This invention relates to a system including a machine for winning mining material, a forward conveyor, and a roof support. More particularly, this disclosure relates to such a system that also includes a rear conveyor.
A variety of different apparatuses exist for mining coal and other materials from underground seams. One apparatus that is commonly used in underground mining operations comprises a mining machine used in instances where extended portions or longwalls of seam are to be mined. Such longwalls may, depending upon the seam configuration, extend for distances of 1200-1500 feet. It is standard practice in this type of mining to mine parallel entries into the seam to be mined and connect those entries with one or more primary passages. This procedure defines the longwall pillar(s) to be mined. The roof of the primary passages is then supported by movable roof supports during the mining of the exposed “face” of the longwall pillar.
Conventional longwall mining techniques employ a mining machine that is known in the industry as a longwall shearer. In alternate arrangements, a plough is used instead of a longwall shearer.
A longwall shearer typically has an elongated mobile frame that is supported on floor-mounted tracks that are adjacent and substantially parallel to the mine face. Rotary driven toothed drums are operably supported on arms on each end of the elongated frame for winning the coal as the frame passes back and forth before the mine face. The won material falls onto a face conveyor that is attached to the floor-mounted tracks and extends parallel to the longwall face. The face conveyor discharges the material onto other conveying apparatuses to transport the material from the seam. As the mine face recedes, the conveyor and track assembly is advanced forward to enable the shearer to continue mining.
More particularly, the cantilevered roof support 16 is a chock roof-engaging beam support unit having a floor-engaging base 42 and a shield 24 supported by two hydraulically operable support legs or rams 28 (only one of which is shown) spaced from the face conveyor to define an access travelling way 30. A roof-engaging beam 32 is pivotally attached at 34, to the shield 24 and the shield 24 is connected by cantilevered linkage 40 to the base 42. The roof-engaging beam 32 also carries at its front end a face sprag assembly 48 including a contact plate 50 that is shown in a face-supporting mode, where the plate 50 is extended from its stowed position by a hydraulic cylinder 54 to a position where it abuts a part of the face. The face sprag assembly's fully extended position is shown in ghost in
The shearer 12 has a mining machine support in the form of an elongated mobile frame 60 with a skid-type shoe 64 that is movably supported on a race 68 that is substantially parallel with the longwall face. A laterally extending rotary drum 70 which has a plurality of mining bits 74 attached thereto is pivotally attached to each end of the elongated mobile frame 60 by a corresponding boom member 78. The operation of the shearer 12 is well known in the mining art and, as such, will not be discussed in detail herein. However, the skilled artisan will appreciate that the shearer 12 is moved back and forth on the race 68 such that the mining bits 74 on the rotating drums 70 can be brought into engagement with the mine face to dislodge material there from. As the face recedes, the race 68 and shearer 12 are advanced towards the face to enable the mining process to be continued.
In some mining operations, as shown in
At the roadway or main gate end of the longwall, an extra wide and extra long roof support assembly 129 is required, and is illustrated in
To assist in supporting the roof, each of the two roof supports 130 also include spaced apart middle plates 176 that extend between the two adjacent roof supports 130, creating an overlap. The overlapping middle plates 176 are not connected. The two adjacent roof supports 130 are used because each roof support has its own pontoons, for the floor of the mine is irregular as the roof support 130 advances. The pontoon of each roof support needs to be able to move vertically independently of the adjacent pontoon. Because the adjacent roof supports are not connected, it is difficult to maintain, as the roof support assembly 129 advances, the same roof support adjacent positions.
In the above-described typical top coal caving longwall mining operation, there are two drilling entries and a wall face across between the entries, with mining then being backwards along the entries. In a different form of mining, illustrated in
It is an object of this disclosure to provide an improved roof support for a top coal caving longwall operation.
Another object of this disclosure is to provide an improved top coal caving system with reduced goaf pressure on the end gates.
Another object of this disclosure is to provide improved top coal caving equipment.
Another object of this disclosure is to provide an improved main gate roof support with better shielding and operation.
This disclosure thus provides a longwall mining system including at least one face end roof support having a longitudinal length, and at least one near end roof support adjacent the face end roof support. The near end roof support has a longitudinal length substantially shorter than the face end roof support longitudinal length. There is also at least one face roof support adjacent the near end roof support, and the face roof support has a longitudinal length substantially shorter than the near end roof support longitudinal length. There is also a forward conveyor extending forward to and attached to the face end roof support, the at least one near end roof support, and the at least one face roof support, and a rearward conveyor extending rearward of and attached to the face end roof support, the at least one near end roof support, and the at least one face roof support.
This disclosure also provides a roof support including a first floor-engaging base, a first shield, a first roof-engaging beam pivotally attached to the first shield, and a first hydraulically operable support leg connected between the first floor-engaging base and the first roof-engaging beam. First linkage pivotally connects the first shield to the first base. The roof support also includes a second floor-engaging base, adjacent but spaced apart from the first floor-engaging base, a second shield, a second roof-engaging beam pivotally attached to the second shield, and a second hydraulically operable support leg connected between the second floor-engaging base and the second roof-engaging beam. Second linkage pivotally connects the second shield to the second base, and a bridge is pivotally connecting to the first base and is pivotally connected to the second base.
Before one embodiment of the disclosure is explained in detail, it is to be understood that the disclosure is not limited in its application to the details of the construction and the arrangements of components set forth in the following description or illustrated in the drawings. The disclosure is capable of other embodiments and of being practiced or being carried out in various ways. Also, it is to be understood that the phraseology and terminology used herein is for the purpose of description and should not be regarded as limiting. Use of “including” and “comprising” and variations thereof as used herein is meant to encompass the items listed thereafter and equivalents thereof as well as additional items. Use of “consisting of” and variations thereof as used herein is meant to encompass only the items listed thereafter and equivalents thereof Further, it is to be understood that such terms as “forward”, “rearward”, “left”, “right”, “upward” and “downward”, etc., are words of convenience and are not to be construed as limiting terms.
In the illustrated embodiment of
A perspective schematic view of the roof supports is illustrated in
More particularly, the bridge 244 extends across the front of the pontoons, midway along the pontoons, and across the rear of the pontoons, as shown in
A jointed sloughing plate 294 (see
Turning now to the details of the various roof supports shown in
The near end cantilevered roof support 208 includes a floor-engaging base 340, a shield 344, a roof-engaging beam 348 pivotally attached to the shield 344, and four spaced apart hydraulically operable forward support legs 352 connected between the floor-engaging base 340 and the roof-engaging beam 348. The near end roof support 208 also includes cantilevered linkage 356 pivotally connecting the shield 344 to the base 340, and two spaced apart hydraulically operable rearward support legs 353 connected between the floor-engaging base 340 and the roof-engaging beam 348. The rearward support legs 364 are spaced apart from the two spaced apart hydraulically operable forward support legs 352.
The near end roof support 208 also includes a rearward conveyor drive 370 pivotally connected to the floor-engaging base 340, the floor-engaging base 340 being pivotally connected to the rearward conveyor drive 370, and a forward conveyor drive 374, the floor-engaging base 340 also being pivotally connected to the forward conveyor drive 374. The near end roof support also includes a short pivoting roof-engaging beam or tailpiece 380 at the rear of the unit.
The face support comprises a floor-engaging base 384, a shield 388, a roof-engaging beam 392 pivotally attached to the shield 388, and two spaced apart hydraulically operable support legs 396 (only one is shown) connected between the floor-engaging base 384 and the roof-engaging beam 392. Cantilevered linkage 398 pivotally connects the shield 388 to the base 384.
The main gate roof support 216 includes two spaced apart sides 500 and 504 (see
The main gate roof support 216 further includes a rearward roof-engaging beam 540 pivotally attached to the rearward shield 516, and the spaced apart hydraulically operable rearward support legs 234 of the sides are connected between the rearward floor-engaging bases 508 and the rearward roof-engaging beam 540. A middle roof-engaging beam 550 is pivotally connected to the rearward roof-engaging beam 540, and the spaced apart hydraulically operable middle support legs 528 of the sides are connected between the middle floor-engaging bases 524 and the middle roof-engaging beam 550. A forward roof-engaging beam 560 is pivotally attached to middle roof-engaging beam 550, and the spaced apart hydraulically operable forward support legs 234′ of the sides are connected between the forward floor-engaging bases 530 and the forward roof-engaging beam 560. The forward, middle and rearward floor-engaging bases of each side combine to form each of the pontoons of the main gate support 216.
In an alternate main gate roof support assembly 400, as shown in
More particularly, the first roof-engaging beam 416 comprises two spaced apart plates 450, and the second roof-engaging beam 436 comprises a plate 454 positioned between the first roof-engaging beam spaced apart plates 450. By virtue of being separate, not connected roof supports 404 and 424, the main gate roof support assembly 400 can advance one roof support, and then advance the other, to aid the longwall mining process.
Various other features and advantage of the invention are set forth in the following claims.
This application is a continuation of prior, U.S. patent application Ser. No. 12/833,291, filed Jul. 9, 2010 now U.S. Pat. No. 8,590,982, and claims the benefit of U.S. Provisional Patent Application No. 61/224,762, filed Jul. 10, 2009, the entire contents of all of foregoing patent applications being incorporated herein by reference.
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Number | Date | Country | |
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20140077580 A1 | Mar 2014 | US |
Number | Date | Country | |
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61224762 | Jul 2009 | US |
Number | Date | Country | |
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Parent | 12833291 | Jul 2010 | US |
Child | 14087839 | US |