FIELD
The present disclosure relates generally to the field of railcar couplers, and more specifically to distributing loads and stresses more evenly or better balanced over railcar coupler bodies to increase the wear life of coupler assemblies.
BACKGROUND
Railcar couplers can be placed on railway cars at each end to permit the connection of each end of a railway car to a next end of an adjacent railway car. However, due to in service loads, natural corrosion, and natural wear and tear after hundreds of thousands of miles on the rails, car coupler assemblies and the components that make up the assemblies will wear and/or crack and break in service over time. The main areas of wear and tear are the surfaces and components of the car couplers that are directly loaded. The coupler head of the coupler is adapted to support a knuckle, which is configured to interlock with an adjacent knuckle on an adjacent railcar. When in the locked position, the loads of the knuckle are primarily transferred directly to the coupler head through the top pulling lug and the bottom pulling lug. As a result, the top and bottom pulling lugs are loaded with the tractive effort of the entire train plus any additional dynamic forces and may experience wear more quickly than other components of the coupler.
SUMMARY
This Summary provides an introduction to some general concepts relating to this disclosure in a simplified form that are further described below in the Detailed Description. This Summary is not intended to identify key features or essential features of the disclosure.
Aspects of the disclosure herein relate to a railcar coupler that can include a coupler body with a shank and a head portion, the head portion may define a cavity for receiving a knuckle, a thrower, a lock, a lock lift assembly, and a pin. The cavity can include a top pulling lug, a bottom pulling lug, and a thrower retaining lug. The top pulling lug can be configured to engage an upper knuckle pulling lug, and the bottom pulling lug being can be configured to engage a lower knuckle pulling lug. During operation of the railcar coupler, the ratio of the stress between the top pulling lug and the bottom pulling lug can be configured to be better balanced to help extend the life of the railcar coupler assembly.
In one example, the top pulling lug and a bottom pulling lug in the coupler body can be configured to balance the loads transferred to the coupler head such that the loads and corresponding stresses between the upper pulling lug and the bottom pulling lug are substantially equal or more balanced. In one example, the top pulling lug and the bottom pulling lug can have substantially equal strengths and deformation rates to evenly distribute or receive loads to or from the upper knuckle pulling lug and the lower knuckle pulling lug to maintain the loads and stresses on the upper knuckle pulling lug and the lower knuckle substantially balanced.
BRIEF DESCRIPTION OF THE DRAWINGS
The foregoing Summary, as well as the following Detailed Description, will be better understood when considered in conjunction with the accompanying drawings in which like reference numerals refer to the same or similar elements in all of the various views in which that reference number appears.
FIG. 1A shows a side perspective view of portions of two railroad cars.
FIG. 1B shows a front right perspective of an example coupler assembly.
FIG. 2A shows a top view of a cross section of the example coupler assembly of FIG. 1B.
FIG. 2B shows a top perspective view of an example knuckle that can be used in conjunction with the example coupler of FIG. 1B.
FIG. 3 shows a side view of a cross section of the example coupler assembly of FIG. 1B.
FIG. 4 shows a top view of another cross section of the example coupler assembly of FIG. 1B.
FIG. 5 shows a top view of a cross section of a portion of the example coupler assembly of FIG. 1B.
FIG. 6A shows another front perspective view of the example coupler body of FIG. 1B.
FIG. 6B shows a bottom view of a cross section along the line 6B of FIG. 6A.
FIG. 7 shows front perspective view of a portion of the example coupler body of FIG. 1B.
FIG. 7A shows a front bottom view of a portion of the coupler body of FIG. 1B.
FIG. 7B shows a top perspective view of a portion of the coupler body of FIG. 1B.
FIG. 7C shows another top perspective view of a portion of the coupler body of FIG. 1B.
FIG. 8 shows a top view of a cross section of a portion of the example coupler assembly of FIG. 1B.
FIG. 9A shows another front perspective view of the example coupler body of FIG. 1B.
FIG. 9B shows a top view of a cross section along the line 9B in FIG. 9A.
FIG. 9C shows another front perspective view of a portion of the example coupler body of FIG. 1B.
FIG. 10A shows a front perspective view of another example coupler body.
FIG. 10B shows a top perspective view of the example coupler body of FIG. 10A.
FIG. 10C shows a cross-sectional view of the example coupler body of FIG. 10A.
FIG. 10D shows a top perspective view of another example coupler body.
FIG. 10E shows a right side perspective view of the example coupler body of FIG. 10A.
FIG. 10F shows a front left side perspective view of the example coupler body of FIG. 10A.
FIG. 10G shows a rear perspective view of the example coupler body of FIG. 10A.
FIG. 10H shows front cross-sectional view of the example coupler body of FIG. 10A.
FIG. 10I shows a top perspective view of the example coupler body of FIG. 10A.
FIG. 11A shows a top view of a cross section of another portion of the example coupler assembly of FIG. 1B.
FIG. 11B shows a rear perspective view of a portion of the example coupler assembly of FIG. 1B.
FIG. 11C shows another top view of a cross section of another portion of the example coupler assembly of FIG. 1B.
FIG. 11D shows a top cross-sectional view of another portion of the example coupler body of FIG. 1B.
FIG. 11E shows a side cross-sectional view of the example coupler body of FIG. 1B.
FIG. 12 shows a side cross-sectional view of another portion of the example coupler assembly of FIG. 1B.
FIG. 13 shows a front cross-sectional view of a portion of the example coupler body of FIG. 1B.
FIG. 14A shows a side perspective view of the example coupler assembly in FIG. 1B in the unlocked position.
FIG. 14B shows a side perspective view of the example coupler assembly in FIG. 1B in the locked position.
FIG. 15A shows a diagram of loads on an example coupler body during a draft condition from the knuckle.
FIG. 15B shows a diagram of loads from the coupler onto an example knuckle during a draft condition.
FIG. 15C shows a diagram of reactive loads on an example coupler body from a knuckle in draft condition.
FIG. 16 depicts the stresses acting on a coupler body during a draft condition in accordance with an example discussed herein.
DETAILED DESCRIPTION
I. Detailed Description of Example Railcar Couplers
In the following description of various examples of railcar couplers and components of this disclosure, reference is made to the accompanying drawings, which form a part hereof, and in which are shown by way of illustration various example structures and environments in which aspects of the disclosure may be practiced. It is to be understood that other structures and environments may be utilized and that structural and functional modifications may be made from the specifically described structures and methods without departing from the scope of the present disclosure.
Also, while the terms “front,” “back,” “rear,” “side,” “forward,” “rearward,” “backward,” “top,” and “bottom” and the like may be used in this specification to describe various example features and elements of the disclosure, these terms are used herein as a matter of convenience, e.g., based on the example orientations shown in the figures and/or the orientations in typical use. Nothing in this specification should be construed as requiring a specific three dimensional or spatial orientation of structures in order to fall within the scope of the disclosure.
FIG. 1A shows a side perspective view of portions of two railroad cars 10, 20 which can be connected by railcar coupler assemblies 50. The railcar coupler assemblies 50 can be mounted within a yoke 30, which can be secured at each end of the railway cars in center sills 40. The center sills 40 can form part of the railcars 10, 20.
FIG. 1B shows a perspective view of a railcar coupler assembly 50. The railcar coupler assembly 50 is shown in a locked position and is configured to connect to another railcar coupler assembly. A Type F coupler head is illustrated in the accompanying Figs. However, the railway car coupler may be any known type of coupler. For example, the railway car coupler assembly 50 may be part of a Type E coupler, a Type H tightlock coupler, a Type EF coupler, or any other type of coupler.
As shown in FIG. 1B, a coupler body 100 can include a shank 106 and a coupler head 102. The coupler head 102 includes a guard arm 142 on which side can be referred to as the guard arm side of the coupler head 102. As shown in FIG. 1B, a knuckle 108 is received on the other side of the coupler head 102 from the guard arm 142, which can be referred to as the knuckle side of the coupler head 102. In addition, a front face 144 is located between the knuckle side and the guard arm side of the coupler head 102.
In the coupler head 102 lies a cavity 104, extending into the coupler head 102, which is configured to receive the knuckle 108 and a thrower 110 (as shown in FIG. 2A), which is configured to move the knuckle 108 from a locked position to an unlocked position. The cavity 104 also receives a lock 112 that can be configured to lock the knuckle 108 in a locked position and an unlocked position.
The knuckle 108 is shown in various views in the Figs. FIGS. 1B, 2A, 3, and 4 show differing perspective and cross-sectional views of the coupler body 100 with the knuckle 108 in the locked position, and FIG. 2B shows a front perspective view of an example knuckle 108. As shown in FIG. 2B, the knuckle 108 can include a nose 116, a tail 118, a flag hole 170, and a pin hole 172. The knuckle 108 is configured to engage a correspondingly shaped knuckle on an adjacent railcar to join two railcars as depicted in FIG. 1A. Also, the nose 116, which is disposed transversely inwardly of pin 114 as seen in FIG. 1B, is configured to engage a knuckle on an adjacent railcar.
As shown in FIG. 1B, the knuckle 108 can be pivotally connected to the coupler head 102 by a vertical pin 114, which extends through the pin hole 172. As discussed in more detail below, the knuckle 108 is configured to rotate about the axis of the vertical pin 114 to move from the locked position to the unlocked position and from the unlocked position to the locked position.
The knuckle 108 is limited in its motion in the coupler body 100. As is shown in FIGS. 2A and 2B, the knuckle 108 can also include a tail stop 168 and a lockface 180, which maintain the position of the knuckle 108 in the coupler body 100 in the locked position. As can be seen in FIG. 2A, for example, when in the locked position, in buff (compression) the knuckle tail stop 168 contacts up against the corresponding contact point 182 on the coupler body 100. Whereas when in draft (tension), the knuckle's lockface 180 contacts the lock 112, which in turn contacts the lock face wall as shown in FIG. 2A, of the coupler body 100. Additionally, as shown in FIG. 2B, the knuckle 108 can be provided with rotational stops 178a, which provide a limit on the amount of rotation of the knuckle 108 in the coupler head 102. For example, in the unlocked position, in draft or as rotated by the thrower 110, the knuckle 108 opens fully and knuckle rotation stops 178a will contact body rotation stops 174 to limit how far the knuckle 108 is permitted to open.
FIG. 3 shows a cross-sectional right side view of the coupler head with the knuckle 108 in the locked position. As is shown in FIG. 3, the knuckle 108 can also include a tail 118, which extends in a rearward direction of the nose 116 when the coupler body 100 is in the locked position. The tail 118 of the knuckle 108 can include an upper knuckle pulling lug 109a and a lower knuckle pulling lug 109b. As discussed herein, the upper knuckle pulling lug 109a and the lower knuckle pulling lug 109b are configured to engage a top pulling lug 130a and a bottom pulling lug 130b of the coupler head 102 body when the knuckle 108 is in the locked position.
FIG. 4 shows a top cross-sectional view of the coupler head 102, which extends through the knuckle 108, and again shows the knuckle 108 in the locked position. As shown in FIG. 4, the knuckle 108 can include a thrower pad 129 for engaging the first leg 122a of the thrower 110. The thrower pad 129 allows the thrower 110 to move the knuckle 108 into the unlocked position.
The coupler head 102 is also shown in various Figs. herein. Referring again to FIG. 1B, pivot lugs 132 can be formed on the coupler head 102 to protect the vertical pin 114. As is shown in FIG. 3, in addition to housing the lock 112, the knuckle 108, and the thrower 110, the cavity 104 of the coupler head 102 can also include a top pulling lug 130a and a bottom pulling lug 130b. The pulling lugs 130a and 130b are configured to engage the upper and lower knuckle pulling lugs 109a and 109b of the knuckle 108, when the knuckle 108 is in the locked position. When coupled to an adjacent rail car, the engagement of the pulling lugs 130a, 130b and the knuckle pulling lugs 109a, 109b can allow the pulling lugs 130a and 130b to receive a transfer draft load from the corresponding knuckle of the adjacent coupler on the adjacent railcar.
The pulling lugs 130a and 130b can be designed such that the stresses placed on the coupler head 102 are more balanced across the upper and lower portions of the coupler body 100. In one example, the pulling lugs 130a, 130b are arranged such that the ratio of the stresses between the pulling lugs is less than 3 to 2. In one example, the ratio of the stresses between the top pulling lug 130a and the bottom pulling lug 130b can be approximately 1 to 1. Therefore, the ratio of the stresses can range from about 3:2 to 1:1 between the pulling lugs of the coupler body 100. The balancing of the stresses helps to decrease pulling lug stresses in the pulling lugs 130a, 130b and can assist in increasing the fatigue or wear life of the coupler head 102 and may also assist in increasing the fatigue life and/or wear life of the knuckle 108.
FIG. 5 shows a top cross-sectional view of the coupler head 102. In one example, to provide a uniform and low stress across the top pulling lug 130a, the top pulling lug 130a can be formed with a substantially constant thickness throughout its full width. As is shown in FIG. 5, the top pulling lug 130a has a substantially uniform thickness extending from a first end 135a to a second end 135b to assist in providing a uniform stress distribution across the top pulling lug 130a. Additionally, the top pulling lug 130a has a first end thickness and a second end thickness, and the first end thickness can be substantially equal to the second end thickness.
Also the top pulling lug 130a defines a first surface 131a, which is configured to engage the upper knuckle pulling lug 109a and an opposing second surface 131b. In one example, the first surface 131a and the second surface 131b of the top pulling lug 130a can define a first and second arcuate path where the first and second arcuate path can be substantially parallel in the same plane at a given height. Also as shown in FIG. 5, the first surface 131a arcuate path follows the surface of the top knuckle pulling lug 109a where the top knuckle pulling lug 109a contacts the top pulling lug 130a. Additionally as shown in FIG. 5, the top pulling lug 130a has a first end surface 131c and a second end surface 131d that extend substantially parallel to each other. Also, as is discussed below, the top pulling lug 130a can also be provided with varying thickness in its longitudinal direction such that the bottom cross sectional area is greater than distal cross-sectional area resulting in a partial frusto-conical like shape.
FIG. 6A shows another front perspective view of the coupler head 102, and FIG. 6B shows a cross section of a portion of the coupler head 102 shown in FIG. 6A. In reference to FIGS. 6A and 6B, in one particular example, at a height 1.5 in. above the horizontal centerline plane P1 of the coupler body 100, the top pulling lug 130a can have a substantially constant thickness D1 which can range from 1 in. to 1.75 in., the linear length D2 can range from 3 in. to 4 in., and the depth D3 that extends from a front-most surface of the top pulling lug 130a to a rear-most surface of the top pulling lug 130a can range from 1 in. to 2 in. In one particular example, the top pulling lug 130a can have a substantially constant thickness D1 which is substantially equal to 1.2 in. and overall linear length D2 substantially equal to 3.5 in. or 3.6 in., and a depth D3 substantially equal to 1.9 in. that extends from a front most surface of the top pulling lug 130a to a rearmost surface of the top pulling lug 130a. Also the four corner fillet radii R1 can be substantially equal at the distal end of the top pulling lug 130a and in one example can be 0.3 in. Additionally, the base fillet radii R2 of the top pulling lug 130a can be formed equal and, in one example, can be equal to 0.375 in.
Referring to FIG. 7, as shown by the dashed lines, the top pulling lug 130a defines a top pulling lug contact area A1 where the upper knuckle pulling lug 109a contacts the top pulling lug 130a. In one example, the approximate arc length of the top pulling lug contact area can be approximately equal to 2.9 in., but can range from 2 in. to 3.5 in. In addition, the length D4 of the top pulling lug contact area can range from 3 in. to 3.5 in., and the height D5 of the top pulling lug contact area can be up to 0.75 in. In one example, the total top pulling lug contact area A1 can be in the range of 1.25 in2 to 2 in2. In one particular example, the linear length D4 of the top pulling lug contact area can be approximately equal to 2.8 in., and the height D5 of the top pulling lug contact area can be approximately equal to 0.6 in. resulting in a total top pulling lug contact area A1 of 1.7 in2, however, in certain examples can be greater than 1.0 in2. In one example, the ratio of the length D4 to the height D5 of the top pulling lug 130a can range between 4 to 1 and 5 to 1 and in more particular examples can be greater than 4 to 1 and can be substantially equal to or approximately 5 to 1.
Additionally as shown in FIG. 7, the distal end of the top pulling lug 130a can include equally sized fillets R2 extending inwardly, which in one example can be approximately equal to 0.6 in. Also the height of the top pulling lug 130a can be approximately equal to 1.2 in., and the length of the top pulling lug 130a at its middle section can be approximately equal to 3.6 in. and approximately 4.3 in. at its base section.
FIGS. 7A-7C show various additional perspective views of the top pulling lug 130a. FIG. 7A shows a front bottom view of the top pulling lug 130b. As depicted in FIG. 7A, the non-contact side lock side fillet radius and the base non-contact side fillet radius R3 can be formed equal to each other. In one example, the fillet radius, R3 can range from 0.5 in. to 0.75 in., and in one particular example, the fillet radius R3 can be equal to 0.6 in. FIG. 7B shows another bottom perspective view of the top pulling lug 130a. As shown in FIG. 7B, the fillet radii R5 extending along the non-contact side and the contact side of the top pulling lug 130a can be formed equal and in one example can range from 0.2 in. to 0.4 in. In one particular example, the fillet radii R5 extending along the non-contact side and the contact side of the top pulling lug 130a can equal 0.3 in. Also in one example, the two opposing fillet radii R4 on the contact side and the non-contact side adjacent to the distal horizontal surface of the top pulling lug can be formed approximately equal to 0.4 in.
FIG. 7C shows another bottom view the top pulling lug 130a. As shown in FIG. 7C, the base of the top pulling lug 130a can be formed much larger than the distal end of the pulling lug 130a. As shown in FIG. 7B, the perimeter of the base of the top pulling lug 130a can be substantial in relation to the distal end of the pulling lug 130a. In one example, the perimeter of the base of the pulling lug 130b can be maximized by extending the base of the top pulling lug 130a to the lock hole 186, the upper buffing shoulder 190a, and the upper front face 188a.
Maximizing the perimeter of the base of the top pulling lug 130a also maximizes the base cross-sectional area A5 of the top pulling lug 130a. In one example, the top pulling lug base cross-sectional area A5 can range from 8 in2 to 13 in2. In one particular example, the top pulling lug base cross-sectional area A5 can be approximately 11.2 in2. Additionally, the cross-sectional area adjacent to the distal end A6, which can be the cross-sectional area immediately below the distal fillets and radii, of the top pulling lug 130a can be formed smaller than the top pulling lug base cross-sectional area A5. In one example, the cross-sectional area adjacent to the distal end A6 of the top pulling lug 130b can be formed between 2 in2 and 4 in2, and in one particular example, the cross-sectional area adjacent to the distal end A6 of the top pulling lug 130b can be approximately 3.1 in2. Therefore, the ratio of the top pulling lug 130a base cross-sectional area A5 to the cross-sectional area adjacent to the distal end A6 of the top pulling lug 130a can be in the range of 2 to 5.5 or greater than 2.5 and in one particular example can be 3.6. Also as is shown in FIG. 7C, various dimensions D17-D20 can be maximized to maximize the base area and perimeter of the base area of the top pulling lug 130b. In one particular example, D17 can be approximately 5.3 in., D18 can be approximately 3.6 in., D19 can be approximately 4.7 in., and D20 can be approximately 3.0 in.
FIG. 8 shows a top cross-sectional view of the coupler head 102 showing the bottom pulling lug 130b. As shown in FIG. 8, like the top pulling lug 130a, the bottom pulling lug 130b can be designed to have a size, and in one example, a substantially uniform thickness to provide for a more uniform stress distribution in the coupler head 102. The example bottom pulling lug 130b has a substantially uniform thickness to provide a uniform stress distribution between the top pulling lug 130a and the bottom pulling lug 130b. In one example, the bottom pulling lug 130b has a substantially constant thickness throughout the full width of the bottom pulling lug 130b, which provides a uniform and low stress across the bottom pulling lug 130b.
FIG. 9A shows another front perspective view of the coupler head 102, and FIG. 9B shows a cross section of a portion of the coupler head 102 along the line 9B shown in FIG. 9A. In reference to FIGS. 9A and 9B, in one example, at a height 1.9 in. below the horizontal centerline plane P2 of the coupler body 100, the bottom pulling lug 130b can have a substantially constant thickness D7 ranging from 1.0 to 1.5 in., which extends in a transverse direction and an overall length D8 ranging from 2.25 in. to 3.25 in. and a depth D9 ranging from 2.0 in. to 2.5 in. that extends from a front-most surface of the bottom pulling lug 130b to a rear-most surface of the bottom pulling lug 130b. This can allow more contact with the lower knuckle pulling lug 109b and better distributes stresses when the coupler body 100 is in draft. Additionally, the bottom pulling lug 130b can be formed with a first end 133a and a second end 133b, and the second end 133b can be formed larger than the first end 133a.
In one particular example, the bottom pulling lug 130b has a thickness D7 approximately equal to 1.2 in. and an overall length D8 approximately equal to 2.6 in., and a depth D9 approximately equal to 2.3 in. that extends from a front most surface of the bottom pulling lug 130b to a rearmost surface of the bottom pulling lug 130b. In another example, the bottom pulling lug 130b has a substantially constant thickness D7 approximately equal to 1.2 in. and an overall length D8 approximately equal to 3.2 in., and a depth D9 approximately equal to 2.3 in. that extends from a front most surface of the bottom pulling lug 130b to a rearmost surface of the bottom pulling lug 130b. Also bottom pulling lug 130b can also be provided with varying thicknesses in the longitudinal direction from a bottom surface to the top surface such that the bottom cross-sectional area is greater than the top cross sectional area. In this way, the bottom pulling lug 130b can converge in the longitudinal direction from the bottom area to the distal end.
Also as shown by the dashed lines in FIG. 9C, the bottom pulling lug 130b defines a bottom pulling lug contact area A2 where the lower knuckle pulling lug 109b contacts the bottom pulling lug 130b. In one example, the approximate arc length of the contact area can range from 2 in. to 3 in. and in one particular example the arc length of the contact area can be 2.9 in. In addition, the length D10 of the contact area can range from 1.0 in. to 3.0 in. and, in one particular example, can be 2.8 in. and the height D11 of the contact area can range from 0.25 in. to 1 in. and, in one particular example, can be 0.6 in. resulting in a total contact area A2 ranging from 1.6 in2. In another specific example, the length D10 can be 2.3 in. and the height D11 of the contact area can be 0.75 in. resulting in a total contact area A2 of approximately 1.7 in2. However, the contact patch area can be greater than 1.0 in2 and can range from 0.25 in2 to 2.25 in2. In one example, the ratio of the length D10 to the height Dii of the bottom pulling lug contact patch area can range from 1.3 to 12 and in certain examples can be greater than 3 to 1 and can be substantially equal to or approximately 5 to 1.
As discussed herein, the example pulling lugs 130a, 130b are configured to balance the stresses across the coupler body 100. This can be accomplished, for example, by maintaining substantially equal contact patch areas between the top pulling lug and the bottom pulling lug. In one example, the top pulling lug contact patch area A1 for engaging the upper knuckle pulling lug 109a and the bottom pulling lug contact patch area A2 configured to engage the lower knuckle pulling lug 109a form a ratio of equal to or less than 1.5. In another example, the ratio of the top pulling lug contact patch area A1 to the bottom pulling lug contact patch area A2 can be approximately 1 to 1. This allows the ratio of the stresses between the top pulling lug and the bottom pulling lug to be approximately 1 to 1.
In one example, AAR Grade E cast steel, with a 120 KSI tensile strength and a 100 KSI yield point can be used to form the example coupler body 100. Having more uniform lugs will provide a reduction in stress that is below the ultimate tensile strength of 120 ksi of this material for a given load of 900 Kips. However, it is contemplated that other grades of steel or iron that have similar mechanical properties could also be used. In one example, the stress levels in the top and bottom lugs were approximately 100 Ksi, which is a reduction in stress when compared to prior coupler head designs. In particular, stress levels of 102 Ksi and 106 Ksi in the top and bottom pulling lugs 130a, 130b respectively can be achieved for a given draft load of 900 Kips. For a comparison example, in previous designs, the stress levels for the top and bottom pulling lugs with a 900 Kips draft load condition coupler experiences 316 Ksi and 208 Ksi in the top and bottom pulling lugs respectively. Therefore, a 68% and 49% reduction in the stresses experienced in the top and bottom pulling lugs from prior designs may be achieved. Lower stress levels in the coupler head and will reduce the tendency for the coupler body 100 to crack or fail in service.
FIGS. 10A-10I show another example bottom pulling lug 230b which can be reduced in size to accommodate for thrower removal and provided with various fillets to assist in better distributing the stresses in the coupler body 100. In one example, the fillets can be formed with larger radii to create a bottom pulling lug 230b allows more contact with the lower knuckle pulling lug 109b and better distributes stresses when the coupler body 100 is in draft condition. In addition, the various fillets and size of the bottom pulling lug 230b can accommodate both the removal of the thrower when desired and can also permit the thrower to be positioned in an inverted position without the thrower 110 becoming displaced from the opening 126 that receives the thrower 110.
FIG. 10A shows a front perspective view of the example bottom pulling lug 230b. As shown in FIG. 10A, the bottom pulling lug 230b can taper towards the distal end of the pulling lug. In one example, the bottom pulling lug 230b can have a height D22, which can range from 1.25 to 1.75 and, in one particular example, can be 1.4 in. In one example, a front thrower middle side fillet radius R13 can range from 1 in to 1.25 in. and, in one particular example, can be approximately 1.125 in.
FIG. 10B shows a top perspective view of the example bottom pulling lug 230b. Because the pulling lug tapers toward its distal end, the length of the pulling lug varies from its base to its distal end. The length D23 adjacent to the base, in one example, can range from 3.25 in. to 3.6 in., and in one particular example can be 3.4 in. A length D24 at the bottom pulling lug midsection close to the distal end can range from 2.3 in. to 2.8 and in one particular example can be approximately 2.6 in. A length D25 at the bottom pulling lugs distal end can range from 2.25 in. to 2.6 and in one particular example can be approximately 2.5 in. Also, the bottom pulling lug 230b can have an average thickness D26 ranging from 0.9 in. to 1.4 in. and in one particular example can be 1.2 in. Additionally, FIG. 10C shows a cross-sectional view of the bottom pulling lug 230b. As shown in FIG. 10C, the rear surface 214 of the contact side of the bottom pulling lug 230b can have a greater slope than the front surface 216 of the non-contact side of the bottom pulling lug 230b.
FIG. 10D shows a top perspective view of the example bottom pulling lug 230b. As shown in FIG. 10D, the bottom pulling lug 230b can be provided with a substantial or larger base fillet radius R6, which can be a constant fillet radius. In one example, the base fillet radius R6 can extend around a majority of the bottom pulling lug 230b base and from the drain hole 212, to the opening 186 for the lock, to the bottom buffing shoulder 190b, to the bottom front face 188b, and to the space 220 between the lock hole and the non-contact side face needed to remove the lock, and as limited by the thrower 110 when the knuckle 108 is in the open position. In one example, the bottom fillet radius R6 can range from 0.5 in. to 1.25 in. and, in one particular example, can be 0.7 in.
FIG. 10E shows a right-side perspective view of the example bottom pulling lug 230b. As shown in FIG. 10E, the non-contact side lock side fillet radius and the right base fillet radius can also be formed larger and equal to each other. In one example, the non-contact side lock side fillet radius and the right base fillet radius both shown as R7 can range from 0.2 in. to 0.5 in., and in a particular example, the non-contact side lock side fillet radius and the right base fillet radius R7 can equal 0.3 in.
FIG. 10F shows a top front left perspective view of the example bottom pulling lug 230b. As shown in FIG. 10F, the top non-contact side fillet radius, the top sides fillet radii, and the non-contact side thrower face radius R8 can all be formed larger than in the previous example bottom pulling lug and can all be formed equal to each other. In one example, the top non-contact side fillet radius, the top sides fillet radii, and the non-contact side thrower face radius each shown as R8 can be formed in the range of 0.25 in. to 0.75 in. In one particular example, the top non-contact side fillet radius, the top sides fillet radii, and the non-contact side thrower face radius R8 can be formed equal to 0.5 in.
FIG. 10G shows a rear perspective view of the bottom pulling lug 230b or the contact side of the bottom pulling lug 230b where the bottom pulling lug 230b contacts the lower knuckle pulling lug. As shown in FIG. 10G, the contact side of the bottom pulling lug 230b, can be provided with various fillets as well. However, as shown in FIG. 10G, the fillets can vary in size. For example, the top contact-side fillet radius R9 can be formed slightly larger than the contact-side lock side fillet radius R10 and the contact-side thrower side fillet radius R11. Also the contact-side lock side fillet radius R10 can be formed larger than the contact-side thrower side fillet radius R11. In one example, top contact-side fillet radius R9 the contact-side lock side fillet radius R10, and the contact-side, thrower-side fillet radius R11 can all be formed in the range of 0.1 to 0.5 in. In one particular example, top contact-side fillet radius R9 can be 0.3 in., the contact-side lock side fillet radius R10 can be 0.3 in. and the contact-side thrower side fillet radius R11 can be 0.2 in.
The top contact-side fillet radius R9, the contact-side lock side fillet radius R10, and the contact-side thrower side fillet radius R11 can form a substantially continuous fillet radius in the range of 0.1 in. to 0.5 in. that extends along the outer edges of the contact side of the bottom pulling lug, starting at the base of the bottom pulling lug 230b on the lock side or lock side hole 186 and continues up in a substantially vertical direction, then in a substantially horizontal direction, then in a substantially vertical direction and ends at the start of the drain hole 212. The base fillet radius R6 bridges the contact-side, thrower-side fillet radius R1 and the contact-side lock side fillet radius R10. In addition, as shown in FIGS. 10F and 10G, the bottom pulling lug 230b can partially resemble a frusto-conical shape.
FIG. 10H shows a cross sectional view of the bottom pulling lug 230b and the thrower 110. As shown in FIG. 10H, the bottom pulling lug 230b extends underneath the thrower 110. In particular, the larger fillet radii R6, R12 along the base allows for the bottom pulling lug 230b to extend underneath the thrower 110 in the thrower position that the thrower 110 assumes when the knuckle is in the unlocked position. Also as shown in FIG. 10H, the area of material forming the bottom pulling lug 230b that extends underneath the thrower 110 starts from the thrower side of the bottom pulling lug 230b at the base of the bottom pulling lug 230b and extends over a slope starting at the fillet R6 at the base of the bottom pulling lug 230b and ends at an intersection of the fillet R12 at the top of the bottom pulling lug 230b and a vertical tangent 218 intersecting the fillet R12 on the bottom pulling lug 230b.
Also as shown in FIG. 10H, the thrower side of the bottom pulling lug can be provided with the fillet radius R12, which extends from the base fillet radius R6. In one example, the fillet radius R12 can be between 1 in. and 1.5 in., and, in one particular example, can be equal to 1.125 in. Also, in one specific example, the distance D12 that the bottom pulling lug 130b extends underneath the thrower can be 1.2 in.
FIG. 10I shows a top perspective view of the bottom pulling lug 230b. As shown in FIG. 10I, the base of the bottom pulling lug 230b can be formed much larger than the distal end of the pulling lug 230b. This permits the bottom pulling lug 230b to assist in distributing the stresses across the coupler body 100, while also allowing the thrower 110 to be maintained in the coupler body 100 when the coupler body 100 is inverted. As shown in FIG. 10I, the perimeter of the base of the bottom pulling lug 230b can be maximized within the coupler body 100. In one example, the perimeter of the base of the pulling lug 230b can be maximized by extending the base of the pulling lug to the drain hole 212, the lock hole 186, the bottom front face 188b, and the bottom buffing shoulder 190b.
Maximizing the perimeter of the base of the bottom pulling lug 230b also maximizes the base area of the bottom pulling lug 230b. In one example, the bottom pulling lug base cross-sectional area A3 can range from 8 in2 to 12 in2. In one particular example, the bottom pulling lug base cross-sectional area A3 can be approximately 10.3 in2. Additionally, a cross-sectional area adjacent to the distal end A4, which does not include the distal fillets or radii of the bottom pulling lug 230b can be formed smaller than the bottom pulling lug base cross-sectional area. In one example, the area A4 adjacent to the distal end of the bottom pulling lug 230b can be formed between 2 in2 and 4 in2, and in one particular example, the cross-sectional area adjacent to the distal end A4 of the bottom pulling lug 130b can be approximately 3.2 in2. Therefore, the ratio of the bottom pulling lug 230b base area A3 to the area A4 adjacent to the distal end of the bottom pulling lug 230b can be in the range of 2 to 5.5 or greater than 2.5 and in one particular example can be 3.3.
Also as is shown in FIG. 10I, various dimensions D13-D16 can be maximized to maximize the base area and perimeter of the base area of the bottom pulling lug 230b. In one particular example, D13 can be approximately 4.8 in., D14 can be approximately 3 in., D15 can be approximately 4.3 in., and D16 can be approximately 3.7 in.
Referring again to FIGS. 2-4, the thrower 110 is located adjacent to the knuckle 108 in a rearward direction of the coupler head 102. The thrower 110 includes an upper trunnion 124a and a lower trunnion 124b and can be provided with a first leg 122a and an opposing second leg 122b. The lower trunnion 124b is configured to be placed into an opening 126 in the coupler head 102, and a bottom surface of the thrower 110 is configured to rest on a thrower support surface 150 in the coupler head 102. The thrower 110 is configured to move the knuckle 108 from a locked position to an unlocked position. In particular, referring to FIG. 3, the thrower 110 is configured to rotate horizontally about the lower trunnion 124b in the coupler head 102 in a position disposed rearwardly of the pulling lugs 130a and 130b.
Turning now to FIG. 11A, the thrower retainer lug 140 profile provides a bearing surface while the knuckle 108 is rotated open and retains the thrower 110 in the same position when the railcar is moved from an upright position to an inverted position. FIG. 11A shows a top cross-sectional view of the coupler head 102 showing the thrower 110. As shown in FIG. 11A, a thrower retaining lug 140 abuts the upper trunnion 124a and prevents the thrower 110 from becoming displaced from the coupler head 102. As shown in FIG. 11A, the thrower retainer lug 140 overlaps a portion of the top surface of the thrower 110. In particular, as shown in FIG. 11B, the first leg 122a can be provided with a thrower retaining shelf 146. The amount of coupler head thrower retainer lug overlap with the thrower retaining shelf 146 can be configured so the thrower 110 can stay in position when the railcar is moved from its upright position to an inverted position. The thrower retaining shelf 146 can be positioned adjacent to the upper trunnion 124a and acts as a safety mechanism for retaining the thrower 110 in place during the operation of the coupler body 100 in a railcar.
In particular, as shown in FIG. 11B, the thrower retaining lug 140 of the coupler body 100 can be provided with a bottom wall 140a spaced above the thrower retaining shelf 146. The bottom wall 140a of the retainer lug 140 can be configured for engagement with the thrower retaining shelf 146 during unusual upward movement of the thrower 110. This prevents accidental dislodgement of the lower trunnion 124b from the opening 126 of a coupler head 102 during normal operating conditions that may occasionally occur in railway service, for example, when the coupler head 102 is subjected to vertical movements or when the railcar is moved from its upright position to an inverted position when the railcar is dumped. This allows the thrower retainer lug 140 to maintain the thrower 110 in the opening 126 in any orientation of the coupler body 100. In one example, as shown in FIG. 11C, the amount of overlap D21 between the thrower 110 and the thrower retaining lug 140 can be greater than or equal to 0.4 in. and in one particular example can be 0.6 in. in the position that the thrower 110 assumes when the knuckle is in the unlocked position. Also, the overlapping area A7 between the thrower 110 and the thrower retaining lug 140 can be greater than or equal to 0.4 in2 and in one particular example can be approximately equal to 0.6 in.2
Certain features can affect the amount of overlap needed between the thrower retaining lug 140 and thrower retaining shelf 146, such as, the diameter of the opening 126 for receiving the lower trunnion 124b of the thrower 110 and the lower trunnion 124b diameter. Also the knuckle 108 rotation stops 178a and the coupler head 102 rotation stops (e.g. coupler body rotation stops 174), the knuckle 108 as centered by the vertical pin 114 relative to the knuckle pin hole 172, and the coupler head slot for receiving the vertical pin 114 may also affect the amount of overlap of the thrower 110 and the thrower retaining lug 140. In particular, the amount of overlap of the thrower 110 and the thrower retaining lug 140 can be dictated or controlled by two operations of the coupler body 100: (1) when the knuckle 108 is open and bottomed out by the knuckle rotation stops 178a of the knuckle 108 and the coupler head 102 rotation stops 174 and when the knuckle 108 is pulled open at the pulling face, which creates overlap between the thrower retaining lug 140 and (2) when the knuckle is removed the thrower 110 is positioned up against the side of the bottom pulling lug 130b for moving the thrower 110 and the thrower retainer lug 140 out of alignment and for lifting the thrower out of the opening 126 (e.g. the thrower has to be tilted in a forward direction and lifted simultaneously for removal from the coupler head 102).
Also, when the knuckle 108 is open, adequate overlap between the coupler head thrower retaining lug 140 and the thrower retaining shelf 146 needs to be maintained to accommodate manufacturing tolerances of the thrower 110 and in order to accommodate for the relative wear of the parts of the coupler body 100, for example, the wear of the thrower retainer lug 140, the thrower 110, the vertical pin 114, the pin hole 172, and the knuckle rotation stops 178a relative to each other.
Additionally, the thrower retainer lug 140 is configured to also allow the thrower 110 to be removed with ease and without any interference from the retaining lug 140 when the thrower 110 is fully opened and against the bottom pulling lug 130b (i.e. with the knuckle removed). Likewise, in order to allow the thrower 110 to fully seat in the opening 126 for receiving the lower trunnion 124b, the thrower retaining lug 140 can be configured to allow the thrower 110 to be installed. This also allows for throwers to be interchanged with the coupler body 100 and allows the thrower retaining lug 140 to maintain the thrower 110 in position during use of the coupler body 100.
Also the size of the thrower retainer lug 140 in conjunction with the bottom pulling lug 130b also allows the thrower 110 to be capable of being installed and removed from the coupler head 102. For instance, with the knuckle 108 removed, the bottom pulling lug 130b establishes and limits the amount of rotation of the thrower 110, but still allows the thrower retainer shelf 146 to be free from, and having no overlap between the thrower retaining lug 140 and the thrower retaining shelf 146, thus allowing the thrower 110 to be lifted up and removed or installed.
Also, as shown in FIGS. 11A-11D the thrower retaining lug 140 can be configured to guide the upper trunnion 124a at a contact portion of the outer circumference through the motion of the thrower 110. This helps maintain the thrower 110 in the same position as the thrower 110 is rotated from the locked position to the unlocked position. The contact portion of the outer circumference can be less than 90 degrees, and can be approximately 30 degrees to 75 degrees. In one specific example, the contact portion of the outer circumference can be approximately 63 degrees.
The geometry and size of the thrower retaining lug 140 allows the bottom pulling lug 130b to be increased in size, which may result in decreasing the pulling lug stress and can help to increase the fatigue life of the coupler head 102. Also as shown in FIG. 11D, the thrower retaining lug 140 can be provided with a first vertical surface 140b and a second vertical surface 140c. The first vertical surface 140b and the second vertical surface 140c can form an angle α less than 90 degrees. In one example, the angle α can be in between 30 and 75 degrees, and in one particular example the angle α can be approximately less than 70 degrees or approximately equal to 63 degrees.
FIG. 11E shows a side cross-sectional view of the example thrower retainer lug 140 and shows the dimensional relationship between the thrower retaining lug 140 and the thrower support surface 150 and the parting line which defines plane P3. In one example, the bottom surface 140a of the thrower retaining lug 140 can be located at a distance D27 of approximately 1.0 in. from the plane P3 and a distance D28 of 1.2 in. from the thrower support surface 150.
A vertical cross-sectional view of the coupler body 100 is depicted in FIG. 12, which shows the lock 112. The lock 112 is configured to maintain the knuckle 108 in either a locked position or an unlocked position regardless of the orientation of the coupler body 100. The lock 112 can include a head 160, a rotor 164, and a leg 158.
As shown in FIG. 12, the lock 112 can be connected to a locklift assembly 184. For a Type F coupler, the locklift assembly 184 can include a lever 154 and toggle 156. A hook 152 can be connected to the lever 154, which is connected to the toggle 156. The toggle 156 can include a lock slot trunnion 162. The trunnion 162 is located in a slot 166 formed in the leg 158 of the lock 112. The coupler head 102 cavity 104 also defines a lock chamber 176 for receiving the head 160 of the lock 112. Also within the cavity 104, the coupler head 102 can also be provided with a knuckle side lock guide 148.
The knuckle slide lock guide 148 is configured to act as a vertical guide for the lock 112. In particular, as shown in FIG. 13, the knuckle slide lock guide 148 provides a vertical guide for the head 160 of the lock 112. Since the knuckle slide lock guide 148 is located adjacent to the thrower 110, when installed, the height of the knuckle side lock guide 148 can also be configured so as to provide adequate clearance for the thrower 110 to be installed and removed. In one particular example, the knuckle side lock guide 148 can be positioned at or more than 2.75 in. and in one particular example can be more than 3.0 in., D29, above the thrower support surface 150 on the coupler head 102.
FIG. 14A shows the coupler in an unlocked position and FIG. 14B shows the coupler in a locked position. To operate the coupler assembly 50 to connect adjacent railcars, as the railcar is moved toward an adjacent railcar, the knuckle 108, in the opened position shown in FIG. 14A, will contact an adjacent guard arm of a coupler located on the adjacent railcar. In connecting the railcars, both the knuckle 108 of the coupler assembly 50 and the knuckle on an adjacent railcar may each rotate inward such that each of the two knuckles can be locked into place within their respective coupler heads such that the knuckles are in the locked position as is shown in FIG. 14B. During the joining process, as is shown in relation to FIGS. 14A and 14B, when the knuckles are rotated, the lock 112 is actuated and configured to slide downward within the cavity of each coupler head to lock the knuckle in place to and join the two couplers together.
To unlock the F coupler, movement of the rotor 164, which can be rotated by an uncoupling lever (not shown) causes the hook 152 and the lever 154 to rotate and through the articulation of the lever 154 and the toggle 156, the lock slot trunnion 162 moves within slot 166 in the lock leg 158 and causes the leg 158 and the head 160 to move from the locked position to the unlocked position. Thus, the lock 112 is engaged and caused to leave its locked position and move to its knuckle-throwing position shown in FIG. 14A. The lock 112 is configured to slide up into the lock chamber 176 such that the head 160 and the leg 158 rotate. The head 160 and the leg 158 are rotated into contact with the thrower 110. Upon engagement with the thrower 110, the rotation of the lock head 160 and the lock leg 158 causes the thrower 110 to pivot and throw the knuckle 108 as is shown in FIG. 14A.
In particular, the second leg 122b of the thrower 110 is configured to be engaged by the lock leg 158 of the lock 112 in the coupler head 102, such that during the unlocking cycle of the coupler assembly 50, the lock 112 moves the second leg 122b of the thrower 110 thereby moving the first leg 122a of the thrower 110 about the lower trunnion 124b against the knuckle 108. Specifically, as the lock 112 is raised out of its locking engagement with knuckle tail 118, the leg 158 of the lock 112 is moved rearwardly against the second leg 122b of the thrower 110 causing the thrower 110 to pivot about the trunnion 124, such that the first leg 122a, through engagement with the thrower pad 129 of the knuckle 108 rotates the knuckle 108 to an unlocked position depicted in FIG. 14A.
Aspects in this disclosure can help to better distribute the load and interaction between the pulling lugs and the knuckle pulling lugs, which may result in coupler bodies and knuckles having less wear and improved fatigue lives as further explained and illustrated below in relation to FIGS. 15A-15C. FIGS. 15A-15C show the main forces or loads acting on the top and bottom pulling lugs 130a, 130b in the coupler body 100 and how the main forces or loads acting on the top and bottom pulling lugs 130a, 130b can be balanced.
FIG. 15A represents the coupler body 100 in draft condition and shows the loads that the coupler body 100 receives from the knuckle 108. When the coupler body 100 is in the draft condition (e.g. when the coupler body 100 is being pulled), as discussed herein, the load of the knuckle 108 is transferred to the coupler body 100 through the top and bottom pulling lugs 130a, 130b. As shown in FIG. 15A, in one example, the coupler body 100 is designed such that the load represented by arrow 200 transferred to the coupler body 100 is evenly distributed amongst the top and bottom pulling lugs 130a, 130b when engaged by the knuckle as represented by arrows 202, such that the loads 202 are equal.
15B represents a knuckle 108 in the draft condition, and the loads the knuckle 108 receives from the coupler body 100. The arrows 208 and 210 illustrate the loads acting on the knuckle 108 from the coupler body 100. Arrows 210 represent the balanced reactive load of the coupler body pulling lugs 130a, 130b on the upper knuckle pulling lug 109a and the lower knuckle pulling lug 109b, where arrows 210 represent an equally distributed load to the upper knuckle pulling lug 109a and the lower pulling lug 109b.
FIG. 15C shows the reaction loads to the knuckle 108 on the coupler body 100 when the coupler body 100 is in the draft condition. The coupler body 100 reaction loads from the knuckle are shown by arrows 206. The top and bottom pulling lugs 130a, 130b assist in spitting the reactive load 204 from the knuckle and dividing the reactive load 204 into equal loads 206.
As discussed herein, the above examples assist in more evenly distributing the stresses in the coupler body top pulling lug and the coupler body bottom pulling lug as the loads are transferred from the knuckle. As discussed, the coupler body top pulling lug can be configured to engage the upper knuckle pulling lug, and the coupler body bottom pulling lug can be configured to engage the lower knuckle pulling lug to receive loads from the knuckle. The coupler body top pulling lug and the bottom pulling lug can be configured to balance the loads transferred to the coupler head such that the loads and corresponding stresses between the upper pulling lug and the bottom pulling lug are substantially equal. Also the coupler body top pulling lug and the coupler body bottom pulling lug can have substantially equal strengths and deformation rates to evenly distribute or receive loads from the upper knuckle pulling lug and the lower knuckle pulling lug to maintain the loads and stresses on the upper knuckle pulling lug and the lower knuckle substantially balanced.
In particular, the coupler body top pulling lug 130a and the bottom pulling lug 130b are designed for equal strength such that the deformation of the top pulling lug and the bottom pulling lug under a draft load, transferred through the upper knuckle pulling lug and the lower knuckle pulling lug, are substantially equal. For example, FIG. 16 illustrates the stresses acting on a coupler body during draft and shows almost equal deformation of the coupler body upper pulling lug and coupler body lower pulling lug under 900,000 lbs. of draft load. The equal strength of the coupler body top pulling lug and the bottom pulling lug is a product of unique dimensional combination of root cross sectional area of the top pulling lug and the bottom pulling lug, the contact area with the respective knuckle pulling lugs, the side-to-side length of the top pulling lug and the bottom pulling lug, and the height of the top pulling lug and the bottom pulling lug.
II. Features of Example Railcar Couplers According to Examples of the Disclosure
In one example, a railcar coupler can include a knuckle having an upper knuckle pulling lug and a lower knuckle pulling lug. A pin can be configured to extend through the knuckle, and the knuckle can be configured to rotate about the pin. The railcar coupler can also include a lock comprising a head and a leg which can be configured to maintain the knuckle in either a locked position or an unlocked position and a lock lift assembly that can be configured to move the lock from a locked position to an unlocked position.
The railcar coupler may also include a thrower configured to move the knuckle from a locked position to an unlocked position and a thrower retaining lug. The thrower may include a lower trunnion and an upper trunnion, and the upper trunnion can define a pivot for the thrower. The upper trunnion can define an outer circumference. The thrower retaining lug is configured to guide the upper trunnion at a contact portion of the outer circumference through a range of motion of the thrower, and the contact portion of the outer circumference can be less than 90 degrees, and, in other examples, can be less than 60 degrees. The thrower retaining lug and the thrower may define an overlapping area such that the thrower is maintained in position in the coupler head regardless of the orientation of the coupler head including when the coupler head is in an upright position and when the coupler head is in an inverted position regardless if the knuckle is an open or closed position. An overlapping distance between the thrower retaining lug and the thrower can be approximately 0.4 in. or more and the overlapping area can be approximately 0.4 in2 or more. The thrower retaining lug can include a first surface and a second surface, and the first surface and the second surface can form an angle of less than 70°.
The railcar coupler may also include a coupler head having a shank and a head portion. The head portion can define a cavity for receiving the knuckle, the thrower, and the lock. The cavity may include a top pulling lug, a bottom pulling lug, a knuckle side lock guide, and the thrower retaining lug. The top pulling lug can be configured to engage the upper knuckle pulling lug, and the bottom pulling lug can be configured to engage the lower knuckle pulling lug to receive loads from the knuckle and can be configured to help balance the loads from the upper knuckle pulling lug and the lower knuckle pulling lug. During operation of the railcar coupler a ratio of the loads between the coupler body top pulling lug and the coupler body bottom pulling lug can be approximately equal to or less than 1.5. The top pulling lug and the bottom pulling lug can be configured to balance the loads received from the knuckle such that the loads and corresponding stresses between the upper pulling lug and the bottom pulling lug are substantially equal. The top pulling lug and the bottom pulling lug can have substantially equal strengths and deformation rates to evenly distribute or receive loads from the upper knuckle pulling lug and the lower knuckle pulling lug to maintain the loads and stresses on the upper knuckle pulling lug and the lower knuckle substantially balanced. Additionally, the upper knuckle pulling lug and the lower knuckle pulling lug can be configured to receive equal reacting loads from the coupler body top pulling lug and the coupler body bottom pulling lug to help increase fatigue lives of the coupler body and the knuckle.
The top pulling lug can include a non-contact side and a contact side, and the top pulling lug can have a substantially uniform thickness from the non-contact side to the contact side. The top pulling lug can define a first end thickness and a second end thickness, and the first end thickness can be substantially equal to the second end thickness. The non-contact side and the contact side can define first and second arcuate paths in a common plane at a predetermined height, and the first and second arcuate paths can be substantially parallel. The top pulling lug can define a top pulling lug length and the bottom pulling lug can define a bottom pulling lug length. The ratio of the top pulling lug length to the bottom pulling lug length can be less than or equal to 1.3.
The top pulling lug can also have a top pulling lug base defining a cross-sectional area larger than a top pulling lug cross-sectional area adjacent to a distal end. In one example, the ratio of the top pulling lug base cross-sectional area to the top pulling lug cross-sectional area adjacent to the distal end can be greater than 2. The bottom pulling lug can have a bottom pulling lug base defining a cross-sectional area larger than a bottom pulling lug cross-sectional area adjacent to a distal end, and in one example, the ratio of the bottom pulling lug base cross-sectional area to the bottom pulling lug cross-sectional area adjacent to the distal end can be greater than 2. In another example, the ratio of the top pulling lug base cross-sectional area to the top pulling lug cross-sectional area adjacent to the distal end can be greater than 2.5. In another example, the bottom pulling lug can have a bottom pulling lug base defining a cross-sectional area larger than a bottom pulling lug cross-sectional area adjacent to a distal end, and the ratio of the bottom pulling lug base cross-sectional area to the bottom pulling lug cross-sectional area adjacent to a distal end can be greater than 2.5. The bottom pulling lug base cross-sectional area can range from 8 in2 to 12.0 in2. In one example, the top pulling lug base cross-sectional area can be approximately 10.5 in2 to 11.5 in2, and the top pulling lug cross-sectional area adjacent to the distal end can be approximately 2.5 in2 to 3.5 in2. The bottom pulling lug base cross-sectional area can be approximately 9.5 in2 to 10.5 in2, and the bottom pulling lug cross-sectional area adjacent to the distal end is approximately 2.5 in2 to 3.5 in2.
In another example, the coupler body bottom pulling lug can have a bottom pulling lug cross-sectional area at the base, and the coupler body top pulling lug can have a top pulling lug cross-sectional area at the base, and a ratio of the top pulling lug cross-sectional area to the bottom pulling lug cross-sectional area can be less than 1.5. In another example, the bottom pulling lug cross-sectional area can be equal to the top pulling lug cross-sectional area.
The bottom pulling lug can converge in the longitudinal direction from the base area to the distal end. A base fillet radius can extend around a majority of the bottom pulling lug base and can extend to a drain hole, an opening for the lock, a bottom buffing shoulder, and a bottom front face.
A contact side of the bottom pulling lug contacting the lower knuckle pulling lug can define a top contact-side fillet radius, a contact-side lock side fillet radius, and a contact-side, thrower side-fillet radius that form a substantially continuous fillet radius in the range of 0.1-0.5 in. extending along the contact side along outer edges of the bottom pulling lug, which starts at the base of the bottom pulling lug on a lock side and continues up in a substantially vertical direction, then in a substantially horizontal direction, then in a substantially vertical direction and ends at the start of a drain hole, and a substantially continuous fillet radius at the base of the bottom pulling lug that bridges the contact-side lock-side fillet radius and the contact-side thrower-side fillet radius
The drain hole can form a substantially continuous fillet radius bridging the contact-side thrower-side fillet radius and a base fillet radius of the bottom pulling lug.
The thrower can be configured to be removed from the coupler head without interference from the bottom pulling lug when aligned up against the bottom pulling lug, the thrower lug and the knuckle side lock guide. In one example, the knuckle side lock guide is positioned about more than 2.75 in. above a thrower support surface on the coupler head.
When the railcar coupler is in the unlocked position, the thrower can overlap with the bottom pulling lug such that the thrower extends over the bottom pulling lug at an area starting from a thrower side of the bottom pulling lug at a base of the bottom pulling lug and extending over a slope starting at a first fillet at the base of the bottom pulling lug and ending at an intersection of a second fillet adjacent the top of the bottom pulling lug and a vertical tangent of the bottom pulling lug. The first fillet radius can be approximately 0.7 in. and the second fillet radius can be approximately 1.125 in.
In one example, during the operation of the railcar coupler a ratio of the stresses between the top pulling lug and the bottom pulling lug can be approximately equal to or less than 1.5. In one example, a stress in the top pulling and a stress in the bottom pulling lug are approximately 120 Ksi in a 900 Kips draft condition.
The top pulling lug can define a top pulling lug contact patch area for contacting the upper knuckle pulling lug, and the bottom pulling lug can define a bottom pulling lug contact patch area configured to engage the lower knuckle pulling lug. The top pulling lug contact patch area for contacting the upper knuckle pulling lug which can be greater than or equal to 1.0 in2. In one example, the bottom pulling lug contact patch area is approximately 1.6 in2. A ratio of the top pulling lug contact patch area to the bottom pulling lug contact patch area can be equal to or less than 1.5. In another example, the ratio of the top pulling lug contact patch area to the bottom pulling lug contact patch area can be approximately 1 to 1. In one example, the ratio of the length to the height of the bottom pulling lug contact patch area can be approximately 5 to 1.
The present disclosure is disclosed above and in the accompanying drawings with reference to a variety of examples. The purpose served by the disclosure, however, is to provide examples of the various features and concepts related to the disclosure, not to limit the scope of the invention. One skilled in the relevant art will recognize that numerous variations and modifications may be made to the examples described above without departing from the scope of the present disclosure.