Patent Grant
9708019
This application claims foreign priority benefits under 35 U.S.C. §119(a)-(d) to European patent application number EP 13001923.5, filed Apr. 12, 2013, which is incorporated by reference in its entirety.
The present disclosure relates to a track-supporting roller assembly for supporting a crawler track of a crawler chassis.
Conventionally, track-supporting rollers made of steel are used to support the upper crawler section of a crawler track in a crawler chassis. The crawler track chain links roll directly on the steel rollers, which may lead to an undesired noise development at the workplace. In addition, it has shown that the metal-on-metal contact between the chain links and the steel rollers results in a greater wear not only of the steel rollers, but also of the chain links of the crawler track. Remedying such signs of wear is very expensive, and cannot be done right at the construction site, but has to be carried out in a workshop. Also, rust deposits may be formed between the steel rollers and the chain links if the construction machine with the crawler chassis remains outdoors on the construction site for a longer period. Above all, this may lead to split-offs on the steel roller surface when the construction machine starts moving, resulting in an unsteady and noisy run of the crawler track.
EP 1 666 345 B1 discloses a crawler chassis having a track-supporting roller assembly which is positioned next to a drive wheel. The track-supporting roller assembly comprises a supporting roller which is mounted on both sides and on which the crawler track rolls along. The supporting roller has an increased diameter at its outer ends, on which position the chain links are supported.
US 2010/0096196 A1 discloses another crawler chassis. The crawler chassis comprises several track-supporting rollers which are arranged on a carrier, respectively mounted on both sides, between a drive wheel and a return wheel. The supporting surface for the chain links is formed by outer portions of the respective track-supporting rollers that have an increased diameter. The respective track-supporting rollers are mounted in a lubricating bushing on both sides. It is difficult, however, to seal the lubricating bushing bearing in such a way that an escape of lubricant from the bearing during the operation is prevented, which could result in an unsteady run of the respective track-supporting rollers.
EP 1 798 138 B1 discloses a mounting structure for a track-supporting roller for a crawler track which is mounted on a lower frame of the crawler chassis. The mounting structure comprises a mounting part and a support part for the carrier roller. The support part comprises a clamping closure which can be screwed such that a shaft of the carrier roller can be mounted in the clamping closure, on which shaft the carrier roller is rotatably fixed. The drawback of this arrangement is that the screw closure can become loose when vibrations occur during the operation, so that the carrier roller may slip out of the support part.
It is an object of the present disclosure to provide a track-supporting roller assembly by means of which a smooth and reliable guidance of the crawler track can be obtained, and which ensures at the same time that the extent of wear signs on the track-supporting roller and on the track chain links of the crawler track guided on the track-supporting roller is reduced.
This object is achieved by providing the track-supporting roller with at least one supporting body made of plastic. The supporting body made of plastic is provided on the track-supporting roller such that the track chain links of the crawler track roll along on the supporting body. The supporting body acts like a damper and, therefore, is able to buffer movements of the upper crawler section of the crawler track such that the noise development is reduced. The supporting body made of plastic is not only characterized by its excellent damping properties during the operation, but also provides for a certain protective function during a standstill of the crawler chassis. This protective function is noticeable, above all, because construction machines remaining outdoors on the construction site for a longer period are no longer subject to rust deposits between the track-supporting rollers and the track chain links. Thus, a gentle start of the crawler chassis is possible without creating split-offs on the track-supporting roller, respectively on the track chain links.
In a preferred embodiment of the disclosure the supporting body is made of polyurethane. Polyurethane is particularly characterized by a high resistance against climatic influences and, therefore, is extremely well suited for use on the construction site. In addition, polyurethane is pertinacious to abrasion and offers excellent adhesive properties, which is an advantage in particular for the guidance of the crawler track. A supporting body of polyurethane furthermore offers excellent damping properties, so that movements of the crawler track can be buffered well without stressing the bearing unit of the track-supporting roller assembly. Thus, a prolonged service life of the bearing unit can be expected. In order to realize a particularly abrasion-resistant support for a crawler track the supporting body is, in another embodiment of the disclosure, made of rubber, above all with a hardness grade of more than 90 shore.
In addition to the excellent abrasion resistance, a supporting body made of rubber also allows the excellent dampening of impact forces of the crawler track so as to prevent these forces from being transferred to the bearing unit of the track-supporting roller assembly.
Preferably, the supporting body has an outer diameter between 40 mm and 100 mm, specifically 50 mm. Thus, the track-supporting roller assembly is very compact. Such a track-supporting roller assembly allows guiding a crawler track at a small height relative to the ground. Guiding the crawler track at a small height is above all advantageous for road finishers as the installation space of the crawler chassis in an upward direction is limited by the material bunker.
According to another embodiment of the disclosure the supporting body is hollow-cylindrical and has an inner diameter between 20 mm and 60 mm. A supporting body with such dimensions is easy to manufacture and easy to couple to the track-supporting roller.
Preferably, the track-supporting roller comprises a shaft on which the supporting body is fixed. The shaft provides for a stable basis on which the supporting body can be mounted in a rotation-fixed manner. The shaft is advantageously made of a metal that has a high bending stiffness. As compared to the supporting body the shaft does not yield to the movement of the crawler track so that the bearing unit can be relieved.
It is particularly favorable if the supporting body is shrunk or cast onto the shaft. Thus, it is possible to fix the supporting body on the shaft in a rotation-fixed and anti-slip manner. This is an advantage because great forces act on the supporting body owing to the guiding, respectively carrying of the crawler track. Rotatability of the supporting body relative to the shaft is not desirable as the supporting body is thus heated up to a particularly great extent and could be damaged.
In another embodiment of the disclosure it is provided that the shaft comprises a stop against which the supporting body bears. Even in the case of great axial lateral forces the supporting body is thus secured against the stop and cannot slip out of place on the shaft.
Preferably, the stop has a smaller outer diameter than the supporting body. Thus, it can be prevented that the stop collides with chain links of the crawler track. This diameter difference relative to the supporting body also helps to achieve a form-fit contact of the crawler track chain links on the track-supporting roller, so that the crawler track can be guided positionally accurate and smoothly.
It is also an advantage if the stop has a greater outer diameter than the shaft on which the supporting body is arranged. Thus, the stop defines a particularly robust counter-bearing for the supporting body.
According to another embodiment of the disclosure the stop has a hollow-cylindrical shape, wherein its inner diameter substantially corresponds to the outer diameter of the shaft. Thus, the stop may be arranged concentrically on the shaft, resulting in a smooth guidance of the crawler track.
An excellent resistance against climatic influences is exhibited by the stop if it is made of plastic, especially of polyurethane. In case the stop, like the supporting body, is permanently in contact with chain links of the crawler track it can thus be prevented that rust deposits occur in the contact area to the chain links. Moreover, the stop, if made of plastic, acts as a protective envelope for the shaft of the track-supporting roller.
The stop may be fixed on the shaft in a particularly stable manner if it is shrunk or cast onto the shaft. This may be accomplished simultaneously with shrinking on, respectively casting on, the supporting body, or in a subsequent or preceding process.
Alternatively, the stop may also be formed integrally with the shaft, however, e.g., formed as a cast body or body of rotation of metal. In the appropriate case this would result in a greater stability of the track-supporting roller.
It is also conceivable that the supporting body encases, at least section-wise, the shaft and also the stop. Thus, the supporting body protects both the stop and the shaft. At the same time, the stop holds the supporting body on the shaft in a stable manner.
Preferably, the bearing unit comprises at least one bearing body which rotatably supports one end of the shaft. The bearing body can be easily fixed to the crawler chassis and ensures a regular rotation of the shaft.
The track-supporting roller assembly is particularly smooth in operation if the track-supporting roller is coupled to the bearing unit by a roller bearing. The roller bearing allows the support of great radial forces, which may take effect in particular in supporting and guiding a crawler track.
According to a particularly preferred embodiment of the disclosure the roller bearing is a self-aligning roller bearing. The self-aligning roller bearing has, above all, the advantage that it can be loaded to a great extent both axially and radially in both directions. In addition, the self-aligning roller bearing is capable of compensating misalignments or deflections of the track-supporting roller, respectively shaft.
Another improvement of the disclosure provides that the self-aligning roller bearing comprises an inner ring which bears against the supporting body. The inner ring thus provides a roller track for the self-aligning roller bearing and, at the same time, an attachment, respectively support, for the supporting body. This has the result that the supporting body is secured against the inner ring and can thus be fixed on the shaft in a stable manner.
Preferably, the self-aligning roller bearing comprises an outer ring which is arranged in the bearing unit. The bearing unit offers enough protection for the outer ring and forms a stable receptacle for same.
The self-aligning roller bearing may be coupled to the bearing unit in a particularly reliable manner by means of a clamping plate. Also, the clamping plate is able to prevent dirt and moisture from penetrating into the self-aligning roller bearing.
The subject matter of the present disclosure also is directed to a crawler chassis having at least one track-supporting roller assembly of the above-described type. The crawler chassis furthermore comprises a crawler track having an upper crawler section and a lower crawler section, wherein the upper crawler section rests on the track-supporting roller of the track-supporting roller assembly in a sagging manner. The sagging of the upper crawler section entails a reduced installation volume of the crawler chassis, which is an advantage in particular for road finishers. This will be described below by means of the figures.
The crawler chassis is suited particularly well for use in a road finisher if it is configured such that the crawler track can be guided by the track-supporting roller assembly such that an upper edge of the upper crawler section of the crawler track is positioned maximally 700 mm, in particular 650 mm, above a lower edge of the lower crawler section. As compared to other crawler chassis heights the height of the herein described crawler chassis is clearly smaller, so that it can be easily installed in a road finisher underneath a material bunker.
The subject matter of the present disclosure also is directed to a road finisher having a crawler chassis with at least one track-supporting roller assembly according to the disclosure of the above-described type. In this road finisher the upper edge of the upper crawler section is at least 50 mm away from a material bunker bottom. This distances is a dimension sufficient for the crawler track not to strike against the material bunker bottom. At the same time, it is possible to maintain a low filling height of the material bunker for the loading of the truck.
The subject matter of the disclosure is explained in more detail by means of the attached drawings.
The track-supporting roller assembly 1 comprises a bearing unit 2 which includes a first bearing body 3 and a second bearing body 4. The first and the second bearing bodies 3, 4 are identical in design. Two bore holes 34 are respectively provided on the bearing bodies 3, 4 and serve to fix the bearing bodies 3, 4.
A track-supporting roller 6 is arranged between the two bearing bodies 3, 4. The ends of the track-supporting roller 6 are rotatably received in the bearing bodies 3, 4.
According to
It can be easily seen in
In
The shaft 10 is coupled to the bearing body 3 by means of a roller bearing R, which is configured as a self-aligning roller bearing 11 in
The inner ring 12 is axially broader than the outer ring 13. The inner ring 12 protrudes into the receptacle 15 of the bearing body 3 and extends substantially up to one end of the shaft 10. The roller bearing track with rollers 14 is completely received in the receptacle 15. The inner ring 12 protrudes out of the receptacle 15 and extends up to the supporting body 7. Thus, the inner ring 12 can prevent the supporting body 7 on shaft 10 from slipping outwardly. The supporting body 7 is thus enclosed between the stop 8 and the inner ring 12 of the self-aligning roller bearing 11, so that the supporting body 7 cannot be displaced in the axial direction along the shaft 10. In the area where the supporting body 7 bears against the inner ring 12 the inner ring 12 may have a greater outer diameter A12 which substantially corresponds to the outer diameter A8 of the stop 8. The inner ring 12 is preferably shrunk onto the shaft 10, but may also be fixed to same by other fixing means.
The self-aligning roller bearing 11 is held in the receptacle 15 by means of a clamping plate 16. The clamping plate 16 is annular and screwed against an end face 17 of the bearing body 3. The clamping plate 16 presses the outer ring 13 of the self-aligning roller bearing 11 positionally fixed into the receptacle 15 so that the outer ring 13 is unable to move in the receptacle. Also, sealing means, e.g., a sealing lip 18, may be provided on the clamping plate 16, which allow a rotation of the inner ring 12 relative to the clamping plate 16, but prevent, at the same time, that dirt, respectively moisture, penetrates into the receptacle 15.
The receptacle 15 comprises a storage or storage area 19. The storage 19 may receive a lubricating grease or lubricating oil. The lubricating grease or lubricating oil may be supplied to the storage 19 through an inlet screw 20. The inlet screw 20 is shown in
The material bunker 23 has a material bunker bottom 32 which is arranged above a front portion of the upper crawler section 30. The material bunker bottom 32 is arranged above the upper crawler section 30 by a distance X. An upper edge 33 of the upper crawler section 30 is positioned, at least along the material bunker bottom 32, at a medium height H, which preferably is 650 mm. Guiding the upper crawler section 30 underneath the material bunker bottom 32 at such a height can be achieved by the compact design of the track-supporting roller assembly. The height H added to distance X results in maximum of 1000 mm. Thus, it is possible to position the material bunker 23 at a preferred loading height above the crawler chassis 22.
While exemplary embodiments are described above, it is not intended that these embodiments describe all possible forms of the invention. Rather, the words used in the specification are words of description rather than limitation, and it is understood that various changes may be made without departing from the spirit and scope of the invention. Additionally, the features of various implementing embodiments may be combined to form further embodiments of the invention.
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| Number | Date | Country | |
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| 20140305717 A1 | Oct 2014 | US |
