid-wall forms a portion of each double I-beam structure. The double I-beam structure has a first I-beam portion with an upper horizontal portion and a lower horizontal portion and a second I-beam portion with an upper horizontal portion and a lower horizontal portion. The upper wall comprises the upper horizontal portion of the first I-beam portion of the double I-beam. The lower wall comprises the lower horizontal portion of the second I-beam portion. The mid wall forms the lower horizontal portion of the first I-beam portion of the double I-beam with the upper wall. The mid-wall forms the upper horizontal portion of the second I-beam portion of the double I-beam with the lower wall. According to an alternate embodiment, the vertical wall 40 may be formed with locations there along, such as for example, legs, like those legs 40c,40d, shown in
According to a preferred embodiment, a plurality of supporting walls or ribs are provided, and preferably there are walls or ribs provided on each side of the vertical wall 40 of the coupler mid shank 20. Referring to the sectional view of
In a preferred configuration, the mid wall, which is illustrated comprised of portions 25,25b,25a, spans from the head 13 and through the shank 14 to the shank end 19 at the end 59 of the coupler 10. According to a preferred embodiment illustrated, the coupler head 13 has an upper wall 28, a lower wall 30 and a front segment of the mid wall 25b. The coupler shank 14 is shown having an upper wall 21 and lower wall 22 at the shank mid portion 20 and at the shank end 19, with the rear segment of the mid wall 25a disposed between the upper and lower walls 21,22. According to a preferred embodiment, the mid wall 25 at the shank mid portion 20, the front mid wall segment 25b and rear mid wall segment 25a are longitudinally aligned.
A key slot 58 is provided in the shank 14 of the coupler 10. The key slot 58 extends through the width of the coupler 10. The mid wall 25 preferably is interrupted by the key slot 58, and there is a mid wall portion or segment 25a at the rear of the key slot 58, and a mid wall portion 25 at the front of the key slot 58. The coupler key slot 58 is provided transversely through the shank 14. The mid wall 25 is shown having a mid wall portion 25 between the coupler head 13 and the key slot 58 and another mid wall portion 25a between the key slot 58 and the coupler end 59. According to some preferred embodiments, a mid wall 25b is provided in the coupler head 13. Preferably, the mid wall 25 and respective mid wall head and shank end portions 25b,25a may be aligned horizontally, and may form a plane through the coupler length.
According to preferred embodiments, the wall 40 preferably may be configured as a longitudinal vertical wall 40 which is provided at the mid shank 20 and at the shank end portion 19. The wall portion 40a at the shank end portion 19 is shown in
In addition to the openings shown provided in the coupler shank 14 (and openings referred to on the opposite shank side), openings preferably are provided in the coupler head 13. According to preferred embodiments, the coupler head openings may include openings in the guard arm 16. The embodiment illustrated includes, for example, openings 17a,17b,17c,17d,17e,17f formed in the side wall 17 of the guard arm 16. The guard arm upper wall 28 is shown having an opening 27. Referring to
The coupler head 13 preferably is configured to couple to a coupler knuckle for coupling the railcar coupler 10 to a second railcar coupler (which may be another coupler 10 or other compatible coupler) of an adjacent railcar. The coupler 10 preferably carries a pivotally mounted knuckle (not shown). The knuckle preferably connects with a knuckle of a coupler on an adjacent railcar. In the embodiment illustrated, the coupler head 13 has a nose portion 43 and a gathering face 18a. The gathering face 18a extends from the nose portion 43 for engaging a second coupler knuckle that is carried by a second railcar coupler (not shown). The gathering face 18a is on a wall 18 of the coupler guard arm 16 (see
According to preferred embodiments, the coupler 10 preferably has walls forming it that have thicknesses between about 0.25 and 3.0 inches. The coupler upper wall 21 and lower wall 22 may be constructed having thicknesses between 0.25 and 3.0 inches. In addition, the mid wall 25 (and mid wall portions 25a,25b) also may be constructed having thicknesses between 0.25 and 3.0 inches. Preferably, the vertical wall 40, as well as the end wall portion 40a may be constructed having thicknesses between 0.25 and 3.0 inches. The guard arm 16 and gathering face wall 18 may have thicknesses between 0.25 and 3.0 inches. According to a preferred embodiment, the coupler 10 may be constructed such that each of the wall thicknesses of the upper wall 21, lower wall 22, mid wall 25, vertical wall 40 and guard arm gathering face wall 18 and guard arm outer wall 17 have thicknesses that are between 0.5 and 2.0 inches. According to some preferred embodiments, the mid wall portions 25a,25b also may be constructed with wall thicknesses that are the same as the wall thickness of the mid wall 25.
According to preferred embodiments, the coupler 10 is made from austempered ductile iron. The austempered ductile iron may be made from ductile iron alloyed with one or more metals selected from the group consisting of nickel, molybdenum, manganese, copper and mixtures thereof. The ductile iron is alloyed with one or more of the metals and is austempered along with one or more of those metals to produce the coupler 10, which, according to preferred embodiments, is an austempered ductile iron coupler.
The coupler 10 may be formed using any method known. One preferred method for forming the coupler 10 includes the use of a mold. The mold may have cope and drag parts, and cores that stand in for spaces. Specifically, the coupler 10 may be produced in a mold cavity within a casting box between cope and drag sections. Sand, such as green sand, may be used to define the interior boundary walls of the mold cavity, and in the production of the coupler 10, a preferred mold may use green sand for the guard arm cavities, whereas cores may be used to produce the openings in the coupler shank. A preferred method involves producing a mold that corresponds with the shape of the coupler 10. The mold produced preferably has two or more mold parts, which may include the cope and drag sections of the mold (mold halves), and one or more cores, which are pieces placed into the mold cavity to take up space and produce a void during the molding process. One production method involves sand casting or a “green sand” method. A flask, which is a box having an open top and open bottom, is filled with sand around a pattern which is a component (such as a wood piece shaped to correspond with the coupler 10 to be formed) that is used to make the impression in the sand. The green sand casting process includes creating a flask or box, which may be done by creating cope and drag sections, so that the pattern may make an impression in the sand and the pattern can be removed from the mold prior to introduction of the molten metal therein. The mold may include additional components, such as, for example a gate and one or more runners through which the molten metal is admitted to one or more parts of the impression formed by the pattern. Gates and runners preferably may be formed similar to the mold impression, for example, with a component, such as wood (e.g., a gate and runner pattern), and are removed prior to the introduction of the molten metal, often with the removal of the pattern. A path of entry or other opening for admission of molten material is made to introduce the molten metal into the mold space formed by the pattern. The molten metal may be introduced through a sprue which is a communication path leading to the gate. The gate generally receives the molten metal that is poured through the sprue opening, and the runners act as conduits through which the molten metal flows to the impression or mold space formed by the pattern. In the case of forming the coupler 10, the mold must further be provided with cores. Cores are generally made from a material that remains present in the molding process during the mold melt introduction and are removable thereafter. According to a preferred embodiment, cores are provided on each side of the mold and extend into the openings on each side of the coupler 10 to block the open spaces of the coupler 10 (such as, for example, the openings 31,32,33,34,35,36,37,38 and those on the opposite side). In some cases, the configuration of the pattern or ultimate coupler part does not allow for removal of a core in its solid form, so it must therefore be broken apart and removed in pieces. According to a preferred embodiment, the coupler 10 is constructed with openings in each side thereof, so that the core may be readily removed by separating it from the coupler without the need to brake the core. According to a preferred embodiment, the cores may be used to form openings and walls in the shank, without the need to break up the core during its removal from the mold (or for removal of the part). The cores generally also may be made from green sand. The “green sand” method involves baking the mold so that the sand will form a mass and stay together during the molding process, and, in particular, when the molten metal is introduced into the mold. However, according to preferred embodiments, the cores of the present invention that may be used for forming the openings and walls of the coupler may be made from something other than green sand where the cores are not required to be broken during the molding process. Once the molten metal is introduced into the mold through the sprue, gate and runners, the molten metal flows around the open areas of the mold and is blocked from entry to areas of the mold that are occupied by cores. In the present method for forming the coupler 10, a preferred arrangement is that the openings 31,32,33,34,35,36,37,38 are blocked by one or more cores, and the openings in the guard arm 16 also preferably are blocked by cores (as may be the internal spaces 27a,29a in the guard arm 16 above and below the guard arm mid wall portion 25b). The placement and positioning of cores in the mold, as well as the ability for a core to remain in place are required in order to produce a usable coupler. The use of cores that may be placed on each side of the coupler and extend into the mold space (that is, the space used to form the coupler) improves the molding and reduces the tendency of the cores to shift during molding when receiving the hot melt. The improvement in the coupler and mold design may reduce instances where the core shifts and the resultant coupler is improperly formed and may need to be scrapped. The mold of the present invention includes a mold for forming the coupler, where the mold has a mold cavity corresponding to the coupler shape. The mold preferably includes a plurality of mold parts, such as, for example, one more cores for forming openings on each side of the coupler shank (which may include the openings in the mid shank and shank end portions), and in the guard arm portion. The mold preferably is configured to produce walls of the coupler that have wall thicknesses from about 0.25 inches up to about 3 inches.
Referring to
According to a preferred embodiment, the core structure 113 preferably forms the coupler shank 14, and when the cores, such as, for example, those cores 113a,113b,113c and lower cores (not shown) of the illustrated core configuration, are arranged in the mold 110 or with the other mold parts, form the shank openings (such as, for example, the openings 31,32,33,34,35,36 and 37,38, and 31a,32a,33a,34a,36a and 37a,38a) and shank mid wall (such as, for example, the wall 25 and wall 25a) and shank vertical wall (such as, for example, the vertical wall 40 and wall 40a). The cores 113b,113c illustrate a preferred embodiment where the cores are fixed to the mold 110, and in particular the drag 111, with fingers 114,115,116,117 projecting into the coupler space to define openings and ribs or walls.
The core structure 113 is shown with a plurality of fingers or projections 114,115,116,117 that intrude into the mold pattern and form the openings in the coupler shank (such as those openings 31,32,33,34,35,36,37,38, and the openings on the opposite side thereof 31a,32a,33a,34a,36a,37a,38a, the opening on the opposite side of opening 35 not shown in the figures). The core structure 113 preferably may be locked or otherwise fixed to the mold 110. The mold part, including the drag 111, the cope (not shown) and core structure 113 locked thereto, preferably form the coupler 10, and, in particular, the coupler shank 14 without detached core portions that may otherwise shift during the molding process. The illustrations in
The coupler 10 is also shown with an optional lower shelf 85, which may be molded with or as part of the coupler head 13.
According to some preferred embodiments, the wall thickness range of the coupler walls may be from about 0.25 to about 3.0 inches. The coupler 10, according to some preferred embodiments, has walls that include at least some wall thicknesses that have thicknesses less than 1 inch, and more preferably, as small as 0.25 inches, or 0.5 inches. For example, the coupler 10 may be produced having a minimum wall thickness where the guard arm wall 18 (e.g., the wall forming the gathering face 18a) may be 0.5 inches or less (as may the guard arm side wall 17), and wherein the shank 14 of the coupler 10 has walls that are 0.5 inches or less, which may include walls comprising the shank mid portion 20, or walls comprising the shank end portion 19, or both. For example, a preferred range for the mid wall 25 (and mid wall portions 25a,25b) may be less than 2.0 inches, and preferably, less than 1 inch, and more preferably, between about 0.375 and 0.875 inches. The vertical wall 40 (and wall portion 40a) also may have a preferred thickness range, which may be less than 2.0 inches, and preferably, less than 1 inch, and more preferably, between about 0.375 and 0.875 inches.
According to a preferred embodiment, the coupler 10 may be constructed so that at least some of the coupler walls have a thickness at least as small as 0.5 inches.
While the invention has been described with reference to specific embodiments, the description is illustrative and is not to be construed as limiting the scope of the invention. For example, although the core structure 113 used for forming the shank 14 has been shown and described being comprised of five components or five cores, greater or lesser numbers of components or cores may be used. In addition, while preferred embodiments are illustrated, according to some alternate embodiments, the openings and walls forming the double I-beam structure may be of different sizes from other openings or other walls. The openings provided in the coupler shank (and at other locations, such as the coupler head and guard arm), may be curved at their edges to facilitate molding and removal of the cores. Alternatively, the openings may be formed using right angle edges. Various modifications and changes may occur to those skilled in the art without departing from the spirit and scope of the invention described herein and as defined by the appended claims.
Number | Name | Date | Kind |
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559005 | Timms | Apr 1896 | A |
1869035 | Wolfe | Jul 1932 | A |
20070125510 | Mautino | Jun 2007 | A1 |
20110168655 | Nibouar | Jul 2011 | A1 |
20130160962 | Nibouar | Jun 2013 | A1 |
Number | Date | Country | |
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20190248387 A1 | Aug 2019 | US |
Number | Date | Country | |
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Parent | 14720395 | May 2015 | US |
Child | 16214351 | US |