Information
-
Patent Grant
-
6379084
-
Patent Number
6,379,084
-
Date Filed
Friday, December 17, 199925 years ago
-
Date Issued
Tuesday, April 30, 200222 years ago
-
Inventors
-
Original Assignees
-
Examiners
- Bagnell; David
- Lagman; Frederick L.
Agents
- Senniger, Powers, Leavitt & Roedel
-
CPC
-
US Classifications
Field of Search
US
- 405 272
- 405 273
- 405 274
- 405 288
- 405 132
- 405 133
- 405 134
- 405 192
- 405 151
- 454 168
- 454 169
- 299 11
- 299 12
- 248 351
- 248 3541
- 248 3544
- 052 217
-
International Classifications
-
Abstract
A stopping system for use in mines. The stopping system includes a king post truss for reinforcing the stopping panels against excessive deflection due to a pressure differential across the stopping panels. The truss has a variable length to accommodate convergence and divergence of the mine walls on which the truss is mounted.
Description
BACKGROUND OF THE INVENTION
This invention relates to a mine stopping using a reinforcing brace or truss to resist deflection of the stopping when there is a pressure differential on opposite sides of the stopping. The stopping comprises a plurality of metal panels in side-by-side relation to a least partially close a passage in a mine and can have a door and/or pressure relief structure mounted in the stopping.
Mine stoppings are widely used in mines to impede or stop the flow of air in mine passages. This invention involves a mine stopping of the general type shown in U.S. Pat. Nos. 4,547,094, 4,820,081 and 4,911,577 but includes reinforcement to reduce deflection caused by air pressure differential loading of the stopping. Many of the prior art stoppings were formed from a plurality of side-by-side telescoping panels that extended from floor to ceiling across the width of the mine passage. The panels were secured together and in place in the mine passage, typically adjacent to the entrance of a passage. The stopping was also sealed to the walls, roof and floor if desired.
Some mine passages can be quite large, e.g., 20 feet wide and 10 feet high and even as large as 60 feet wide and 35 feet high. Further, the pressure differential across a stopping can be large. The large pressure differential and/or the large size of the mine passages that a stopping closes can subject the stopping to large forces which causes the stopping to bend or deflect. To reduce this deflection, bracing across the stopping is needed. The bracing can also be used to secure the panels of the stopping together in side-by-side relation. However, current bracing has not been as strong, versatile and simple to use in a mine as one would prefer.
Stoppings can also be provided with one or more doors and/or pressure relief or control means. In stoppings that include one or more doors, some resistance to deflection has been accomplished by using floor to ceiling jacks at positions intermediate the side walls which shortened the span for the bracing reinforcement which helped reduce deflection.
Another of the problems with the use of stoppings in mines is that the mine walls tend to shift over time, generally moving closer together from the weight of the overburden. Likewise, the floor and ceiling move closer together over time. Thus, a requirement for a stopping is to be able to accommodate this change in passage size over time without detrimental effect on the stopping.
SUMMARY OF THE INVENTION
Among the several objects of this invention may be noted the provision of improved mine stoppings of the type using a brace for reinforcement against deflection under load; the provision of such a stopping structure that will be effective in at least partially blocking a mine passage from air flow and is easy to install and maintain without excessive attention; the provision of a reinforcing truss for mine stoppings that is versatile in use and easy to install and that will accommodate mine passage size changes without operator attendance; the provision of such a truss that has a variable length to accommodate different sizes of passages and changes in the size of the passage after installation; the provision of such a truss that provides adequate resistance to deflection under load and requires reduced material for construction; the provision of a stopping system that includes a door and a door frame that cooperate with an extensible reinforcing truss that is easy to install and maintain and effective in reducing deflection while eliminating the need for floor to ceiling jacks; and the provision of a reinforcing truss that can be used at a joint between two sets of stopping panels that are in end-to-end relation to reinforce the stopping against deflection and to join the sets of stopping panels in end-to-end relation.
One aspect of the present invention involves the provision of a high pressure stopping system for use in a mine to at least partially block a mine passage. The stopping system includes a plurality of stopping panels positioned side-by-side to form a stopping wall extending between opposite side walls of a mine passage. An elongate brace is provided on a low pressure side of the stopping wall for reinforcing the stopping wall against deflection. The brace includes a central beam and at least one slide member operatively associated with the central beam to provide relative movement therebetween whereby the brace has a variable length.
Another aspect of the present invention includes the provision of a truss for reinforcing a mine stopping system against deflection when under load. The stopping system includes a plurality of stopping panels secured together side-by-side to form a stopping wall for at least partially closing a mine passageway. The truss includes a compression chord that has opposite ends. The chord comprises a central beam having opposite ends and at least one slide member slidably mounted on the central beam adjacent one end thereof. The slide member is movable relative to the central beam for varying the length of the compression chord. A tension chord having opposite ends is secured to the central beam adjacent opposite ends of the central beam. A web extends between the central beam and the tension chord generally at the center of the truss.
The present invention is also directed to a stopping system for use in mines to form a stopping wall to at least partially block a mine passage having side walls. The stopping wall has a normally high pressure side and a normally low pressure side. The stopping system includes a plurality of stopping panels positioned adjacent one another and secured together in side-by-side relation to form a portion of the stopping wall. A door frame defines an opening through the stopping wall and the door frame includes a pair of spaced apart generally vertical columns secured to some of the stopping panels. The door frame also includes a generally horizontal lintel that extends between the columns and is secured to some of the stopping panels. The columns each have a lower end disposed for engagement with a floor of the mine passage at a position between side walls of the mine passage. Each column also has an upper end spaced from a roof of the mine passageway and positioned adjacent a respective end of the lintel and secured thereto. The columns and lintel cooperate to reinforce the wall against deflection under a pressure differential load. At least one door is movably mounted on at least one of the columns and is sized and shaped to at least substantially close the opening.
Another aspect of the present invention involves the provision of a mine stopping system that includes a brace. The brace includes an elongate central beam and at least one slide member operatively associated with the central beam to provide relative movement therebetween whereby the brace has a variable length. The brace is secured to and extends between mine walls of a mine passageway. The system comprises a first set of generally vertical lower stopping panels that are positioned side->bide and have upper and lower ends. A second set of generally vertical upper stopping panels are positioned side-by-side and have upper and lower ends. The upper stopping panels are positioned above the lower stopping panels with the lower ends of the upper panels being positioned adjacent the upper ends of the lower stopping panels. The first and second sets of panels are positioned in the mine passageway and at least partially close the mine passageway. Means is provided for securing the central beam to selected upper and lower stopping panels adjacent the lower ends of the upper panels and the upper ends of the lower panels.
Other objects and features will be in part apparent and in part pointed out hereinafter.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1
is a fragmentary perspective view of a mine stopping in a mine with the stopping having a plurality of reinforcing trusses secured thereto with one side channel shown exploded.
FIG. 2
is a perspective view of a reinforcing truss.
FIG. 3
is side elevation view of a reinforcing truss.
FIG. 4
is sectional view of the reinforcing truss taken alone the line
4
—
4
of FIG.
3
.
FIG. 5
is a perspective view of a stopping with a door unit with one side channel shown exploded.
FIG. 6
is an enlarged fragmentary sectional view taken along the line
6
—
6
of
FIG. 5
showing details of a support column and lintel.
FIG. 7
is an enlarged fragmentary view of the lintel and column shown in FIG.
5
.
FIG. 8
is a enlarged fragmentary end sectional view of a modified form of the truss and stopping system.
FIG. 9
is an enlarged fragmentary sectional view of the stopping system taken along the line
9
—
9
of FIG.
7
.
Corresponding reference characters indicate corresponding parts throughout the several views of the drawings.
DESCRIPTION OF THE PREFERRED EMBODIMENT
Referring to
FIG. 1
, the numeral
1
generally designates a high pressure stopping system adapted for use in mines to at least partially close a mine passage
3
. The system can be used to substantially or partially seal the passage against air flow therethrough. In the form of the invention shown in
FIG. 1
, the stopping system
1
is used to substantially seal against air flow creating a pressure differential across the stopping system
1
with a normally high pressure side
8
and a normally low pressure side
9
. This pressure differential applies force to the stopping system
1
in the direction of the higher pressure side
8
toward the lower pressure side
9
. In operation, it is to be understood that the high pressure side
8
and the low pressure side
9
may switch under certain circumstances but are normally in one orientation. Sealing can be accomplished by having the top edge
4
, side edges
5
,
6
and bottom edge
7
positioned adjacent to the top or ceiling
12
, side walls
14
,
15
and the floor
16
respectively and having suitable sealing material
17
(e.g., polymeric foam such as polyurethane and polystyrene) therebetween.
The stopping system
1
, in the form of the invention shown, includes a plurality of stopping panels
18
positioned in side-by-side relation and extending vertically in the mine passage
3
. The stopping panels
18
can be of any suitable style, e.g., each one can be fabricated as a single piece panel or as a pair of panel sections
19
and
20
(
FIG. 1
) which are preferably channel shaped (
FIG. 9
) in transverse cross section. The panel sections
19
and
20
are slidably or telescopically connected, i.e. one fits within the other and can move coaxially relative to one another to form a telescoping stopping panel
18
as exemplified in U.S. Pat. Nos. 4,547,094, 4,820,081 and 4,911,577. As best seen in
FIG. 9
, the panel sections
19
,
20
have a channel shaped transverse cross section with a panel web portion
22
, opposing flanges
23
and inturned legs
24
. The panel sections
19
and
20
are preferably of the same shape with one being smaller than the other so the smaller one will fit within the larger one for connection and telescoping movement. Preferably, the panels
19
,
20
are metal, preferably steel.
When the panels
18
are installed in a mine, they are positioned in side-by-side relation and are extended in length to provide the desired height. The panels
18
are suitably secured in place in the mine passage
3
in the side-by-side relation. Such securement can be by any suitable means and helps prevent substantial relative movement between adjacent side-by side panels
18
. As best seen in
FIG. 1
, rib angles or bars
28
are placed against the legs
24
of the panels
19
,
20
and are secured thereto as for example by twist wires
30
or any other suitable means.
Referring now to
FIGS. 1 and 2
, the stopping system
1
includes one or more horizontal reinforcing braces or trusses
35
which are extensible or variable in length. Preferably each truss
35
includes a compression chord designated generally
31
, a tension chord designated generally
32
and a web designated generally
33
. The web
33
extends between the compression chord
31
and the tension chord
32
. When more than one truss
35
is used in a stopping system
1
, the horizontal trusses are spaced apart vertically and are preferably generally parallel. Anchor means
38
is also provided for mounting or securing the truss
35
to the mine wall.
The compression chord
31
is generally straight and has a variable length. The compression chord
31
has at least one central support member or beam
37
and as shown, there is one central beam
37
. Length adjustment or variation is provided by having at least one slide member
41
mounted on the central beam
37
for telescoping movement. As shown, the central beam
37
is tubular having a rectangular transverse cross section with inside dimensions. The slide member
41
has a corresponding rectangular transverse cross section with outside dimensions slightly smaller than the inside dimensions of the central beam
37
and is slidably received therein for telescoping movement. It is to be understood that the cross sectional shape of the central beam
37
can vary and preferably corresponds generally to the cross sectional shape of the slide member
41
received therein. Preferably a slide member
41
is mounted in each of opposite ends of the central beam
37
permitting length adjustment or variation of the compression chord
31
at both ends of the central beam
37
. The illustrated structure show the use of two slide members
41
in a truss
35
, however, only one can be used on a truss. The length of the slide members
41
should be such that they will accommodate the maximum amount of mine wall divergence without disengaging from the central beam
37
. During cycles of mine wall convergence and divergence, the central beam
37
could work completely to one side of the mine passage. Thus, the slide member
41
on the opposite end of the central support member would need to be long enough to prevent disengagement from the central beam
37
. Additionally, the slide members
41
need to be sufficiently engaged in the central beam
37
to provide the necessary strength for the truss
35
to support the anticipated loads on the truss
35
.
The anchor means
38
is operable to retain the truss
35
in position in the mine when the mine walls converge and diverge and load is applied to the stopping
1
. An anchor means
38
is affixed to a slide member
41
in a manner that will allow tension and compression to be applied to the slide member for movement out of and into the central beam
37
respectively and still maintain integrity of the attachment of the anchor means
38
to a slide member
41
. The anchor means
38
is preferably operable to allow for or effect both expansion and contraction of the length of the truss
35
and maintain the truss
35
secured to the mine walls. The anchor means
38
is secured to a mine wall to prevent movement of the truss
35
relative to or along the mine passage. As shown, the anchor means
38
includes a plate
45
connected or secured to an exteriorly positioned free end of each of the slide members
41
. The plate
45
lies in a plane that is generally perpendicular to the longitudinal axis of the respective slide member
41
. The plate
45
has apertures
46
for receiving appropriate fasteners
47
such as anchor bolts that are anchored into the side walls
5
,
6
. Other forms of anchor means
38
could be used. For example, the anchor means
38
can be brackets or the like, separate from the truss
35
, that are secured to the mine walls. Further by way of example, the plate member
45
could have a clevis type mount (not shown) secured thereto and be separate from the slide member
41
. The corresponding slide member
41
would have a through bore for receiving a pin. Such a plate
45
would be secured to the mine wall. One end of the truss would then be lifted into place and a pin (not shown) placed through the clevis and the through bore to pivotally mount one end of the truss
35
in place. The other end would then be lifted with a jack or the like and secured in place with an anchor plate
45
secured to the slide member
4
as described above. This type mount could simplify installation where a lifting device capable of lifting the truss in its entirety is not available.
Retaining means is also provided to restrict telescoping movement of the slide members
41
in the central beam
37
. As shown, the retaining means is preferably friction lock means including T-handled set screws
49
that are threadably mounted in the central support member
37
. When the set screws
49
are tightened, they will engage respective slide members
41
and frictionally retain the slide members
41
in their initial adjusted position or a subsequent position due to wall movement. The friction between the set screws
49
and the slide members
41
resists relative telescoping of the central beam
37
and slide members
41
. However, convergence or divergence of the side walls overcomes the frictional force causing telescoping movement of the slide members
47
relative to the central beam
37
. Such telescoping movement does not inelastically deform the central support member
37
or the slide members
41
and does not alter their structural integrity. Because the engagement is frictional, should the mine walls move after installation of the truss
35
, the slides
41
will still be able to move in either an extension or contraction direction relative to the central beam
37
. This relative movement prevents excessive axial loading of the central beam
37
and the slide members
41
.
In a preferred form of the truss
35
, the truss is in the form of a king post truss. As shown in
FIG. 2
, the web
33
includes a compression member such as a king post
52
, having opposite ends
53
and
54
. The king post
52
is mounted generally centrally of the central beam
37
. It has one end
53
adjacent to and suitably secured to the central beam
37
adjacent the center thereof such as by welding. The king post
52
, as shown, has a generally rectangular transverse cross section and can be tubular. The other end
54
is positioned a distance from the central beam
37
. The king post
52
can be generally perpendicular to the central beam
37
.
The tension chord
32
is a tension or brace member that has opposite end portions
58
,
59
and a center portion
57
. The end portions
58
,
59
are positioned adjacent opposite ends of the central beam
37
and are suitably secured thereto, as by welding. The end
54
of the king post
52
engages the center portion
57
and is preferably suitably secured thereto, as by welding. The tension chord
32
can be made from a flat metal strap and, when the truss
35
is in use, normal loading thereof will put the tension chord
32
in tension allowing for the use of a simple transverse cross section.
When the truss
35
is loaded from the pressure differential, the loading force is directed from the front side
67
of the central beam
37
toward the end
54
placing the tension chord
32
in tension and the king post
52
in compression.
The truss
35
is provided with suitable securement means that is affixed to the central beam
37
for attaching or securing the truss
35
to the stopping panels
18
. As best seen in
FIG. 4
, the securement means includes a plurality of uprights
61
(formed from metal plate, for example) suitably secured to the central beam
37
and spaced apart along the length thereof. An elongate panel securement member such as rib member
62
, such as a metal angle, is suitably secured to the uprights
61
with the open side facing away from the truss
35
and toward the stopping panels
18
. The rib member
62
is preferably a metal angle. Twist wires, clamps or other suitable means
30
can be used to secure the rib member
62
and hence the truss
35
to the stopping panels
18
(
FIGS. 1
,
8
).
A modified form of truss
35
and stopping system is provided and is best seen in FIG.
8
. The modified truss is designated generally as
65
. It is the same as the truss
35
except that it uses two securement members which are shown as upper and lower sets of uprights
61
and rib members
62
. The ribs
62
and sets of uprights
61
are positioned on opposite sides of the central beam
37
whereby the two rib members
62
are spaced apart in positions above and below the central beam
37
. In this embodiment, the truss
65
can be used at a joint between two sets of stopping panels
18
to secure them in end-to-end abutting relation allowing the use of shorter stopping panels
18
. For example, two ten (10) foot sets of stopping panels
18
can be used instead of one twenty (20) foot set of stopping panels
18
. The joint
66
between the two sets of stopping panels
18
is located between the two rib members
62
. The brace or truss
65
is secured to the stopping panels
18
as described above for the truss
35
with clamps or twist wires
30
. If desired, one or more trusses
35
can be used along with the truss
65
on a stopping system
1
for additional reinforcement.
As seen in
FIG. 1
, the stopping system can utilize one or more trusses
35
secured thereto in a generally horizontal orientation. The trusses
35
are secured to the stopping panels
18
on the normally low pressure side of the stopping system to reduce bending or deformation of the stopping system. Such mounting and loading places the tension chord
32
in tension. The generally V-shape of the truss
35
and tension chord
32
results in a smaller quantity of material being needed to provide the required strength. Also, the general V-shape of the truss
35
results in the truss having a higher or larger moment of inertia at the center of the truss
35
than at its opposite ends. Further, in the V-shape form of truss
35
, the moment of inertia continuously increases from adjacent each end of the truss toward the central area of the truss
35
where it is at a maximum.
A modified form of the invention is shown in
FIGS. 5
,
6
,
7
and
9
. In this form, a stopping system
71
is provided with a selectively openable door
70
that will allow passage of personnel or equipment thru the stopping system and/or the controlled passage of air therethrough.
The stopping system
71
includes a door frame means
72
comprising spaced apart generally vertical columns
73
and a header or lintel
74
spaced from the floor
16
and ceiling
12
and secured to upper ends
75
of the columns
73
. The columns
73
can have feet
76
that are adapted to be suitably secured to the floor
16
by fasteners
77
to prevent movement of the columns on the floor
16
and along the mine passage. The columns
73
preferably have a height less than the height of the ceiling. The columns
73
can have any suitable transverse cross section and preferably are tubular with a generally rectangular transverse cross section.
The lintel
74
is suitably secured to the columns
73
adjacent their upper ends
75
. As shown in
FIG. 7
, the lintel has brackets
79
secured to opposite ends of the lintel
74
, e.g., by welding. The brackets
79
are in turn suitably secured to sleeves
80
such as by welding. The sleeves
80
are tubular and are sized to slide over the columns
73
and to be adjustably secured in selected vertical position on the columns, e.g., by set screws
81
. This mounting arrangement allows for adjustability of the components during installation. The lintel
74
can have any suitable transverse cross section and can be tubular with a generally rectangular transverse cross section. The lintel
74
has an upper disposed surface
84
with an upwardly opening channel member
85
secured (e.g., welded) thereto and extending along the length of the lintel
74
. The channel member
85
is preferably generally U-shaped with two upstanding legs
86
defining an upwardly opening channel
87
(see FIG.
6
).
The stopping system
71
includes stopping panels
18
positioned between the columns
73
and the side walls
14
,
15
and secured in place as described above. Shorter stopping panels
18
are positioned above the lintel
74
, extending upwardly therefrom. The shorter stopping panels
18
are positioned between the lintel
74
and the ceiling
12
and are suitably secured together with ribs
28
and twist wires
30
. The lower disposed ends
88
of the stopping panels
18
above the lintel
74
are positioned in the channel
87
between the legs
86
to secure them against movement as described below. A truss
35
is also mounted or secured in the channel member
85
to reinforce the stopping system
71
in an area adjacent the lintel. The truss
35
reduces the amount of deflection or movement of the columns
73
and the lintel
74
during loading and thus eliminates the need for floor to ceiling columns. The central beam
37
of the truss
35
is placed in the channel
87
between the lower end portions
88
of the stopping panels and a leg
86
of the channel. The truss
35
and the stopping panels
18
above the lintel
74
are supported vertically by the lintel
74
. The channel member
85
functions as a securement means associated with the truss
35
and the stopping panels
18
above the lintel
74
for tying the lintel to the central beam
37
and upper stopping panels
18
at a position adjacent to the lower ends
88
of the selected stopping panels. When the stopping system
71
deflects under load, the truss
35
is urged into frictional engagement with one leg
86
by the stopping panels
18
in the channel member
85
. The channel member
85
thus secures or retains the selected stopping panels
18
above the lintel
74
and the truss
35
substantially immovable relative to one another. As shown in
FIG. 5
, one or more additional trusses
35
can be used on the stopping system
71
.
The use of a lintel
74
and columns
73
changes the load distribution on the truss
35
relative to the form of the invention shown in FIG.
1
and should also help reduce deflection of the stopping system.
The door
70
can include one or more door panels or leaves
90
suitably movably mounted on the columns
73
as for example by hinges
91
. The leaves
90
can be retained closed by a suitable latch
92
. One of the leaves
90
can have a man door
94
movably mounted thereon. Alternatively, in the absence of a door
70
, the man door
94
can be movably mounted in stopping panels
18
to provide a selectively openable passage for regulated flow of air thru the stopping system
71
. As shown, varying amounts of air flow can be provided by having a series of different sized leaves
94
,
95
,
96
movably mounted on the stopping system
71
and their respective passages thru the stopping system
71
.
As seen in
FIGS. 1 and 5
, a pair of vertical anchor channels
98
can be mounted on the side walls
14
,
15
, as with anchor bolts (not shown) and be positioned between the plates
45
and the respective side wall
14
,
15
. These channels provide smoother surfaces than the walls
14
,
15
and thus a better side fit for the stopping panels
18
. Seal material
17
can be used between the stopping system
1
or
71
and the ceiling
12
, side walls
14
,
15
and the floor
16
of the mine passage.
In a preferred embodiment, the stopping systems are constructed of metal, e.g., steel.
The embodiments of the invention disclosed above are illustrative. Many variations of the mine stopping I and truss
35
are possible without departing from the scope of the invention. For instance, the truss
35
may have other shapes than the general V-shape, e.g., generally rectangular. The cross sectional shapes of the components of the truss can also be different for example the tension chord
32
could be an angle member and the compression chord
31
and slide members
41
could be round. The mounting means
38
for the truss could be clevis type mounts instead of plates
45
secured to the slide members
41
.
The trusses
35
,
65
provide an advantage of being easy to install in a mine environment. They will also accommodate convergence and divergence of the mine and still be effective in supporting the stopping panels
18
against deflection from air pressure. The structure of the trusses allows them to self adjust to accommodate mine convergence and divergence reducing maintenance and costs. By having variable length, the trusses can be used in mine passages of various widths increasing the versatility of application thereby decreasing the number of different trusses needed for an inventory. The truss
65
further provides a simple means of joining together end-to-end stopping panels
18
while also providing resistance to deflection of the stopping system from pressure differentials on the stopping system.
When introducing elements of the present invention or the preferred embodiment(s) thereof, the articles “a,” “an,” “the,” and “said” are intended to mean that there are one or more of the elements. The terms “comprising,” “including,” and “having” are intended to be inclusive and mean that there may be additional elements other than the listed elements.
As various changes could be made in the above constructions without departing from the scope of the invention, it is intended that all matter contained in the above description or shown in the accompanying drawings shall be interpreted as illustrative and not in a limiting sense.
Claims
- 1. A high pressure stopping system for use in a mine to at least partially block a mine passage, said stopping system comprising:a plurality of stopping panels adapted to be positioned side-by-side to form a stopping wall extending between opposite side walls of a mine passage; and an elongate brace for reinforcing the stopping wall against deflection, said brace comprising a tubular central beam and at least one telescoping slide member telescopically engaging the central beam to provide relative movement therebetween whereby said brace has a variable length.
- 2. A stopping system as set forth in claim 1 further comprising anchor members at opposite ends of the brace adapted to be secured to respective side walls for securing said central beam and slide member against movement relative to the mine passage.
- 3. A stopping system as set forth claim 2 including means securing the brace to selected stopping panels of the stopping wall with said brace being generally horizontally disposed and extending between the side walls of the mine passage.
- 4. A stopping system as set forth in claim 2 wherein said anchor members are secured to the brace adjacent its said opposite ends.
- 5. A stopping system as set forth in claim 4 wherein said brace includes two slide members telescopingly mounted on opposite ends of the central beam, and friction lock means for locking the slide members in adjusted position with respect to the central beam, said friction lock means being adapted to permit telescoping of the slide members and the central beam relative to one another in the event of convergence of the mine walls.
- 6. A stopping system as set forth in claim 5 wherein said anchor members are secured to respective slide members.
- 7. A stopping system as set forth in claim 6 wherein each anchor member includes a plate connected to a respective slide member and lying in a plane generally perpendicular to a longitudinal axis of the slide member.
- 8. A stopping system as set forth in claim 6 wherein said brace is in the form of a truss in which said central beam and slide members comprise a compression chord of the truss, said brace further comprising a generally V-shaped tension chord connected to the compression chord adjacent opposite ends thereof and a web extending between the tension and compression chords.
- 9. A stopping system as set forth in claim 8 wherein the web includes a king post extending generally at right angles to the compression chord.
- 10. A stopping system as set forth in claim 9 wherein said tension chord is attached to the king post.
- 11. A truss for reinforcing a mine stopping system against deflection when under load, said stopping system comprising a plurality of stopping panels secured together side-by-side to form a stopping wall for at least partially closing a mine passageway, said truss comprising:a compression chord having opposite ends and comprising a central beam having opposite ends and at least one slide member slidably mounted on said central beam adjacent one end thereof and being movable relative to the central beam for varying the length of the compression chord; a tension chord having opposite ends secured to the central beam adjacent opposite ends of the central beam; and a web extending between the central beam and the tension chord generally at a center of the truss.
- 12. A truss as set forth in claim 11 wherein the truss has a larger moment of inertia generally at the center of the truss than at opposite ends of the truss.
- 13. A truss as set forth in claim 12 further comprising anchor members at opposite ends of the compression chord adapted to be secured to respective side walls for securing said central beam and slide member against movement relative to the mine passage.
- 14. A truss as set forth in claim 13 wherein said compression chord further comprises two slide members telescopingly mounted on opposite ends of the central beam, and friction lock means for locking the slide members in adjusted position with respect to the central beam, said friction lock means being adapted to permit telescoping of the slide members and the central beam relative to one another in the event of convergence of the mine walls.
- 15. A truss as set forth in claim 14 wherein said anchor members are secured to the compression chord adjacent its said opposite ends.
- 16. A truss as set forth in claim 15 wherein each anchor member includes a plate connected to a respective slide member and lying in a plane generally perpendicular to a longitudinal axis of the slide member.
- 17. A truss as set forth in claim 15 wherein said tension chord is generally V-shaped and said web extends between the tension and compression chords generally at the center of the truss.
- 18. A truss as set forth in claim 17 wherein the web includes a king post extending generally at right angles to the compression chord and secured to the compression chord and the tension chord.
- 19. A truss as set forth in claim 12 further comprising an elongate panel securement member affixed to the central beam and extending along a substantial portion of the length of the central beam for securing the central beam to said stopping panels.
- 20. A truss as set forth in claim 19 wherein the securement member includes a plurality of spaced apart uprights secured to the central beam and a rib member secured to the uprights with said rib member extending along at least a portion of the length of the central beam and being spaced from the central beam.
- 21. A truss as set forth in claim 20 comprising two securement members affixed to the central beam above and below the central beam.
- 22. A truss as set forth in claim 21 wherein each rib member comprises an angle bar.
- 23. A stopping system installed in a mine to form a stopping wall to at least partially block a mine passage having side walls, said stopping wall having a normally high pressure side and a normally low pressure side, said stopping system comprising:a plurality of stopping panels positioned adjacent one another and secured together in side-by-side relation to form a portion of said stopping wall; a door frame defining an opening through the stopping wall, said door frame including a pair of spaced apart generally vertical columns secured to some of the stopping panels and a generally horizontal lintel secured to some of the stopping panels and extending between said columns, said columns each having a lower end disposed for engagement with a floor of the mine passage at a position between side walls of the mine passage and an upper end spaced from a roof of the mine passageway and positioned adjacent a respective end of the lintel and secured thereto, said columns and lintel cooperating to reinforce the wall against deflection under a pressure differential load; and at least one door movably mounted on at least one of said columns.
- 24. A stopping system as set forth in claim 23 further including a brace for reinforcing said stopping wall against deflection, said brace having opposite ends and comprising at least one elongate central beam, at least one slide member operatively associated with the central beam to provide relative movement therebetween whereby said brace has a variable length, at least one anchor member at one end of the brace attachable to a mine wall for securing the brace against movement relative to the mine passage, and mounting means for mounting the brace in a position above the lintel adjacent to selected stopping panels and extending up from the lintel.
- 25. A stopping system as set forth in claim 24 wherein said mounting means includes an upwardly opening channel attached to the, lintel for receiving the central beam of the brace and lower end portions of said selected stopping panels.
- 26. A stopping system as set forth in claim 25 wherein said brace includes two slide members telescopingly mounted on opposite ends of the central beam and friction lock means for frictionally retaining said slide members in adjusted position with respect to the central beam, said friction lock means being adapted to permit telescoping of the slide members and the central relative to one another in the event of convergence of the mine side walls.
- 27. A stopping system as set forth in claim 26 wherein said anchor members are secured to the brace adjacent its said opposite ends.
- 28. A stopping system as set forth in claim 27 wherein each anchor member includes a plate connected to a respective slide member and lying in a plane generally perpendicular to a longitudinal axis of the slide member.
- 29. A stopping system as set forth in claim 28 wherein said brace is in the form of a truss in which said central beam and slide members comprise a compression chord of the truss, said brace further comprising a generally V-shaped tension chord connected to the compression chord adjacent opposite ends thereof and a web extending between the tension and compression chords.
- 30. A stopping system as set forth in claim 29 wherein the web includes a king post extending generally at right angles to the compression chord.
- 31. A mine stopping system installed in a mine comprising:a brace comprising an elongate central beam, at least one slide member operatively associated with the central beam to provide relative movement therebetween whereby said brace has a variable length, and anchor members at opposite ends of the brace attached to mine walls of a mine passageway so that the brace is secured to and extends between said mine walls; a first set of generally vertical lower stopping panels positioned side-by-side and having upper and lower ends; a second set of generally vertical upper stopping panels positioned side-by-side and having upper and lower ends, the upper stopping panels being positioned above lower stopping panels with the lower ends of the upper panels positioned adjacent the upper ends of the lower stopping panels, the first and second sets of panels being positioned in said mine passageway and at least partially closing the mine passageway; and means for securing the beam to selected upper and lower stopping panels adjacent the lower ends of the upper panels and the upper ends of the lower panels, said at least one slide member being operatively associated with the central beam so that said at least one slide member may move relative to the central beam upon movement of at least one of said mine walls.
- 32. A mine stopping system as set forth in claim 31 wherein said brace includes a first and second elongate panel securement members affixed to the beam and extending along a substantial portion of the length of the beam.
- 33. A mine stopping system as set forth in claim 32 further including means cooperating with the panel securement members and the upper and lower stopping panels for securing the brace to the first and second stopping panels.
- 34. A mine stopping system as set forth in claim 33 wherein said securement members are positioned above and below the central beam.
- 35. A mine stopping system as set forth in claim 34 wherein each securement member comprises a plurality of spaced apart uprights secured to the beam and a rib member secured to the uprights with said rib member extending along at least a portion of the length of the beam and being spaced from the beam.
- 36. A mine stopping system as set forth in claim 34 wherein said brace is in the form of a truss in which said central beam and slide member comprise a compression chord of the truss, said brace further comprising a generally V-shaped tension chord connected to the compression chord adjacent opposite ends thereof and a web extending between the tension and compression chords.
- 37. A mine stopping system as set forth in claim 36 wherein the web includes a king post extending generally at right angles to the compression chord.
- 38. A mine stopping system as set forth in claim 37 wherein said tension chord is attached to the king post.
- 39. A mine stopping system as set forth in claim 38 wherein said brace includes two slide members telescopingly mounted on opposite ends of the central beam and said brace further including friction lock means for locking the slide members in adjusted position with respect to the central beam, said friction lock means being adapted to permit telescoping of the slide members and the central beam relative to one another in the event of convergence of the mine walls.
- 40. A mine stopping system as set forth in claim 39 wherein one of said anchor members are secured to said brace adjacent its said opposite ends.
- 41. A mine stopping system as set forth in claim 40 wherein each anchor member includes a plate connected to a respective slide member and lying in a plane generally perpendicular to a longitudinal axis of the slide member.
- 42. A mine stopping system as set forth in claim 41 wherein said king post has opposite ends with one end secured to the central beam and the other end secured to the tension chord.
- 43. A mine stopping system as set forth in claim 42 wherein each securement member comprises a plurality of spaced apart uprights secured to the central beam and a rib member secured to the uprights with said rib member extending along at least a portion of the length of the central beam and being spaced from the central beam.
- 44. A mine stopping system as set forth in claim 43 wherein there are two securement members affixed to the central beam above and below the central beam.
- 45. A high pressure stopping system installed in a mine to at least partially block a mine passage, said stopping system comprising:a stopping wall extending between opposite side walls of a mine passage; and an elongate brace for reinforcing the stopping wall against deflection, said brace comprising a central beam having a component which extends perpendicular to the stopping wall to resist lateral forces exerted against the stopping wall by air pressure.
- 46. A high pressure stopping system as set forth in claim 45 further comprising at least one movable member engaging the central beam to provide relative movement therebetween whereby said brace has a variable length.
- 47. A high pressure stopping system as set forth in claim 46 wherein the central beam has a rectangular cross section, said component including sides of the beam extending perpendicular to the stopping wall.
- 48. A high pressure stopping system as set forth in claim 45 wherein the brace includes an anchor member at an end of the brace engaging one of said side walls, the brace being generally horizontally disposed and extending between the side walls of the mine passage.
- 49. A brace for reinforcing a stopping wall in a mine against deflection, said brace comprising:a tubular central beam, at least one telescoping slide member telescopically engaging the central beam to provide relative movement therebetween whereby said brace has a variable length, anchor members at opposite ends of the brace adapted to be secured to side walls of the mine, and friction lock means for locking the telescoping slide member in position with respect to the central beam, said friction lock means being adapted to permit telescoping of the telescoping member relative to the central beam in the event of movement of the side walls of the mine.
- 50. A brace as set forth in claim 49 further comprising a rib member fixed to the central beam for securing the brace to the stopping wall.
- 51. A brace as set forth in claim 49 wherein the central beam has a rectangular cross section.
- 52. A brace installed in a mine for reinforcing a stopping wall against deflection, said brace comprising:a central beam, and at least one slide member slidably engaging the central beam to provide relative movement therebetween whereby said brace has a variable length, each of said beam and slide member being mounted on the stopping wall so that a component of the beam extends perpendicular to the stopping wall to resist lateral forces exerted against the stopping wall by air pressure.
- 53. A brace as set forth in claim 52 further comprising anchor members at opposite ends of the brace secured to side walls of the mine.
- 54. A brace as set forth in claim 52 further comprising lock means locking the slide member in position with respect to the central beam.
- 55. A brace as set forth in claim 52 further comprising a rib member fixed to the central beam for securing the brace to the stopping wall.
- 56. A brace as set forth in claim 52 wherein the central beam has a rectangular cross section, said component including sides of the beam extending perpendicular to the stopping wall.
US Referenced Citations (22)