System and method for supporting sidewalls or ribs in coal mines

Abstract

A cuttable, sinkable mining bolt system for use in supporting the sidewall or rib in a coal mine. A bearing plate has a plurality of hollow cores defined transaxially therein and a central hole defined axially therethrough, the bearing plate made of modified recycled, rigid PVC compound. A fiberglass bolt is adapted to be inserted through the central hole of bearing plate. Bolt is one-piece consisting of glass fiber reinforced plastic. Head component includes a square head and integral, beveled washer for self-centering in the bearing plate as rod component is driven into rib. Bearing plates are adapted to sink into a refuse stream. Hollow cores of bearing plate reduce the material and thus the weight and expense of the bearing plate while still allowing the bearing plates to sink. Optionally, rod components can be inserted transaxially through the hollow cores to increase the strength and coverage of the system.

Claims

1. A mining bolt system, comprising: a bearing plate, said bearing plate having a top bearing surface and a bottom bearing surface, each said top bearing surface and said bottom bearing surface entirely flat but for a central hole defined axially therethrough, said bearing plate further having six hollow cores defined transaxially therein; and, a bolt, said bolt including a rod portion and a bolt head, said rod portion having a surface, said bolt head including a first annular and a second annular with a beveled washer fixed between said first annular and said second annular, said beveled washer defined by a tapered surface and a flange, said bolt including a knob formed on said first annular.

2. The mining bolt system of claim 1, wherein said hollow cores are uniformly spaced.

3. The mining bolt system of claim 1, wherein said bolt consists of glass fiber reinforced polymer (GFRP).

4. The mining bolt system of claim 3, wherein said bolt head is over-molded to said rod portion to form said bolt entirely as a one-piece bolt.

5. The mining bolt system of claim 3, wherein said rod surface is granular.

6. The mining bolt system of claim 3, wherein said knob has an indentation defined on a knob top therefor.

7. The mining bolt system of claim 1, wherein said bearing plate is a rigid, polyvinyl chloride compound (PVC).

8. The mining bolt system of claim 1, including a sleeve integrally formed between said second annular and said rod portion.

9. The mining bolt system of claim 1, further comprising a strand chuck assembly for placement around a cable strand such that said cable strand and strand chuck assembly can be disposed underlying said bearing plate to receive an inward compression force from said bearing plate.

10. A mining bolt system, comprising: one or more bearing plates, each said bearing plate having a central bore defined transaxially therethrough, said bearing plate adapted to abut a side wall of a mine; a bolt, said bolt including a rod portion and a bolt head, said rod portion having a surface, said bolt head integrally formed to said rod portion, said bolt including an integral, beveled washer transitioning from said bolt head to said rod portion, said bolt received through said central bore with said beveled washer self-centering within said bearing plate, thereby securing said bearing plate to said side wall to provide an inward force against said sidewall; a rebar received transaxially by said bearing plate, wherein said rebar is adapted to connect more than one of said bearing plates across said side wall to thereby enhance said inward force; wherein each said bearing plate includes an undulating surface, said undulating surface defined by a pair of edge surfaces which travel downward to form edges, said undulating surface further defined by a dipping medial portion relative to said edge surfaces to thereby define a pair of pockets through which said rebar is received; and, a strand chuck assembly for placement around said rebar such that said rebar and said strand chuck assembly can be disposed within said pocket underlying said bearing plate to receive an inward compression force from said bearing plate.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) FIG. 1 shows a perspective view of the bearing plate.

(2) FIG. 2 shows a perspective view of the bolt, which includes both head and rod portion.

(3) FIG. 3 shows a broken perspective view of the fiberglass bolt inserted through the central hole of bearing plate along with the rod portions of each bolt passing transaxially through the hollow cores bores of the bearing plate (both ‘y’ and ‘x’ axis penetration).

(4) FIG. 4 shows a side view in elevation of the bolt system applied across a mine side wall side view with bearing plates of various size.

(5) FIG. 5 shows a perspective view of the bolt system in an alternative, vertical arrangement.

(6) FIG. 6 shows a perspective view of the bolt system in an alternative arrangement around the corner of the side wall.

(7) FIG. 7 shows a perspective view of the bolt system in an alternative, continuous, horizontal arrangement.

(8) FIG. 8 shows a perspective view of an alternative embodiment.

(9) FIG. 9 is a graph of a load test.

(10) FIG. 10 is a table of pull testing data.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT

(11) Referencing then FIGS. 1-10, shown is the instant cuttable mining bolt system, or rock bolt system. The rock bolt 6 is for use in supporting the sidewall or rib in a coal mine for example. As used herein, “side wall 19” means a wall, roof or any supporting rib within a mine or rock formation, tunnel or within any environment which requires anchoring. “A” as used in the claims means one or more. The instant mining bolt system comprehends three main subassemblies, namely a bearing plate 1, a bolt 6 and rebar 26 (connecting rods or cable strands), as follows.

(12) The first subassembly is a bearing plate 1. Bearing plate 1 has a top bearing surface 1a and a bottom bearing surface 1b. The top bearing surface 1a and bottom bearing surface (not visible are each entirely flat but for a central hole 5. Bearing plate 1 preferably consists of a modified recycled, rigid polyvinyl chloride (PVC) compound. In one embodiment, the PVC is formulated for high specific gravity if desirable (regular PVC can be used without additives). Due the formulation of the PVC, the high specific gravity still allows the bearing plate 1 to sink in solutions to 1.6 SG or greater, which might be typical for iron-containing wastewater, thus falling to the bottom of any preparation facility heavy media vessel, to thereby enter the refuse stream. In other words, whereas the SG of PVC is typically 1.4 and would sink in water, the formulation must be such that it sinks in a higher SG medium and the instant formulation accomplishes this. The formulation is available from Meridian Precision, Inc., Pine Grove, Pa. In the preferred embodiment (although not limited thereto) bearing plate 1 is square having a width of 6″, depth of 6″ and a height of 1″, but because the bearing plates 1 are extruded, various lengths, widths and depths may be used. Defined transaxially (along ‘x’ axis) through the bearing plate 1 are a plurality of hollow cores 2, i.e. defined entirely from front edge 3 to back edge 4. The hollow cores 2 preferably each measure ⅝″ in diameter and are uniformly spaced, 1″ apart from each center (0.375 inch gap), and in this example, six (6) hollow cores 2 are shown. The hollow cores 2 reduce the weight of the bearing plate 1 and thus increases ease of use and decreases expense while the strength and specific gravity of the system is still maintained. Additionally, as further described below, the hollow cores 2 can receive rebar 26 or connecting rods such as rod portions 7 of the fiberglass bolt 6 itself. The central hole 5 is defined entirely through bearing plate 1 with center through ‘y’ axis, thus axially defined through the center of bearing plate 1 as shown. “Axially” also means inward towards the side wall 19, or along ‘y’ axis. Thus, central hole 5 is adapted to receive fiberglass bolt 6 axially therethrough, as follows.

(13) The second subassembly comprises the bolt 6. A preferably fiberglass bolt 6 is provided which is adapted to insert through the bearing plate 1 by way of central hole 5, thus driving into side wall 19 while bearing plate 1 forcefully abuts the same to thereby anchor the side wall 19 at the location of entry. Bolt 6 has a rod portion 7 and integral bolt head 8. In the exemplar embodiment the rod portion 7 can range from 48″ to 60″ in length and would be saleable in these two lengths but any length can be used. The diameter of each rod portion 7 would preferably range from 0.603 to 0.703, but again, these measurements may vary as to both desired characteristics and tolerances. In the exemplar embodiment the bolt 6 is an Aslan 100 glass fiber reinforced polymer (GFRP) that combines fiberglass roving with a thermoset vinyl-ester resin system to create a long-lasting alternative to steel. The rod portion 7 has a rod surface 9 which can be modified to be roughened with granules to thereby be textured or granular to aid in grip.

(14) Bolt head 8 is formed integral to rod portion 7, thereby forming a one-piece bolt 6. The bolt head 8 includes a first annular 14 and a second annular 15 with a beveled washer 11 fixed between the first annular 14 and the second annular 15, thus transitioning from bolt head 8 to rod portion 7 is an integral, beveled washer 11, preferably hemi-spherical, which self-centers within the bearing plate 1. Beveled washer 11 is defined by a tapered surface 13 and a flange 12. A sleeve 10 is integrally formed between the second annular 15 and the rod portion 7. A generally cubical knob 16 is formed on the first annular 14. An indentation is defined on a top surface 18 of knob 16 which acts as a physical stop to correct the depth of the over-mold manufacturing process because the bolt head 8 is injection molded around rod portion 7 to form entire bolt 6. More particularly, an over-mold process uses 50% GFRP products that are heated, molten stage, then shrunk around the rod portion 7 to achieve at least 10,000 tensile strength (see FIG. 9). This process results in the similar, sinkable characteristics of the bearing plate 1 such that both the bolt 6 and the bearing plate 1 sink (and, of note, non-conductive).

(15) The third subassembly includes one or more rebar 26. “Rebar 26” in this embodiment means connecting rods or dowels, which may be made of any material such as traditional steel, or they can be formed of similar polymer make-up as the rod portion 7 and could, in fact, be the rod portions themselves. Additionally, they can be steel cables as further defined (i.e. cable strand). More particularly, while rod portions 7 are the long end of bolt 6 and are, in one embodiment, driven in to the side wall 19 with the bearing plate 1 providing in inward (towards the side wall 19) retaining force against the sidewall/rib, axially through each bearing plate 1, the rod portions 7 can serve the secondary function of being inserted transaxially through the hollow cores 2 of the one or more bearing plates 1. In addition, the bearing plates 1 can be resized along the length of the system if they are used merely to capture a rod portion 7. The rebar 26 is not adhered to the bearing plate 1 but rather “inserted” therein to rely on friction for securement and to absorb any load. Any number of rebar 26 and accompanying hollow cores 2 of bearing plate 1 can be used depending on the needed application, i.e. only some of the hollow cores 2 could be occupied. For instance, referencing FIGS. 3-7, shown is an embodiment wherein the rebar 26 (as defined) are inserted and thus secured through the hollow cores 2 of bearing plates 1 transaxially. Moreover, the mining bolt system, therefore, can be disposed in various configurations, e.g. vertical or horizontal, any orientation, and at various locations, e.g. around a corner 20 of the side wall 19 (see FIG. 6). “Vertically” would mean, for example, in an arrangement where the rebar 26 travels from floor to ceiling of a tunnel and “horizontal” would therefore be generally perpendicular to this arrangement. Of course, this provides for an orientation at any angle or corner as long as the hollow cores 2 nearly face opposing hollow cores 2 to form the connection prior to receiving the load (and thereafter potentially moving). In addition, any number of hollow cores 2 may be occupied (e.g. two outer, then two inner on an adjacent bearing plate 1). Therefore, “any orientation” is meant to cover such variations and numbers and is defined herein as the combination bearing plates 1 and rebars 26 ability to tension in a variety of configurations as shown and described. As such, the system upon assemblage is further tensioned by providing an additional inward force towards the side wall 19 as each bolt 6 bears against the bearing plate 1 and, in combination, rebar 26 provides an added inward force. Accordingly, a means is provided for increasing the leveraging and thus enhancing the anchoring force of the bearing plate 1 when the bearing plates 1 are coupled with additional rebar 26 and/or all subassemblies are used in combination.

(16) With specific reference now to FIG. 8, shown is an alternative embodiment of the bearing plate 1 and rebar 26 combination wherein the rebar 26 underlies the bearing plate 1. The rebar 26 here takes the form of a steel cable and although the rebar 26 is still “received transaxially” by the bearing plate 1, it is received by defined pockets 27. More specifically, the bearing plate 1 excludes the hollow cores 2 and instead includes an undulating surface 21, the undulating surface 21 defined by a pair of edge surfaces 23 which travel downward (relative to an edge surface 23 of bearing plate 1) to form edges 24, the undulating surface 21 further defined by a dipping (also downward) medial portion 22 relative to the same edge surfaces 23 to thereby define a pair of pockets 27 underlying the bearing plate 1. A strand chuck assembly 25 (may comprise two, three or more “wedges”) can be placed around the rebar 26, here a cable, such that the cable and strand chuck assembly 25 can be disposed within the pocket underlying the bearing plate 1 to receive an inward (towards the side wall 19) compression force from the bearing plate 1 when a similar bolt 6 (not shown in this figure) is anchored.

(17) In use therefore, and in a method for supporting a side wall 19, multiple bearing plates 1 are anchored into the side wall 19 axially, further comprising the step of fastening a fiberglass bolt 1 through the bearing plate 1 into the side wall 19; and the an inward force (toward the side wall 19) of the bearing plates 1 are enhanced by inserting fiberglass rebar 26 transaxially through the bearing plates 1, and with such combinations arranged across the side wall 19 in any orientation.

EXAMPLE 1

(18) Testing to determine the tensile strength of the fiberglass bolt prototype was conducted. The fiberglass bolt head was used to mimic the loading conditions that would be applied to the system in an underground application. Test results are shown in FIGS. 9 and 10 and are in accordance with ASTM F432-I3 Section 10.4 for Bearing and Header Plates.