This invention disclosure generally relates to a railcar draft gear assembly and, more specifically, to a railcar draft gear assembly utilizing a spring assembly comprised of a stack of elastomeric pads and an elongated guide rod for maintaining the stacked pads in general alignment relative to each other and relative to a longitudinal axis of the draft gear assembly whereby optimizing spring performance.
A railroad freight car draft gear assembly has been used for years at opposite ends of a railcar to absorb and cushion impact forces directed against and to the railcar. Most railcar draft gear assemblies include a housing having an inner tapered bore at an open end, an elongated spring arranged within the housing, and a friction clutch assembly including a series of friction members along with a wedge or actuator arranged in the tapered bore of the housing and movable against the spring upon compression of the draft gear assembly. The wedge is arranged in operable combination with the friction members such that impact blows directed against the wedge are transferred axially to the spring and radially to the housing. A spring seat can be arranged between an end portion of each friction member and the spring.
Recently, elastomeric materials have been used and accepted as replacements for steel springs. One elastomeric spring assembly offering beneficial results is disclosed in U.S. Pat. No. 5,351,844 to R. A. Carlstedt and includes multiple elastomeric spring units stacked in axial relation relative to each other. Each spring unit of the spring assembly includes an elastomer pad sandwiched between two metal plates. The metal plates are bonded or otherwise secured to opposed faces of the elastomer pad. Amongst other advantages, the metal plates serve to limit snaking and/or buckling problems while furthermore serving to center the elastomeric spring assembly relative to the draft gear housing. Such a spring assembly has been successfully used for years in combination with railcar draft gears.
In one form, the draft gear housing is provided with an elongated opening between a closed end and an open end of the housing and extending along a sidewall of the draft gear housing to allow the spring units to be inserted in a direction generally normal to a longitudinal axis of the draft gear assembly and stacked relative to each other within the draft gear housing. Maintaining the spring units in alignment relative to each other and generally centered relative to the longitudinal axis of the draft gear assembly is an important consideration when designing a railcar draft gear assembly. Moreover, maintaining the elongated spring assembly in relatively centered relationship relative to the longitudinal axis of the draft gear is also important to overall performance of the draft gear assembly.
The draft gear assembly is arranged within a pocket in the railcar and extends generally parallel to a longitudinal axis of the railcar. Accordingly, when the railcar travels through a curve, the railcar tends to impart unequal forces to the draft gear assembly. Such unequal forces applied to the draft gear assembly are also frequently transferred to the elongated spring assembly tending for the individual spring units to become misaligned relative to each other and relative to the longitudinal axis of the draft gear. As mentioned, displacement of the individual spring units relative to each other and relative to the longitudinal center of the draft gear assembly can result in undesirable overall performance of the railcar draft gear assembly.
Railcar manufacturers and suppliers for supplying such railcar manufacturers are continually seeking methods and ways of reducing the manufacturing costs of railcars and the components used to build such railcars without having to sacrifice performance and quality. When considering costs savings in connection with a draft gear assembly, however, the available options are few. First, the size of the draft gear housing cannot be changed without adversely affecting the relationship of the fixed size pocket in a railcar centersill wherein the draft gear assembly is accommodated. Second, and with the size of the draft gear assembly being standardized or fixed, the amount of steel used to form the draft gear housing has already been minimized as with openings and voids wherever possible. Exacerbating these design challenges is the fact that speeds of railcars are steadily increasing, thus, adding to the impact loads imparted to the draft gear assembly during railcar operation. As such, the size of the spring assembly used to absorb, dissipate and return energy imparted thereto during railcar operations cannot be reduced without adversely affecting performance and operation of the draft gear assembly.
Thus, there remains a continuing need and desire to provide a railcar draft gear assembly which is economically designed to have high shock absorbing capacities while offering enhanced performance by maintaining the spring units of the elongated spring assembly in aligned relation relative to each other and relative to the longitudinal axis of the draft gear assembly.
In accordance with one aspect there is provided a railcar draft gear assembly having a longitudinal axis and including a housing having a closed end, an open end; and wall structure extending between the ends, with the housing wall structure defining a spring chamber and an opening in a side thereof. A friction clutch assembly is arranged in operable combination with the open end of the housing and includes a wedge member. A spring seat is guided for reciprocal movements within the spring chamber in response to forces being exerted upon the draft gear assembly. The spring seat has a generally centralized bore which opens to opposed surfaces thereof. An elongated spring is operably disposed within and between the closed end of the housing and the clutch assembly for absorbing, dissipating and returning energy imparted to the draft gear assembly. The spring includes a series of axially stacked elastomeric pads which are inserted into the spring chamber through the opening in the side of the housing in a direction generally normal to the longitudinal axis of the draft gear assembly. Each elastomeric pad has a generally centralized bore opening to opposed surfaces of the pad. An elongated guide rod, having an axis arranged generally coaxial with the longitudinal axis of the draft gear, is insertable endwise through the spring seat and pads after the spring seat and pads are inserted into the spring chamber for maintaining general alignment of the pads relative to each other and relative to the longitudinal axis of the draft gear assembly. Structure, arranged within the housing, is provided for inhibiting endwise displacement of the guide rod during operation of the draft gear assembly.
In one form, the friction clutch assembly further includes a series of friction members arranged in equally spaced relation relative to each other and in operable combination with the wedge member. Preferably, the open end of the housing defines a series of inner angled longitudinally extended surfaces extending from the open end of the housing, with each inner angled surface on the housing combining with an outer angled surface on each friction member to define an angled surface therebetween.
In one embodiment, the structure for inhibiting endwise displacement of the guide rod during operation of the draft gear assembly includes interlocking instrumentalities provided on the elongated guide rod and the housing. In another form, the structure for inhibiting endwise displacement of the guide rod includes a latching mechanism selectively operable between locked and unlocked conditions in response to rotation of the elongated guide rod about the axis thereof. In one form, such a latching mechanism includes a latch secured toward a first end of and rotatable with the elongated guide rod, and a keeper carried by the housing and selectively arranged in operable combination with the latch.
In this later embodiment, the guide rod is configured toward a second end to facilitate rotation of the guide rod about the axis thereof. Moreover, the structure for inhibiting endwise displacement of the guide rod during operation of the draft gear assembly further includes an apparatus arranged toward the second end of the elongated guide rod for inhibiting inadvertent rotation of the guide rod about the axis thereof whereby maintaining the latch and keeper in position relative to each other to inhibit endwise displacement of the guide rod after the guide rod is inserted through the pads.
In another form, the latching mechanism includes a latch toward a first end of and rotatable with the guide rod, and a keeper provided on a plate disposed between the closed end of the housing and the elastomeric pad of the spring disposed closest to the closed end of the housing. In this embodiment, the guide rod is configured toward a second end to facilitate rotation of guide rod about the axis thereof. The structure for inhibiting endwise displacement of the guide rod during operation of the draft gear assembly can furthermore include an apparatus arranged toward the second end of the elongated guide rod for inhabiting inadvertent rotation of the guide rod about its axis whereby maintaining the latch and keeping in position relative to each other to inhibit endwise displacement of the guide rod after it is inserted through the pads.
According to another aspect, there is provided a railcar draft gear assembly having a longitudinal axis and includes an axially elongated metal housing having a closed end, an open end; and wall structure extending between the ends, with the wall structure defining a spring chamber and an opening in a side thereof: A friction clutch assembly, including an actuator extending at least partially beyond the open end of the housing and a series of equi-distantly spaced friction members, is arranged in operable combination with and between the actuator and the open end of the housing. A spring seat is disposed in the housing for guided reciprocatory movements and extends generally normal to the longitudinal axis of the draft gear assembly. The spring seat has a generally centralized bore opening to opposed surfaces thereof. An elongated spring is operably disposed within and between the closed end of the housing and the spring seat for absorbing, dissipating and returning energy imparted to the draft gear assembly. The spring includes a series of axially stacked elastomeric pads which are inserted into the chamber through the opening in the side of the housing in a direction generally normal to the longitudinal axis of the draft gear assembly. Each elastomeric pad has a generally centralized bore opening to opposed surfaces of the pad. An elongated guide rod is insertable endwise through the spring seat and pads after they are inserted into and arranged in stacked relationship in the spring chamber. Structure, arranged within the housing, is provided for inhibiting endwise displacement of the guide rod during operation of the draft gear assembly.
Preferably, the friction members of the friction clutch assembly are arranged in equally spaced relation relative to each other. In one embodiment, the open end of the housing defines a series of inner angled longitudinally extended surfaces extending from the open end of the housing, with one inner angled surface on the housing combining with an outer angled surface on each friction member to define an angled surface therebetween.
In a preferred form, the structure for inhibiting endwise displacement of the guide rod during operation of the draft gear assembly includes interlocking instrumentalities provided on the elongated guide rod and the housing. In one form, such interlocking instrumentalities includes a latching mechanism selectively operable between locked and unlocked conditions in response to rotation of the elongated guide rod about the axis thereof. In one form, such a latching mechanism includes a latch secured toward a first end of and rotatable with the elongated guide rod, and a keeper carried by the housing and selectively arranged in operable combination with the latch. In this later embodiment, the guide rod is preferably configured toward a second end to facilitate rotation of guide rod about the axis thereof.
Preferably, the structure for inhibiting endwise displacement of the guide rod during operation of the draft gear assembly further includes an apparatus arranged toward the second end of the guide rod for inhibiting inadvertent rotation of the guide rod about the axis thereof. As such, the latch and keeper are releasably maintained in position relative to each other to inhibit endwise displacement of the guide rod after the guide rod is inserted through the pads.
Alternatively, the latching mechanism includes a latch secured toward a first end of and rotatable with the elongated guide rod. In this embodiment, a keeper is provided on a plate disposed between the closed end of the housing and the elastomeric pad of the spring disposed closest to the closed end of the housing. In this later embodiment, the guide rod is configured toward a second end to facilitate rotation of the guide rod about the axis thereof. The structure for inhibiting endwise displacement of the guide rod during operation of the draft gear assembly further includes an apparatus arranged toward the second end of the elongated guide rod for inhibiting inadvertent rotation of the guide rod about the axis thereof whereby releasably maintaining the latch and keeper in position relative to each other to inhibit endwise displacement of the guide rod after the guide rod is inserted through the pads.
According to another aspect there is provided a method of assembling a railcar draft gear assembly having a longitudinal axis and including a housing with a closed end, an open end, and wall structure extending between the closed and open ends so as to define a chamber, with the housing wall structure defining an opening having a closed margin in the side of the housing. The method of assembling a railcar draft gear assembly includes the steps of: inserting a spring seat through the housing opening and into the chamber in a direction extending generally normal to the longitudinal axis of the draft gear assembly, with the spring seat defining a generally centralized bore opening to opposed surfaces thereof. Next, the spring seat is held in a releasably raised position relative to the opening defined by the housing. Then, a series of elastomeric pads are inserted into the chamber in a direction extending generally normal to the longitudinal axis of the draft gear assembly such that the pads are stacked one upon the other to define a spring between the closed end of the housing and the spring seat, with each pad having a generally centralized bore opening to opposed surfaces of the pad. The spring seat is then released from its raised position relative to the opening defined by the housing. The spring is compressed. An elongated guide rod is passed through the centralized bore in the spring seat and though the generally centralized bore in each of the pads so as to maintain general alignment of the pads relative to each other and relative to the longitudinal axis of the draft gear assembly. The guide rod has an elongated axis. Compression of the spring is released so as to allow the spring to push the spring seat upwardly against the housing. The end of the guide rod is secured within the housing and in general alignment with the longitudinal axis of the draft gear assembly so as to maintain general alignment of the pads relative to each other and relative to the longitudinal axis of the draft gear assembly while inhibiting endwise displacement of the guide rod relative to the housing during operation of the draft gear assembly. Then, a friction clutch assembly is pressed into operable combination with the open end of the housing until an actuator of the friction clutch assembly is captured by the housing.
Preferably, the method further involves the step of: aligning the pads inserted into the chamber relative to each other before compressing the spring.
After the spring seat is initially released, the step of compressing the spring preferably involves the further steps of: a) initially compressing a first set of elastomeric pads within the housing; b) holding the first set of elastomeric pads axially compressed within the housing to allow at least one additional elastomeric pad to be stacked upon the first set of elastomeric pads; c) again raising the spring seat to a position relative to the opening in the side of the housing whereby allowing at least one additional elastomeric pad to be inserted into the spring chamber in a direction extending generally normal to the longitudinal axis of the draft gear assembly and in generally axially aligned and stacked relationship with the first set of pads, with the one additional elastomeric pad having a generally centralized bore opening to opposed surfaces thereof; d) releasing the spring seat from its raised position relative to the opening defined by the housing; and, then, e) compressing all the pads in the chamber.
According to one method of assembling-a railcar draft gear assembly the step of: holding the set of elastomeric pads in an axially compressed state within the housing involves using a plurality of bars in operable combination with the uppermost elastomeric pad in the set of pads arranged in the housing. After compressing all the pads in the chamber, the plurality of bars extending arranged in operable combination with the uppermost elastomeric pad in the set of pads are removed.
In one form, the step of: securing a first end of the guide rod within the housing and in general alignment with the longitudinal axis of the draft gear assembly preferably involves rotating the guide rod to interengage cooperating instrumentalities on a latching mechanism arranged within the housing. According to this aspect, the method of assembling a railcar draft gear assembly further involves the step of: inhibiting rotation of the guide rod during operation of the draft gear assembly. Preferably, an end section of the guide rod is configured to facilitate rotation of the guide rod about the axis thereof.
While this invention disclosure is susceptible of embodiment in multiple forms, there are shown in the drawings and will hereinafter be described preferred embodiments, with the understanding the present disclosure sets forth exemplifications of the disclosure which are not intended to limit the disclosure to the specific embodiments illustrated and described.
Referring now to the drawings, wherein like reference numerals indicate like parts throughout the several views, there is shown in
Housing 16 also includes wall structure 25. In the embodiment shown for exemplary purposes in
As shown in
In the embodiment shown in
Turning to
In the illustrated embodiment, the friction clutch assembly 40 further includes a wedge or actuator 50 arranged for axial movement relative to the open end 24 of housing 16. As shown in
Turning again to
Wedge 50 is formed from any suitable metallic material. In a preferred form, wedge member 50 is formed from an austempered ductile iron material. Moreover, and as shown in
As shown in
Spring 60 has an axially elongated configuration and is generally centered within spring chamber 30 of the draft gear housing 16. Spring 60 forms a resilient column for storing dissipating and returning energy imparted or applied to the free end 52 of wedge 50 during operation of the draft gear assembly 10. As mentioned, spring 60 is precompressed during assembly of the draft gear assembly 10 and serves to maintain the components of the friction clutch assembly 40, including friction members 42 and wedge 50, in operable combination relative to each other and within the draft gear housing 16. In one embodiment, spring 60 develops about a 10,000 pound preload force for the draft gear assembly 10 and, in combination with the friction clutch assembly 40. is capable of absorbing, dissipating and returning impacts or energy directed axially thereto in the range of between 450,000 lbs. and about 700,000 lbs.
As shown in
Each elastomeric pad preferably has a generally rectangular shape (
The pads 62 can be formed from any of a myriad of thermoplastic materials. Preferably, each pad 62 is formed from a copolyesther polymer elastomer of the type manufactured and sold by the DuPont Company under the tradename HYTREL™or equivalent materials. The elastomer used to form each pad 62 has inherent physical properties making it unsuitable for use as a spring. Applicants' assignee has advantageously discovered it is possible to impart spring-like characteristics to such elastomeric materials. Co-assigned U.S. Pat. No. 4,198,037 to D. G. Anderson patent better describes the above noted polymer material and forming process. The applicable portions of U.S. Pat. No. 4,198,037 are incorporated herein by reference. Suffice it to say, each pad 62 is preferably formed from the above-described thermoplastic material and has a plastic strain to elastic strain ratio greater than 1.5 to 1.
Returning to
Assembly 10 furthermore includes a spring seat or follower 80 arranged within the draft gear housing 16 and operably disposed between the second spring end 63 and a lower end 44 of each friction member or shoe 42 of the clutch assembly 40. As shown in
As shown in
In the embodiment shown by way of example in
Spring seat 80 is formed from any suitable metallic material. In a preferred form, spring seat 80 is formed from an austempered ductile iron material. During the operation of the draft gear assembly 10, and besides moving vertically within the friction bore 32 of the draft gear housing 16, the friction shoes or members 42 likewise move radially inwardly and outwardly relative to the longitudinal axis 18 of the draft gear 10. Forming spring seat 80 preferably from the austempered ductile iron adds lubricity of the contacting surface engagement between the friction members or shoes 42 and the surface 82 of the spring seat 80.
Assembly 10 furthermore includes an axially elongated guide rod 90 having a longitudinal axis 92 arranged generally coaxial with the longitudinal axis 18 of draft gear assembly 10. Guide rod 90 preferably has a generally cylindrical configuration of a predetermined diameter for the majority of its length along with a first or lower end 94 and a second or upper end 96 arranged in general axial alignment relative to each other. Moreover, the guide rod 90 has a length defined between the ends 94, 96 which is preferably greater than the distance between the closed end 20 of the draft gear housing 16 and the upper surface 85 on spring seat 80. The guide rod 90 is insertable through and guided by the marginal edge of the bore 86 in the spring seat 80 and passes through the bore 68 in each spring pad 62 after the spring seat 80 and pads 62 of spring 60 are inserted into chamber 30. The guide rod 90 functions to maintain general alignment of the spring pads 62 relative to each other and relative to axis 18 thereby optimizing performance of the spring 60 during operation of draft gear assembly 12.
After being inserted through the bore 86 in the spring seat 80 and through the bore 68 in each of the spring pads 62, the guide rod 90 is releasably secured relative to axis 18 of the draft gear assembly 10 by structure, generally indicated in
Structure 100 includes interlocking instrumentalities, generally identified by numeral 102, for releasably holding the guide rod 90 in place while conjointly facilitating positioning of the guide rod 90 and thereby the pads 62 of spring 60 relative to the longitudinal axis 18 of assembly 10. In one form, illustrated by way of example in
In the embodiment shown by way of example in
As shown in
In this form or embodiment, the lower end 94 of the guide rod 90 is provided with the latch 130 which coacts with the keeper 110 of mechanism 104 so as to position the guide rod 90 relative to the longitudinal axis of the draft gear assembly 10 while inhibiting axial or endwise displacement of the guide rod 80 during operation of the draft gear assembly 10. In this latching mechanism embodiment, latch 130 rotates and moves with the guide rod 90.
In the form shown in
Between each lobe 99, 99′ on the head portion 97 and the remaining length thereof, guide rod 90 is provided with a open-sided recessed channel or groove 98 having an axial width generally equal to or only slightly larger than the distance between the bottom surface 114′ and a top surface 116′ on the keeper 110 of mechanism 104. The groove or channel 98 provides the guide rod 90 with a pair of opposed or confronting surfaces or radial shoulders 98′ and 98″.
As shown in
To allow the guide rod 90 to be removed, for whatever reason, from its operable association with housing 16, spring 60 and spring seat 80, the latching mechanism 104 is simply and readily moved to an unlocked condition. With the embodiment shown in
Returning to
In the form shown by way of example in FIGS, 3 and 9, apparatus 140 includes a plate 142 disposed between face or end 85 on spring seat 80 and the friction members 42. Preferably, plate 142 is supported by the face or end 85 on the seat projection 84. In the illustrated embodiment, plate 142 is designed and configured to operably fit between but not operationally interfere with the friction members 42 and/or seat 80. Because it operably fits between the friction members 42, plate 142 is inhibited from rotating during operation of assembly 10.
As shown in
The operative length of the guide rod 90 is such that when rod 90 is arranged in a locked condition with latching mechanism 104, the upper end 96 of the rod 90 is preferably arranged in operable combination with apparatus 140. More specifically, and in that embodiment illustrated in
Moreover, the cross-sectional configuration of at least the lengthwise portion of the guide rod upper end 96 extending from an upper terminal end of the guide rod 90 can facilitate rotation of the guide rod 90 about axis 92 through use of a suitable tool (not shown), such as a socket wrench and the like, whereby facilitating operation of the latching mechanism 104 in either a locked or unlocked condition. Alternatively, and as shown in
As mentioned, the interlocking instrumentalities for releasably holding the guide rod 90 in place while conjointly facilitating positioning of the guide rod 90 and thereby the pads 62 of spring 60 relative to the longitudinal axis 18 of assembly 10 can take various forms without detracting or departing from the spirt and scope of this invention disclosure.
As with mechanism 104, the mechanism 204 shown in
In the form shown in
As shown in
To allow guide rod 90 to be removed, for whatever reason, from its operable association with housing 16, spring 60 and spring seat 80, the latching mechanism 204 is simply and readily moved to an unlocked condition in the same manner as discussed regarding latching mechanism 104. That is, and to condition mechanism 204 in an unlocked condition, the guide rod 90 is simply rotated about 90 degrees about axis 92 from the locked condition or position shown in dash lines in
Like structure 100 discussed above, the structure 200 for inhibiting endwise displacement of the guide rod 90 during operation of the draft gear assembly 10 can furthermore include an apparatus, generally identified by numeral 340 in
As mentioned, the interlocking instrumentalities for releasably holding the guide rod 90 in place while conjointly facilitating positioning of the guide rod 90 and thereby the pads 62 of spring 60 relative to the longitudinal axis 18 of assembly 10 can take various forms without detracting or departing from the spirt and scope of this invention disclosure.
In the embodiment shown by way of example in
Suffice it to say, and as shown in
Moreover, in this embodiment of the invention disclosure, the guide rod 90 is inhibited from axial shifting movements during operation of the draft gear assembly 10. To accomplish these desirable ends, and in this form or embodiment, the lower end 94 of the guide rod 90 is provided with a bore 431 which, preferably, passes through the guide rod 90 and opens at opposed ends to a periphery of the guide rod 90. Bore 431 has a diameter equal to or slightly larger than a bore 423 in the draft gear housing 16 extending generally normal to the longitudinal axis 18 o assembly 10. Moreover, and when the guide rod 90 is fully inserted into operable combination with assembly 10, the bore 431 defined at the lower end 94 of the guide rod 90 aligns with the bore 423 in the draft gear housing 16.
In this embodiment, the interlocking instrumentalities 402 further includes a locking pin or rod 441 which is selectively insertable through, removable from, and guided by the bore 423 in the draft gear housing 16. When the guide rod 90 is fully inserted into operable combination with assembly 10, the pin or rod 441 can be inserted endwise through the bore 423 in the draft gear housing and into the bore 431 on the guide rod 90 whereby inhibiting the guide rod 90 against endwise or axial movement during operation of the draft gear assembly. 10.
To allow guide rod 90 to be removed, for whatever reason, from its operable association with housing 16, spring 60 and spring seat 80, the locking pin 441 is simply and readily removed from its operable association with the guide rod 90 by removing the pin 441 from the bore 431 in the guide rod whereby allowing guide rod 90 to be endwise or axially removed from effecting alignment of the pads 82 relative to the longitudinal axis 18 of assembly 10 and thus allowing the pads 62 to be removed from chamber 30 through opening 70.
According to another aspect of this invention disclosure, there is provided a method of assembling a railcar draft gear assembly 10 having a longitudinal axis 18 and including a housing 16 with a closed end 20, an open end 24, and wall structure 25 extending between the closed and open ends 20 and 24, respectively, so as to define a chamber 30, with the wall structure defining an opening 70 having a closed margin. The method of assembling a railcar draft gear assembly 10 includes the steps of: inserting a spring seat 80 into the housing chamber 30 in a direction extending generally normal to the longitudinal axis 18 of the draft gear assembly, with the spring seat 80 defining a generally centralized bore 86 opening to opposed surfaces 82 and 85 thereof. Another step in the method involves holding the spring contacting surface 82 on the spring seat 80 in a raised position relative to the opening 70 defined by the housing 16 such that a series of elastomeric pads 62 can be inserted into the housing chamber 30 in a direction extending generally normal to the longitudinal axis 18 of the draft gear assembly and such that the pads 62 inserted into the housing chamber 30 are generally axially aligned and stacked one upon the other to define an axially elongated spring 60 extending between the closed end 20 of the housing and the spring seat 80, with each pad 62 having a generally centralized bore 68 opening to opposed surfaces 64, 66 of the pad 62. Another step involves: releasing the spring seat 80 from being held in a raised position relative to the opening 70 defined by the housing 16. Still another step in the method involves: compressing the spring lengthwise. Yet another step in the method involves: installing an elongated guide rod 90 through the centralized bore 86 in the spring seat and though the generally centralized bore 68 in each of pad 62 comprising spring 60 so as to maintain general alignment of the pads 62 relative to each other and relative to the longitudinal axis 18 of the draft gear assembly 10. The elongated guide rod 90 has an elongated axis 92. Yet another step in the process involves decompressing the spring whereby allowing the spring seat 90 to be positioned and held by the housing under the influence of the decompressed spring 60. The method also involves the step of securing the guide rod 90 within the housing 16 and in general alignment with the longitudinal axis 18 of the draft gear assembly so as to inhibit endwise displacement of the guide rod 90 relative to the housing 16 during operation of the draft gear assembly 10. Another step in the method involves: pressing a friction clutch assembly 40 into operable combination with the open end 24 of the housing 16 until an actuator 50 of the friction clutch assembly 40 is captured by the housing 16
In a preferred form, the method of assembling a railcar draft gear assembly further involves the step of: aligning the pads 62 inserted into the housing chamber 30 relative to each other before compressing the spring 60. Preferably, the step of compressing the spring 60 involves the furthers step of: a) releasing the spring seat from its raised position relative to the opening 70 in the housing 16; b) initially and axially compressing a first set of elastomeric pads 62 axially within the housing 16; c) holding the first set of elastomeric pads in an axially compressed state within the housing 16 to allow at least one additional elastomeric pad 62 to be stacked upon the first set of elastomeric pads 62; d) again raising and releasably holding the spring seat 90 relative to the opening 70 defined by the housing 70 so as to allow at least one additional elastomeric pad 62 to be inserted into the housing chamber 30 in a direction extending generally normal to the longitudinal axis 18 of said draft gear assembly 10 and in generally axially aligned and stacked relationship with the first set of pads 62, with the at least the one additional elastomeric pad 62 having a generally centralized bore 68 opening to opposed surfaces 64, 66 of the at least one additional elastomeric pad 62; e) releasing the spring seat from its raised position relative to the opening 70 defined by the housing 16; and then, f) compressing all the pads in the housing chamber 30.
Preferably, and as shown in
In one embodiment of this invention disclosure the step of: securing an end of the guide rod 90 within the housing and in general alignment with the longitudinal axis 18 of the draft gear assembly 10 so as to inhibit endwise displacement of the guide rod 90 relative to the housing 30 during operation of the draft gear assembly 10 involves rotating the guide rod 92 about its axis 92 to interengage interlocking instrumentalities 102 on a latching mechanism 104 arranged within the housing 30. Preferably, the method of assembling a railcar draft gear assembly further involving the step of: inhibiting rotation of the guide rod 90 during operation of the draft gear assembly 10. In one embodiment, the method of assembling a railcar draft gear assembly 10 further involves the step of: configuring an end section 96 of the guide rod 90 to facilitate rotation of said guide rod 90 about the axis 92 thereof.
From the foregoing, it will be observed that numerous modifications and variations can be made and effected without departing or detracting from the true spirit and novel concept of this invention disclosure. Moreover, it will be appreciated, the present disclosure is intended to set forth an exemplification which is not intended to limit the disclosure to the specific embodiment illustrated. Rather, this disclosure is intended to cover by the appended claims all such modifications and variations as fall within the spirit and scope of the claims.
Number | Name | Date | Kind |
---|---|---|---|
3581909 | Peterson | Jun 1971 | A |
4198037 | Anderson | Apr 1980 | A |
4576295 | Carlstedt | Mar 1986 | A |
4591059 | Hammarlund | May 1986 | A |
4735328 | Carlstedt | Apr 1988 | A |
4960215 | Carlstedt | Oct 1990 | A |
5104101 | Anderson et al. | Apr 1992 | A |
5351844 | Carlstedt | Oct 1994 | A |
6478173 | Carlstedt | Nov 2002 | B2 |
6488162 | Carlstedt | Dec 2002 | B1 |
6520360 | Withall et al. | Feb 2003 | B1 |
6792871 | O'Donnell et al. | Sep 2004 | B2 |
6796448 | Wilt et al. | Sep 2004 | B1 |
6862999 | Wilt et al. | Mar 2005 | B2 |
6877623 | Salis | Apr 2005 | B2 |
7044061 | O'Donnell et al. | May 2006 | B2 |
7624884 | Palermo et al. | Dec 2009 | B2 |
20120292279 | Wilt et al. | Nov 2012 | A1 |
Number | Date | Country | |
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20140202973 A1 | Jul 2014 | US |