Patent Grant
7836615
This application relates to snow plows, agriculture equipment, construction excavator teeth, and other road machinery, and more specifically to guards, and wear resistors for the wear surfaces, i.e. blades and teeth, thereof.
Usually the heavy steel cutting or wear edges of blades, teeth, and skid shoes are expendable and can be removable, e.g., with bolts, to the bottom of, for example, a plow moldboard, backhoe bucket, grinder wheel, etc. As a blade scrapes along the pavement or ground it wears. The wear often is uneven, and the blades and teeth (cutting edges) sometimes break during plowing, digging, scraping, etc. All this maintenance and the associated downtime are costly.
The blade on typical snow plowing machines is subjected to extensive vibration, impact, and abrasive action, resulting from the scraping action between the cutting edge of the blade and the roadbed over which the machine travels. As a result, the blade edge wears and chips due to the road abrasion and impact and must be replaced every few hours. This is a costly proposition because of the down time of the machine and cost expended in manpower and materials to make a blade changeover.
It is conventional to provide to the plow or plow attachment frame caster-like wheels, mushroom shoes, or wear skid shoes which are attached to, but spaced from, the plow moldboard for the purpose of supporting part of the load on the blade. These known prior art devices are relatively bulky, expensive to manufacture, and difficult to install on the snow plow. The cast iron material typically used on the wear shoes does not provide protection against fracturing or breakage, due to the relative brittleness of cast iron, when the shoes are subjected to impacts. The shoes are expensive to maintain and replace.
Thus, there has been a need for an improved means which supports the cutting edge of, for example, a snow plow blade from the roadbed for reducing or dampening the undesirable vibrating, impact and abrasive action on the blade. The disadvantages of present wear shoe constructions have resulted in the improved skid shoe-wear surface of the present disclosure which effectively reduces blade wear and shoe replacement resulting from road abrasion. Furthermore, the present disclosure can increase blade (cutting edge) life, skid shoe life, reduce blade breakage and maintenance, and protect the moldboard, bucket or similar mounted thereto.
In one embodiment, the present disclosure relates to a skid shoe for a snow plow blade, and more particularly, to a shoe which is bolted to the plow moldboard at the pre-existing bolt holes used to fasten the blade to the moldboard. Alternatively, the skid shoe can be mounted to the plow attachment frame. The skid shoe can include a wear surface including an abrasion resistant welding deposit filling one or more cavities along, and integrated with, the wear surface. In other embodiments, the present disclosure provides wear resistors embedded within blades and teeth for improved wear resistance along the associated cutting edges.
One aspect of this disclosure provides an expendable wear part adapted for replaceable attachment to, for example, a snow plow blade or other mounting attachment of an associated component of road machinery. The wear part comprises a steel casting having a mounting surface and a wear surface. The wear surface has at least a first cavity extending along and below the wear surface. The at least first cavity includes an abrasion-resistant welding deposit therein for extending the service life of the wear surface of the wear part. The deposit comprises a weldment material selected from the group consisting of chrome carbide, vanadium carbide, and tungsten carbide. The weldment material can have a higher hardness than the steel casting.
Another aspect of the disclosure provides for an expendable wear part adapted for replaceable attachment. The wear part comprises a steel casting. The wear part includes a direction of travel when in an engaged position. The steel casting includes a wear surface having a plurality of cavities extending along the wear surface. The plurality of cavities each have an abrasion-resistant welding deposit therein. The welding deposit has a higher hardness than the steel casting. The welding deposits in the plurality of cavities overfills the cavities and forms substantially parallel bulbous deposits adjacent to and extending outwardly from the wear surface of the casting. The deposits can be longitudinally aligned with, or transverse to, the direction of travel.
Yet another aspect provides a method for extending the life of an expendable wear part adapted for replaceable attachment. The method comprises casting a steel wear part having a plurality of cavities extending longitudinally along a wear surface of the wear part. The method further comprises welding a series of abrasion resistant deposit layers in the cavities wherein the layers are spaced from one another and run along the majority of the length of the wear surface of the casting and wherein the deposit layers have a higher hardness than the steel casting wear part. The cavities can be aligned with, or transverse to, a direction of travel of the wear part when the wear part is in an engaged and use position.
In a first embodiment, the wear resistant surface made in accordance with the teachings of the present disclosure is illustrated in
The skid shoe 10, according to a first embodiment, includes a mounting plate 12 which is secured to the backside of a conventional snow plow blade 18 at the pre-existing bolt holes 16 used to fasten a cutting edge 20 and a moldboard 15 such that shoe 10 can be mounted close to the cutting edge 20 of snow plow blade 18. One of the advantages of the moldboard shoe 10 is that it can be mounted to mounting structure 14 using longer bolts 22 and the same bolt openings 16 which are used in securing cutting edge 20 to moldboard 15. Thus, the present construction eliminates complicated and bulky supporting structure for the skid shoe 10, thereby reducing the time and cost of fitting the skid shoe 10 onto the snow plow blade 18. Further, the bolts 22 for mounting moldboard 15, moldboard shoe 10 and structure 14 become shock and impact absorbers for the cutting edge 20 of snow plow blade 18.
It is to be appreciated that the bolt mounting openings 16 for snow plow blade 18 are located along moldboard 14 at standard spacings of 8-inch or 12-inch centers. As shown, the mounting plate 12 includes a set of spaced apart mounting openings 24 and 26, respectively, such that moldboard shoe 10 may be mounted to the snow plow blade 18 having a 12-inch bolt hole center. Other standard mounting hole spacings are also within the scope of the present disclosure.
The moldboard shoe 10 further includes a generally horizontal skid or wear surface 30. One or more cavities 40, 42 are cast into the moldboard shoe 10 at the time of casting. The moldboard shoe 10 can be cast from steel for greater strength and resiliency.
In one mounting arrangement, the skid shoe 10 resides close to the blade cutting edge 20 and thus is a more integral part of the blade 18 and, therefore, capable of absorbing more of the undesirable abrasive wear.
The steel casting can take on the following analysis (balance iron).
The greater the impact resistance, shear strength, and hardness of the panel sections, generally the better. Accordingly, armor steel castings can be used, typically ones with high chromium, carbon and silicon contents. Other armor steels, quenched and tempered ultraservice steels, and maraging steels also are useful here. The casting process can include the provision of one or more cavities 40, 42 in association with the wear surface 30.
Subsequent to casting, the cavities 40, 42 can be filled and/or overfilled by welding therein a layered carbide matrix. The layered carbide matrix can be composed of a series of layered deposits 50, 52, one on top of another until the cavity is filled or overfilled. Overfilling the cavity can result in a convex or bulbous layer 60, 62 of carbide matrix terminating beyond, i.e. extending below, the wear surface 30 of the shoe 10. The matrix provides a reconstitutable embedded weldment or resistor 50, 52 for increased wear resistance of the wear surface 30. In one exemplary embodiment, the two longitudinal cavities 40, 42 extend along substantially the length of the wear surface 30. The cavities 40, 42 can be spaced from one another and proximal to opposing edges 44, 46, respectively, of the shoe 10. Referring now to
The weldments 50, 52 can comprise a weight of between 1 and 4 pounds. The weldments 50, 52 can increase the weight of each shoe from about 5% to about 20%. The plurality of weldments 50, 52 can be aligned with the wear surface 30 such that when the plow is in use and traveling along the road surface, the weldments 50, 52 are transverse to the direction of travel. Alternatively, the weldments can be aligned such that they are aligned with the direction of travel.
The weld deposits 50, 52 can have the following analysis (balance iron):
Conventional hard-facing or wear-facing weldments can be used for the deposits. So-called chrome carbide steels are the most common, e.g., Stoody Company No. 121, although vanadium carbide (Stoody No. 134) and tungsten carbide ones also can be used very effectively. It is to be appreciated that the weldment material deposited in the cavity has a higher hardness than the steel casting.
The weldment metal must be abrasion-resistant. Generally, it is a high chrome ferrous metal weld. It is reconstitutable in the sense that it can be repaired or replaced by redeposition of carbide matrix by welding.
The wear surface 30 and the embedded or integrated weldments 50, 52 help to support the cutting edge 20 of the blade such that the abrasive action and impact from the roadbed 3 works on the wear surface 30 and weldments 50, 52 of the skid or moldboard shoes 10 instead of the blade cutting edge 20, thereby substantially prolonging the life of the cutting edge 20. In addition, the weldments 50, 52 substantially prolong the life of the associated shoe 10 due to the wear surface 30 being a combination of carbide matrix and steel casting. The present wear resistors are intended to perform better than mechanically fastened solid carbide bars would under the extreme conditions of vibration, impact and thermal shock experienced by snow plow blades.
The surface area of the weldments 150, 152 can comprise from about 20% to about 30% of the total surface area of the bottom wear surface 130.
The expendable wear parts or shoes I 10 are adapted for replaceable attachment to, for example, a snow plow mold board or snow plow mounting arrangement 170 (
It is to be appreciated that skid shoe 110 includes a set of spaced apart mounting openings 124 and 126 such that shoe 110 may be mounted to the snow plow mounting frame 170. Other standard mounting hole spacings and arrangements are also within the scope of the present disclosure.
The welding deposits 150, 152 in the first and second cavities 140, 142 can overfill the cavities forming substantially parallel bulbous deposits 160, 162 extending outwardly from the wear surface 130 of the casting (see
The wear part 110 can include a thickness 134 between the wear surface 130 and an upper surface 132 of the shoe 110. The first and second cavities 140, 142 can include a depth 143, 145 wherein the depth is at least one half of the thickness 134 of the wear part 110.
In one exemplary shape, the essentially flat or panel portion of each shoe 110, as shown in
In another exemplary embodiment (
The surface area of the weldments 250, 252 can comprise from about 20% to about 30% of the total surface area of the bottom wear surface 230.
The expendable wear parts or shoes 210 are adapted for replaceable attachment to, for example, a snow plow mold board or snow plow mounting arrangement 270 (
It is to be appreciated that skid shoe 210 includes a set of spaced apart mounting openings 224 and 226 such that shoe 210 may be mounted to the snow plow mounting frame 270. Other standard mounting hole spacings and arrangements are also within the scope of the present disclosure.
The welding deposits 250, 252 in the first and second cavities 240, 242 can overfill the cavities forming substantially parallel bulbous deposits 260, 262 extending outwardly from the wear surface 230 of the casting. The first and second cavities 240, 242 can be spaced from one another and run along the majority of the length of the wear surface 230 of the casting (refer to
The wear part 210 can include a thickness 234 between the wear surface 230 and an upper surface 232 of the shoe 210. The first and second cavities 240, 242 can include a depth 243 wherein the depth is at least one half of the thickness 234 of the wear part 210.
In one exemplary shape, the essentially circular skid shoe 210, as shown in
When the wear parts comprise a plow skid shoe, a pair of skid shoes 10, 110, 210 are typically provided for attachment to opposite ends of a blade or opposing sides of a snow plow attachment frame 14, 170, 270 whereby the wear surface 30, 130, 230 of each plow skid shoe 10, 110, 210 is simultaneously in sliding engagement with a road surface 3 during use thereof. Thus, the pair of shoes 10, 110, 210 provide the majority of total wear surface when the plow vehicle is in use.
The wear part includes a direction of travel when an associated plow is in an engaged and use position. The deposits 50, 52, 150, 152, 250, 252 can be longitudinally aligned with, or transverse to, the direction of travel. The plurality of cavities 40, 42, 140, 142, 240, 242 can be spaced from one another and run along the majority of the length of the wear surface 30, 130, 230 of the castings (
The method of welding the deposits can include depositing the matrix layers one on top of another wherein each individual layer running along substantially the length of the cavity. It is to be appreciated that the weldments 50, 52, 150, 152, 250, 252 can be reconstituted prior to the wear surface reaching the wear line.
Although not illustrated, the present disclosure also relates to excavating and other agriculture tools such as revolving cutter head excavators for use in mines or dredgers. The wear surfaces can be, for example, on the cutting teeth or scrapers therefore.
Revolving cutter head excavators consist of a drive wheel that rotates around a shaft and is driven by a means of rotation. The periphery of the revolving cutter head excavator has a series of buckets equipped with teeth arranged in directions that are essentially radial. Dredgers do not have buckets and their teeth are distributed around the periphery in a rotary ogival structure. Each tooth consists of a single-unit tooth body structure made of a mechanically resistant metal or alloy such as steel, having a fixing area to connect it to the bucket or the ogival structure and a working area to dig the soil. The working area is generally flat and shaped like a shovel and is bounded by a leading face that points in the direction of movement of the periphery of the wheel or ogival structure in the preferred direction of rotation and a trailing face or face opposite the leading face. The leading face and the trailing face are generally flat or slightly curved and are connected by a front tapered facet that defines a transverse cutting edge. If the tooth is mounted on the bucket or the ogival structure, the transverse cutting edge is essentially parallel to the axis of rotation of the assembly and the general plane formed by the tooth shovel or working area generally slants in the direction of the direction of movement of the tooth in the preferred direction of rotation.
During operation, part of the peripheral zone of the bucket or cutter cuts into the ground, the transverse cutting edge of the teeth bites into the ground and the leading face pushes up the material. This results in considerable wear of the transverse cutting edge and the leading face.
One common solution to increase the service life and the efficiency of the teeth is to hardface the external surface of the leading face and the tapered front facet in order to cover them with a coat of molten carbide by fusing a welding bead.
Although this process significantly increases the service life of the tooth, wear still occurs, relatively slowly at the start of use when the hard material still covers the front facet; wear then becomes much faster when the hard material that covers the front facet is itself damaged by wear. The tooth can only be used as long as the length of its working area has not reduced too extensively and this defines the maximum permissible area of wear of the tooth.
In particular, as soon as the front facet has lost its protective coating of hard material, wear becomes much faster despite the existence of a layer of hard material on the leading face of the tooth.
Dredger teeth with a composite structure are known consisting of a metal tooth body containing inserts of a hard anti-abrasion material. In document U.S. Pat. No. 3,805,423, a prefabricated insert is fitted in appropriate recesses in the metal tooth body where it is fixed by welding or brazing. The insert, in the embodiment shown in
In contrast to providing prefabricated inserts, the present disclosure, similar to the above description for skid shoes, provides for a steel casting with one or more cavities. The cavities can be transverse to the cutting edge of the teeth and extend along a majority of the length of the teeth. Each of the cavities can subsequently be filled with a carbide matrix by way of welding layers of deposits according to the detailed description provided above.
While particular embodiments have been described, alternatives, modifications, variations, improvements, and substantial equivalents that are or may be presently unforeseen may arise to applicants or others skilled in the art. Accordingly, the appended claims as filed and as they may be amended are intended to embrace all such alternatives, modifications variations, improvements, and substantial equivalents.
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