This invention relates to endless rubber track belts.
Rubber endless tracks such as for use on agricultural or industrial vehicles typically have an internal center ribbon of individual lugs which engage drive bars on a drive wheel. The continued use and contact between the drive bar and drive lugs cause internal lug stresses, and surface wear at the points of contact. Additionally, the internal center ribbon of lugs are typically functioning not only to transmit power from the drive wheel to the track, but also to retain the track onto the vehicle. Contact between the vehicle undercarriage wheels and the longitudinal or guide surfaces of the inner lugs frequently occurs as the vehicle maneuvers during normal service. This contact can cause wearing of the inner lugs which can be severe depending upon various vehicle design features and usage applications. Driving and/or guiding forces on the inner lugs, henceforth referred to as guide-drive lugs, can lead to eventual chunking of the rubber surface and possibly to complete removal of the drive lugs, making the track unserviceable. Thus a track belt having guide-drive lugs which are stronger and more resistant to wear is desired.
The invention provides in a first aspect an endless rubber track belt comprising a rubber carcass having an inner surface having one or more guide-drive lugs and an outer surface having tread lugs, the guide-drive lugs having a reinforcement layer which extends substantially along the width of the drive lug.
The guide-drive lugs 16 as shown in
As shown in
The guide-drive lugs as shown in
The reinforcement layer, or layers, may comprise the following materials: nylon, polyester, polyethylene, polyurethane, rayon, Kevlar, aramid, metal, natural fibers such as cotton, glass fibers, carbon fibers, ceramic fibers or plastic fibers. The reinforcement material may also be a fiber loaded rubber layer, with fibers oriented in a transverse direction or in a random direction. For example, the reinforcement material may comprise tire ply (rubber coated cords), with the fibers oriented in any desired orientation. The fibers may be natural fibers such as cotton, nylon, polyester, polyethylene, polyurethane, rayon, glass fibers, steel, or plastic. The invention is not limited to the reinforcement materials stated above, and may also comprise any low friction material considered suitably effective for the specific type of track belt usage. It is preferable that the reinforcement material having a low coefficient of friction in the range of about 0.10 to about 0.80.
If the reinforcement material is tire ply, then two or more layers may be used. If two or more layers are used, the layers may have cords oriented at opposite angular orientation, e.g., layer one has parallel cords oriented at 45 degrees, while layer two has parallel cords oriented at −45 degrees (although any desired angular orientation may be used). Preferably, light nylon tire cord is used, which is used in airsprings.
The reinforcement material may comprise the track inner surface or be embedded under the track inner surface at a distance d, d typically being in the range of about 0.020″ to about 0.13″. Preferably, the reinforcement layer is covered on both sides with a skim coat layer of rubber.
The reinforcement layer is preferably incorporated into the track belt during the track belt manufacturing process. In this case, the reinforcement material is prepared independently, and prior to, the track manufacturing process. The track belt can be formed and vulcanized in a pressurized molding process. Molds used in said process have shaped lug cavities which form guide-drive lugs into their intended final shape. The guide-drive lugs can be presented to the final molding process as non premolded extruded pieces, which are cut to length, approximately the shape of the lug cross sectional contour. At the ends they may be cut on a bias to more approximate the ends of the mold cavities. Otherwise, the lugs may be pre-molded similar to what is illustrated in U.S. Pat. No. 5,536,464. Said slugs can be covered individually with separate pieces of reinforcing materials prior to lugs being presented to the track belt build and vulcanization process. Alternatively, the guide-drive lug reinforcing material can be applied to the particular surfaces as a continuous piece. In this method, the prepared inner lug slugs are positioned onto the inside surface of the uncured carcass at their intended final molded relative locations. Then, prior to molding, the single piece of reinforcement is placed over the green inner lug slugs. Additional fitting of the reinforcement to the green inner slugs may be done at this time; however, the process of compressing the mold may also be relied on to form fit the reinforcement over the intended surfaces. After the reinforcement has been fitted to the inner lug slugs final vulcanization occurs via imparting appropriate pressure and temperature onto the uncured track belt. This is the final step in incorporating the guide-drive reinforcement to the track belt.
While certain representative embodiments and details have been shown for the purpose of illustrating the invention, it will be apparent to those skilled in this art that various changes and modifications may be made therein without departing from the spirit or scope of the invention.
This application claims the benefit of U.S. Provisional Application No. 60/741,951 filed Dec. 2, 2005.
Number | Date | Country | |
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60741951 | Dec 2005 | US |