CA2570022A1 - Friction stabilizer with tabs - Google Patents
Friction stabilizer with tabs Download PDFInfo
- Publication number
- CA2570022A1 CA2570022A1 CA 2570022 CA2570022A CA2570022A1 CA 2570022 A1 CA2570022 A1 CA 2570022A1 CA 2570022 CA2570022 CA 2570022 CA 2570022 A CA2570022 A CA 2570022A CA 2570022 A1 CA2570022 A1 CA 2570022A1
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- Canada
- Prior art keywords
- tubular body
- tabs
- tab
- gap space
- friction stabilizer
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
- Abandoned
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- 239000003381 stabilizer Substances 0.000 title claims abstract description 142
- 238000003780 insertion Methods 0.000 claims abstract description 50
- 230000037431 insertion Effects 0.000 claims abstract description 50
- 229910000831 Steel Inorganic materials 0.000 claims abstract description 24
- 239000010959 steel Substances 0.000 claims abstract description 24
- 239000002184 metal Substances 0.000 claims abstract description 19
- 229910052751 metal Inorganic materials 0.000 claims abstract description 19
- 238000005304 joining Methods 0.000 claims abstract description 16
- 238000000034 method Methods 0.000 claims description 23
- 238000003466 welding Methods 0.000 claims description 16
- 238000005097 cold rolling Methods 0.000 claims description 11
- 238000003825 pressing Methods 0.000 claims description 9
- 238000004519 manufacturing process Methods 0.000 claims description 8
- 238000009434 installation Methods 0.000 claims description 5
- 238000004080 punching Methods 0.000 abstract description 10
- 238000005096 rolling process Methods 0.000 abstract description 3
- 230000007423 decrease Effects 0.000 description 11
- 238000004806 packaging method and process Methods 0.000 description 6
- 229910000851 Alloy steel Inorganic materials 0.000 description 5
- 239000011435 rock Substances 0.000 description 5
- 238000005065 mining Methods 0.000 description 4
- 229910001335 Galvanized steel Inorganic materials 0.000 description 3
- 230000001154 acute effect Effects 0.000 description 3
- 230000003247 decreasing effect Effects 0.000 description 3
- 239000008397 galvanized steel Substances 0.000 description 3
- 238000012856 packing Methods 0.000 description 3
- 239000000463 material Substances 0.000 description 2
- 230000006835 compression Effects 0.000 description 1
- 238000007906 compression Methods 0.000 description 1
- 230000001066 destructive effect Effects 0.000 description 1
- 238000007429 general method Methods 0.000 description 1
- 238000007689 inspection Methods 0.000 description 1
- 229910001092 metal group alloy Inorganic materials 0.000 description 1
- 239000007787 solid Substances 0.000 description 1
- 239000010935 stainless steel Substances 0.000 description 1
- 229910001220 stainless steel Inorganic materials 0.000 description 1
- 238000011179 visual inspection Methods 0.000 description 1
Classifications
-
- E—FIXED CONSTRUCTIONS
- E21—EARTH OR ROCK DRILLING; MINING
- E21D—SHAFTS; TUNNELS; GALLERIES; LARGE UNDERGROUND CHAMBERS
- E21D21/00—Anchoring-bolts for roof, floor in galleries or longwall working, or shaft-lining protection
- E21D21/0026—Anchoring-bolts for roof, floor in galleries or longwall working, or shaft-lining protection characterised by constructional features of the bolts
- E21D21/004—Bolts held in the borehole by friction all along their length, without additional fixing means
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- Engineering & Computer Science (AREA)
- Mining & Mineral Resources (AREA)
- Structural Engineering (AREA)
- Life Sciences & Earth Sciences (AREA)
- General Life Sciences & Earth Sciences (AREA)
- Geochemistry & Mineralogy (AREA)
- Geology (AREA)
- Vibration Prevention Devices (AREA)
Abstract
A friction stabilizer having tabs comprising a tubular body comprising an exterior surface and having a first portion and having a second portion provided with a taper. The first portion has an impact end and the second portion has an insertion end. A tab is on the tubular body and extends outward from the exterior surface of the tubular body in a direction toward the impact end and away from the insertion end of the tubular body. The tabs can be rectangular shaped or triangular shaped or have other shapes which prevent the friction stabilizer from being removed from a drilled bore in a mine. When the friction stabilizer with tabs is inserted into a drilled bore in a mine, the tabs do not impede insertion. But, after insertion into the drilled bore the tabs resist removal of the tubular body, and thus allow the stabilizer to support the mine wall or ceiling. The friction stabilizer is made by taking a steel coil and punching the shape of the tabs in the metal, for example sheet metal, unrolled from the coil. A notch is also punched into the sheet at a predetermined location.
Rolling die roll the tubular body, and a cutting machine cuts the tubular body at the notches, so tubular bodies of predetermined length are cut. The tabs extend from the exterior surface of the tubular body due to the natural spring constant of the steel or metal from which the tubular body is made. A weld ring is welded to the impact end and has a weld ring gap space. In another embodiment the tubular body has first portion, a second portion with a bent portion joining them together. An extendable tab is formed in the first portion proximal the bend portion and the extendable tab is diametrically opposite a tube gap space.
Rolling die roll the tubular body, and a cutting machine cuts the tubular body at the notches, so tubular bodies of predetermined length are cut. The tabs extend from the exterior surface of the tubular body due to the natural spring constant of the steel or metal from which the tubular body is made. A weld ring is welded to the impact end and has a weld ring gap space. In another embodiment the tubular body has first portion, a second portion with a bent portion joining them together. An extendable tab is formed in the first portion proximal the bend portion and the extendable tab is diametrically opposite a tube gap space.
Description
FRICTION STABILIZER WITH TABS
Cave-ins are a constant threat associated with underground mining operations. It is difficult to predict when and where a cave-in will occur.
Typically, workers are provided with little or no warning prior to a cave-in, and thus they have a minimal amount of time to react to a cave-in. Indeed, mine walls or ceilings that appear fine upon visual inspection may have significant fractures just below their surfaces, making them structurally weak and prone to collapse. Cave-ins are very destructive and may result in miners becoming trapped and/or injured.
Additionally, equipment and niachinery may be damaged or destroyed.
Friction type stabilizers have been used in mining operations to stabilize walls and ceilings of the mine. Such stabilizers are pounded into bores drilled in mine walls and ceilings. The stabilizers fonn a friction fit with the drilled bore. But, these stabilizers may slide out of the drilled bores when the rock wall or ceiling shifts/moves, and in such situations the stabilizers are unable to prevent a rnine wall or ceiling cave-in.
Therefore, it would be desirable to provide a new and improved stabilizer that decreases the likelihood of a cave-in. It would also be desirable if the stabilizer was compatible with existing mining equipment and inexpensive to fabricate.
The friction stabilizer with tabs according to this invention is used to secure the walls and ceilings of mines to thus prevent a cave-in from occurring. The friction stabilizer with tabs comprises a hollow body, preferably tubular. The tubular body comprises ati impact end, an insertion end, a first portion and a second portion.
The second portion has a notch and is tapered.
The tubular body has an interior and an exterior surface, and tabs are connected to and extend from the tubular body. The tabs extend in a direction leading away from the insertion end of the tubular body and in a direction leading towards the impact end of the tubular body. The tabs each make an acute angle with the exterior surface of the tubular body. The tabs can be rectangular shaped and there can be three such tabs extending from the exterior surface of the tubular body. Each rectangular shaped tab further comprises parallel tab side edges and a tab free edge connecting between the tab side edges.
In other embodiments, the tabs may be triangular shaped tabs, curved shaped tabs, polygonal shaped tabs, U-shaped tabs, tabs having both curved portions and linear portions, semi-circular shaped tabs, hook shaped tabs, parabolic shaped tabs, and combinations of the above. Also, the tabs can be of any shape that inhibits the withdrawal of the friction stabilizer with tabs from the drilled bore in a mine. The above-described tabs are punched into the sheet from which the tubular body is formed by a punching machine, thus they are joined to the tubular body at bends.
The tubular body further comprises a first gap space wall and a second gap space wall spaced apart from one another by a tube gap space. The tube gap space is used for allowing the tubular body to be compressed radially inward when the tubular body is driven into a drilled bore in a mine having, the drilled bore having a diameter less than the outer diameter of the tubular body.
The friction stabilizer further comprises a weld ring having a weld ring gap space, and the weld ring is joined to the tubular body such that the weld ring gap space and tube gap space are aligned. The weld ring is joined to the exterior surface of the first portion of the tubular body at the impact end of the tubular body by, for example, a weld. The weld ring gap space is used for allowing the weld ring to be compressed radially inward. 'The weld ring can have a rectangular cross section or a circular cross section.
In another embodiment, a friction stabilizer for installation in a structural body is provided. The friction stabilizer has a tubular body comprising a first portion a bent portion and a second portion with and the bent portion joining the first portion and second portion. The first portion has an extendable tab and a joining portion joins the extendable tab and the tubular body such that the extendable tab is proximal the bent portion. The friction stabilizer also has a tube gap space and an opening diametrically opposite the tube gap space, such that the extendable tab extends from the joining portion into the opening. The extendable tab is diametrically opposite the tube gap space.
The tubular body is movable from an uncompressed position to a compressed position, such that when in the tubular body is in the uncompressed position the extendable tab is partly positioned in the opening. The tubular body also has an exterior surface and when in the uncompressed position the extendable tab is elevated a minimal amount relative to the surrounding exterior surface of the tubular body. The extendable tab extends outward from the tubular body when the tubular body is in the conipressed position, for example when hammered into a drilled bore.
The friction stabilizer includes an insertion end and an opposed impact end with a weld ring having a weld ring gap space joined to the impact end, such that the weld ring gap space is diametrically opposite the tube gap space. The extendable tab extends in a direction toward the impact end and away from the insertion end.
The friction stabilizer can have another extendable tab proximal the extendable tab and positioned diametrically opposite the tube gap space. The extendable tab can be rectangular or have any suitable geometric shape.
Either embodiment of the friction stabilizer is made by similar processes. The process begins by providing a coil of metal and unrolling the coil of metal into a strip, followed by pressing the shape of the tab or extendable tab to be formed into the strip of metal. The strip is moved through cold rolling dies, and in one embodiment the strip is rolled into a tubular body having a tube gap space such that the tabs extend from the tubular body. In the other embodiment the strip is rolled into a tubular body having a tube gap space and an exterior surface such that the extendable tab is elevated a minimal amount relative to the exterior surface and is diametrically opposite the tube gap space. The method also includes providing a weld ring having a weld ring gap space and welding the weld ring to the impact end of the tubular body.
To use the friction stabilizer with tabs, a drilled bore is made in the wall or ceiling of the mine. The wall is sufficiently solid and of sufficient thickness to accommodate a bore of sufficient length, and the drilled bore has a diameter slightly less than the diameter of the tubular body. A support plate having an opening is provided, the operiing being sized such that the tubular body can pass through the opening. The opening in the plate is aligned with the drilled bore. The tapered end of the tubular body is aligned with and inserted through the opening in the plate and into the drilled bore so that the taper of the tubular body is received in the drilled bore.
Then a pneumatic or hydraulic hammer or some other means for hammering is used for pounding or driving the stabilizer with tabs into the drilled bore. As the stabilizer with tabs is driven into the drilled bore the tabs move or flex inwardly towards the exterior surface of the tubular body. This allows the friction stabilizer with tabs to be hammered into the drilled bore without the tabs impeding movement. During the pounding process the plate becomes trapped between the weld ring and the surrounding ceiling or wall of the mine, as the case may be.
Additionally, the tubular body compresses and the gap space distance decreases as the friction stabilizer is driven into the drilled bore. Then, if loading force is applied to remove the tubular body with tabs,.the tabs immediately dig into the surrounding wall which surrounds the drilled bore, making the removal of the tubular body significantly more difficult. Such loading force may come from the plate that is providing support. Thus, if the ceiling or wall begins to cave-in, the tabs will keep digging into the surrounding wall, and the friction stabilizer having tabs continues to work against a cave-in. This digging-in action could stop a cave-in in progress or limit the severity of a cave-in. Additionally, the digging-in action could provide miners with extra time to get out of harms way, or provide inspectors with time so that they can conduct an on site inspection.
The use of the friction stabilizer having the extendable tab is the same the friction stabilizer is hammered into a drilled bore. However, as the friction stabilizer is hamniered into the drilled bore, it moves from an uncompressed position to a compressed position. As this occurs, the extendable tab moves away from the exterior surface of the tubular body and extends outward and into the surrounding drilled bore. The extendable tab is positioned deep in the drilled bore after hammering, which advantageously provides the friction stabilizer with increased axial load carrying capacity.
Cave-ins are a constant threat associated with underground mining operations. It is difficult to predict when and where a cave-in will occur.
Typically, workers are provided with little or no warning prior to a cave-in, and thus they have a minimal amount of time to react to a cave-in. Indeed, mine walls or ceilings that appear fine upon visual inspection may have significant fractures just below their surfaces, making them structurally weak and prone to collapse. Cave-ins are very destructive and may result in miners becoming trapped and/or injured.
Additionally, equipment and niachinery may be damaged or destroyed.
Friction type stabilizers have been used in mining operations to stabilize walls and ceilings of the mine. Such stabilizers are pounded into bores drilled in mine walls and ceilings. The stabilizers fonn a friction fit with the drilled bore. But, these stabilizers may slide out of the drilled bores when the rock wall or ceiling shifts/moves, and in such situations the stabilizers are unable to prevent a rnine wall or ceiling cave-in.
Therefore, it would be desirable to provide a new and improved stabilizer that decreases the likelihood of a cave-in. It would also be desirable if the stabilizer was compatible with existing mining equipment and inexpensive to fabricate.
The friction stabilizer with tabs according to this invention is used to secure the walls and ceilings of mines to thus prevent a cave-in from occurring. The friction stabilizer with tabs comprises a hollow body, preferably tubular. The tubular body comprises ati impact end, an insertion end, a first portion and a second portion.
The second portion has a notch and is tapered.
The tubular body has an interior and an exterior surface, and tabs are connected to and extend from the tubular body. The tabs extend in a direction leading away from the insertion end of the tubular body and in a direction leading towards the impact end of the tubular body. The tabs each make an acute angle with the exterior surface of the tubular body. The tabs can be rectangular shaped and there can be three such tabs extending from the exterior surface of the tubular body. Each rectangular shaped tab further comprises parallel tab side edges and a tab free edge connecting between the tab side edges.
In other embodiments, the tabs may be triangular shaped tabs, curved shaped tabs, polygonal shaped tabs, U-shaped tabs, tabs having both curved portions and linear portions, semi-circular shaped tabs, hook shaped tabs, parabolic shaped tabs, and combinations of the above. Also, the tabs can be of any shape that inhibits the withdrawal of the friction stabilizer with tabs from the drilled bore in a mine. The above-described tabs are punched into the sheet from which the tubular body is formed by a punching machine, thus they are joined to the tubular body at bends.
The tubular body further comprises a first gap space wall and a second gap space wall spaced apart from one another by a tube gap space. The tube gap space is used for allowing the tubular body to be compressed radially inward when the tubular body is driven into a drilled bore in a mine having, the drilled bore having a diameter less than the outer diameter of the tubular body.
The friction stabilizer further comprises a weld ring having a weld ring gap space, and the weld ring is joined to the tubular body such that the weld ring gap space and tube gap space are aligned. The weld ring is joined to the exterior surface of the first portion of the tubular body at the impact end of the tubular body by, for example, a weld. The weld ring gap space is used for allowing the weld ring to be compressed radially inward. 'The weld ring can have a rectangular cross section or a circular cross section.
In another embodiment, a friction stabilizer for installation in a structural body is provided. The friction stabilizer has a tubular body comprising a first portion a bent portion and a second portion with and the bent portion joining the first portion and second portion. The first portion has an extendable tab and a joining portion joins the extendable tab and the tubular body such that the extendable tab is proximal the bent portion. The friction stabilizer also has a tube gap space and an opening diametrically opposite the tube gap space, such that the extendable tab extends from the joining portion into the opening. The extendable tab is diametrically opposite the tube gap space.
The tubular body is movable from an uncompressed position to a compressed position, such that when in the tubular body is in the uncompressed position the extendable tab is partly positioned in the opening. The tubular body also has an exterior surface and when in the uncompressed position the extendable tab is elevated a minimal amount relative to the surrounding exterior surface of the tubular body. The extendable tab extends outward from the tubular body when the tubular body is in the conipressed position, for example when hammered into a drilled bore.
The friction stabilizer includes an insertion end and an opposed impact end with a weld ring having a weld ring gap space joined to the impact end, such that the weld ring gap space is diametrically opposite the tube gap space. The extendable tab extends in a direction toward the impact end and away from the insertion end.
The friction stabilizer can have another extendable tab proximal the extendable tab and positioned diametrically opposite the tube gap space. The extendable tab can be rectangular or have any suitable geometric shape.
Either embodiment of the friction stabilizer is made by similar processes. The process begins by providing a coil of metal and unrolling the coil of metal into a strip, followed by pressing the shape of the tab or extendable tab to be formed into the strip of metal. The strip is moved through cold rolling dies, and in one embodiment the strip is rolled into a tubular body having a tube gap space such that the tabs extend from the tubular body. In the other embodiment the strip is rolled into a tubular body having a tube gap space and an exterior surface such that the extendable tab is elevated a minimal amount relative to the exterior surface and is diametrically opposite the tube gap space. The method also includes providing a weld ring having a weld ring gap space and welding the weld ring to the impact end of the tubular body.
To use the friction stabilizer with tabs, a drilled bore is made in the wall or ceiling of the mine. The wall is sufficiently solid and of sufficient thickness to accommodate a bore of sufficient length, and the drilled bore has a diameter slightly less than the diameter of the tubular body. A support plate having an opening is provided, the operiing being sized such that the tubular body can pass through the opening. The opening in the plate is aligned with the drilled bore. The tapered end of the tubular body is aligned with and inserted through the opening in the plate and into the drilled bore so that the taper of the tubular body is received in the drilled bore.
Then a pneumatic or hydraulic hammer or some other means for hammering is used for pounding or driving the stabilizer with tabs into the drilled bore. As the stabilizer with tabs is driven into the drilled bore the tabs move or flex inwardly towards the exterior surface of the tubular body. This allows the friction stabilizer with tabs to be hammered into the drilled bore without the tabs impeding movement. During the pounding process the plate becomes trapped between the weld ring and the surrounding ceiling or wall of the mine, as the case may be.
Additionally, the tubular body compresses and the gap space distance decreases as the friction stabilizer is driven into the drilled bore. Then, if loading force is applied to remove the tubular body with tabs,.the tabs immediately dig into the surrounding wall which surrounds the drilled bore, making the removal of the tubular body significantly more difficult. Such loading force may come from the plate that is providing support. Thus, if the ceiling or wall begins to cave-in, the tabs will keep digging into the surrounding wall, and the friction stabilizer having tabs continues to work against a cave-in. This digging-in action could stop a cave-in in progress or limit the severity of a cave-in. Additionally, the digging-in action could provide miners with extra time to get out of harms way, or provide inspectors with time so that they can conduct an on site inspection.
The use of the friction stabilizer having the extendable tab is the same the friction stabilizer is hammered into a drilled bore. However, as the friction stabilizer is hamniered into the drilled bore, it moves from an uncompressed position to a compressed position. As this occurs, the extendable tab moves away from the exterior surface of the tubular body and extends outward and into the surrounding drilled bore. The extendable tab is positioned deep in the drilled bore after hammering, which advantageously provides the friction stabilizer with increased axial load carrying capacity.
Brief Description Of The Figures FIG. 1 is an elevational view of the friction stabilizer having tabs.
FIG. 2 is a side elevational view of the friction stabilizer having tabs.
FIG. 3 is a bottom plan view of the friction stabilizer having tabs.
FIG. 4 is a top plan view of the friction stabilizer having tabs.
FIG. 5 is a sectiorial view of the friction stabilizer having tabs taken along cut line 5-5.
FIG. 6 is a sectior-al view of the friction stabilizer having tabs taken along cut line 6-6.
FIG. 7 is a top plan view of the strip of steel used to manufacture the friction stabilizer having tabs.
FIG. 8 shows a bottom plan view of a second embodiment of the friction stabilizer with rectangular tabs according to a second embodiment of the invention.
FIG. 9 shows a side elevational view of the second embodiment of the friction stabilizer with rectangular tabs.
FIG. 10 shows a top plan view of the second embodiment of the friction stabilizer with rectangular tabs.
FIG. 11 shows a sectional view of the second embodiment of the friction stabilizer with rectangular tabs taken along cut line 11-11 in FIG. 10.
FIG. 12 shows a sectional view of the second embodiment of the friction stabilizer with rectangular tabs taken along cut line 12-12 in FIG. 8.
FIG. 13 shows a bottom plan view of a third embodiment of the friction stabilizer with tabs.
FIG. 14 shows a side elevational view of the third embodiment of the friction stabilizer with tabs.
FIG. 15 shows a'top plan view of the third embodiment of the friction stabilizer with tabs.
FIG. 16 shows a sectional view of a third embodiment of the friction stabilizer with.
tabs taken along cut line 16-16 in FIG. 15. 30 FIG. 17 shows a sectional view of the third embodiment of the friction stabilizer with tabs taken along cut line 17-17 in FIG. 13.
FIG. 18 shows a bottom plan view of a fourth embodiment of the friction stabilizer with tabs.
FIG. 19 shows a side elevational view of the fourth embodiment of the friction stabilizer with tabs.
FIG. 20 shows a top plan view of the fourth embodiment of the friction stabilizer with tabs.
FIG. 21 shows a sectional view of the fourth embodiment of the friction stabilizer with tabs taken along cut line 21-21 in FIG. 20.
FIG. 22 shows a sectional view of the fourth embodiment of the friction stabilizer with tabs taken along cut line 22-22 in FIG. 18.
FIG. 23 shows a bottom plan view of a fifth embodiment of the friction stabilizer with tabs.
FIG. 24 shows a side elevational view of the fifth embodiment of the friction stabilizer with tabs.
FIG. 25 shows a top plan view of the fifth embodiment of the friction stabilizer with tabs.
FIG. 26 shows a cross sectional view of the fifth embodiment of the friction stabilizer with tabs taken along cut line 26-26 in FIG. 25.
FIG. 27 shows a cross sectional view of the fifth embodiment of the friction stabilizer with tabs taken along cut line 27-27 in FIG. 23.
FIG. 27A shows a top plan view of a of a sixth embodiment of the friction stabilizer with tabs having a plurality of differently shaped tabs.
FIG. 28 is a diagrammatic view of the manufacturing process used for manufacturing the friction stabilizer with tabs.
FIG. 29 is a top plan view of the weld ring having a circular shaped cross section.
FIG. 30 is a sectional view taken along cut line 30-30 in FIG. 29 of the weld ring having a circular shaped cross section.
FIG. 30a is a view, partly in section, of the circular weld ring and tubular body joined together with a weld.
FIG. 31 is a top plan view of the weld ring having a rectangular shaped cross section.
FIG. 32 is a sectional view taken along cut line 32-32 in FIG. 31 of the weld ring having a rectangular shaped cross section.
FIG. 32a is a view, partly in section, of the rectangular weld ring and tubular body joined together with a weld.
FIG. 33 is a top plan view of the planar plate.
FIG. 34 is a sectional view of the planar plate taken along cut line 34-34 in FIG. 33.
FIG. 35 is a top plan view of the domed plate.
FIG. 36 is a sectional view of the domed plate taken along cut line 36-36 in FIG. 35.
FIG. 37 is a sectional view of a mine showing friction stabilizers having tabs deployed in the mine.
FIG. 38 is a bottom plan view of a seventh embodiment of the friction stabilizer having an extendable tab.
FIG. 39 is a front elevational view of the of the seventh embodiment of the friction stabilizer having the extendable tab.
FIG. 40 is a top plan view of the seventh embodiment of the friction stabilizer having the extendable tab.
FIG. 41 is a is a sectional view of the seventh embodiment taken along cut line cut line 41-41 as shown in FIG. 40.
FIG. 42 is a sectional view of the seventh embodiment taken along cut-line 42-42 as shown in FIG. 38.
FIG. 43 is a sectional view of a mine showing the friction stabilizer having the extendable tab.
FIG. 44 shows an enlarged view, partly in section, of FIG. 43.
FIG. 45 is a diagrammatic view of the manufacturing process used for manufacturing the friction stabilizer with extendable tabs.
Description At the outset, it noted that like reference numbers are intended to identify the same structure, portions, or surfaces consistently throughout the figures.
It is also noted that when the term "about" is used in connection with describing a number that the riumber includes numbers in decimal form that can be rounded to that number.
Shown generally in FIGS. 1-6 is the friction stabilizer 20 with tabs 25.
FIG. 4 shows a top plan view of the friction stabilizer with tabs 20. As shown in FIGS. 1 and 3, the friction stabilizer with tabs 20 comprises a tubular body 22 having tabs 25 extending therefrom. The tubular body 22 is elongate and has a first portion 33 and a second portion 34. The second portion 34 is formed integral joined to the first portion 33, and the second portion 34 has a taper 35. The tubular body 22 has an impact end 30 and an insertion end 32 that are spaced from one another by the length, designated L in FIG. 4, of the tubular body 22. The taper 34 extends from the insertion end 32 in a direction toward the impact end 30, until it reaches the first portion 33. The tubular body 22 may comprise a total length L of about sixty inches, about four inches of which comprise the second portion 34 having the taper 35.
The tubular body 22 further comprises an interior surface 24 and an exterior surface 26, as shown in FIGS. 3 and 5. The interior surface 24 defines a stabilizer interior 23 internal to the tubular body 22.
As further shown in FIGS. 3 and 5, the tubular body 22 has a first gap space wall 27 and a second gap space wall 29 which are spaced apart from one another. The first and second gap space walls 27, 29, respectively, extend along the length L of the tubular body 22, from the impact end 30 of the tubular body 22 to the insertion end 32 of the tubular body 22. The first and second gap space walls, 27, 29, respectively, define a tube gap space 28 between them, that extends in the direction of the of the longitudinal axis, designate X in FIG. 2, of the tubular body 22.
As shown in FIGS 3 and 5, the tube gap space 28 extends along the length L of the body 22, from the impact end 30 to the insertion end 32 of the tubular body 22. The tube gap space 28 defined between the first and second gap space walls 27, 29 is used for allowing tubular body 22 to be compressed radially inward. In a manner to be described presently, the diameter designated D in FIG. 5, of the tubular body decreases when the tubular body 22 is driven into a drilled bore 50 formed in a wall 52 or ceiling 54 of a mine 56, as shown in FIG. 37. The drilled bore 50 has a bore diameter 51, designated B in FIG. 37, that is less than the diameter D of the tubular body 22.
A notch 36 is defined in the taper 35 of the second portion 34 of the tubular body 22. The notch 36 allows the taper 35 to be formed in the tubular body 22 at the insertion end 32 thereof when the tubular body 22 is being rolled.
The taper is used for allowing the insertion end 32 of the tubular body 22 to be initially fitted or inserted into the drilled bore 50. After the taper 35 is fitted into the drilled bore 50, 30 the impact end 30 of the tubular body 22 can be pounded causing the tubular body 22 to move into the drilled bore 50.
In accordance with the invention, the tubular body 20 comprises tabs 25 that extend from the exterior surface 26 in a direction toward the impact end 30 of the tubular body 20, and away from the insertion end 32 of the tubular body 22. The tabs 25 work against the removal of the tubular body 22 from a drilled bore 50 in a mine 56. As a result, the tabs 25 advantageously decrease the likelihood of a mine 56 cave-in, as will be described presently.
In a preferred embodiment, the tabs 25 are embodied to be rectangular shaped tabs 40. In particular, there is a first rectangular shaped tab 40a, a second rectangular shaped tab 40b, and a third rectangular shaped tab 40c. The first rectangular shaped tab 40 is positioned closest to the insertion end 32 of the tubular body 22, and the third rectangular shaped tab 40c is positioned farthest from the insertion end 32 of the tubular body 22, as shown in FIG. 4. The second rectangular shaped tab 40b is positioned between the first and second rectangular shaped tabs 40a, 40c, respectively. The first, second, and third rectangular shaped tabs 40a, 40b, and 40c respectively, are punched out of, laser cut, or otherwise formed in the tubular body 22, in ainethod to be described presently.
The first, second, and third rectangular shaped tabs 40a, 40b, and 40c, respectively, extend outward from the exterior surface 26 of the tubular body 22.
Each rectangular shaped tab 40a, 40b, 40c comprises two parallel tab side edges 43 and a tab free edge 45 that extends between the tab side edges 43, as shown in FIG. 7, which is a top plan view of the flat strip of metal 102 from which the tubular body 22 is formed. The tab side edges 43 and tab free edges 45 are shown in FIGS. 1, 6, and 7. It is noted that the tabs 40a, 40b, and 40c shown throughout FIGS. 1-6 are structurally the same.
Each of the rectangular shaped tabs 40a, 40b, and 40c, respectively, is joined to the tubular body 22 along a bend 44, with the bend being opposite the tab free edge 45. The bends 44 are closer to the insertion end 32 of the tubular body 22 than the tab free edge 45. Each of the rectangular shaped tabs 40a, 40b, and 40c, respectively, makes an acute angle with the exterior surface 26 of the tubular body 22, as shown in FIG. 2. Also, the rectangular shaped tabs 40a, 40b, and 40c, respectively, extend in a direction leading away from the insertion end 32 of the tubular body 22, and in a direction leading toward the impact end 30 of the tubular body 22, as shown in FIG. 2. The rectangular shaped tabs 40a, 40b, and 40c, respectively, are spaced apart from one another along the tubular body 22, and are formed in the tubular body 22 such that they are opposite to the tube gap space 28, as shown in FIG. 6.
It is further noted that there are openings 48, as shown in FIG. 2, in the tubular body 22 under the rectangular shaped tabs 40a, 40b, and 40c, respectively, where they extend from the exterior surface 26.
Then, when the tubular body 22 is pounded into a drilled bore 50 insertion end 32 first, the rectangular shaped tabs 40a, 40b, and 40c, respectively, bend inward along their bends 44 in a direction toward the openings 48 in the tubular body 22. In other words, the rectangular shaped tabs 40a, 40b, and 40c, respectively, move back into the tubular body 22 from which they were punched, and thus they do not impede the tubular body 22 from being pounded into the drilled bore 50 in the wall 52 or ceiling 54 of the mine 56, as shown in FIG. 37. Then, in the event of a mine cave-in or wall collapse, the tubular body 22 advantageously remains in place and supports the mine wall 52 or ceiling 54, since the rectangular shaped tabs 40a, 40b, and 40c, respectively, resist removal from the drilled bore 50 and dig into the surrounding rock. This is due to the fact that the natural spring constant of the first, second, and third rectangular shaped tabs 40a, 40b, 40c, respectively, forces them to dig into the drilled bore 50.
The three rectangular shaped tabs 40a, 40b, and 40c, respectively, are spaced along a tubular body 22 about sixty inches long such that the first tab 40a is about four inches from the insertion end 32 of the tubular body 22, the second tab 40b is about fourteen inches from the insertion end 32 of the tubular body 22, and the third tab 40c is about twenty-four inches from the insertion end 32 of the tubular body 22.
The rectangular shaped tabs 40a, 40b, and 40c, respectively, can be sized such that the tab side edges 43 are about 0.5 inches long, and the tab free edge 45 is about 1.0 inch.
The rectangular shaped tabs 40a, 40b, and 40c, respectively, advantageously provide for a stabilizer 20 that, when installed in a mine, can support greater loads than stabilizers having smooth exterior surfaces. Of course, the dimensions may differ in other embodiments.
The friction stabilizer 20 further includes a weld ring 31 that in one embodiment is rectangular shaped, that is, its cross section is rectangular shaped as shown in FIGS. 31, 32, and 32a. The rectangular shaped weld ring 31 has a weld ring gap space 39 and flat sides 31a. The rectangular shaped weld ring 31 is positioned around exterior surface 26 of the tubular body 22 adjacent to the impact end thereof, as shown in FIGS. 1-4. The weld ring gap space 39 is aligned with the tube gap space 28 defined in the tubular body 22. The rectangular shaped weld ring 31 is welded to the exterior surface 26 of the tubular body 22. The weld 49 that joins the tubular body 22 and rectangular shaped weld ring 31 is best shown in FIG. 5.
It is noted that the weld ring gap space 39 and tube gap space 28 allow for the tubular body 22 to be compressed as it is driven into the drilled bore 50 having a bore diameter 51 less than the diameter of the tubular body 22. The rectangular shaped weld ring 31 is used for supporting a plate 58 in a manner to be described presently.
In another embodiment, the rectangular shaped weld ring 31 and the tubular body 22 can be welded together, without the tube gap space 28 and weld ring gap space being aligned.
FIG 5 is a sectional view of the tubular body 22 taken along cut line 5-5 of FIG. 3, and FIG. 6 is a sectional view of the tubular body 22 taken along cut line 6-6 of FIG. 3.
It is noted that a circular shaped weld ring 37 having a circular shaped cross section, as shown in FIGS. 29, 30, and 30a, can be successfully used in accordance with the present invention. However, the rectangular shaped weld ring 31 having a rectangular shaped cross section advantageously provides for a higher quality weld. This is due to the fact that a space 38 can form during the welding process under the weld 49 that joins the circular shaped weld ring 37 and the exterior surface 26 of the tubular body 22, as shown in FIG. 30a. Additionally, to successfully weld the circular shaped weld ring 37 to the tubular body 22, the weld gun must be accurately positioned. However, such accurate positioning is oftentimes difficult to achieve, because the machinery that does the welding vibrates excessively. As a result, the majority of the weld 49 can end up on the circular shaped weld ring 37 or on the exterior surface 26 of the tubular body 22. Thus, the weld 49 may end up catching only one of the circular shaped weld ring 37 or exterior surface 26 of the tubular body 22, and/or a space 38 may be formed under the weld 49 as shown in FIG. 30a.
The rectangular shaped weld ring 31 shown in FIGS. 31, 32, and 32a advantageously has flat sides 31a. As a result there is no space 38 between the flat surfaces 3 la rectangular shaped weld ring 31 and the exterior surface 26 of the tubular body 22, since these two surfaces make direct contact with one another leaving no room for a space 38 to form under the weld 49. Thus, a high quality weld 49 can be made between the flat surfaces 31a of the rectangular shaped weld ring 31 and exterior surface 26 of the tubular body 22, even in the presence of the vibrations generated by the welding machines.
The above-described invention can be variously embodied. FIGS. 8-12 generally show a second embodiment of the friction stabilizer 20a having rectangular shaped tabs 40. The tubular body 22a of the second embodiment is substantially the same as the tubular body 22 of the first embodiment, in that the tubular body 22a comprises an exterior surface 26, first and second gap space walls 27,29, respectively, a tube gap space 28, an impact end 30, an insertion end 32, a rectangular weld ring 31 having a weld ring gap space 39, a first portion 33, and a second portion 34 having a taper 35 having a notch 36. Each rectangular tab 40 of the second embodiment has parallel tab side edges 43 and a tab free edge 45. The second embodiment comprises a row 128 of rectangular shaped tabs 40 that are joined to the tubular body 22a at bends 44, and which are spaced from one another at predetermined spaced intervals, designated I in FIG. 9, along the length L of the tubular body 22a. It is noted that the row 128 extends from the side of the tubular body 22a opposite the tube gap space 28. As shown in FIGS. 8-10, there are five rectangular shaped tabs 40 in the row 128. Of course, in other embodiments, the row of tabs 128 may comprise fewer or more than five rectangular shaped tabs 40.
FIG. I 1 is a sectional view of the tubular body of the second embodiment taken along cut line 11-11 of FIG. 10, and FIG. 12 is a sectional view of the tubular body of the second embodiment taken along cut line 12-12 taken of FIG.
8. The tubular body 22a can be used for supporting the walls 52 and ceiling 54 of a mine 56 in the same manner as previously described in connection with the first embodiment.
FIGS. 13-17 generally show a third embodiment of the friction stabilizer 20b with tabs. In this embodiment, the tubular body 22b comprises triangular shaped tabs 41. The tubular body 22b of the third embodiment is substantially the same as the tubular body 22 of the first embodiment, in that the tubular body 22b comprises an exterior surface 26, first and second gap space walls 27,29, respectively, a tube gap space 28, an impact end 30, insertion end 32, a rectangular weld ring 31 having a weld ring gap space 39, a first portion 33, and a second portion 34 having a taper 35 having a notch. Each triangular shaped tab 41 of the third embodiment has two edges 46 that meet at a point 47, thus forming a triangle shape. The triangular shaped tabs 41 are joined to the tubular body 22b at bends 44, as shown. There is a row 129 of triangular shaped tabs 41 that extend from the tubular body 22b at predetermined spaced intervals, designated I in FIG. 13, along the length L of the tubular body 22b. It is noted that the row 128 extends from the side of the tubular body 22b opposite the tube gap space 28. As shown in FIGS. 13-17, there are five triangular shaped tabs 41 in the row 130. In other embodiments, the row of triangular shaped tabs 130 may comprise fewer or more than five triangular shaped tabs 41.
FIG. 16 is a sectional view taken along cut line 16-16 of FIG. 15, and FIG. 17 is a sectional view taken along cut line 17-17 of FIG. 13. The tubular body 22b can be used in the same manner as described above in connection with the first embodiment for supporting the walls 52 and ceiling 54 of a mine 56.
FIGS. 18-22 generally show a fourth embodiment of the friction stabilizer 20c with tabs. In the fourth embodiment, the tubular body 22c comprises a plurality of rows 128 of rectangular shaped tabs 40. The rectangular shaped tabs 40 in each row 128 are spaced from one another, and the rows 128 are spaced about ninety degrees from one another about the exterior surface 26 of the tubular body 22c, as viewed in sectional figures 21 and 22. The tubular body 22c of the fourth embodiment is substantially the same as the tubular body 22 of the first embodiment, in that the tubular body 22c comprises an exterior surface 26, first and second gap space walls 27,29, respectively, a tube gap space 28, an impact end 30, insertion end 32, a rectangular weld ring 31 having a weld ring gap space 39, a first portion 33, and a second portion 34 having a taper 35 having a notch. Each rectangular shaped tab 40 of the fourth embodiment is joined to the tubular body 22c at a bend 44, and extends in a direction toward the weld ring 31. As shown in FIGS. 18-22 there are three rows 128 of the rectangular shaped tabs 40, with five rectangular shaped tabs 40 per row.
In other embodiments, there can even be more rows 128 of rectangular shaped tabs 40 provided for on the tubular body 22c, or the number of rectangular shaped tabs 40 in each row may be increased or decreased.
FIG. 21 is a sectional view taken along cut line 21-21 of FIG. 20, and FIG. 22 is a sectional view taken along cut line 22-22 of FIG 18. The tubular body 22c can be used in the same manner as described above in connection with the first embodiment for supporting the walls 52 and ceiling 54 of a mine 56.
FIGS. 23-27 generally show a fifth embodiment of the friction stabilizer 20d. In the fifth embodiment, the tubular body 22d comprises a plurality of rows 130 of triangular shaped tabs 41. The tubular body 22d of the fifth embodiment is substantially the same as the tubular body 22 of the third embodiment, in that the tubular body 22d comprises an exterior surface 26, first and second gap space walls 27,29, respectively, a tube gap space 28, an impact end 30, insertion end 32, a rectangular weld ring 31 having a weld ring gap space 39, a first portion 33, and a second portion 34 having a taper 35 having a notch. Each triangular shaped tab 41 of the fifth embodiment is joined to the tubular body 22d at a bend 44, and extends away from the tubular body 22d. The edges 46 of each triangular shaped tab 41 meet at a point 47. As shown in FIGS. 23-25 there are three rows 130 of the triangular shaped tabs 41, with five tabs 41 per row 130. The rows 130 of triangular shaped tabs 41 are spaced about ninety degrees from one another about the exterior surface 26 of the tubular body 22d, as viewed in FIGS. 26 and 27. In yet other embodiments, there can even be more rows 130 of triangular shaped tabs 41 provided for on the tubular body 22d.
FIG. 26 is a sectional view taken along cut line 26-26 of FIG. 25, and FIG. 27 is a sectional view taken along cut line 27-27 of FIG. 23. The tubular bod_v 22d can be used in the same manner as described above in connection with the first embodiment for supporting the walls 52 and ceiling 54 of a mine 56.
Shown in FIG. 27A is a sixth embodiment of the friction stabilizer 20e wherein the tubular body 22e has a plurality of differently shaped tabs 25.
The tabs 25 may be curved shaped tabs, rectangular shaped tabs, triangular shaped tabs, polygonal shaped tabs, U-shaped tabs, tabs having both curved portions and linear portions, semi-circular shaped tabs, hook shaped tabs, parabolic shaped tabs, combinations of the above, or any other shaped tab that inhibits the withdrawal of the friction stabilizer 20e from the drilled bore 50 in the mine 56. The above-described tabs 25 may extend in patterns, rows, series, or randomly from the exterior surface 26 of the friction stabilizer 20e. As shown in FIG. 27A, a plurality of differently shaped tabs 25, as described above, extend from the friction stabilizer 20e. In other embodiments, a single tab 25, for example a rectangular shaped tab 40 or a triangular shaped tab 41, may extend from the exterior surface 26 of the friction stabilizer 20.
The single tab may be any of the above shapes. Thus, the present invention has significant versatility and may be variously embodied, and all of these embodiments are within the scope of the present invention.
In a seventh embodiment shown in FIGS. 38-45, there is a friction stabilizer 20f having a tubular body 22f. As shown in FIGS. 38-42, the tubular body 22f is elongate and has a first portion 33 a bent portion 53 and a second portion 34 with the bent portion 53 joining the first portion 33 and the second portion 34. The tubular body 22f is preferably formed as one piece. The first portion 33 has an impact end 30 and the second portion 34 has an opposed insertion end 32. The first portion 33 also has a weld ring 31 joined to it with, for example a weld 49, and the weld ring 31 can have a rectangular or circular cross section. The second portion 34 of the tubular body 22f has a taper 35, and the taper 35 extends from the insertion end 32 in a direction toward the impact end 30 until it meets with the bent portion 53.
In addition, the tubular body 22f includes an interior surface 24 that is concave and an opposed exterior surface 26 that is convex, as shown in FIGS.
41 and 42. The interior surface 24 defines a stabilizer interior 23 that is internal to the tubular body 22f.
As further shown in FIGS. 38, 41 and 42, the tubular body 22f has a first gap space wall 27 and a second gap space wall 29 which are spaced apart from one another and face one another. As shown in FIG. 39, the first and second gap space walls 27, 29, respectively, extend along the length of the tubular body 22f, designated L in FIG. 39, from the impact end 30 of the tubular body 22f to the insertion end 32 of the tubular body 22f. A tube gap space 28 extends from the first gap space wall 27 to the second gap space wall 29 and the length L of the tubular body 22f, from the impact end 30 to the insertion end 32. As shown in FIGS. 40-43, the weld ring 31 has a weld ring gap space 39, and the weld ring 31 is welded to the first portion 33 with a weld 49, such that the weld ring gap space 39 is diametrically opposite the tube gap space 28, as shown in FIG. 41.
In addition, the tubular body 22f is capable of being compressed radially inward because of the tube gap space 28. In a manner to be described presently, the diameter of the tubular body 22f designated D in FIG. 39 decreases when the tubular body 22f is hammered into a drilled bore 50 having a smaller diameter, designated B in FIG. 43, as will be described in greater detail presently.
As shown in FIGS. 38, 39 and 42, a notch 36 is defined in the taper 35 of the second portion 34 of the tubular body 22f. The notch 36 extends from the insertion end 32 partly into the second portion 34 of the tubular body 22f.
The taper 35 of the second portion 34 increases in the vicinity of the notch 36. Thus, the tube gap space 28 decreases in the second portion 34 due to the taper 35, and tube gap space 38 decreases an additional amount in the vicinity of the notch 36. This facilitates introduction of the tubular body 22f into the drilled bore 50. In addition, the notch 36 allows the taper 35 to be formed in the tubular body 22f at the insertion end 32 thereof when the tubular body 22f is roll formed. After the taper 35 is fitted into the drilled bore 50, the impact end 30 of the tubular body 22f can be hammered causing the tubular body 22f to move into the drilled bore 50.
The tubular body 22f has a thickness designated TT as shown in FIG.
41 which extends from the exterior surface 24 to the opposed interior surface 26 of the tubular body 22f.
As shown in FIGS. 38-40 and 42, the tubular body 22f has a single extendable tab 25b that is joined to the first portion 32 of the tubular body 22f with a tab joining portion 180. The extendable tab 25b is positioned diametrically opposite the tube gap space 28. In addition, and extendable tab 25b is proximal the bent portion 37. In particular, the extendable tab 25b is positioned such that moving from right to left in FIGS. 38-40, the insertion end 32 is first encountered and then the second portion 34 is encountered. Next, the bent portion 53 is encountered, and then the first portion 33 is encountered with the tab joining portion 180 and extendable tab 25b being encountered immediately thereafter. Thus, the extendable tab 25b is proximal the bent portion 53, but not joined to the bend portion 53. In addition, the extendable tab 25b extends in a direction leading away from the insertion end 32 of the tubular body 22f and in a direction leading towards the impact end 30 of the tubular body 22f, as shown in FIGS. 38-40.
As previously mentioned, the tubular body 22f is capable of compressing radially inward, for example when it is hammered into a drilled bore 50 having diameter less than that of the tubular body 22f, as will be described presently.
The tube gap space 28 allows for such inward radial compression of the tubular body 22f. Thus, the tubular body 22f is capable of moving from a non-compressed position 190 (as shown in FIGS. 38-42) to a compressed position 192 when hammered into a drilled bore.
As shown in FIGS. 38, 40 and 42, the extendable tab 25b has an interior tab surface 182 and an opposed exterior tab surface 184, and because the extendable tab 25b is formed in the tubular body 22f, it also has a thickness designated TT. The tubular body 22f has an opening 48 in which the extendable tab 25b is partly positioned. In particular, when the tubular body 22f is in the non-compressed position 190 as shown in FIGS. 38- 40 and 42, the extendable tab 25b is partly positioned in the opening 48, and partly elevated with respect to the surrounding exterior surface 26 of the tubular body 22f. As shown in FIGS. 39 and 42, the extendable tab 25b extends a minimal amount relative to the surrounding exterior surface 26 of the tubular body. Thus, the extendable tab 25b is bent at the joining portion 180 such that the extendable tab 25b makes a makes a minimal angle with respect to the surrounding exterior surface 26 of the tubular body 22f.
As shown in FIGS. 39 and 42, when tubular body 22f is in the non-compressed position 190, the extendable tab 25b is partly in the opening 48 and partly raised or elevated a minimal amount relative to the surrounding exterior surface 26 of the first portion 33, as described above.
When the tubular body 22f is radially compressed and is moved to the compressed position 192 (for example when hammered into a drilled bore 50 as will be described presently and as shown in FIGS. 43 and 44), the extendable tab 25b bends at the joining portion 180, and the extendable tab 25b moves out of the opening 48. The extendable tab 25b extends away from the exterior surface 26 the tubular body 22f, such that the extendable tab 25b makes an acute angle with the exterior surface 26 of the tubular body 22f. Thus, the extendable tab 25b is caused to move out of the opening 48 when the tubular body 22f is compressed, and is capable of moving from a non-extended position 183, as shown in FIGS. 38-40 and 42, when the tubular body 22f is in the non-compressed position 190, to an extended position 185, as shown in FIGS. 43 and 44, when the tubular body 22f is in the compressed position 192.
FIGS 43 and 44 show the friction stabilizer 20f installed in a drilled bore 50. During installation the insertion end 32 of the tubular body 22f is introduced into the drilled bore 50, and the extendable tab 25b is in the above-described non-extended position 183. As hammering begins, the tube gap space 28 decreases and the tubular body 22f begins to compress radially inward, and the extendable tab 25b moves out of the opening 48 and moves to the extended position 185 such that it contacts the drilled bore 50. After hammering, the extendable tab 25b engages the drilled bore thus increasing the axially holding capacity of the friction stabilizer 20f.
The extendable tab 25b positioned diametrically opposite the tube gap space 28 and proximal the bent portion 37, as described above, advantageously significantly increases the axial load bearing capacity of the tubular body 22f. Two extendable tabs 25b each positioned diametrically opposite the tube gap space 28 and each proximal the bent portion 37 as described above also advantageously significantly increase the holding capacity or axial load bearing capacity of the friction stabilizer 20f. The second extendable tab 25b is shown in phantom lines in FIG. 40, and as shown, the extendable tabs 25b are proximal to one another . A
third extendable tab 25b could also be formed in the tubular body 22f is the same manner as described above and in line with the other extendable tabs 25b. In other embodiments there can be more than three extendable tabs 25b each positioned diametrically opposite the tube gap space 28.
The extendable tab 25f can have any geometry, for example it can be rectangular shaped as shown in FIG. 38a. It can also be triangle shaped, curved, polygonal or virtually any shape that can engage a drilled bore 50.
There are additional advantages associated with the extendable tab 25b. For example, the tubular body 22f is safer to handle in the mine because the extendable tab 25b is in the non-extended position 183 prior to introduction into the drilled bore 50. Thus, there is a reduced likelihood that mine workers and factory works will be injured by the extendable tab 25b. Another advantage is that the extendable tab 25b does not extend outward from the surrounding exterior surface 26 of the tubular body 22f until the tubular body 22f has been hammered into the drilled bore 50, thus the friction stabilizers 20f can be neatly stacked for shipment.
Another advantage is the increased axial holding capacity of the friction stabilizer 20f.
To manufacture the friction stabilizer with tabs 20, reference is made to the schematic shown in FIG. 28. The process or method begins with a coil of metal, preferably steel or a steel alloy 100. First, a planar or flat strip of steel 102 pulled from the steel coil, in the direction indicated by the arrows in FIG.
28. The strip 102 has a width, designated W in FIG. 7, that is about three inches wide in the first embodiment. In other embodiments, the width could be more than or less than three inches, depending on the particular application or customer requirement.
As the strip of steel 102 is pulled from the coil 100, it moves onto a conveyor 105. The strip of steel 102 passes through a pressing machine 104 wherein the tab side edges 43 and tab free edges 45 are pressed into the flat strip of steel 102.
Pressing machines are well known to those having ordinary skill in the art. It is to be understood that the tab side edges 43 and free edges 45 may also be laser cut or otherwise formed in the sheet of steel 102 at this point in the manufacturing process, by the use of a laser or other device. The shape of the tab 25 is thus formed in the sheet of steel 102. It is to be further understood that any desired shape of the tab 25 could be formed by the pressing machine 104.
The strip 102 is next moved by conveyor 105 through a punching machine 106 where the notches 36 are punched out of or otherwise formed into the flat strip 102. Punching machines 106 are known to those having ordinary skill in the art. In another embodiment, the notches 36 could be punched from the strip 102 first, and then the tabs 40 pressed in the strip 102.
A means for measuring 108 continuously measures the length of the strip 102 prior to the punching machine 106 so that the notch 36 can be punched in the strip 102 at the desired position in the strip 102. The final length of the friction stabilizer with tabs 20 is thus determined by the notch 36 location in the strip 102.
Next, the strip 102 passes from the punching machine 106 and is moved by conveyor 105 through a cold roll forming mill 110. The cold roll forming mill 110 comprises a series of stands having top and bottom rolling die 112a, 112b, respectively.
Cold roll forming mills 110 are known to those having ordinary skill in the art.
As the strip 102 progresses from stand to stand in the cold rolling mill 110 it is formed into a tubular body 22 having the above-described tube gap space 28.
At the same time, the rectangular shaped tabs 40 begin to move away from the exterior surface 26 of the continuous tubular body 22z that is being formed in the cold rolling mill 110. This is attributed to the fact that the natural spring constant of the steel, steel alloy, galvanized steel, or other metal from which the continuous tubular body 22z, is made causes the rectangular shaped tabs 40 to extend from the exterior surface 26 thereof. It is noted that if the tabs do not extend out, then they may be mechanically pushed out of the tubular body 22.
As the continuous tubular body 22z exits the cold roll forming mill 110, the tabs 40 extend from it as previously described and it has notches 36, but still has to be cut to the predetermined length. The continuous tubular body 22z is then moved by conveyor 105 through a cut-off press 114, where the notch 36 in the tubular body 22 signals the cut-off press 114 to cut the tubular body 22 to the predetermined length at the notch 36. The length of the tubular body may be about 60 inches as shown in FIG. 1 and described in the first embodiment, but in other embodiments, the tubular body 22 can be formed to have a length of 18 inches, 24 inches, over six feet, or any length required for the particular job, application, or customer order.
The tubular body 22 is then placed on conveyor 105 and transported to a swaging station 116. At the swaging station 116, the insertion end 32 of the tubular body 22, where the notch 36 is located, has pressure applied to it such that the taper 35 is formed at the insertion end 32. It is noted that the notch 36 provides the space for the taper 35 to be formed in the section portion 34 in the swaging station 116.
The tubular body 22 is then moved by a conveyor 105 to a welding station 118. At the welding station 118 the rectangular shaped weld ring 38 is fitted about the impact end 30 of the tubular body 22, such that the weld ring gap space 39 aligns with the tube gap space 28. In another embodiment the weld ring gap space 39 and tube gap space 28 are not aligned. While held in this position by the welding machine, the tubular body 22 and weld ring 38 are welded together, and thus joined by a weld 49. Welding stations 118 are well known to those having ordinary skill in that art. After welding, the weld ring 38 is joined with the impact end 30 of the tubular body 22. The weld ring gap space 39 may be laser cut or punched out of the weld ring 38.
After exiting the welding station 118, the tubular bodies 22 are moved by conveyor 105 to a packing station 120 having an automatic packaging machine 121. Every other tubular body 22 is then turned end over end and automatically packaged in bundles 122 of, for example, six tubular bodies 22, by the automatic packaging machine 121. Automatic packaging machines 121 are known to those having ordinary skill in the art. The bundles 122 are transported by conveyor 105 to a shipping station 124, placed in crates 126, and shipped.
FIG. 2 is a side elevational view of the friction stabilizer having tabs.
FIG. 3 is a bottom plan view of the friction stabilizer having tabs.
FIG. 4 is a top plan view of the friction stabilizer having tabs.
FIG. 5 is a sectiorial view of the friction stabilizer having tabs taken along cut line 5-5.
FIG. 6 is a sectior-al view of the friction stabilizer having tabs taken along cut line 6-6.
FIG. 7 is a top plan view of the strip of steel used to manufacture the friction stabilizer having tabs.
FIG. 8 shows a bottom plan view of a second embodiment of the friction stabilizer with rectangular tabs according to a second embodiment of the invention.
FIG. 9 shows a side elevational view of the second embodiment of the friction stabilizer with rectangular tabs.
FIG. 10 shows a top plan view of the second embodiment of the friction stabilizer with rectangular tabs.
FIG. 11 shows a sectional view of the second embodiment of the friction stabilizer with rectangular tabs taken along cut line 11-11 in FIG. 10.
FIG. 12 shows a sectional view of the second embodiment of the friction stabilizer with rectangular tabs taken along cut line 12-12 in FIG. 8.
FIG. 13 shows a bottom plan view of a third embodiment of the friction stabilizer with tabs.
FIG. 14 shows a side elevational view of the third embodiment of the friction stabilizer with tabs.
FIG. 15 shows a'top plan view of the third embodiment of the friction stabilizer with tabs.
FIG. 16 shows a sectional view of a third embodiment of the friction stabilizer with.
tabs taken along cut line 16-16 in FIG. 15. 30 FIG. 17 shows a sectional view of the third embodiment of the friction stabilizer with tabs taken along cut line 17-17 in FIG. 13.
FIG. 18 shows a bottom plan view of a fourth embodiment of the friction stabilizer with tabs.
FIG. 19 shows a side elevational view of the fourth embodiment of the friction stabilizer with tabs.
FIG. 20 shows a top plan view of the fourth embodiment of the friction stabilizer with tabs.
FIG. 21 shows a sectional view of the fourth embodiment of the friction stabilizer with tabs taken along cut line 21-21 in FIG. 20.
FIG. 22 shows a sectional view of the fourth embodiment of the friction stabilizer with tabs taken along cut line 22-22 in FIG. 18.
FIG. 23 shows a bottom plan view of a fifth embodiment of the friction stabilizer with tabs.
FIG. 24 shows a side elevational view of the fifth embodiment of the friction stabilizer with tabs.
FIG. 25 shows a top plan view of the fifth embodiment of the friction stabilizer with tabs.
FIG. 26 shows a cross sectional view of the fifth embodiment of the friction stabilizer with tabs taken along cut line 26-26 in FIG. 25.
FIG. 27 shows a cross sectional view of the fifth embodiment of the friction stabilizer with tabs taken along cut line 27-27 in FIG. 23.
FIG. 27A shows a top plan view of a of a sixth embodiment of the friction stabilizer with tabs having a plurality of differently shaped tabs.
FIG. 28 is a diagrammatic view of the manufacturing process used for manufacturing the friction stabilizer with tabs.
FIG. 29 is a top plan view of the weld ring having a circular shaped cross section.
FIG. 30 is a sectional view taken along cut line 30-30 in FIG. 29 of the weld ring having a circular shaped cross section.
FIG. 30a is a view, partly in section, of the circular weld ring and tubular body joined together with a weld.
FIG. 31 is a top plan view of the weld ring having a rectangular shaped cross section.
FIG. 32 is a sectional view taken along cut line 32-32 in FIG. 31 of the weld ring having a rectangular shaped cross section.
FIG. 32a is a view, partly in section, of the rectangular weld ring and tubular body joined together with a weld.
FIG. 33 is a top plan view of the planar plate.
FIG. 34 is a sectional view of the planar plate taken along cut line 34-34 in FIG. 33.
FIG. 35 is a top plan view of the domed plate.
FIG. 36 is a sectional view of the domed plate taken along cut line 36-36 in FIG. 35.
FIG. 37 is a sectional view of a mine showing friction stabilizers having tabs deployed in the mine.
FIG. 38 is a bottom plan view of a seventh embodiment of the friction stabilizer having an extendable tab.
FIG. 39 is a front elevational view of the of the seventh embodiment of the friction stabilizer having the extendable tab.
FIG. 40 is a top plan view of the seventh embodiment of the friction stabilizer having the extendable tab.
FIG. 41 is a is a sectional view of the seventh embodiment taken along cut line cut line 41-41 as shown in FIG. 40.
FIG. 42 is a sectional view of the seventh embodiment taken along cut-line 42-42 as shown in FIG. 38.
FIG. 43 is a sectional view of a mine showing the friction stabilizer having the extendable tab.
FIG. 44 shows an enlarged view, partly in section, of FIG. 43.
FIG. 45 is a diagrammatic view of the manufacturing process used for manufacturing the friction stabilizer with extendable tabs.
Description At the outset, it noted that like reference numbers are intended to identify the same structure, portions, or surfaces consistently throughout the figures.
It is also noted that when the term "about" is used in connection with describing a number that the riumber includes numbers in decimal form that can be rounded to that number.
Shown generally in FIGS. 1-6 is the friction stabilizer 20 with tabs 25.
FIG. 4 shows a top plan view of the friction stabilizer with tabs 20. As shown in FIGS. 1 and 3, the friction stabilizer with tabs 20 comprises a tubular body 22 having tabs 25 extending therefrom. The tubular body 22 is elongate and has a first portion 33 and a second portion 34. The second portion 34 is formed integral joined to the first portion 33, and the second portion 34 has a taper 35. The tubular body 22 has an impact end 30 and an insertion end 32 that are spaced from one another by the length, designated L in FIG. 4, of the tubular body 22. The taper 34 extends from the insertion end 32 in a direction toward the impact end 30, until it reaches the first portion 33. The tubular body 22 may comprise a total length L of about sixty inches, about four inches of which comprise the second portion 34 having the taper 35.
The tubular body 22 further comprises an interior surface 24 and an exterior surface 26, as shown in FIGS. 3 and 5. The interior surface 24 defines a stabilizer interior 23 internal to the tubular body 22.
As further shown in FIGS. 3 and 5, the tubular body 22 has a first gap space wall 27 and a second gap space wall 29 which are spaced apart from one another. The first and second gap space walls 27, 29, respectively, extend along the length L of the tubular body 22, from the impact end 30 of the tubular body 22 to the insertion end 32 of the tubular body 22. The first and second gap space walls, 27, 29, respectively, define a tube gap space 28 between them, that extends in the direction of the of the longitudinal axis, designate X in FIG. 2, of the tubular body 22.
As shown in FIGS 3 and 5, the tube gap space 28 extends along the length L of the body 22, from the impact end 30 to the insertion end 32 of the tubular body 22. The tube gap space 28 defined between the first and second gap space walls 27, 29 is used for allowing tubular body 22 to be compressed radially inward. In a manner to be described presently, the diameter designated D in FIG. 5, of the tubular body decreases when the tubular body 22 is driven into a drilled bore 50 formed in a wall 52 or ceiling 54 of a mine 56, as shown in FIG. 37. The drilled bore 50 has a bore diameter 51, designated B in FIG. 37, that is less than the diameter D of the tubular body 22.
A notch 36 is defined in the taper 35 of the second portion 34 of the tubular body 22. The notch 36 allows the taper 35 to be formed in the tubular body 22 at the insertion end 32 thereof when the tubular body 22 is being rolled.
The taper is used for allowing the insertion end 32 of the tubular body 22 to be initially fitted or inserted into the drilled bore 50. After the taper 35 is fitted into the drilled bore 50, 30 the impact end 30 of the tubular body 22 can be pounded causing the tubular body 22 to move into the drilled bore 50.
In accordance with the invention, the tubular body 20 comprises tabs 25 that extend from the exterior surface 26 in a direction toward the impact end 30 of the tubular body 20, and away from the insertion end 32 of the tubular body 22. The tabs 25 work against the removal of the tubular body 22 from a drilled bore 50 in a mine 56. As a result, the tabs 25 advantageously decrease the likelihood of a mine 56 cave-in, as will be described presently.
In a preferred embodiment, the tabs 25 are embodied to be rectangular shaped tabs 40. In particular, there is a first rectangular shaped tab 40a, a second rectangular shaped tab 40b, and a third rectangular shaped tab 40c. The first rectangular shaped tab 40 is positioned closest to the insertion end 32 of the tubular body 22, and the third rectangular shaped tab 40c is positioned farthest from the insertion end 32 of the tubular body 22, as shown in FIG. 4. The second rectangular shaped tab 40b is positioned between the first and second rectangular shaped tabs 40a, 40c, respectively. The first, second, and third rectangular shaped tabs 40a, 40b, and 40c respectively, are punched out of, laser cut, or otherwise formed in the tubular body 22, in ainethod to be described presently.
The first, second, and third rectangular shaped tabs 40a, 40b, and 40c, respectively, extend outward from the exterior surface 26 of the tubular body 22.
Each rectangular shaped tab 40a, 40b, 40c comprises two parallel tab side edges 43 and a tab free edge 45 that extends between the tab side edges 43, as shown in FIG. 7, which is a top plan view of the flat strip of metal 102 from which the tubular body 22 is formed. The tab side edges 43 and tab free edges 45 are shown in FIGS. 1, 6, and 7. It is noted that the tabs 40a, 40b, and 40c shown throughout FIGS. 1-6 are structurally the same.
Each of the rectangular shaped tabs 40a, 40b, and 40c, respectively, is joined to the tubular body 22 along a bend 44, with the bend being opposite the tab free edge 45. The bends 44 are closer to the insertion end 32 of the tubular body 22 than the tab free edge 45. Each of the rectangular shaped tabs 40a, 40b, and 40c, respectively, makes an acute angle with the exterior surface 26 of the tubular body 22, as shown in FIG. 2. Also, the rectangular shaped tabs 40a, 40b, and 40c, respectively, extend in a direction leading away from the insertion end 32 of the tubular body 22, and in a direction leading toward the impact end 30 of the tubular body 22, as shown in FIG. 2. The rectangular shaped tabs 40a, 40b, and 40c, respectively, are spaced apart from one another along the tubular body 22, and are formed in the tubular body 22 such that they are opposite to the tube gap space 28, as shown in FIG. 6.
It is further noted that there are openings 48, as shown in FIG. 2, in the tubular body 22 under the rectangular shaped tabs 40a, 40b, and 40c, respectively, where they extend from the exterior surface 26.
Then, when the tubular body 22 is pounded into a drilled bore 50 insertion end 32 first, the rectangular shaped tabs 40a, 40b, and 40c, respectively, bend inward along their bends 44 in a direction toward the openings 48 in the tubular body 22. In other words, the rectangular shaped tabs 40a, 40b, and 40c, respectively, move back into the tubular body 22 from which they were punched, and thus they do not impede the tubular body 22 from being pounded into the drilled bore 50 in the wall 52 or ceiling 54 of the mine 56, as shown in FIG. 37. Then, in the event of a mine cave-in or wall collapse, the tubular body 22 advantageously remains in place and supports the mine wall 52 or ceiling 54, since the rectangular shaped tabs 40a, 40b, and 40c, respectively, resist removal from the drilled bore 50 and dig into the surrounding rock. This is due to the fact that the natural spring constant of the first, second, and third rectangular shaped tabs 40a, 40b, 40c, respectively, forces them to dig into the drilled bore 50.
The three rectangular shaped tabs 40a, 40b, and 40c, respectively, are spaced along a tubular body 22 about sixty inches long such that the first tab 40a is about four inches from the insertion end 32 of the tubular body 22, the second tab 40b is about fourteen inches from the insertion end 32 of the tubular body 22, and the third tab 40c is about twenty-four inches from the insertion end 32 of the tubular body 22.
The rectangular shaped tabs 40a, 40b, and 40c, respectively, can be sized such that the tab side edges 43 are about 0.5 inches long, and the tab free edge 45 is about 1.0 inch.
The rectangular shaped tabs 40a, 40b, and 40c, respectively, advantageously provide for a stabilizer 20 that, when installed in a mine, can support greater loads than stabilizers having smooth exterior surfaces. Of course, the dimensions may differ in other embodiments.
The friction stabilizer 20 further includes a weld ring 31 that in one embodiment is rectangular shaped, that is, its cross section is rectangular shaped as shown in FIGS. 31, 32, and 32a. The rectangular shaped weld ring 31 has a weld ring gap space 39 and flat sides 31a. The rectangular shaped weld ring 31 is positioned around exterior surface 26 of the tubular body 22 adjacent to the impact end thereof, as shown in FIGS. 1-4. The weld ring gap space 39 is aligned with the tube gap space 28 defined in the tubular body 22. The rectangular shaped weld ring 31 is welded to the exterior surface 26 of the tubular body 22. The weld 49 that joins the tubular body 22 and rectangular shaped weld ring 31 is best shown in FIG. 5.
It is noted that the weld ring gap space 39 and tube gap space 28 allow for the tubular body 22 to be compressed as it is driven into the drilled bore 50 having a bore diameter 51 less than the diameter of the tubular body 22. The rectangular shaped weld ring 31 is used for supporting a plate 58 in a manner to be described presently.
In another embodiment, the rectangular shaped weld ring 31 and the tubular body 22 can be welded together, without the tube gap space 28 and weld ring gap space being aligned.
FIG 5 is a sectional view of the tubular body 22 taken along cut line 5-5 of FIG. 3, and FIG. 6 is a sectional view of the tubular body 22 taken along cut line 6-6 of FIG. 3.
It is noted that a circular shaped weld ring 37 having a circular shaped cross section, as shown in FIGS. 29, 30, and 30a, can be successfully used in accordance with the present invention. However, the rectangular shaped weld ring 31 having a rectangular shaped cross section advantageously provides for a higher quality weld. This is due to the fact that a space 38 can form during the welding process under the weld 49 that joins the circular shaped weld ring 37 and the exterior surface 26 of the tubular body 22, as shown in FIG. 30a. Additionally, to successfully weld the circular shaped weld ring 37 to the tubular body 22, the weld gun must be accurately positioned. However, such accurate positioning is oftentimes difficult to achieve, because the machinery that does the welding vibrates excessively. As a result, the majority of the weld 49 can end up on the circular shaped weld ring 37 or on the exterior surface 26 of the tubular body 22. Thus, the weld 49 may end up catching only one of the circular shaped weld ring 37 or exterior surface 26 of the tubular body 22, and/or a space 38 may be formed under the weld 49 as shown in FIG. 30a.
The rectangular shaped weld ring 31 shown in FIGS. 31, 32, and 32a advantageously has flat sides 31a. As a result there is no space 38 between the flat surfaces 3 la rectangular shaped weld ring 31 and the exterior surface 26 of the tubular body 22, since these two surfaces make direct contact with one another leaving no room for a space 38 to form under the weld 49. Thus, a high quality weld 49 can be made between the flat surfaces 31a of the rectangular shaped weld ring 31 and exterior surface 26 of the tubular body 22, even in the presence of the vibrations generated by the welding machines.
The above-described invention can be variously embodied. FIGS. 8-12 generally show a second embodiment of the friction stabilizer 20a having rectangular shaped tabs 40. The tubular body 22a of the second embodiment is substantially the same as the tubular body 22 of the first embodiment, in that the tubular body 22a comprises an exterior surface 26, first and second gap space walls 27,29, respectively, a tube gap space 28, an impact end 30, an insertion end 32, a rectangular weld ring 31 having a weld ring gap space 39, a first portion 33, and a second portion 34 having a taper 35 having a notch 36. Each rectangular tab 40 of the second embodiment has parallel tab side edges 43 and a tab free edge 45. The second embodiment comprises a row 128 of rectangular shaped tabs 40 that are joined to the tubular body 22a at bends 44, and which are spaced from one another at predetermined spaced intervals, designated I in FIG. 9, along the length L of the tubular body 22a. It is noted that the row 128 extends from the side of the tubular body 22a opposite the tube gap space 28. As shown in FIGS. 8-10, there are five rectangular shaped tabs 40 in the row 128. Of course, in other embodiments, the row of tabs 128 may comprise fewer or more than five rectangular shaped tabs 40.
FIG. I 1 is a sectional view of the tubular body of the second embodiment taken along cut line 11-11 of FIG. 10, and FIG. 12 is a sectional view of the tubular body of the second embodiment taken along cut line 12-12 taken of FIG.
8. The tubular body 22a can be used for supporting the walls 52 and ceiling 54 of a mine 56 in the same manner as previously described in connection with the first embodiment.
FIGS. 13-17 generally show a third embodiment of the friction stabilizer 20b with tabs. In this embodiment, the tubular body 22b comprises triangular shaped tabs 41. The tubular body 22b of the third embodiment is substantially the same as the tubular body 22 of the first embodiment, in that the tubular body 22b comprises an exterior surface 26, first and second gap space walls 27,29, respectively, a tube gap space 28, an impact end 30, insertion end 32, a rectangular weld ring 31 having a weld ring gap space 39, a first portion 33, and a second portion 34 having a taper 35 having a notch. Each triangular shaped tab 41 of the third embodiment has two edges 46 that meet at a point 47, thus forming a triangle shape. The triangular shaped tabs 41 are joined to the tubular body 22b at bends 44, as shown. There is a row 129 of triangular shaped tabs 41 that extend from the tubular body 22b at predetermined spaced intervals, designated I in FIG. 13, along the length L of the tubular body 22b. It is noted that the row 128 extends from the side of the tubular body 22b opposite the tube gap space 28. As shown in FIGS. 13-17, there are five triangular shaped tabs 41 in the row 130. In other embodiments, the row of triangular shaped tabs 130 may comprise fewer or more than five triangular shaped tabs 41.
FIG. 16 is a sectional view taken along cut line 16-16 of FIG. 15, and FIG. 17 is a sectional view taken along cut line 17-17 of FIG. 13. The tubular body 22b can be used in the same manner as described above in connection with the first embodiment for supporting the walls 52 and ceiling 54 of a mine 56.
FIGS. 18-22 generally show a fourth embodiment of the friction stabilizer 20c with tabs. In the fourth embodiment, the tubular body 22c comprises a plurality of rows 128 of rectangular shaped tabs 40. The rectangular shaped tabs 40 in each row 128 are spaced from one another, and the rows 128 are spaced about ninety degrees from one another about the exterior surface 26 of the tubular body 22c, as viewed in sectional figures 21 and 22. The tubular body 22c of the fourth embodiment is substantially the same as the tubular body 22 of the first embodiment, in that the tubular body 22c comprises an exterior surface 26, first and second gap space walls 27,29, respectively, a tube gap space 28, an impact end 30, insertion end 32, a rectangular weld ring 31 having a weld ring gap space 39, a first portion 33, and a second portion 34 having a taper 35 having a notch. Each rectangular shaped tab 40 of the fourth embodiment is joined to the tubular body 22c at a bend 44, and extends in a direction toward the weld ring 31. As shown in FIGS. 18-22 there are three rows 128 of the rectangular shaped tabs 40, with five rectangular shaped tabs 40 per row.
In other embodiments, there can even be more rows 128 of rectangular shaped tabs 40 provided for on the tubular body 22c, or the number of rectangular shaped tabs 40 in each row may be increased or decreased.
FIG. 21 is a sectional view taken along cut line 21-21 of FIG. 20, and FIG. 22 is a sectional view taken along cut line 22-22 of FIG 18. The tubular body 22c can be used in the same manner as described above in connection with the first embodiment for supporting the walls 52 and ceiling 54 of a mine 56.
FIGS. 23-27 generally show a fifth embodiment of the friction stabilizer 20d. In the fifth embodiment, the tubular body 22d comprises a plurality of rows 130 of triangular shaped tabs 41. The tubular body 22d of the fifth embodiment is substantially the same as the tubular body 22 of the third embodiment, in that the tubular body 22d comprises an exterior surface 26, first and second gap space walls 27,29, respectively, a tube gap space 28, an impact end 30, insertion end 32, a rectangular weld ring 31 having a weld ring gap space 39, a first portion 33, and a second portion 34 having a taper 35 having a notch. Each triangular shaped tab 41 of the fifth embodiment is joined to the tubular body 22d at a bend 44, and extends away from the tubular body 22d. The edges 46 of each triangular shaped tab 41 meet at a point 47. As shown in FIGS. 23-25 there are three rows 130 of the triangular shaped tabs 41, with five tabs 41 per row 130. The rows 130 of triangular shaped tabs 41 are spaced about ninety degrees from one another about the exterior surface 26 of the tubular body 22d, as viewed in FIGS. 26 and 27. In yet other embodiments, there can even be more rows 130 of triangular shaped tabs 41 provided for on the tubular body 22d.
FIG. 26 is a sectional view taken along cut line 26-26 of FIG. 25, and FIG. 27 is a sectional view taken along cut line 27-27 of FIG. 23. The tubular bod_v 22d can be used in the same manner as described above in connection with the first embodiment for supporting the walls 52 and ceiling 54 of a mine 56.
Shown in FIG. 27A is a sixth embodiment of the friction stabilizer 20e wherein the tubular body 22e has a plurality of differently shaped tabs 25.
The tabs 25 may be curved shaped tabs, rectangular shaped tabs, triangular shaped tabs, polygonal shaped tabs, U-shaped tabs, tabs having both curved portions and linear portions, semi-circular shaped tabs, hook shaped tabs, parabolic shaped tabs, combinations of the above, or any other shaped tab that inhibits the withdrawal of the friction stabilizer 20e from the drilled bore 50 in the mine 56. The above-described tabs 25 may extend in patterns, rows, series, or randomly from the exterior surface 26 of the friction stabilizer 20e. As shown in FIG. 27A, a plurality of differently shaped tabs 25, as described above, extend from the friction stabilizer 20e. In other embodiments, a single tab 25, for example a rectangular shaped tab 40 or a triangular shaped tab 41, may extend from the exterior surface 26 of the friction stabilizer 20.
The single tab may be any of the above shapes. Thus, the present invention has significant versatility and may be variously embodied, and all of these embodiments are within the scope of the present invention.
In a seventh embodiment shown in FIGS. 38-45, there is a friction stabilizer 20f having a tubular body 22f. As shown in FIGS. 38-42, the tubular body 22f is elongate and has a first portion 33 a bent portion 53 and a second portion 34 with the bent portion 53 joining the first portion 33 and the second portion 34. The tubular body 22f is preferably formed as one piece. The first portion 33 has an impact end 30 and the second portion 34 has an opposed insertion end 32. The first portion 33 also has a weld ring 31 joined to it with, for example a weld 49, and the weld ring 31 can have a rectangular or circular cross section. The second portion 34 of the tubular body 22f has a taper 35, and the taper 35 extends from the insertion end 32 in a direction toward the impact end 30 until it meets with the bent portion 53.
In addition, the tubular body 22f includes an interior surface 24 that is concave and an opposed exterior surface 26 that is convex, as shown in FIGS.
41 and 42. The interior surface 24 defines a stabilizer interior 23 that is internal to the tubular body 22f.
As further shown in FIGS. 38, 41 and 42, the tubular body 22f has a first gap space wall 27 and a second gap space wall 29 which are spaced apart from one another and face one another. As shown in FIG. 39, the first and second gap space walls 27, 29, respectively, extend along the length of the tubular body 22f, designated L in FIG. 39, from the impact end 30 of the tubular body 22f to the insertion end 32 of the tubular body 22f. A tube gap space 28 extends from the first gap space wall 27 to the second gap space wall 29 and the length L of the tubular body 22f, from the impact end 30 to the insertion end 32. As shown in FIGS. 40-43, the weld ring 31 has a weld ring gap space 39, and the weld ring 31 is welded to the first portion 33 with a weld 49, such that the weld ring gap space 39 is diametrically opposite the tube gap space 28, as shown in FIG. 41.
In addition, the tubular body 22f is capable of being compressed radially inward because of the tube gap space 28. In a manner to be described presently, the diameter of the tubular body 22f designated D in FIG. 39 decreases when the tubular body 22f is hammered into a drilled bore 50 having a smaller diameter, designated B in FIG. 43, as will be described in greater detail presently.
As shown in FIGS. 38, 39 and 42, a notch 36 is defined in the taper 35 of the second portion 34 of the tubular body 22f. The notch 36 extends from the insertion end 32 partly into the second portion 34 of the tubular body 22f.
The taper 35 of the second portion 34 increases in the vicinity of the notch 36. Thus, the tube gap space 28 decreases in the second portion 34 due to the taper 35, and tube gap space 38 decreases an additional amount in the vicinity of the notch 36. This facilitates introduction of the tubular body 22f into the drilled bore 50. In addition, the notch 36 allows the taper 35 to be formed in the tubular body 22f at the insertion end 32 thereof when the tubular body 22f is roll formed. After the taper 35 is fitted into the drilled bore 50, the impact end 30 of the tubular body 22f can be hammered causing the tubular body 22f to move into the drilled bore 50.
The tubular body 22f has a thickness designated TT as shown in FIG.
41 which extends from the exterior surface 24 to the opposed interior surface 26 of the tubular body 22f.
As shown in FIGS. 38-40 and 42, the tubular body 22f has a single extendable tab 25b that is joined to the first portion 32 of the tubular body 22f with a tab joining portion 180. The extendable tab 25b is positioned diametrically opposite the tube gap space 28. In addition, and extendable tab 25b is proximal the bent portion 37. In particular, the extendable tab 25b is positioned such that moving from right to left in FIGS. 38-40, the insertion end 32 is first encountered and then the second portion 34 is encountered. Next, the bent portion 53 is encountered, and then the first portion 33 is encountered with the tab joining portion 180 and extendable tab 25b being encountered immediately thereafter. Thus, the extendable tab 25b is proximal the bent portion 53, but not joined to the bend portion 53. In addition, the extendable tab 25b extends in a direction leading away from the insertion end 32 of the tubular body 22f and in a direction leading towards the impact end 30 of the tubular body 22f, as shown in FIGS. 38-40.
As previously mentioned, the tubular body 22f is capable of compressing radially inward, for example when it is hammered into a drilled bore 50 having diameter less than that of the tubular body 22f, as will be described presently.
The tube gap space 28 allows for such inward radial compression of the tubular body 22f. Thus, the tubular body 22f is capable of moving from a non-compressed position 190 (as shown in FIGS. 38-42) to a compressed position 192 when hammered into a drilled bore.
As shown in FIGS. 38, 40 and 42, the extendable tab 25b has an interior tab surface 182 and an opposed exterior tab surface 184, and because the extendable tab 25b is formed in the tubular body 22f, it also has a thickness designated TT. The tubular body 22f has an opening 48 in which the extendable tab 25b is partly positioned. In particular, when the tubular body 22f is in the non-compressed position 190 as shown in FIGS. 38- 40 and 42, the extendable tab 25b is partly positioned in the opening 48, and partly elevated with respect to the surrounding exterior surface 26 of the tubular body 22f. As shown in FIGS. 39 and 42, the extendable tab 25b extends a minimal amount relative to the surrounding exterior surface 26 of the tubular body. Thus, the extendable tab 25b is bent at the joining portion 180 such that the extendable tab 25b makes a makes a minimal angle with respect to the surrounding exterior surface 26 of the tubular body 22f.
As shown in FIGS. 39 and 42, when tubular body 22f is in the non-compressed position 190, the extendable tab 25b is partly in the opening 48 and partly raised or elevated a minimal amount relative to the surrounding exterior surface 26 of the first portion 33, as described above.
When the tubular body 22f is radially compressed and is moved to the compressed position 192 (for example when hammered into a drilled bore 50 as will be described presently and as shown in FIGS. 43 and 44), the extendable tab 25b bends at the joining portion 180, and the extendable tab 25b moves out of the opening 48. The extendable tab 25b extends away from the exterior surface 26 the tubular body 22f, such that the extendable tab 25b makes an acute angle with the exterior surface 26 of the tubular body 22f. Thus, the extendable tab 25b is caused to move out of the opening 48 when the tubular body 22f is compressed, and is capable of moving from a non-extended position 183, as shown in FIGS. 38-40 and 42, when the tubular body 22f is in the non-compressed position 190, to an extended position 185, as shown in FIGS. 43 and 44, when the tubular body 22f is in the compressed position 192.
FIGS 43 and 44 show the friction stabilizer 20f installed in a drilled bore 50. During installation the insertion end 32 of the tubular body 22f is introduced into the drilled bore 50, and the extendable tab 25b is in the above-described non-extended position 183. As hammering begins, the tube gap space 28 decreases and the tubular body 22f begins to compress radially inward, and the extendable tab 25b moves out of the opening 48 and moves to the extended position 185 such that it contacts the drilled bore 50. After hammering, the extendable tab 25b engages the drilled bore thus increasing the axially holding capacity of the friction stabilizer 20f.
The extendable tab 25b positioned diametrically opposite the tube gap space 28 and proximal the bent portion 37, as described above, advantageously significantly increases the axial load bearing capacity of the tubular body 22f. Two extendable tabs 25b each positioned diametrically opposite the tube gap space 28 and each proximal the bent portion 37 as described above also advantageously significantly increase the holding capacity or axial load bearing capacity of the friction stabilizer 20f. The second extendable tab 25b is shown in phantom lines in FIG. 40, and as shown, the extendable tabs 25b are proximal to one another . A
third extendable tab 25b could also be formed in the tubular body 22f is the same manner as described above and in line with the other extendable tabs 25b. In other embodiments there can be more than three extendable tabs 25b each positioned diametrically opposite the tube gap space 28.
The extendable tab 25f can have any geometry, for example it can be rectangular shaped as shown in FIG. 38a. It can also be triangle shaped, curved, polygonal or virtually any shape that can engage a drilled bore 50.
There are additional advantages associated with the extendable tab 25b. For example, the tubular body 22f is safer to handle in the mine because the extendable tab 25b is in the non-extended position 183 prior to introduction into the drilled bore 50. Thus, there is a reduced likelihood that mine workers and factory works will be injured by the extendable tab 25b. Another advantage is that the extendable tab 25b does not extend outward from the surrounding exterior surface 26 of the tubular body 22f until the tubular body 22f has been hammered into the drilled bore 50, thus the friction stabilizers 20f can be neatly stacked for shipment.
Another advantage is the increased axial holding capacity of the friction stabilizer 20f.
To manufacture the friction stabilizer with tabs 20, reference is made to the schematic shown in FIG. 28. The process or method begins with a coil of metal, preferably steel or a steel alloy 100. First, a planar or flat strip of steel 102 pulled from the steel coil, in the direction indicated by the arrows in FIG.
28. The strip 102 has a width, designated W in FIG. 7, that is about three inches wide in the first embodiment. In other embodiments, the width could be more than or less than three inches, depending on the particular application or customer requirement.
As the strip of steel 102 is pulled from the coil 100, it moves onto a conveyor 105. The strip of steel 102 passes through a pressing machine 104 wherein the tab side edges 43 and tab free edges 45 are pressed into the flat strip of steel 102.
Pressing machines are well known to those having ordinary skill in the art. It is to be understood that the tab side edges 43 and free edges 45 may also be laser cut or otherwise formed in the sheet of steel 102 at this point in the manufacturing process, by the use of a laser or other device. The shape of the tab 25 is thus formed in the sheet of steel 102. It is to be further understood that any desired shape of the tab 25 could be formed by the pressing machine 104.
The strip 102 is next moved by conveyor 105 through a punching machine 106 where the notches 36 are punched out of or otherwise formed into the flat strip 102. Punching machines 106 are known to those having ordinary skill in the art. In another embodiment, the notches 36 could be punched from the strip 102 first, and then the tabs 40 pressed in the strip 102.
A means for measuring 108 continuously measures the length of the strip 102 prior to the punching machine 106 so that the notch 36 can be punched in the strip 102 at the desired position in the strip 102. The final length of the friction stabilizer with tabs 20 is thus determined by the notch 36 location in the strip 102.
Next, the strip 102 passes from the punching machine 106 and is moved by conveyor 105 through a cold roll forming mill 110. The cold roll forming mill 110 comprises a series of stands having top and bottom rolling die 112a, 112b, respectively.
Cold roll forming mills 110 are known to those having ordinary skill in the art.
As the strip 102 progresses from stand to stand in the cold rolling mill 110 it is formed into a tubular body 22 having the above-described tube gap space 28.
At the same time, the rectangular shaped tabs 40 begin to move away from the exterior surface 26 of the continuous tubular body 22z that is being formed in the cold rolling mill 110. This is attributed to the fact that the natural spring constant of the steel, steel alloy, galvanized steel, or other metal from which the continuous tubular body 22z, is made causes the rectangular shaped tabs 40 to extend from the exterior surface 26 thereof. It is noted that if the tabs do not extend out, then they may be mechanically pushed out of the tubular body 22.
As the continuous tubular body 22z exits the cold roll forming mill 110, the tabs 40 extend from it as previously described and it has notches 36, but still has to be cut to the predetermined length. The continuous tubular body 22z is then moved by conveyor 105 through a cut-off press 114, where the notch 36 in the tubular body 22 signals the cut-off press 114 to cut the tubular body 22 to the predetermined length at the notch 36. The length of the tubular body may be about 60 inches as shown in FIG. 1 and described in the first embodiment, but in other embodiments, the tubular body 22 can be formed to have a length of 18 inches, 24 inches, over six feet, or any length required for the particular job, application, or customer order.
The tubular body 22 is then placed on conveyor 105 and transported to a swaging station 116. At the swaging station 116, the insertion end 32 of the tubular body 22, where the notch 36 is located, has pressure applied to it such that the taper 35 is formed at the insertion end 32. It is noted that the notch 36 provides the space for the taper 35 to be formed in the section portion 34 in the swaging station 116.
The tubular body 22 is then moved by a conveyor 105 to a welding station 118. At the welding station 118 the rectangular shaped weld ring 38 is fitted about the impact end 30 of the tubular body 22, such that the weld ring gap space 39 aligns with the tube gap space 28. In another embodiment the weld ring gap space 39 and tube gap space 28 are not aligned. While held in this position by the welding machine, the tubular body 22 and weld ring 38 are welded together, and thus joined by a weld 49. Welding stations 118 are well known to those having ordinary skill in that art. After welding, the weld ring 38 is joined with the impact end 30 of the tubular body 22. The weld ring gap space 39 may be laser cut or punched out of the weld ring 38.
After exiting the welding station 118, the tubular bodies 22 are moved by conveyor 105 to a packing station 120 having an automatic packaging machine 121. Every other tubular body 22 is then turned end over end and automatically packaged in bundles 122 of, for example, six tubular bodies 22, by the automatic packaging machine 121. Automatic packaging machines 121 are known to those having ordinary skill in the art. The bundles 122 are transported by conveyor 105 to a shipping station 124, placed in crates 126, and shipped.
After the friction stabilizer with tabs 20 has been rolled and formed as described above, the tabs 40 may have sharp tab side edges 43 and tab free edges 45.
Thus, another step that may be included in the process or method is a grinding step, which takes place prior to automatic packing of the tubular bodies 22. During the grinding step, any sharp tab side edges 43 and tab free edges 45 are ground down and dulled, thus decreasing the likelihood of a worker being cut or injured by the tabs 40.
The same general method or process is carried out to make the other embodiments of the friction stabilizer having tabs 20, described above. For each embodiment the pressing machine 104 would stamp, punch, or cut edges in the strip of steel 102 such that the tab 25 of desired shape may be formed (rectangular shaped tabs, triangular shaped tabs, curved shaped tabs, polygonal shaped tabs, U-shaped tabs, tabs having both curved portions and linear portions, semi-circular shaped tabs, hook shaped tabs, parabolic shaped tabs, combinations of the above, or any other shaped tab that inhibits the withdrawal of the friction stabilizer with tabs 20 from the drilled bore 50 in the mine 56).
To make the friction stabilizer 20f having the tubular body 20f with the extendable tab 25b, reference is made to the schematic shown in FIG. 45. The process or method begins with a coil of metal, preferably steel or a steel alloy 100.
First, a planar or flat strip of steel 102 pulled from the steel coil, in the direction indicated by the arrows in FIG. 45. The strip 102 has a width, designated W in FICi.
7, that is about three inches wide in the first embodiment. In other embodiments, the width could be more than or less than three inches, depending on the particular application or customer requirement.
As the strip of steel 102 is pulled from the coil 100, it moves onto a conveyor 105. The strip of steel 102 passes through a pressing machine 104 wherein the extendable tab 25b is pressed, laser cut or otherwise defined in the flat strip of steel 102. Pressing machines are well known to those having ordinary skill in the art.
The strip 102 is next moved by conveyor 105 through a punching machine 106 where the notches 36 are punched out of or otherwise formed into the flat strip 102. Punching machines 106 are known to those having ordinary skill in the art. In another embodiment, the notches 36 could be punched from the strip 102 first, and then the tabs 40 pressed in the strip 102.
Thus, another step that may be included in the process or method is a grinding step, which takes place prior to automatic packing of the tubular bodies 22. During the grinding step, any sharp tab side edges 43 and tab free edges 45 are ground down and dulled, thus decreasing the likelihood of a worker being cut or injured by the tabs 40.
The same general method or process is carried out to make the other embodiments of the friction stabilizer having tabs 20, described above. For each embodiment the pressing machine 104 would stamp, punch, or cut edges in the strip of steel 102 such that the tab 25 of desired shape may be formed (rectangular shaped tabs, triangular shaped tabs, curved shaped tabs, polygonal shaped tabs, U-shaped tabs, tabs having both curved portions and linear portions, semi-circular shaped tabs, hook shaped tabs, parabolic shaped tabs, combinations of the above, or any other shaped tab that inhibits the withdrawal of the friction stabilizer with tabs 20 from the drilled bore 50 in the mine 56).
To make the friction stabilizer 20f having the tubular body 20f with the extendable tab 25b, reference is made to the schematic shown in FIG. 45. The process or method begins with a coil of metal, preferably steel or a steel alloy 100.
First, a planar or flat strip of steel 102 pulled from the steel coil, in the direction indicated by the arrows in FIG. 45. The strip 102 has a width, designated W in FICi.
7, that is about three inches wide in the first embodiment. In other embodiments, the width could be more than or less than three inches, depending on the particular application or customer requirement.
As the strip of steel 102 is pulled from the coil 100, it moves onto a conveyor 105. The strip of steel 102 passes through a pressing machine 104 wherein the extendable tab 25b is pressed, laser cut or otherwise defined in the flat strip of steel 102. Pressing machines are well known to those having ordinary skill in the art.
The strip 102 is next moved by conveyor 105 through a punching machine 106 where the notches 36 are punched out of or otherwise formed into the flat strip 102. Punching machines 106 are known to those having ordinary skill in the art. In another embodiment, the notches 36 could be punched from the strip 102 first, and then the tabs 40 pressed in the strip 102.
A means for measuring 108 continuously measures the length of the strip 102 prior to the punching machine 106 so that the notch 36 can be punched in the strip 102 at the desired position in the strip 102. The final length of the friction stabilizer with tabs 20f is thus determined by the notch 36 location in the strip 102.
Next, the strip 102 passes from the punching machine 106 and is moved by conveyor 105 through a cold roll forming mill 111. The cold roll forming mill 111 comprises a series of stands having top and bottom extendable tab rolling die 113a, 113b, respectively. As the strip 102 progresses from stand to stand in the cold rolling mill 111 it is formed into a tubular body 22f having the above-described tube gap space 28. During cold rolling the extendable tab 25b extends from the strip 102 only a minimal amount from the exterior surface 26 of the continuous tubular body 22z that is being formed in the cold rolling mill 111. It is pointed out that this cold rolling is different from the above-described cold rolling, in that the tubular body 22f is rolled such that the extendable tab 25a does not fully extend outward during the cold rolling processes. That is, the cold rolling process is such that it prevents the full extension of the extendable tab 25b. Rather, the extendable tab 25b extends only a minimal amount from an exterior surface of the continuous tubular body 22z.
The continuous tubular body 22z is then moved by conveyor 105 through a cut-ofTpress 114, where the notch 36 in the tubular body 22 signals the cut-off press 114 to cut the tubular body 22f to the predetermined length at the notch 36.
The length of the tubular body 22f may be about 60 inches as shown in FIG. 1 and described in the first embodiment, but in other embodiments, the tubular body 22 can be formed to have a length of 18 inches, 24 inches, over six feet, or any length required for the particular job, application, or customer order.
The tubular body 22f is then placed on conveyor 105 and transported to a swaging and ring station 116. At the swaging and ring station 116, the insertion end 32 of the tubular body 22f, where the notch 36 is located, has pressure applied to it such that the taper 35 is formed at the insertion end 32, and the weld ring is positioned around the continuous tubular body 22z. It is noted that the notch provides the space for the taper 35 to be formed in the section portion 34 in the swaging station 116.
The tubular body 22f is then moved by a conveyor 105 to a welding station 118. At the welding station 118 the weld ring 38 is fitted about the impact end 30 of the tubular body 22f, such that the weld ring gap space 39 is diametrically opposite the tube gap space 28. While held in this position by the welding machine, the tubular body 22 and weld ring 31 are welded together, and thus joined by a weld 49. After welding, the weld ring 38 is joined with the impact end 30 of the tubular body 22.
After exiting the welding station 118, the tubular bodies 22f are moved by conveyor 105 to a packing station 120 having an automatic packaging machine 121. Every other tubular body 22 is then turned end over end and automatically packaged in bundles 122 of, for example, six tubular bodies 22f, by the automatic packaging machine 121. In addition, because the extendable tab 25b is not extended, the bundles can be advantageously readily stacked. Automatic packaging machines 121 are known to those having ordinary skill in the art. The bundles 122 are transported by conveyor 105 to a shipping station 124, placed in crates 126, and shipped.
To use the friction stabilizer 20 with tabs, a drilled bore 50 is made in a wall 52 or ceiling 54 of a mine 56 having a floor 55, as shown in FIG. 37. It is understood that forming a drilled bore 50 in a mine 56 is known to those having ordinary skill in the art. The drilled bores 50 are made in the 52 ceilings and/or walls 54 of the mine 56. The drilled bore 50 has a diameter, designated B in FIG.
37, which is less than the diameter of the tubular body 22, designated S and shown in FIG. 4.
As shown in FIGS. 33 and 34, a plate 58 having a plate opening 60 is provided. The plate 58 has planar surfaces 59, and is of metal, preferably steel, steel alloys, stainless steel, and galvanized steel. The plate opening 60 is sized such that the friction stabilizer 22 can be moved through the opening 60. But, the weld ring 38 is too large to pass through the plate opening 60. The plate 58 is positioned such that the opening 60 is brought into alignment with the drilled bore 50 the wall 52 or ceiling 54, as the case may be, of the mine 56, and held in that position.
Since the taper 35 at the insertion end 32 of the tubular body 22 has a diameter less than the diameter, designated B, of the drilled bore 50, the insertion end 30 of the tubular body 22 can be readily moved into the drilled bore 50. In particular, the insertion end 32 is moved through the opening 60 in the plate 58, such that the taper portion 34 is moved into the drilled bore 50. However, because the diameter, designated S, of the tubular body is greater than the diameter, designated B, of the drilled bore 50, the first portion 33 of the tubular body 22 must be driven into the drilled bore 50.
To accomplish this, the impact end 30 of the tubular body 22 is driven by a pneumatic hammer, hydraulic hammer, or other means for hammering or driving (not shown) into the drilled bore 50. The tubular body 22 compresses radially inward as it is driven into the drilled bore 50, such that the tube gap space 28 decreases.
Additionally, the tabs 40 fold in a direction toward the exterior surface 26 of the tubular body 22, and do not resist insertion of the tubular body 22 into the drilled bore 50. As a result of tubular body 22 being driven into the lesser diameter drilled bore 50, the tubular body 22 compresses radially inward and the tube gap space 28 and weld ring gap space 39 both decrease. The tubular body 50 then exerts expanding forces against the adjacent surrounding drilled bore wall 51.
Also, in another embodiment shown in FIGS. 35 and 36, the plate can be a domed-shaped plate 64 having a domed portion 65. The domed portion 65 has an opening 67 for receiving the friction stabilizer 20 there-through.
Contact surfaces 69 are provided on the domed plate 64 and are used for contacting the wall 52 or ceiling 54 of the mine 56.
It is noted that as the stabilizer 20 with tabs is driven into the drilled bore 50, the rectangular shaped tabs 40 move downwardly toward the tubular body 22 and do not obstruct insertion into the drilled bore 50. However, once driven into the drilled bore 50, the tabs 40 force outwardly from the tubular body 22 due to the natural spring constant of the steel or other material from which the stabilizer with tabs 20 is made. The tabs 40 contact the adjacent surrounding drilled bore wall 51 and dig into it, resulting in the friction stabilizer with tabs 20 being held in the drilled bore 50 by both a friction fit created by the expanding forces generated by the tubular body 22, and by the tabs 40 digging into the drilled bore 50.
Then, if force is applied to remove the friction stabilizer with tabs 20, the tabs 40 immediately dig into the adjacent drilled bore wall 51 and work against removal of the stabilizer with tabs 20 from the drilled bore 50. This significantly reduces the likelihood that the stabilizer with tabs 20 will work its way out of the drilled bore 50 and advantageously significantly increases the amount of weight or force the friction stabilizer with tabs 20 can support. Thus the friction stabilizer with tabs 20 advantageously decreases the likelihood of a cave-in of walls 52 and/or ceilings 54 of a mine 56.
In addition, the plate 58, which is trapped between the weld ring 38 and mine wall 52 or ceiling 54 after installation, provides for additional support of the surrounding mine walls 52 and ceilings 54, as the case may be. It is noted that the plate 58 is supported by the weld ring 38. Thus, if the rock above the plate fractures and weakens, the plate 58 supports the rock, and the plate 58 in turn is supported by the friction stabilizer with tabs 20 in the drilled bore 50, and the tabs 40 advantageously constantly working against removal of the friction stabilizer with tabs 20 from the drilled bore 51.
The present invention also provided for a mine support system 80. In particular, the friction stabilizer 20 having tabs can be positioned and spaced from one another in drilled bores 50 that are spaced about three feet apart from one another in all directions, for example in the walls 52 and ceiling 54 of the mine 56. A
wire mesh 65 is provided. The wire mesh 65 is positioned adjacent to the walls 52 and ceiling 54 of the mine 56. Then the plates 58 are aligned with the drilled bores 50 in the manner described above. Next, the friction stabilizer 20 is driven into the drilled bore 50 in the manner previously described. The wire mesh 65 extends between all of the plates 58 in the mine and is trapped between the plates 58 and the mine wall 52 and plates 58 and ceiling 54. The wire mesh 65 serves to support any rocks or debris that break off of the walls 52 or ceiling 54 of the mine 56. The ability of the wire mesh 65 to support greater loads is advantageously increased, because the friction stabilizer having tabs 40 can support a greater load from the wire mesh 65. Thus, the stabilizer with tabs 20 can be used as an, integral part of a mine support system 80 to prevent mine 56 cave-ins.
It is noted that the above-described support system 80 can be used in combination with any of the above-described embodiments of the friction stabilizer having tabs 20.
As previously described, in other embodiments the tabs 25 can be any of a plurality of different shapes (rectangular shaped tabs, triangular shaped tabs, curved shaped tabs, polygonal shaped tabs, U-shaped tabs, tabs having both curved portions and linear portions, semi-circular shaped tabs, hook shaped tabs, parabolic shaped tabs, combinations of the above, or any other shaped tab that inhibits the withdrawal of the friction stabilizer with tabs 20 from the drilled bore 50 in the mine 56).
Additionally, in other embodiments, the rectangular shaped tabs 40 can be formed such that they extend from the tubular body 22 anywhere from the exterior surface 26 of the tubular body 22 including randomly or in patterns. The same is true with respect to all of the above-described differently shaped tabs 25, in that they may all extend from the tubular body 22 randomly or in patterns. Also, the number of tabs 25 can be varied regardless of the shape of the tab 25. In addition, the size of the tab 25 can be varied depending on the requirements of the particular application in which the stabilizer 20 will be deployed. In yet other embodiments a single tab 25 having any of the above described shapes may extend from the tubular body 22. Also, in other embodiments the length of the taper 35 of the second portion 34 may be increased or decreased.
With respect to the seventh embodiment, as shown in FIGS. 43 and 44, during the hammering process the tubular body 22f compresses radially inward as it is hammered into the drilled bore 50, and moves from the non-compressed condition 190 to the compressed condition 192. As this occurs, the extendable tab 25b moves out of the opening 48. Stated differently, the extendable tab 25b extends outward from the tubular body 22f as the tubular body 22f is hammered deeper into the drilled bore 50, and the extendable tab 25b extends into the surrounding drilled bore 50.
When hammering is complete, the extendable tab 25b advantageously extends into the drilled bore 50 at a position deep inside the drilled bore 50, advantageously resulting in increased axial holding capacity of the friction stabilizer 20f which prevents mine collapse.
Also, the diameter of the tubular body 22 of the friction stabilizer with tabs 20 may be more or less than an inch, but in other embodiments the diameter of the stabilizer may be customized to suit particular needs for a particular application.
The tubular body 22 can comprise various lengths L, for example the sixty inch length described above, or a length required for a particular application. For example, some mines 56 may require tubular bodies 22 having lengths of twelve, eighteen, or forty inches, whereas other mines 56 may require tubular bodies 22 having lengths of over two hundred inches. The friction stabilizer having tabs 20 may be used in these mining applications. The material from which the stabilizer 20 and weld ring 38 are made comprises metal, such as steel, steel alloys, galvanized steel, high strength steel, metal and metal alloys.
Although a friction stabilizer 20 with tabs has been described, the present invention could be otherwise embodied without departing from the principles thereof, and all such embodiments come with the scope and sprit of the present invention for a friction stabilizer 20 having tabs.
Next, the strip 102 passes from the punching machine 106 and is moved by conveyor 105 through a cold roll forming mill 111. The cold roll forming mill 111 comprises a series of stands having top and bottom extendable tab rolling die 113a, 113b, respectively. As the strip 102 progresses from stand to stand in the cold rolling mill 111 it is formed into a tubular body 22f having the above-described tube gap space 28. During cold rolling the extendable tab 25b extends from the strip 102 only a minimal amount from the exterior surface 26 of the continuous tubular body 22z that is being formed in the cold rolling mill 111. It is pointed out that this cold rolling is different from the above-described cold rolling, in that the tubular body 22f is rolled such that the extendable tab 25a does not fully extend outward during the cold rolling processes. That is, the cold rolling process is such that it prevents the full extension of the extendable tab 25b. Rather, the extendable tab 25b extends only a minimal amount from an exterior surface of the continuous tubular body 22z.
The continuous tubular body 22z is then moved by conveyor 105 through a cut-ofTpress 114, where the notch 36 in the tubular body 22 signals the cut-off press 114 to cut the tubular body 22f to the predetermined length at the notch 36.
The length of the tubular body 22f may be about 60 inches as shown in FIG. 1 and described in the first embodiment, but in other embodiments, the tubular body 22 can be formed to have a length of 18 inches, 24 inches, over six feet, or any length required for the particular job, application, or customer order.
The tubular body 22f is then placed on conveyor 105 and transported to a swaging and ring station 116. At the swaging and ring station 116, the insertion end 32 of the tubular body 22f, where the notch 36 is located, has pressure applied to it such that the taper 35 is formed at the insertion end 32, and the weld ring is positioned around the continuous tubular body 22z. It is noted that the notch provides the space for the taper 35 to be formed in the section portion 34 in the swaging station 116.
The tubular body 22f is then moved by a conveyor 105 to a welding station 118. At the welding station 118 the weld ring 38 is fitted about the impact end 30 of the tubular body 22f, such that the weld ring gap space 39 is diametrically opposite the tube gap space 28. While held in this position by the welding machine, the tubular body 22 and weld ring 31 are welded together, and thus joined by a weld 49. After welding, the weld ring 38 is joined with the impact end 30 of the tubular body 22.
After exiting the welding station 118, the tubular bodies 22f are moved by conveyor 105 to a packing station 120 having an automatic packaging machine 121. Every other tubular body 22 is then turned end over end and automatically packaged in bundles 122 of, for example, six tubular bodies 22f, by the automatic packaging machine 121. In addition, because the extendable tab 25b is not extended, the bundles can be advantageously readily stacked. Automatic packaging machines 121 are known to those having ordinary skill in the art. The bundles 122 are transported by conveyor 105 to a shipping station 124, placed in crates 126, and shipped.
To use the friction stabilizer 20 with tabs, a drilled bore 50 is made in a wall 52 or ceiling 54 of a mine 56 having a floor 55, as shown in FIG. 37. It is understood that forming a drilled bore 50 in a mine 56 is known to those having ordinary skill in the art. The drilled bores 50 are made in the 52 ceilings and/or walls 54 of the mine 56. The drilled bore 50 has a diameter, designated B in FIG.
37, which is less than the diameter of the tubular body 22, designated S and shown in FIG. 4.
As shown in FIGS. 33 and 34, a plate 58 having a plate opening 60 is provided. The plate 58 has planar surfaces 59, and is of metal, preferably steel, steel alloys, stainless steel, and galvanized steel. The plate opening 60 is sized such that the friction stabilizer 22 can be moved through the opening 60. But, the weld ring 38 is too large to pass through the plate opening 60. The plate 58 is positioned such that the opening 60 is brought into alignment with the drilled bore 50 the wall 52 or ceiling 54, as the case may be, of the mine 56, and held in that position.
Since the taper 35 at the insertion end 32 of the tubular body 22 has a diameter less than the diameter, designated B, of the drilled bore 50, the insertion end 30 of the tubular body 22 can be readily moved into the drilled bore 50. In particular, the insertion end 32 is moved through the opening 60 in the plate 58, such that the taper portion 34 is moved into the drilled bore 50. However, because the diameter, designated S, of the tubular body is greater than the diameter, designated B, of the drilled bore 50, the first portion 33 of the tubular body 22 must be driven into the drilled bore 50.
To accomplish this, the impact end 30 of the tubular body 22 is driven by a pneumatic hammer, hydraulic hammer, or other means for hammering or driving (not shown) into the drilled bore 50. The tubular body 22 compresses radially inward as it is driven into the drilled bore 50, such that the tube gap space 28 decreases.
Additionally, the tabs 40 fold in a direction toward the exterior surface 26 of the tubular body 22, and do not resist insertion of the tubular body 22 into the drilled bore 50. As a result of tubular body 22 being driven into the lesser diameter drilled bore 50, the tubular body 22 compresses radially inward and the tube gap space 28 and weld ring gap space 39 both decrease. The tubular body 50 then exerts expanding forces against the adjacent surrounding drilled bore wall 51.
Also, in another embodiment shown in FIGS. 35 and 36, the plate can be a domed-shaped plate 64 having a domed portion 65. The domed portion 65 has an opening 67 for receiving the friction stabilizer 20 there-through.
Contact surfaces 69 are provided on the domed plate 64 and are used for contacting the wall 52 or ceiling 54 of the mine 56.
It is noted that as the stabilizer 20 with tabs is driven into the drilled bore 50, the rectangular shaped tabs 40 move downwardly toward the tubular body 22 and do not obstruct insertion into the drilled bore 50. However, once driven into the drilled bore 50, the tabs 40 force outwardly from the tubular body 22 due to the natural spring constant of the steel or other material from which the stabilizer with tabs 20 is made. The tabs 40 contact the adjacent surrounding drilled bore wall 51 and dig into it, resulting in the friction stabilizer with tabs 20 being held in the drilled bore 50 by both a friction fit created by the expanding forces generated by the tubular body 22, and by the tabs 40 digging into the drilled bore 50.
Then, if force is applied to remove the friction stabilizer with tabs 20, the tabs 40 immediately dig into the adjacent drilled bore wall 51 and work against removal of the stabilizer with tabs 20 from the drilled bore 50. This significantly reduces the likelihood that the stabilizer with tabs 20 will work its way out of the drilled bore 50 and advantageously significantly increases the amount of weight or force the friction stabilizer with tabs 20 can support. Thus the friction stabilizer with tabs 20 advantageously decreases the likelihood of a cave-in of walls 52 and/or ceilings 54 of a mine 56.
In addition, the plate 58, which is trapped between the weld ring 38 and mine wall 52 or ceiling 54 after installation, provides for additional support of the surrounding mine walls 52 and ceilings 54, as the case may be. It is noted that the plate 58 is supported by the weld ring 38. Thus, if the rock above the plate fractures and weakens, the plate 58 supports the rock, and the plate 58 in turn is supported by the friction stabilizer with tabs 20 in the drilled bore 50, and the tabs 40 advantageously constantly working against removal of the friction stabilizer with tabs 20 from the drilled bore 51.
The present invention also provided for a mine support system 80. In particular, the friction stabilizer 20 having tabs can be positioned and spaced from one another in drilled bores 50 that are spaced about three feet apart from one another in all directions, for example in the walls 52 and ceiling 54 of the mine 56. A
wire mesh 65 is provided. The wire mesh 65 is positioned adjacent to the walls 52 and ceiling 54 of the mine 56. Then the plates 58 are aligned with the drilled bores 50 in the manner described above. Next, the friction stabilizer 20 is driven into the drilled bore 50 in the manner previously described. The wire mesh 65 extends between all of the plates 58 in the mine and is trapped between the plates 58 and the mine wall 52 and plates 58 and ceiling 54. The wire mesh 65 serves to support any rocks or debris that break off of the walls 52 or ceiling 54 of the mine 56. The ability of the wire mesh 65 to support greater loads is advantageously increased, because the friction stabilizer having tabs 40 can support a greater load from the wire mesh 65. Thus, the stabilizer with tabs 20 can be used as an, integral part of a mine support system 80 to prevent mine 56 cave-ins.
It is noted that the above-described support system 80 can be used in combination with any of the above-described embodiments of the friction stabilizer having tabs 20.
As previously described, in other embodiments the tabs 25 can be any of a plurality of different shapes (rectangular shaped tabs, triangular shaped tabs, curved shaped tabs, polygonal shaped tabs, U-shaped tabs, tabs having both curved portions and linear portions, semi-circular shaped tabs, hook shaped tabs, parabolic shaped tabs, combinations of the above, or any other shaped tab that inhibits the withdrawal of the friction stabilizer with tabs 20 from the drilled bore 50 in the mine 56).
Additionally, in other embodiments, the rectangular shaped tabs 40 can be formed such that they extend from the tubular body 22 anywhere from the exterior surface 26 of the tubular body 22 including randomly or in patterns. The same is true with respect to all of the above-described differently shaped tabs 25, in that they may all extend from the tubular body 22 randomly or in patterns. Also, the number of tabs 25 can be varied regardless of the shape of the tab 25. In addition, the size of the tab 25 can be varied depending on the requirements of the particular application in which the stabilizer 20 will be deployed. In yet other embodiments a single tab 25 having any of the above described shapes may extend from the tubular body 22. Also, in other embodiments the length of the taper 35 of the second portion 34 may be increased or decreased.
With respect to the seventh embodiment, as shown in FIGS. 43 and 44, during the hammering process the tubular body 22f compresses radially inward as it is hammered into the drilled bore 50, and moves from the non-compressed condition 190 to the compressed condition 192. As this occurs, the extendable tab 25b moves out of the opening 48. Stated differently, the extendable tab 25b extends outward from the tubular body 22f as the tubular body 22f is hammered deeper into the drilled bore 50, and the extendable tab 25b extends into the surrounding drilled bore 50.
When hammering is complete, the extendable tab 25b advantageously extends into the drilled bore 50 at a position deep inside the drilled bore 50, advantageously resulting in increased axial holding capacity of the friction stabilizer 20f which prevents mine collapse.
Also, the diameter of the tubular body 22 of the friction stabilizer with tabs 20 may be more or less than an inch, but in other embodiments the diameter of the stabilizer may be customized to suit particular needs for a particular application.
The tubular body 22 can comprise various lengths L, for example the sixty inch length described above, or a length required for a particular application. For example, some mines 56 may require tubular bodies 22 having lengths of twelve, eighteen, or forty inches, whereas other mines 56 may require tubular bodies 22 having lengths of over two hundred inches. The friction stabilizer having tabs 20 may be used in these mining applications. The material from which the stabilizer 20 and weld ring 38 are made comprises metal, such as steel, steel alloys, galvanized steel, high strength steel, metal and metal alloys.
Although a friction stabilizer 20 with tabs has been described, the present invention could be otherwise embodied without departing from the principles thereof, and all such embodiments come with the scope and sprit of the present invention for a friction stabilizer 20 having tabs.
Claims (20)
1. A friction stabilizer for installation in a structural body, the friction stabilizer comprising:
a) a tubular body comprising a first portion a bent portion and a second portion with and the bent portion joining the first portion and second portion, c) a joining portion joins an extendable tab to the first portion such that the extendable tab is proximal the bent portion.
a) a tubular body comprising a first portion a bent portion and a second portion with and the bent portion joining the first portion and second portion, c) a joining portion joins an extendable tab to the first portion such that the extendable tab is proximal the bent portion.
2. The friction stabilizer according to claim 1 wherein the tubular body has a tube gap space and an opening diametrically opposite the tube gap space and the extendable tab extends from the joining portion into the opening such that the extendable tab is diametrically opposite the tube gap space.
3. The friction stabilizer according to claim 2 wherein the tubular body is movable from an uncompressed position to a compressed position, such that when in the tubular body is in the uncompressed position the extendable tab is partly positioned in the opening.
4. The friction stabilizer according to claim 2 wherein the tubular body has an exterior surface and the tubular body is movable from an uncompressed position to a compressed position and when in the uncompressed position the extendable tab is elevated a minimal amount relative to the surrounding exterior surface of the tubular body.
5. The friction stabilizer according to claim 3 wherein the extendable tab extends outward from the tubular body when the tubular body is in the compressed position.
6. The friction stabilizer according to claim 4 wherein the extendable tab extends outward from the tubular body when the tubular body is in the compressed position
7. The friction stabilizer according to claim 2 further including an insertion end and an opposed impact end with a weld ring having a weld ring gap space joined to the impact end such that the weld ring gap space is diametrically opposite the tube gap space.
8. The friction stabilizer according to claim 7 wherein the extendable tab extends in a direction toward the impact end and away from the insertion end.
9. The friction stabilizer according to claim 2 further comprising another extendable tab proximal the extendable tab and positioned diametrically opposite the tube gap space.
10. The friction stabilizer according to claim 4 wherein the extendable tab has a rectangular shape.
11. The friction stabilizer according to claim 4 wherein the extendable tab has a triangular shaped tab.
12. The friction stabilizer according to claim 4 wherein the extendable tab has a polygonal shape.
13. The friction stabilizer according to claim 4 wherein the tab has a curved shape.
14. A method of making a friction stabilizer for installation in a structural body, the method comprising the steps of:
providing a coil of metal and unrolling the coil of metal into a strip, pressing the shape of an extendable tab to be formed into the strip of metal such that the extendable tab is joined to the strip of metal with a joining portion, moving the strip of metal through cold rolling dies and roll forming the strip of steel into a tubular body having a tube gap space with an exterior surface such that the extendable tab is diametrically opposite the tube gap space.
providing a coil of metal and unrolling the coil of metal into a strip, pressing the shape of an extendable tab to be formed into the strip of metal such that the extendable tab is joined to the strip of metal with a joining portion, moving the strip of metal through cold rolling dies and roll forming the strip of steel into a tubular body having a tube gap space with an exterior surface such that the extendable tab is diametrically opposite the tube gap space.
15. The method according to claim 14 further including:
roll forming the strip to have a first portion with an impact end, a second portion with an insertion end, and a bent portion that joins the first and second portions and forming the extendable tab in the first portion proximal the bent portion.
roll forming the strip to have a first portion with an impact end, a second portion with an insertion end, and a bent portion that joins the first and second portions and forming the extendable tab in the first portion proximal the bent portion.
16. The method according to claim 15 further comprising:
forming the first portion such that the extendable tab is elevated a minimal amount relative to the surrounding exterior surface.
forming the first portion such that the extendable tab is elevated a minimal amount relative to the surrounding exterior surface.
17. The method according to claim 16 wherein the step of pressing the shape of the extendable tab into the strip of metal such that the extendable tab extends in a direction toward the impact end and away from the insertion end of the tubular body.
18. The method according to claim 15 further comprising:
forming the first portion with an opening such that the extendable tab is partly positioned in the opening.
forming the first portion with an opening such that the extendable tab is partly positioned in the opening.
19. The method according to claim 15 further comprising aligning a weld ring having a weld ring gap space with the impact end such that the weld ring gap space is diametrically opposite the tube gap space and welding the weld ring to the impact end.
20. A method of supporting a mine having at least one drilled bore from caving-in, the method comprising the steps of:
providing a friction stabilizer having a tubular body with a tube gap space such that the tubular body is capable of moving between an uncompressed position and a compressed position, providing the tubular body with a first portion having an impact end and a second portion having a taper and joining the first and second portions with a bent portion, providing the first portion with an impact end and the second portion with an insertion end and providing the tubular body with a tube gap space, providing the tubular body with an exterior surface and providing the first portion with an opening proximal the bent portion, providing a joining portion and joining an extendable tab to the first portion such that the extendable tab is proximal the bent portion and partly positioned in the opening, with the extendable tab extending in a direction toward the impact end and elevated a minimal amount relative to the exterior surface of the tubular body when the tubular body is in the uncompressed position and wherein the extendable tab is diametrically opposite the tube gap space, aligning the impact end of the tubular body with the drilled bore and hammering the impact end of the tubular body and driving the tubular body into the drilled bore such that the tubular body compresses radially inward and moves from the uncompressed position to the compressed position such the extendable tab moves out of the opening and engages the drilled bore to support axial loads imparted thereon by the mine.
providing a friction stabilizer having a tubular body with a tube gap space such that the tubular body is capable of moving between an uncompressed position and a compressed position, providing the tubular body with a first portion having an impact end and a second portion having a taper and joining the first and second portions with a bent portion, providing the first portion with an impact end and the second portion with an insertion end and providing the tubular body with a tube gap space, providing the tubular body with an exterior surface and providing the first portion with an opening proximal the bent portion, providing a joining portion and joining an extendable tab to the first portion such that the extendable tab is proximal the bent portion and partly positioned in the opening, with the extendable tab extending in a direction toward the impact end and elevated a minimal amount relative to the exterior surface of the tubular body when the tubular body is in the uncompressed position and wherein the extendable tab is diametrically opposite the tube gap space, aligning the impact end of the tubular body with the drilled bore and hammering the impact end of the tubular body and driving the tubular body into the drilled bore such that the tubular body compresses radially inward and moves from the uncompressed position to the compressed position such the extendable tab moves out of the opening and engages the drilled bore to support axial loads imparted thereon by the mine.
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
CA 2570022 CA2570022A1 (en) | 2006-12-05 | 2006-12-05 | Friction stabilizer with tabs |
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
CA 2570022 CA2570022A1 (en) | 2006-12-05 | 2006-12-05 | Friction stabilizer with tabs |
Publications (1)
Publication Number | Publication Date |
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CA2570022A1 true CA2570022A1 (en) | 2008-06-05 |
Family
ID=39521168
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
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CA 2570022 Abandoned CA2570022A1 (en) | 2006-12-05 | 2006-12-05 | Friction stabilizer with tabs |
Country Status (1)
Country | Link |
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CA (1) | CA2570022A1 (en) |
Cited By (1)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN112554920A (en) * | 2020-12-24 | 2021-03-26 | 辽宁工程技术大学 | Flexible supporting type circulating steel belt for underground temporary support of coal mine |
-
2006
- 2006-12-05 CA CA 2570022 patent/CA2570022A1/en not_active Abandoned
Cited By (1)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN112554920A (en) * | 2020-12-24 | 2021-03-26 | 辽宁工程技术大学 | Flexible supporting type circulating steel belt for underground temporary support of coal mine |
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