Patent Grant
10322732
The present invention relates to the field of coupler knuckles for use in coupling railroad cars and more particularly to an improved coupler knuckle and core assemblies for producing a coupler knuckle.
Railroad vehicles are generally connected together with couplers. Railroad couplers are typically constructed to railroad standards so that couplers used on railroad cars may be coupled together even if produced by different manufacturers. Common knuckles are American Association of Railroads (“AAR”) Standard E and F type railroad car couplers, and, in particular, the knuckles used in these couplers.
In the typical operation of railway vehicles, each railway car or vehicle is provided with a coupler. The couplers generally are attached to a yoke mounted on the center sill of the railway car. Each coupler of a railway car is centrally located and faces a coupler of an adjacent car, which, when brought into engagement with each other, join the cars together. The couplers carry a pivotally mounted knuckle thereon. A knuckle is pivotally carried on a coupler. The knuckle operation is regulated with other components which may include a knuckle lock, knuckle thrower, and knuckle lock lift. These components function to secure the knuckle in different positions, where the knuckle is able to receive and engage with another knuckle of a coupler of an adjacent car, and where the knuckle is released to disengage from another knuckle. Releasing the knuckle from engagement may be accomplished by disengaging the knuckle lock (which usually is done with a tool that is removably positioned in the lock lift). The knuckle is held on the coupler and pivots between locked and unlocked positions.
Knuckles are often manufactured from cast steel, and the knuckle casting weighs approximately 84 lbs. The cast steel used is grade E, tensile strength 120,000 psi, yield strength of 100,000 psi, elongation of 14%, reduction of area 30%. One problem that has been encountered over time when the knuckle is in use is fatigue cracking. Cracks form in the knuckle, and eventually over time, lead to the failure of the knuckle. When the knuckle fails, it must be replaced. In some cases, a train consisting of a number of railway cars will carry one or two spare knuckles for use in the event a knuckle fails. However, the task of replacing a knuckle is difficult, and, depending on the length of the train (i.e., number of cars), the location of the failed knuckle, and the weather conditions (snow, rain, heat, etc.), a replacement knuckle, often weighing 80 pounds or more, must be carried from the car in which it is carried (such as a location at the front or rear of the train) to the car with the damaged knuckle. Train separations are not uncommon, and occur daily. There are about 100,000 train separations a year, or about 275 separations per day, which are considered to be a result of knuckle failure. There are also a number of instances where the knuckle cannot be replaced on the train, but, where the entire car with the damaged knuckle must be taken to a repair facility. In these instances, the car needs to be taken out of service.
Aside from being burdensome for the railway operators and personnel, knuckle failures also can be costly, requiring a train to be delayed or one or more cars taken out of service. The production of coupler knuckles typically involves the use of cores that are placed in a mold. The cores are masses of material that block the molten metal from an area of the mold when the knuckle casting is being produced. The cores define cavities in the knuckle that is produced. The front core of a knuckle is commonly referred to as the finger core. The finger core produces an internal cavity in the knuckle. Another core used to produce a knuckle is the rear core, often referred to as the kidney core. Traditional knuckles have been observed to fail at the front, or finger core portion of the knuckle, or at the kidney core or rear portion.
The core of the finished knuckle is generally seen as a cavity in the knuckle, where the core was positioned during the casting of the knuckle. It is the practice of a knuckle that is cast to cast the knuckle around a core. The common practice is to utilize a core within the casting, and then break the core apart when the knuckle has been cast. This practice, aside from being time consuming, generally requires precise positioning of the core, such as, in a jig, and that the core remain in position during the casting process. U.S. Pat. No. 2,688,412, issued on Sep. 7, 1954, to F. C. Kulieke, for a “Coupler Knuckle Casting”, discloses cavities being formed in a knuckle casting using interlocking cores that are placed within the cope and drag mold sections.
Current methods used for forming knuckles have drawbacks and are known to produce failures in the final product when the core is misaligned or has shifted during the forming process.
There is a need for a process for producing a knuckle that may be done with improved precision and less waste, and for a knuckle having improved capabilities for handling forces and having improved strength or fatigue life.
In addition, there is a need for an improved knuckle that is able to handle force loads and is suitably resistant to cracking and failure.
An improved coupler knuckle and system, method and core assembly for production of a coupler knuckle are provided. The improved coupler knuckle is designed to facilitate handling of force loads transmitted to the coupler knuckle through components of the coupling system, the vehicle to which the coupler is associated, and other coupler knuckles (e.g., of an adjacent vehicle) that are in engagement with the coupler knuckle.
The coupler knuckle production method includes the use of cores to create cavities in the formed knuckle. According to a preferred method, the knuckle is produced by casting, using a mold, such as, for example, cope and drag sections, that close together around the cores, and into which molten metal may be introduced. The preferred method may produce the cores from materials typically used for core production, such as, for example, green sand or a resin. The core material is provided so that it may withstand the temperatures of the molten metal during the molding process (retaining its core shape when encountering the hot metal), but, after the molten metal has solidified, the cores can be broken apart (through vibrations, shaking, contact with a tool, or other suitable means) and allowed to exit the knuckle casting through the openings that are formed in the knuckle.
According to some preferred embodiments, the knuckle is constructed to locate openings for removal of the cores after the casting has taken place.
An improved core assembly is provided to produce a knuckle, including improved knuckles shown and described herein. The improved core assembly, preferably, includes a number of components, which may be connected to define cavities within the knuckle. The connected core assembly preferably may define a plurality of cavities that are interconnected, while, at the same time, providing planes of material that form the knuckle casting. According to some preferred embodiments, the core assembly is configured with a plurality of core pieces which are disposed at different relative heights to define cavities and planes of material within the knuckle casting.
It is an object of the invention to produce an improved coupler knuckle that has an interior construction to facilitate improved force handling and transmission of force loads through the knuckle, including from one end of the knuckle to the other.
It is another object of the invention to provide an improved knuckle and a process for producing an improved knuckle, where the knuckle has increased fatigue resistance and improved strength.
It is another object of the invention to produce a knuckle that has a plurality of spaced apart layers in the knuckle interior which are separated by cavities.
It is another object of the invention to accomplish any one or more of the above objects, where a knuckle has a horizontal cavity extending from the nose wall thereof through the body to the tail, and more preferably, where the cavity is formed to have at least one opening at the tail.
It is another object of the invention to accomplish any one or more of the above objects, where the knuckle cavities are defined by the cores, and where the mold parts into which the cores are placed (such as the mold cope and drag sections) define the exterior walls of the knuckle.
According to some preferred embodiments, the cores define a cavity within the tail section, pivot pin section, and nose section, including a flag hole.
According to some preferred embodiments, the cores include at least one central core that forms a continuous cavity through the tail section, pivot pin section, and nose section. According to some preferred embodiments, the central core may be used with one or more upper and lower cores. According to one embodiment, the central core and at least one upper core are used to form cavities in the knuckle produced using the cores. According to another embodiment, the central core and at least one lower core are used to form cavities in the knuckle produced using the cores.
According to a preferred embodiment, the cores include a central core which forms a continuous cavity through the tail, pivot pin, and nose sections, and at least one upper core that forms the pivot pin cavity section and nose cavity section, and at least one lower core that forms the pivot pin cavity section and nose cavity section.
According to another embodiment, a molding assembly is provided for producing a knuckle casting. The molding assembly includes a cope section and drag section, and cores positioned in the cope and drag sections, which, according to preferred embodiments, are secured within the mold sections with locking cores.
The knuckles produced from the cores and mold assembly may be made from any suitable metal. According to some preferred embodiments, the mold assembly is designed to receive molten metal, including ductile iron, which may be alloyed with other metals and elements. A knuckle casting is produced by admitting molten metal into the mold assembly. According to some preferred embodiments, the knuckle casting may be subjected to suitable austempering steps of heating and cooling. For example, knuckles formed from austempered ductile iron, alloys, and austempered steel and alloys, may be produced using the cores and mold assembly shown and described herein. Knuckles also may be produced using Grade E steel and the mold assembly to produce a casting
These and other advantages are provided by the invention.
The coupler knuckle 110 is illustrated including a force handling structure, which preferably has one or more transverse layers that span across the knuckle interior, and which are separated by cavities. Referring to
The knuckle 110 preferably is constructed with an improved force handling construction, which preferably, includes a plurality of layers that include the top wall or layer 115, the bottom wall or layer 118 and two mid layers, including the first mid layer 116 and second mid layer 117 which are separated by cavities therebetween, respectively, the first or upper cavity 121, second or lower cavity 124, and mid cavity 128. The layers include an upper layer 115 which is shown forming an upper surface of the top of the knuckle 110, and a lower layer 118 forming a lower surface of the bottom of the knuckle 110.
As shown in
According to a preferred embodiment, the mid layers 116,117 are disposed for alignment in a direction of anticipated and expected pulling forces, when the knuckle 110 is employed on a railroad car coupling, and a pulling force is exerted on the knuckle 110.
Referring to
The knuckle 110 has a pin bore 150 formed therein. As shown in
As shown in
According to a preferred construction, the transverse layers 115,116,117,118 are provided along a path parallel to the anticipated force direction that the knuckle 110 handles when a pulling force is applied to the knuckle 110. The arrangement of the layers 115,116,117,118 of the knuckle 110 preferably allows force loads to be handled through the knuckle in preferred directions.
Referring to
According to a preferred embodiment, cavities within the knuckle 110 are formed from a plurality of cores. As shown in
Referring to
According to a preferred embodiment, the core components 201,202,203, preferably are constructed with engaging surfaces formed on engaging lugs. According to some embodiments, the engaging surfaces may be matingly configured, such as, for example, being formed as draft surfaces. The upper core component 201 is shown with upper lugs 251,252 with respective engaging surfaces 251a,252a. The upper lug 251 is shown having an upper portion 251b on which the surface 251a is provided. The engaging surfaces 251a,252a of the respective upper lugs 251,252 engage with the respective engaging surfaces 219c,220c of the respective core components that are the locking core portions 219a,220a. The upper core component 201 also has lower lugs 253,254 with respective engaging surfaces 253a,254a which engage the engaging surfaces 255a,256a of the respective upper lugs 255,256 of the mid core component 203. Although the upper core component lug is referred to as an upper lug 251 and a lower lug 253, they may comprise a single structure (as may the lugs 255,262 of the central core component 203, and lugs 257,260 of the lower core component 202). The lower core component 202 engages with the lower locking core portions 219b,220b. The lower core component lower lug 257 is shown including lower portion 257b which has an engaging surface 257a thereon. The engaging surfaces 257a,258a of the respective lower core component lower lugs 257,258 engage with the respective engaging surfaces 219f,220f of the respective locking core portions 219b,220b. The locking core portions 219b,220b may be the same as the locking core portions 219a,220a shown at the upper end of the core assembly 200. As illustrated in the drawings, the lower core component 202 includes upper lugs 260,261 with respective engaging surfaces 260a,261a which engage with the respective engaging surfaces 262a,263a of the respective mid core component lower lugs 262,263.
The core components forming the flag hole 170 of the knuckle 110 are shown including the upper core component 201, lower core component 202 and mid core component 203. Locking cores 219a,219b are shown with lug portions 219c,219d thereof, respectively, which preferably may form opposite ends of the flag cavity or flag hole 170. According to alternate embodiments, where the flag hole 170 of the knuckle 110 has a closed bottom, or is recessed at the lower layer or wall 118 thereof, the lower lug 257 of the lower core component 202 may form the bottom of the flag cavity. Alternatively, the lower lug 257 may be provided with an alternate configuration at the lower end thereof. Alternatively, the lower locking core portion 219b may be excluded from the assembly 200 to provide a flag hole configuration that does not extend through the knuckle lower layer 118, such as, for example, where the lower lug 257 of the lower core component 202 defines the bottom of the flag hole 170. With the locking core portion 219b omitted, a bore may not form at that location. According to some preferred embodiments, the lower core component 202 may be configured as a mirror image of the upper core component 201. Alternatively, where the flag hole 170 of a knuckle to be, produced is not to extend through the lower wall or layer 118 of the knuckle 110, the lower core component 202 may be a mirror image of the upper core component 201 in all respects (for example, where the locking core portion 219b is omitted), or, in come embodiments, in substantially all respects, (e.g., except for the lower lug 257 or portion thereof). According to some other embodiments, the lower core component 202 may be similar to the upper core component 210, but may have an alternate lower lug 257 (e.g., shorter) (as well as the omission of the locking core portion 219b).
According to an alternate embodiment, the upper and lower core components 201,202 are vertically aligned with each other. According to some preferred embodiments, the front portions of each of the upper, lower and mid core components 201,202,203 are vertically aligned with each other. A recess 201a,202a,203a may be provided in the front of each respective core component 201,202,203. Although shown on the upper portion of the core components, a recess also may be provided on the lower portion thereof.
A pivot pin bore or cavity 150 in the knuckle 110 is formed by the core assembly 200. As shown, according to a preferred embodiment, core components 201,202,203,220a,220b are aligned to form a vertical pivot pin cavity in the knuckle 110 (corresponding with the cavity 150,
According to a preferred embodiment, the upper core component 201 and lower core component 202 are shown including respective lateral lugs 251,253 and 257,260 and respective lateral or connecting core portions 291,297. Although the lugs 251,253 are referred to, they may be provided as a single component, as with the lugs 257,260 and lugs 255,262. The central core component 203 is illustrated including a lateral connecting core portion 299 that connects with one or more of the central lugs 255,262 defining a portion of the flag hole cavity 170 of the knuckle 110. The lateral core portions 291,299,297 form the respective passageways 125,126,127 in the knuckle 110 (
As shown in
According to a preferred construction, the coupler knuckle 110 is made from a suitably strong material. One material is steel, and preferably grade E steel. According to some preferred embodiments, the coupler knuckle 110 is made from austempered metal, such as, for example, austempered ductile iron, austempered steel, as well as other austempered metals and austempered metal alloys. The coupler knuckle 110 made from austempered ductile iron (ADI) may be produced using 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, manganese, molybdenum, or copper, magnesium or combinations thereof have been added to improve hardenability. Austempered steel and other austempered metals and austempered metal alloys, may be produced by any suitable austempering process. The knuckle may be cast, and then austempered.
According to one embodiment, the knuckle has improved fatigue-resistance and is lighter in weight than existing current knuckles. When constructing the coupler knuckle from an ADI having a specific gravity of about 0.26 lbs/in^3, the density is less than that of grade E cast steel, 0.283 lbs/in^3 and a weight reduction of about 8% may be achieved using the ADI to construct the knuckle 110 versus using grade E cast steel.
According to an alternate embodiment, the knuckle 110 may be constructed from austempered steel. Austempered steel is produced by a suitable austempering process. For example, austempering of steel may be accomplished by heat-treating cast steel to which specific amounts of chromium, magnesium, manganese, nickel, molybdenum, or copper, or combinations thereof, have been added to improve hardenability; the quantities of the elements needed to produce the austempered steel from the cast alloy steel are related to the knuckle configurations and, for example, may depend on the thickest cross-sectional area of the knuckle.
According to alternate embodiments, the knuckle 110 may be formed using a molding process where the molten material is added to a mold. According to one embodiment, the knuckle 110 is constructed by forming a wax casting, where the wax is coated with a suitable material that can receive the molten metal. The wax is then removed from the coating that becomes the mold, and molten material is then introduced into the coating. The material may be subject to a suitable austenitizing process to produce a knuckle made from austempered metal.
Alternatively, the knuckle 110 may be formed by an alternative process that involves constructing a mold that is the shape of the knuckle 110, where the mold is formed from a material that is designed to disintegrate when contacted with the molten material that is to form the knuckle 110. One example of a method for producing a knuckle is set forth in co-pending U.S. patent application Ser. No. 14/171,700, filed on Feb. 3, 2014, for a process for producing a coupler knuckle and improved coupler knuckle. One preferred method involves forming the mold that resembles the knuckle 110, where the mold has the same and shape and volume of the knuckle 110 to be produced. The mold may be formed using injection molding, three dimensional (3-D) printing or other suitable procedure. The mold resembling the knuckle 110 in shape and volume is then coated with a coating that covers the interior and exterior surfaces of the mold. The coating may be applied one or more times, and may be applied by brushing, spraying, immersing, or other suitable application process. The mold interior spaces that are to remain as cavities in the formed knuckle 110 preferably are filled with an inert material, such as sand. The material that is to form the knuckle 110 is then introduced into the mold to contact the disintegratable mold material forming the mold, and the molten metal occupies the space that the mold previously had. The mold coating, which is made from a material that does not melt or degrade when exposed to the molten metal, remains and contains the molten metal. According to this method, preferably, the mold that is within the coating disintegrates by decomposing to form by products, such as a gas that passes through the coating. Once the molten material used to form the knuckle 110 has been allowed to cure, then the knuckle 110 may be broken away from the coating to provide a formed product. The resultant knuckle formed may be subjected to an austempering process, such as, for example, where ductile iron (e.g., a ductile iron alloy) is the molten metal used for the casting, and a knuckle composed of ADI is formed therefrom.
Preferred methods for constructing the knuckle 110 involve the use of mold parts, such as, for example, cope and drag mold sections that may be brought together around cores (such as the core components). One preferred method for producing a knuckle involves preparing or providing a cope mold section 211, a drag mold section 212 and cores, such as the core assembly 200 of core components shown and described herein. The assembled mold parts receive molten metal (e.g., iron, steel or other alloy metal) which fills the spaces of the mold which represent the volume of the knuckle to be produced. The knuckle casting is allowed to solidify, and then core assembly of core components is separated from the knuckle 110. Preferred methods involve shaking or vibrating the knuckle to break apart the cores, or other ways of applying a force to the cores. The cores and core assembly 200 may be made from any suitable material, including green sand and/or resins. According to a preferred embodiment, the method involves the use of a core assembly made from material that will not melt or substantially degrade in the presence of the molten metal (at least not to any extent that would adversely affect the formation of the knuckle 110). Preferably, the cores and core assembly 200 include locking core portions that aid in securing the core assembly within the mold. According to preferred embodiments, mold cope and drag sections include corresponding recesses for receiving the locking core portions to hold the cores of the core assembly in place.
According to one preferred method, a coupler knuckle for a railcar is produced using mold components. As shown, in accordance with a preferred embodiment, referring to
The method includes positioning a core assembly, such as, according to a preferred embodiment, the core assembly 200 of core components 201,202,203,219a,220a,219b,220b,221, within the mold, and preferably, within either the cope mold portion 211 or the drag mold portion 212. The core assembly 200 and cores thereof define the internal cavities of the coupler knuckle to be produced, and according to a preferred embodiment, includes a central core component 203 defining a mid or central cavity 128 of the coupler knuckle 110. The central cavity 128 encompasses cavities along the length of the knuckle 110, including the front of the knuckle 110 and the rear of the knuckle 110. Once the core assembly 200 of core components is positioned within the mold cope and drag, the cope and drag mold portions 211,212 are closed together with the core assembly 200 therebetween. The core assembly 200 and assembled core components 201,202,203,219a,220a,219b,220b,221 may be secured to the mold cope 211 and/or drag 212 in a desired portion by positioning locking portions of the respective cores into recesses of the cope 211 and drag 212. For example, according to a preferred embodiment, the central cavity end portion 128a defines an end of the coupler knuckle 110 that is the tail 130 of the knuckle. A tail locking portion 221 spans beyond the central core component 203 that defines the central cavity end portion 128a and beyond the knuckle 110. The tail locking portion 221 is shown connecting to the central core component 203. The tail locking portion 221 may be received in a recess (not shown) in the core 211 or drag 212 or both, such as, the recess 212a shown in the drag 212 (there also being a recess (not shown) in the core 211).
The cores or core components 201,202,203,219a,220a,219b,220b,221 of the core assembly 200 produce cavities in the formed knuckle 110. The upper core component 201 forms an upper cavity 121, and, according to preferred embodiments, forms a portion of pivot pin bore 150. The lower core component 202 forms a lower cavity 124, and, according to preferred embodiments, forms a portion of the pivot pin bore 150. The central or mid core component 203 defines a central cavity 128.
The method involves positioning and assembling the core components so that the upper core component 201, lower core component 202, and mid core component 203 are arranged in a substantially parallel configuration to form substantially horizontal cavities in the knuckle 110. The upper core component 201, lower core component 202, and central core component 203 preferably may have a tapered configuration that widens as each core spans from at least its respective pin bore core portion to the front (toward the nose). According to some alternate embodiments, the central core component 203 and at least one of the upper core component 201 or lower core component 202 form a core assembly, which produces a knuckle having a central cavity, such as, for example, the cavity 128 of the knuckle 110, and at least one additional cavity, such as, for example, the upper cavity 121 or lower cavity 124.
Referring to
The molten metal, or melt as it is sometimes referred to, is introduced into the mold cavity now including the core assembly 200 of core components therein. The knuckle casting is formed within the mold cavity as the molten metal is allowed to solidify. When the knuckle is solidified, then the knuckle and mold are separated from each other. As shown in the knuckle 110 formed with the core assembly 200 of core components, a plurality of substantially parallel cavities 121,124,128 are formed in the coupler knuckle 110 (
According to some embodiments, the method may involve placing the mold components and core components in a jig to hold the components together.
The knuckle 110, while according to a preferred embodiment is formed using the core assembly of core components, may be formed using other suitable methods, such as, for example, lost foam, wax casting, and the like.
These and other advantages may be realized with the present invention. 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. The knuckles according to the invention preferably also may be constructed to have improved surface finishes to provide higher fatigue strength. According to some alternate embodiments, a knuckle may be provided having a surface finish of 125-175 RMS. Knuckles according to the invention, such as the knuckle 110 shown and described herein, may be constructed with walls having any suitable wall thickness dimensions. According to some alternate embodiments, knuckles may be constructed having wall thicknesses from between about 0.25 in. and about 1.5 in., and, according to some other embodiments, from between about 0.25 in to 1.25 in. In addition, according to some preferred embodiments, the coupler knuckles according to the invention may be constructed having the advantages discussed herein and meet the AAR specification, M-216, or exceed it.
Although the knuckle has been described herein according to preferred embodiments being formed by casting and with the cores shown and described herein, according an alternate embodiments, the knuckle may be produced using other methods, including methods disclosed in our co-pending U.S. patent application Ser. No. 14/171,700, filed on Feb. 3, 2014, for a process for producing a coupler knuckle and improved coupler knuckle, the complete contents of which are herein incorporated by reference. Alternatively, in accordance with an alternate embodiment, the core assembly may be provided with the central core component and one of the upper or lower core components. This variation also may include extensions, preferably, of the central core component in the flag hole cavity core portion and pivot pin cavity core portion. Alternatively, the extended core portion may connect with a locking core, such as the locking cores shown and described herein that connect with an upper core component or lower core component. The lateral or connecting core portions connect with the lugs forming the flag hole cavity, and, accordingly, may connect at a location of the lug so as to connect with one or more of the lateral lugs of a core component. 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.
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