1. Field of Invention
The current invention relates generally to apparatus, systems and devices for processing a variety of materials such as coal. More particularly, the apparatus, systems and devices relate to separating materials from rock. Specifically, the apparatus, systems and devices provide for separating coal from rock using spinning flails, impact grids, and separating grizzlies.
2. Description of Related Art
It is often necessary upon removing coal from a mine or strip pit to further process the coal before it is used. This can be done by breaking the coal and sorting it into certain sizes and removing rocks, shale or other impurities therefrom. Depending upon the final use for which the coal is intended and the type and hardness of the particular coal being mined, the coal is broken and separated into predetermined size particles. Two inch sized particles are a common size for many burning applications.
This crushing and splitting of the coal has been performed by various types of equipment such as a rotary roll crusher in which coal passes between and is crushed by counter-rotating rolls and then discharged into a chute or conveyor for subsequent shipment. Such roll crushers have the disadvantage in that everything including coal and other impurities must go through the crusher rolls and everything is broken into smaller particles. It is preferable that impurities be removed, not crushed, and transported with the coal. Another type of prior art crusher or breaker is a rotary breaker which consists of a large hollow rotating drum having a plurality of holes and baffles inside which will break the coal as it is tumbled within the drum.
Although these breakers perform satisfactorily, they require a considerable amount of energy for rotating the drum or crusher rolls. Furthermore, it is difficult to change the setting for the size of coal desired. Also, it is difficult to confirm the breaking force with the hardness of the particular seam of coal being broken by the equipment.
These known crushers usually are located at a coal wash plant which may be located some distance from the mine or pit, requiring the coal together with the impurities to be transported to the processing site with the refuse or removed impurities being returned to the original site for disposal. All of these hauling and processing operations increase the cost of processing the coal.
Several types of coal breakers use rotors which propel the coal against impact surfaces for breaking the coal into smaller particles. Although these breakers perform satisfactorily, they require a relatively large motor and increased power because of the heavy structural members since the rotor. changes the direction of the coal or material being broken after being struck with the rotor blades. Also, the rotor blades perform some of the crushing or breaking action instead of merely propelling the coal particles and increasing the speed thereof for impact crushing against a surface. These types of rotary crushers also have the disadvantage of not removing the coal particles as soon as possible after being reduced to the desired size. The coal and sized particles will remain in the crusher for a longer period of time than necessary resulting in the particles being further reduced in size which results in fines or dust being created which may be too small for use and sale.
Many of these problems have been eliminated by the coal breaker and sorter construction of U.S. Pat. No. 4,592,516.
It is also desirable to reduce damage to the flair assemblies and particularly the flair paddles which are subject to considerable unbalanced forces and to provide ease of maintenance when damaged.
Therefore, there is a need for an improved coal breaker and sorter which eliminates many of the above problems and satisfies needs existing in the art by providing an improved flair assembly.
One aspect of an embodiment of the invention includes an aggregate accelerator for sorting a material such as coal from rock. The aggregate accelerator includes a housing; a grizzly inside the housing to allow material of a certain size to pass through the grizzly; a flail assembly with at least two independent paddles inside the housing, wherein the flail assembly is to spin and hit material to be separated from rock and wherein when the flail assembly is spinning and before hitting the material the at least two independent paddle are generally adjacent and co-planar due to centrifugal force; an impact grate assembly inside the housing to receive and break material hit by the flail assembly; and at least one lower grate to allow material of a predetermined size to pass through the at least one lower grate to be collected, wherein the grizzly, flail assembly, impact grate assembly and the at least one lower grate are configured to separate stone from the material, and wherein the at least one lower grate does not allow material larger the predetermined size to pass through the least one lower grate so that this material can be discarded.
In another aspect of the invention an example embodiment may provide an aggregate accelerator for sorting a material such as coal from rock and soil which includes a flair assembly having a rotatable shaft; at least two independent paddles operatively mounted on the shaft for hitting aggregate passing through the breaker and sorter when the shaft is rotating; and a flexible mounting assembly connecting the said two independent paddles to the shaft providing flexibility of movement between the paddles and shaft and between said paddles and for positioning the two paddles adjacent and co-planar to each other due to centrifugal force when the shaft is rotating.
One or more example embodiments that illustrate the best mode(s) are set forth in the drawings and in the following description. The appended claims particularly and distinctly point out and set forth the invention.
The accompanying drawings, which are incorporated in and constitute a part of the specification, illustrate various example methods, and other example embodiments of various aspects of the invention. It will be appreciated that the illustrated element boundaries (e.g., boxes, groups of boxes, or other shapes) in the figures represent one example of the boundaries. One of ordinary skill in the art will appreciate that in some examples one element may be designed as multiple elements or that multiple elements may be designed as one element. In some examples, an element shown as an internal component of another element may be implemented as an external component and vice versa. Furthermore, elements may not be drawn to scale.
Similar numbers refer to similar parts throughout the drawings.
The coal breaker and sorter 1 is illustrated in
The coal breaker and sorter 1 further includes a pair of motors 13A-B installed in a motor housing 15 located adjacent the back wall 7C of the upper housing 5A and connected to motor sheaves 17A-B. The motor sheaves 17A-B are each respectively connected to belts 19A-B that are each connected to flail (rotor) sheaves 21A-B as illustrated. Each of the flail sheaves 21A-B is connected to a flail assembly 23A-B. Flail assembly 23A is an upper flail assembly 23A and is located above lower flail assembly 23B.
A first feed scalping grizzly 25 extends downward from the opening 11 toward a bottom end of flail assembly 23A. A first grizzly feed chute 27 extends from a bottom end of the first feed grizzly 25 and extends parallel to the first scalping grizzly 25 as illustrated in
An upper impact grate assembly 31 is located near the front wall 7A of the upper housing 5A. A lower scalping grizzly 33 extends from a bottom end of the upper impact assembly 31 and is pointed downward toward a bottom end of a lower impact grate assembly 35. One or more lower grates 37A-B can be located in an upper portion of lower housing 5B. A lower final sorting grate 39 is located near the bottom of the lower housing 5B and an output chute 41 is located near a lower front side of the lower housing 5B. A conveyer belt 43 can be placed below the lower final sorting grate 39 and around a conveyer wheel 45.
The upper impact grate assembly 31 can have two halves 47A-B where each half can be mounted in the upper housing 5A so that each half has a pivot at pivot points P1-2. Adjustment mechanisms 49 can be used to rotate each half 47A-B of the upper impact grate assembly 31 within slots 51A-B cut in the right and left walls 7B to create a desired angle, α, between the two halves 47A-B. When the desired position is reached, the adjustment mechanisms 49 can lock the two halves 47A-B in place. The adjustment mechanisms 49 can be bolts or other device as understood by those with ordinary skill in the art.
Similarly, the lower impact grate assembly 35 can have two halves 53A-B where each half can be mounted in the upper housing 5A so that each half has a pivot at pivot points P3-4. Adjustment mechanisms 49 can be used to rotate each half 53A-B of the lower impact grate assembly 35 within slots 55A-B cut in the right and left walls 7B to create a desired angle, β, between the two halves 53A-B. When the desired position is reached, the adjustment mechanisms 49 can lock the two halves 53A-B in place.
The upper grizzly 25 includes cross-member devices 57, 59. The lower grizzly 33 has similar cross-member devices 61, 63. As discussed in detail below the cross-member devices 57, 59 are used to connect elongated grizzly bars 65 together into panels. The cross-member devices 57, 59, 61, 63 can be formed out of metal bars, L-shaped metal bars or a different type of metal bar or out of different material. The lower grizzly 33 is illustrated with an adjustment mechanism 64 and with its upper cross-member member 61 attached to a pivotal rod 66. The adjustment mechanism 64 allows the position of the lower grizzly 33 to be moved to a desired position as indicated by arrow A. In other embodiments, the upper grizzly 25 could also include a similar adjustment device 64.
Each paddle 79A-B has a left end 84 and a right end 86. The left end 84 of each paddle 79A-B is connected two outer brackets 85 and one inner bracket 87. Each of these brackets 85, 87 are rigidly connected to the cylinder 81. In the example embodiment, these brackets 85, 87 are generally equilateral shaped triangles with rounded points or vertices but they can be other shapes. The inner bracket 87, in the example embodiment is thicker than the two outer brackets 85. Each Bracket 85, 87 has a central hole 89 (best seen in
The paddles 79A-B are constructed with short bars 97, long bars 99 and plate bars 101. In the example embodiment these bars are made with metal that is preferably a strong/heavy steel. As probably best seen in
The long bars 99 include thick bars 99A and thin bars 99B. One thick bar 99A has two thin bars 99B place on both sides of it at the left end 84 of each paddle 79A-B and also at each right end 86 of each paddle 79A-B. Holes 107 (
Some of the physical dimensions of the example embodiment will now be mentioned, however, in other configurations of the example embodiment, one or more other dimensions could be used. As indicated in
The upper scalping grizzly 25 will be further described with reference to
For example, clevis pin wedges can be passed through holes 125 holes (
As best seen in
As is best seen in
As mentioned above, the lower scalping grizzly 33 has an adjustment device 64. As illustrated in
Having described the coal breaker and sorter 1, its use and operation will now be described. One feature of the coal breaker and sorter 1 is that it can be “tuned” for a particular coal/rock/dirt combination from a particular coal deposit to extract a maximum amount of coal of an optimum size from that deposit. “Tuning” is possible because coal is compressed bio-material that tends to shatter when struck while different rocks tend to break and not shatter. By finding optimal settings/positions of various components of the coal breaker and sorter 1 it is possible to more efficiently separate more coal from unwanted rock/dirt based on the way these different materials break apart. Traditionally, prior art accelerators pretty much had one setting for breaking/separating coal from rock and soil. The “tuning” can be done before separating coal if the properties of a particular coal/rock/dirt combination to be processed are known. Alternatively, the tuning can be performed while separating coal and it can later be tweaked while in operation to adjust the proper settings needed for maximum productive coal separation.
The coal breaker and sorter 1 can be tuned or adjusted by selecting optimal positions for the upper grizzly 25 and the lower grizzly 33 by adjusting their adjustment devices 64. These adjustments determine how much material passes thought these scalping grizzlies 25, 33 before being struck by their respective rotor/flail assemblies 23A-B. Further tuning/adjusting can be accomplished by adjusting, as discussed above, the angle, α, between both halves 47A-B of the upper impact grate assembly 31 as well as the angle, β, of both halves 53A-B of the lower impact grate assembly 35. Adjusting the impact grate assemblies 31, 35 in this way controls how material being processed travels upon hitting the impact grate assemblies 31, 35. For example, material hitting the impact grate assemblies 31, 35 can be controlled so that it does not fly in an upward direction so that it cannot be hit a second time by the same flail/rotor assembly 23A-B. Additionally, the speed of the flail/rotor assemblies 23A-B can also be turned to a specific material being processed. Typically the upper flail/rotor assembly 23A is run at about 400 rotations per minute (rpm) and the lower flail rotor assembly 23B is run between +20 and −50 rpm of the upper flail/rotor assembly 23A.
Before beginning processing material the motors 13A-B are started so that their paddles 69 begin to spin so that a centrifugal force pushes them outward because they are attached to chains 83. Preferably, additional material to be processed should have been earlier prescreened so that it is small enough to be handled by the coal breaker and sorter 1. For example, material no bigger than 10×10 inches should be processed by the coal breaker and sorter 1.
As best illustrated in
Because the paddles 79A-B are connected by chains 83 there is some freedom of movement (as best seen in
After hitting the upper impact grate assembly 31, large coal material and rock 149 then drop and slide downward and onto the lower grizzly 33. Further fines 147 pass through the grizzly 33 while larger coal material and rock 149 continue to slide downward on the grizzly 33 until they reach the lower flail/rotor assembly 23B spinning in the direction of arrow F where they are again struck by this flail/rotor assembly's paddles 79A-B and propelled in the direction of arrow G toward the lower impact grate assembly 35. Upon striking spikes on the lower impact grate assembly 35 and the lower impact grate assembly 35 itself the larger coal material 149 further shatters and breaks apart and passes through the lower impact grate assembly 35 as more fines material 147. Notice that first fines feed chute 29 prevents fines material 147 falling from the upper scalping grizzly 25 from being hit by the lower flail/rotor assembly 23B.
Fines 147 and larger coal and rock 149 that do not make it through the lower impact grate assembly 35 fall downward to reach the lower grates 37A-B where the fines 147 pass through and the larger coal and rock 149 slides downward and onto output chute 41 where it slides out of the coal breaker and sorter 1 so that it can be further processed or disposed of. Fines passing through lower grates 37A-B and passing downward through the back side 7C of the coal breaker and sorter 1 pass through lower final grate 39 and onto the conveyer belt 43 so that these fines can by stockpiled and/or further processed.
In the foregoing description, certain terms have been used for brevity, clearness, and understanding. No unnecessary limitations are to be implied therefrom beyond the requirement of the prior art because such terms are used for descriptive purposes and are intended to be broadly construed. Therefore, the invention is not limited to the specific details, the representative embodiments, and illustrative examples shown and described. Thus, this application is intended to embrace alterations, modifications, and variations that fall within the scope of the appended claims.
Moreover, the description and illustration of the invention is an example and the invention is not limited to the exact details shown or described. References to “the example embodiment”, “an embodiment”, “one example”, “an example”, and so on, indicate that the embodiment(s) or example(s) so described may include a particular feature, structure, characteristic, property, element, or limitation, but that not every embodiment or example necessarily includes that particular feature, structure, characteristic, property, element or limitation. Furthermore, repeated use of the phrase In the example embodiment” or “in the example embodiment” does not necessarily refer to the same embodiment, though it may.