Single Roller-Idler Assembly For Crawler Undercarriage

Technical Field

This invention relates generally to track-type tractor undercarriages and more particularly to a means for resiliently mounting on a track-type vehicle with a suspended undercarriage the rear idler and an adjacent track roller such that both are bogied adding softness to the rear of the vehicle to reduce undercarriage loads and improve the ride for the operator.

Background Art

Most land vehicles utilize either wheels or crawler tracks for the purpose of supporting the frame of the vehicle above the ground and for converting power into motion. Crawler tracks, whic-h typically have a relatively great area of ground contact, are fairly rugged and can be designed to substantially conform to depressions and other irregularities in the ground. They are most commonly chosen for vehicles which will be operating where conditions are severe: deep snow, battlefields, marshy areas, heavy construction, etc.

Typically, crawler tracks include a front and a rear idler, which are freely turning wheels around which a track chain is placed; several freely turning rollers mounted between the idlers, which serve to transfer the weight of the vehicle to the ground by limiting the upward movement of the track; a track drive sprocket which serves to convert power from the engine into motion of the tracks and hence of the vehicle; and, a roller frame upon which the idlers and rollers are mounted. In some designs the drive sprocket is located at

/

V-7

the extreme rear of the crawler track replacing one of the idlers.

The technology of crawler tractors has advanced to the point where they are reasonably reliable, durable and efficient. However, there is much yet to be done toward improving the ability of crawler undercarriage systems to absorb mechanical shocks and equalizing the pressure exerted upon the ground by each incremental length of the track in contact with it. Advancement in these areas will serve to increase the rate at which the vehicles can travel, this being currently limited in most cases by the amount of mechanical shock the vehicle and its operator can absorb. It will also serve to improve the vehicle performance in mud and other condi- tions where poor weight distribution across the track can result in the vehicle becoming unduly mired in the surface across which it travels.

In crawler track undercarriage systems mechani¬ cal shock is generally dealt with in two manners. The more obvious is through use of traditional shock absorbers in one form or another. In U.S. Patent 1,836,446, issued December 15, 1931, Christie details a system in which the rollers are rotatably mounted on an end of a connecting member another end of which is rotatably connected to the roller frame, the freedom of movement of the member and hence the roller being limited by a coil spring. A related system, using a resilient pad

- placed between the connecting member and a mechanical stop, is described in U.S. Patent 3,774,708 issued to Purcell et al on November 27, 1973. Holt, in U.S.

Patent 1,317,651, issued September 30, 1919, teaches a similar system involving leaf springs. A combination of a leaf spring suspension for the roller-roller frame mounting and the encasement of each roller axle in a

resilient material is set forth in U.S. Patent 1,547,053 issued to Kegresse on July 21, 1925,

A second commonly used system for lessening the amount of shock transferred from the crawler tracks to the remainder of the vehicle is by use of some load transfer mechanism. In its simplest form this is achieved by rotatably connecting two or more rollers to a rigid member known as a bogie which is itself pivotally con¬ nected to the roller frame. When an undercarriage with bogie-mounted rollers passes over a bump, a rock for example, the bogie is caused to rotate allowing the track to deflect upward at the point overlying the rock while forcing that part of the track under the other roller connected to the bogie to move downward. In this manner the pressure exerted upon the ground by the track is reduced at points where a crawler undercarriage with non-bogied rollers would cause very great loading. Compensation is achieved through the increased loading under the other roller on the bogie. In this manner the occurrence of great variations in the load borne across the length ^' of the track is mitigated. With such a system of ground pressure equalization the vehicle tends to bog down less often in soft materials such as snow and mud. Mechanical shocks resulting from passing over bumps, ridges, etc. are lessened as the crawler track has a certain degree of give. In addition, shock absorb¬ ing means can be incorporated into the bogie-roller frame mounting for bogied rollers. See, for example, U.S. Patent 3,774,708 issued to Purcell et al on November 27, 1973.

An existing difficulty in mounting the rollers on bogies is that bogies are best suited for two rollers. With three rollers on a single bogie, it is likely that one roller will often exert no pressure on the track

whatsoever, for example, where the ground is perfectly level save a deep depression under one of the three rollers. With but a single roller, the bogie system is not possible. Therefore, while adequate technology exists for shockably mounting an even number of rollers on a roller frame a difficulty arises when it is neces¬ sary to include on a crawler track undercarriage an odd number of resiliently biased rollers. The addition of a single roller may be necessary, for example, to accom- modate a specific length of track on the ground for a given vehicle weight. An early solution to this problem was -provided by S ythe in U.S. Patent 1,906,116 issued April 25, 1933. Smythe proposed mounting a roller and an idler on a single bogie. There was no provision, however, for any shock absorbing means other than that inherent to the bogie. Consequently, this arrangement transmitted a great deal of mechanical shock to the track frame necessitating lower speeds and strengthened vehicle components. Christie's U.S. Patent 1,836,446 issued December

15, 1931, detailed supra, does describe a means of shockably mounting a single roller, but this scheme is disadvantageous in load distribution to systems using bogie mountings, and additionally would seem to be unduly expensive to produce. It is, however, no doubt feasible.

Another difficulty with existing track-type tractor undercarriages is that there is little if any provision for absorbing the shocks imposed when the rear of the crawler track undercarriage strikes a rock, a ridge, a tree or some other protruding surface in the process of backing up. As in the 1,906,116 patent, the rear idler will directly transmit the resulting shock to the track roller frame resulting in the imposition

of very great transient loadings. This problem was addressed in the 3,774,708 patent with a proposal for the inclusion of a pneumatic or hydraulic rear idler recoil device. The state of the art of track-type tractor undercarriages would be further improved were the rear idler provided with recoil capability in a less expensive and complicated manner.

The present invention is directed to over¬ coming one or more of the problems as set forth above.

Disclosure of Invent-ion

In one aspect of the present invention, a track-type tractor undercarriage includes a roller and a rear idler connected by a means which causes loads on the two to be shared in a predetermined fashion. This load sharing connection means also includes additional shock absorbing means for further minimizing the effects of transient loadings.

The present invention provides a solution toward the need for a way of including on a suspended undercarriage a single roller - that is, a roller paired to no other roller - which has all the load equalizing and shock absorbing properties that are currently obtainable for paired rollers.

Brief Description of the Drawings Fig. 1 is a partial side view of an embodiment of the present invention;

Fig. 2 is a partial top view of Fig. 1;

Fig. 3 shows the rear idler single roller bogie incorporated into a crawler undercarriage; Fig. 4 shows the vector loading scheme on the rear idler;

Fig. 5 shows the action of the invention when a bump passes under the single roller; and

Fig. 6 shows the action of the invention when an elevated area passes beneath the idler.

Best Mode For Carrying Out the Invention

Referring to Figs. 1, 2, and 3, a crawler track undercarriage 10 has a track roller frame 12 with a fore section 14 and an aft section 16. This crawler track undercarriage 10 could be used on a vehicle such as a track-type tractor, battle tank, snowmobile, or any other vehicle requiring an endless track system. Pivotally mounted on the aft section 16 of the track roller frame 12 is an idler-single roller assembly for a crawler track undercarriage, generally indicated by the figure 18. Several bogied roller pairs 20 pivotal¬ ly attached to the frame 12, a front idler 22 rotatably mounted on the frame 12, and an elevated drive sprocket

24 positioned between the fore section 14 and aft section 16 complete a support system around which a track chain 26 is placed.

The bogied roller pairs 20 can assume many well known configurations, consequently no detailed description need be provided here. .An excellent example of such an -assembly is—detailed—in U.S__._. Patent 3,774,708 issued to Purcell et al on November 27, 1973. The idler-single roller assembly 18 can be used in combina- tion with any number of bogied roller pairs 20.

Similarly, the track roller frame 12 can assume many well known configurations. In the instant arrangement, it is made of two rigid parallel frame plates 28 connected by numerous support members 29 for structural strength and holding the frame plates 28 in fixed, substantially parallel relationship one to the other. The track roller frame 12 is joined at a pivotal connection 30 to a vehicle main frame (not sho ^* wn) .

Pivotally attached at a pivotal connection 32 by axially aligned spaced apart support link pivot pins 33 to both frame plates 28, is a support link 34 having an aft end 36 and a fore end 38. The support link 34 'has an inboard half 44 and an outboard half 46. These two halves 44 and 46 are rigidly joined in a parallel, spaced apart symetric relationship by a crossmember 48 having an upper face 50 and a lower face 54. The entire support link 34 is located and pivotable within the two frame plates 28 with only the pivot pins 33 extending through the frame plates 28. The aft ends 36 of the two halves 44 and 46 of the support link 34 have bifurcations 56 and 58, respectively.

A bogie link assembly 60 has an inner arm 66 and an outer arm 68, each having an aft end 69, rigidly joined in a parallel, spaced apart symmetrical rela¬ tionship by an upper bogie plate 70 situated between upper fore ends 72 of the two arms, 66 and 68. The bogie link arms 66 and 68 are pivotally connected at a pivotal connection 73 intermediate their ends to support link 34 by bogie link pins 74 passing through the bi¬ furcations 56 and 58 of support link halves 44 and 46, respectively. . _. . .

Rotatably mounted on an idler axle 84 running between an aftmost position 86 on the inner bogie arm 66 to an aftmost position 86 on the outer arm 68 is an idler 88.

Rotatably mounted on a roller axle 90 running between a foremost position 92 on the inner bogie arm 66 and a foremost position 92 on the outer bogie arm 68 is a track roller 94.

Removably attached to substantially the entirety of the lower face 54 of the crossmember 48 of the support link 34 is a resilient sheet 96 made of rubber or an equivalent. Attached to the upper bogie plate 70

is a compressible suspension pad 98 made of rubber or some other resilient material. This suspension pad and all others used in the present invention must be capable of repeatedly sustaining a loading of at least several tons without suffering any significant degradation of its resiliency. Such suspension pads are well known in the art.

On track roller frame 12 and substantially parallel to the crossmember upper face 50 when in its steady state operating position (that is, its location when there is constant vehicle velocity on a level, smooth surface) and upwardly located a spaced distance therefrom is a support link stop 100 having a lower face 102. This is a rigid plate perpendicular to and running between the frame plates 28. Removably attached to the lower face 102 of support member stop 100 is a thin sheet of resilient material 104 such as rubber. Attached to the crossmember upper face 50 is a suspension pad 106 similar to the support link suspension pad 98. In the preferred embodiment of this invention the components of the rear idler-single roller assembly 18 must be so sized and aligned that in steady state operation of a vehicle including a crawler track 10 with such an assembly, the track chain 26 will be elevated ^' a spaced distance above the ground at the point it contacts the lowest point on the idler 88. The resiliency and size of the suspension pads 98 and 106 must be such that they effectively absorb shocks and sufficiently deform so as to permit adequate bogie action of the roller 94 - idler 88 combination to allow adequate load transfer away from whichever of the two is overloaded. '

In the best, mode for carrying out this inven¬ tion the axes of the bogie link pivotal connection 73, the support link pivotal connection 32, and the idler axle 84 are to be coplanar. Additionally, this plane

must bisect an angle 107 formed by tangents to the idler 88 at the boundaries of the track 26 and idler 88 contact. Referring to Fig. 4, these are at points 108. With such a geometry all nontransient loads imposed on the idler 88 due to chain tension will be borne by the frame at pivot pin 32 with substantially no loading either o'f suspension pad 98 or of suspension pad 106. Referring to Fig. 4, the loading that the track chain 26 imposes on the idler 88 may be represented by load vectors A and B tangent to the idler 88 at the bound¬ aries of track-idler contact 108. It is axiomatic that in a nontransient situation the magnitude of vectors A and B are substantially equal, consequently their resultant, or vector sum, is a vector C bisecting the angle 107 between vectors A and B, vector C consequently being perpendicular to and passing through each of the axes of the bogie link pin 82, the support link pin 34, and the idler pin 90.

Industrial Applicability The idler-single roller assembly 18 is suited for incorporation in the crawler track undercarriage 10 of any track-type vehicle. As adequate technology exists for bogie mounted roller pairs 20 of a shock absorbing nature the idler-single roller bogie 18 is used to greatest advantage in a crawler track under¬ carriage 10 which must include a roller 94 which cannot be bogie mounted to any other roller 110 and which must be shock absorbingly mounted.

Neglecting gravitational and frictional forces, substantially every appreciable force which the rear idler-single roller assembly 18 must sustain will enter the system by acting on the track chain 26. The track chain 26 contacts the rear idler-single roller assembly 18 only at portions of the periphery of the roller

94 and the idler 88 as shown in Figs. 1 and 3, conse¬ quently all external forces acting on the rear idler- single roller assembly 18 enter via the roller 94 and the idler 88. As the roller 94 and the idler 88 each have but a single connection with remainder of the crawler track undercarriage 10, the roller axle 90 and the idler axle 84, respectively, the forces acting on the system may be considered to act through these connec¬ tions. Consider the case in which no forces whatsoever act on the crawler track 10. For the purposes of example all shock absorbing elements will be deemed to be in their lowest energy state, springs neither in compression or tension, and all resilient pads, including the suspen- sion pads 98 and 106, will be in contact with but not compressed against their respective stops. Under these conditions the lowest points of each roller 94,110 will be substantially coplanar; however, in the best embodi¬ ment of the present invention the lowest point on the idler 88 will be vertically removed a distance above this plane. "

Placing the crawler track undercarriage 10 under consideration and a vehicle to which it is connected (not shown) on a flat, level surface, the weight of the vehicle (not shown) will be borne through the track chain 26 by the rollers 94,110. The magnitude of the load carried by the single roller 94 incorporated in this invention is determined by the weight and weight distribution of the vehicle (not shown) as well as by the number and position of the other rollers 110 in the crawler track undercarriage 10. The load borne by the roller 94 incorporated in the idler-single roller assembly 18 will act upward through the roller axle 90 causing compression of the suspension pads 106 and 98. Conse- quently, the load passes from the track roller frame 12 to the ground as, of course, it must. The compression

OMP

of the suspension pads 106 and 98 results in a realign¬ ment of the components of the idler-single roller assembly 18. The compression of the track frame sus¬ pension pad 106 causes the support link fore end 38 to rotate upward about the support link pivot pins 33 causing the support link aft end 36 to rotate downward lowering the position of the idler axle 84 and conse¬ quently of the idler 88 itself. The compression of the support link suspension pad 98 causes the bogie link fore end 72 to rotate upward about the bogie link pins 74 resulting in downward rotation of the bogie link aft end 69 resulting in further downward movement of the idler 88. As a consequence of placing the vehicle (not. shown) on the ground, the idler 88 moves to a position nearer the plane of the lowest points on the rollers 94,110. As is well known in the art, it is important that in this position, or in steady state operation, the lowest point of the idler 88 be at a higher elevation than the lowest point of the rollers 94,110. This is achieved by matching the size and alignment of the bogie link 60 and support link 34 and the size and resiliency of the suspension pads 98 and 106 to the loadings anticipated for the roller 94 - idler 88 combination. A prime feature of the present invention is its provision of load distribution. As is shown in Fig. 5, should the rear roller 94 pass over a bump the loading it undergoes is increased. This increased loading causes further compression of both suspension pads 98,106 as described above resulting in further downward movement of the idler 88. This further downward movement will be in many cases sufficient to bring the idler 88 in contact with the ground thereby shifting a portion of the load to the idler 88. In this situation the bulk of the load will be borne by the track frame 12 at the

support member stop 100 and some smaller portion, owing to that portion of the load transferred to the idler 88, by the support link pivotal connection 32.

For the instance in which the idler 88 passes over a projection it becomes disproportionately loaded causing upward rotation of the bogie link aft end 69 bringing about downward rotation of the bogie link fore end 72 and, consequently, downward movement of the roller 94. The roller 94 will either contact the ground or move downward sufficiently to take slack out of the track 26 and thereby become loaded. In either case, the single roller 94 will be loaded causing a load to be imposed on the bogie link pin 74 resulting in downward rotation of the support link fore end 38 causing the support link suspension pad 98 to be compressed in a scissors-like action. In this case the load is borne by the track frame 12 at the support link pivot pin 32.

In the case in which conditions are such that the roller 94 and the idler 88 are substantially equally loaded the track frame 12 absorbs the load in a combi¬ nation of the two manners set forth above.

As opposed to a rigidly mounted odd roller, the present invention provides smoother operation, that is, greatly decreased transient loadings, of the vehicle 112 to which it is attached owing to its shock absorbing characteristics. In addition, the load which the crawler track undercarriage 10 must support is more evenly distributed across that portion of the track chain 26 which is in proximity with the idler-single roller assembly 18 thereby decreasing the extent to which bogging down in materials such as mud and snow can occur.

As the invention described herein contains no element, for the case of the rear idler-single roller assembly 18, extending forward of the roller 94 or aft of the idler 88 it is quite space efficient and can be

incorporated into existing crawler track designs to provide an additional roller. In most cases this will involve no more than a minor increase in crawler track undercarriage 10 length. The addition of this extra roller 94 will provide a lower ground pressure crawler track undercarriage 10 of a totally suspended nature without the expense and undue length an additional full double roller bogie would entail.

While the best embodiment envisioned for the present invention is a crawler track undercarriage 10 including a single roller-rear idler assembly 18 , other uses are possible. For example, it might be advan¬ tageous in certain applications to include a single roller idler bogie at the front rather than the rear of a crawler track undercarriage 10. Likewise, it might be desired to include both a front and rear single roller- idler assembly 18 on a single crawler track undercarriage 10.

Further aspects, objects, advantages, and uses of this invention can be obtained from a study of the drawings, the disclosure, and the appended claims. It should be understood that the idler-single roller assembly 18 can assume many other configurations without departing from the claims.

OMPI