BACKGROUND OF THE INVENTION
[0001] The present invention is directed to an apparatus configured for use with a door
or other barrier for maintaining the door or other barrier in a position and capable
of resisting a trans-barrier force less than a predetermined magnitude. When the
trans-barrier force exceeds the predetermined magnitude, the apparatus is designed
to yield and allow the barrier to move in response to the trans-barrier force, thereby
avoiding damage to the barrier and, further, avoiding damage to adjacent supporting
structures for the barrier, such as guide rails, supports, tensioning mechanisms,
and the like.
[0002] The preferred embodiment of the present invention is particularly adaptable for use
with a door of the roll-up type which is generally used for environmental control
between two spaces, such as between sections of a warehouse, or the like. In such
doors, a motor-driven roller controls the upward and downward movement of the door
to control access through an opening. An assembly of cables, associated pulleys, and
tension springs serves as a tensioning mechanism. The tensioning mechanism is driven
by the roller motor and connected to a guide follower apparatus. The guide follower
apparatus is attached to the bottom, or leading edge, of the roller door and interacts
with guide rails adjacent the opening. In such installations, the door is generally
flexible and is kept under tension to aid in maintaining alignment of the door with
respect to the guide rails and the opening.
[0003] It is common that such door installations are subjected to abuse during normal operations
by the impact of machinery, such as fork lifts, with the bottom (leading edge) of
the door. In previous designs, such abuse inflicted serious damage to the door and
its associated guide rails, tensioning mechanism, and other parts. Such damage often
jammed the door in its down (closed) position, causing serious delays in operations
in spaces about the door since the door blocked access through the opening.
[0004] Previous efforts have been made to accommodate these destructive forces accidentally
imparted to such doors. One solution has been to provide a hinged guide rail so that
application of force to the door causes the hinged panel of the guide rail to pop
loose and rotate away from the guide follower attached to the bottom, leading edge,
of the door. That swinging open of the guide rail allowed the door and guide follower
to swing free in response to the application of the destructive force.
[0005] The hinged guide rail solution had problems and shortcomings: the cables in the door
tensioning mechanism could snarl, stretch, break, or otherwise become damaged; associated
pulleys and tension springs of the tensioning mechanism could similarly be damaged;
and, perhaps most important, since the guide rails were generally placed adjacent
the opening, as opposed to within the opening, the hinged guide rail only accommodated
trans barrier forces in one direction, away from the wall surrounding the opening.
Trans-barrier forces applied in the opposite direction (toward the wall) would not
operate to pop open the hinged panel of the guide rail and would serve only to drive
the door and its associated guide follower against the wall surrounding the opening.
Of course, driving the door against the wall caused damage to the guide follower,
door, guide rail, tensioning apparatus, and other parts of the door installation.
[0006] The present invention is designed to overcome the shortcomings of these previous
attempts to provide a trans-barrier force accommodation mechanism to avoid damage
to a barrier and its associated structures and mechanisms. In one of its embodiments,
the present invention uses a structure which accommodates trans-barrier forces in
two directions.
[0007] Further, great precision of determination of the predetermined magnitude of the trans-barrier
force at which the apparatus will allow the door to yield can be achieved in the present
invention through the use of a shear pin-type or similar assembly.
SUMMARY OF THE INVENTION
[0008] The invention is an apparatus configured for maintaining a barrier in a position
against a trans-barrier force less than a predetermined magnitude. The barrier has
associated structures for cooperating with the apparatus to define the position in
which the barrier is maintained.
[0009] The apparatus comprises a guide follower attached to the barrier and operatively
interactive with the associated structures for defining the barrier position. The
guide follower of the apparatus comprises a first portion attached to the barrier
and a second portion operatively interactive with the associated structures. The first
portion and the second portion are in an interfitting relation and define at least
one pair of mating surfaces, each of which mating surfaces is transverse to the barrier
and oriented to allow sliding disengagement of the first portion and the second portion
in response to application of a trans-barrier force to the barrier in excess of a
predetermined magnitude.
[0010] The present invention, therefore, maintains the barrier, such as a roll-up door,
in a desired position with respect to the associated structures of the barrier and
with respect to the opening through which access is controlled by the barrier. By
using the apparatus of the present invention to effect the operative interaction between
the barrier and its associated structures, trans-barrier forces applied against the
barrier can be accommodated up to a predetermined magnitude without affecting the
door. For trans-barrier forces in excess of the predetermined magnitude, the apparatus
of the present invention will yield by slidingly disengaging the first portion and
the second portion of the apparatus to allow the barrier to be displaced in response
to the trans-barrier force. In such manner, the trans-barrier force is not transmitted
to the associated structures of the barrier so that damage to the associated structures
is avoided.
[0011] The predetermined force at which the first portion and the second portion of the
apparatus will disengage may be definitively established by the structure of the apparatus.
For example, a shear pin may be employed in a manner whereby the shear pin intersects
at least one of the mating surfaces defined by the interface of the first portion
and the second portion of the apparatus. The shear pin can be designed to shear in
response to a force which can be precisely determined by the material, diameter, and
other parameters of the shear pin.
[0012] Other structural details for establishing the predetermined force at which the first
portion and the second portion of the apparatus will disengage include: choice of
materials of the interfitting faces of the first portion and second portion of the
apparatus which define the mating pairs of surfaces; and treatment of the mating surfaces
by providing undulations, ridges, serrations, or other structural features on those
surfaces.
[0013] It is, therefore, an object of the present invention to provide an apparatus for
maintaining a barrier in a position against a trans-barrier force less than a predetermined
magnitude, and enabling displacement of the barrier in response to a trans-barrier
force in excess of that predetermined magnitude without causing damage to the barrier
or to barrier-associated structures.
[0014] A further object of this invention is to provide an apparatus for maintaining a barrier
in a position against a trans-barrier force less than a predetermined magnitude which
can respond to trans-barrier forces in two directions with respect to the barrier
without occasioning damage to the barrier or to barrier-associated structures.
[0015] Yet a further object of the present invention is to provide an apparatus for maintaining
a barrier in a position against a trans-barrier force less than a predetermined magnitude
in which the predetermined magnitude can be established with accuracy.
[0016] Further objects and features of the present invention will be apparent from the following
specification and claims when considered in connection with the accompanying drawings
illustrating the preferred embodiments of the invention.
DETAILED DESCRIPTION OF THE DRAWINGS
[0017]
Fig. 1 is an exploded view of a prior art roll-up door of the type contemplated for
use with the apparatus of the present invention.
Fig. 2 is a top view of a prior art guide rail assembly with a hinged cover.
Fig. 3 is a partial schematic view of a prior art roll-up door showing details of
a door tensioning mechanism.
Fig. 4 is a perspective view of the preferred embodiment of the present invention.
Fig. 5 is a plan section view of the sliding block assembly of the present invention,
taken along Section 5-5 of Fig. 6.
Fig. 6 is a top view of the sliding block assembly of the preferred embodiment of
the present invention.
Fig. 7 is a top view of the sliding block assembly of an alternate embodiment of the
present invention which is configured to respond to trans-barrier forces in one direction
only.
Fig. 8 is a plan view of the sliding block assembly of an alternate embodiment of
the present invention in which the interface between the first portion and second
portion of the apparatus comprises a single dovetail joint.
Fig. 9 is a plan view of the sliding block assembly of an alternate embodiment of
the present invention in which the interface between the first portion and the second
portion of the apparatus comprises a pair of bulbous-ended walls and complementary
receiving channels.
Fig. 10 is a plan view of the sliding block assembly of an alternate embodiment of
the present invention in which the interface between the first portion and second
portion of the apparatus comprises a single bulbous-ended wall and complementary receiving
channel.
Fig. 11 is a plan view of the sliding block assembly of an alternate embodiment of
the present invention in which the interface between the first portion and the second
portion of the apparatus comprises a tangential rod and complementary receiving channel.
Fig. 12 is a plan view of the sliding block assembly of an alternate embodiment of
the present invention in which the interface between the first portion and second
portion of the apparatus comprises a pair of walls having a T-shaped cross section
and complementary receiving channels.
Fig. 13 is a plan view of the sliding block assembly of an alternate embodiment of
the present invention in which the interface between the first portion and second
portion of the apparatus comprises a metal C-shaped channel and a pendant mating block
slidable within that channel.
Fig. 14 is a perspective view of the sliding block assembly of an alternate embodiment
of the present invention in which the interface between the first portion and second
portion of the apparatus comprises embedded linear bearing assemblies.
Fig. 15 is a plan view of an alternate embodiment of the present invention with a
portion of an associated door shown in phantom.
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT
[0018] Fig. 1 illustrates the principal elements of a roll-up door assembly 10 in an exploded
perspective view. The roll-up door assembly 10 principally consists of a roller 12
directly driven by a motor 14. On the roller 12 is the flexible door 16 and cable
reels 18. The roller 12 is situated adjacent an opening 20 in a wall 22. Adjacent
the opening 20 and mounted to the wall 22 are guide rails 24.
[0019] In operation, the door 16 is rolled and unrolled upon the roller 12 in response to
movement of the roller 12 by the motor 14. The door 16 is maintained in a position
adjacent the opening 20 by the guide rails 24, in a manner to be described in greater
detail hereinafter.
[0020] For purposes of clarity and ease of understanding the invention, like elements will
be identified by like reference numerals in the various drawings.
[0021] In Fig. 2, a top view of a prior art guide rail 24 is illustrated attached to a wall
22. The guide rail 24 comprises a wall 26 of generally L-shape with a first leg 28
affixed to the wall 22 and a second leg 30 depending from the first leg 28. A cover
32 is hinged to the second leg 30 at a hinge 34. The cover 32 presents a guide wall
36 in facing relation to a guide wall 38 depending from first leg 28. The guide walls
36 and 38 define a channel 40 which leads from without the guide rail 24 to an interior
chamber 42 defined by the wall 26 and the cover 32.
[0022] In operation, the door 16 and its associated guide follower (not shown in Figs. 1
and 2) slidingly travel within the channel 40 so that the guide rail 24 guides the
door 16 in a desired orientation with respect to the opening 20 as the motor 14 rotates
the roller 12 to move the door 16 upward and downward within the channel 40.
[0023] The interior chamber 42 contains the tensioning mechanism (not shown in Figs. 1 and
2) in a manner to be described in greater detail hereinafter.
[0024] The guide rail 24 of Fig. 2 responds to application of a trans-barrier force F applied
to the door 16 in a direction away from the wall 22 as follows: as the trans-barrier
force F is applied to the door 16, the door 16 will impinge upon the guide wall 36,
urging the cover 32 to rotate about the hinge 34 in a direction as indicated by the
arcuate arrow R in Fig. 2. Thus, the door 16 will no longer be resisted in its movement
in the direction of the arrow F in Fig. 2 by the guide wall 36 and will, therefore,
freely swing away from the wall 22 in response to the trans-barrier force F.
[0025] A serious shortcoming of the prior art design illustrated in Figs. 1 and 2 is best
illustrated in Fig. 3, a more detailed illustration of one side of a roll-up door
assembly 10. In Fig. 3, the guide rail 24 is illustrated with the cover 32 removed
to reveal the details of the tensioning mechanism 44.
[0026] The tensioning mechanism 44 includes a cable 46 which is attached at a first end
48 to the cable reel 18 on the roller 12. The cable is led through pulleys 50, 52,
and 54 and terminates at a second end 56. The second end 56 is attached to an extension
arm 58 of a guide follower 60. The guide follower 60 is attached to the door 16. A
tension spring 62 is attached between the pulley 50 and a tab 64 associated with the
guide rail 24 to maintain the cable 46 in tension.
[0027] As can be seen in Fig. 3, the door 16 and the guide follower 60 extend beyond the
inner edge 25 of the guide rail 24. The inner edge 25 is the closest edge to the door
16 of the first leg 28 of the guide rail 24, which first leg 28 is attached to the
wall 22 adjacent the opening 20.
[0028] As can be seen in Fig. 2, the inner edge 25 is substantially co-terminous with one
end of the channel 40. Thus, while the cover 32 of the guide rail 24 is not illustrated
in Fig. 3, it can be plainly seen from Fig. 3 that the door 16 and its attached guide
follower 60 extend through the channel 40 to the interior chamber 42 of the guide
rail 24 in its travel upward and downward in response to rotation of the roller 12
by the motor 14.
[0029] As can further be seen from the detailed illustration of Fig. 3, when a trans-barrier
is applied to the door 16 in a direction away from wall 22 so that the door 16 and
the guide follower 60 urge the cover 32 outward about its hinge 34, there is occasion
for the guide follower 60 to snarl, tangle, or stretch the cable 46 and cause serious
damage to the tensioning mechanism 44 to the extent that significant down time with
the door 16 jammed in its downward (closed) position is a distinct possibility. It
is this shortcoming of the design of the prior art door mechanism illustrated in Figs.
1, 2, and 3 which the present invention overcomes.
[0030] Fig. 4 illustrates a perspective view of the preferred embodiment of the present
invention. In Fig. 4, a flexible door 16 is illustrated with a leading edge segment
64 attached at the bottom of the flexible door 16. The leading edge segment 64 extends
the full width of the flexible door 16 and is attached to a guide follower 66.
[0031] The preferred embodiment of the guide follower 66 includes a pair of U-shaped brackets
68 and 70 oriented in facing relation and embracing a sliding block assembly 72. The
sliding block assembly 72 is comprised of two portions 72a and 72b of material preferably
having a low coefficient of friction, such as urethane or the like, and joined in
a multi-dovetail joint 74.
[0032] The U-shaped bracket 68 may be unitarily formed with the leading edge segment 64
or may be attached by bolting, adhesive, or other commonly known means to the leading
edge segment 64. A guide follower arm 76 may be similarly unitarily formed with the
U-shaped bracket 70 or attached to the U-shaped bracket 70. The guide follower arm
76 extends substantially perpendicularly from the U-shaped bracket 70 and is configured
to slidingly engage a guide rail structure adjacent an opening and accommodate a tensioning
mechanism in the manner previously known and illustrated in Figs. 1-3.
[0033] Also included in the preferred embodiment of the guide follower 66 is a shear pin
78 configured to be inserted in an aperture 80. The aperture 80 is oriented to intersect
the dovetail joint 74 substantially throughout the length of the dovetail joint 74
so as to intersect the mating surfaces established at the boundaries of the sliding
block assembly portion 72a and sliding block assembly portion 72b, as will be described
in greater detail hereinafter.
[0034] The sliding block assembly 72 is retained between the facing U-shaped brackets 68
and 70 by means generally known in the industry, such as bolting (not shown in Fig.
4), adhesive, or the like.
[0035] Fig. 5 illustrates a plan section view of the sliding block assembly of the preferred
embodiment of the present invention. In Fig. 5, the sliding block assembly 72 is held
between the two U-shaped brackets 68 and 70 and the dovetail joint 74 establishes
pairs of mating surfaces 82a-82i. As may be seen in Fig. 6, in a top view of the
preferred embodiment of the sliding block assembly illustrated in Fig. 5, the plurality
of mating surfaces 82a-82i are substantially perpendicular to the two faces 84 and
86 of the sliding block assembly 72. Using such a construction for the sliding block
assembly 72, the sliding block assembly 72 will separate into a first portion comprising
U-shaped bracket 68 and sliding block assembly portion 72a and a second portion comprising
U-shaped bracket 70 with its attached guide follower arm 76 and sliding block assembly
portion 72b upon application of a force, for example, against the leading edge segment
64 of the door 16 in either of the two directions substantially perpendicular to the
leading edge segment 64. Thus, a fork lift or other machine impacting the leading
edge segment 64 of the door 16 from either side of the door 16 will, if the force
is of sufficient magnitude, shear the shear pin 78 (referring to Fig. 4) and effect
a sliding disengagement of the two portions 72a and 72b of the sliding block assembly
72.
[0036] Preferably, the material of the sliding block assembly 72 is selected to provide
a minimal coefficient of friction in order that minimal amounts of the trans-barrier
force applied to the leading edge segment 64 will be transmitted through the sliding
block assembly 72 to the guide follower arm 76. In such manner, the guide follower
arm 76 will impact a minimal amount on its associated guide rail and tensioning mechanism,
thereby precluding damage to the guide rail and tensioning mechanism.
[0037] Returning to Figs. 5 and 6, the aperture 80 is clearly shown as passing entirely
through the sliding block assembly 72 and intersecting pairs of mating surfaces 82b,
82d, 82f, and 82h. Proper selection of the shear pin material, diameter, and other
parameters serves to precisely define the amount of trans-barrier force which must
be applied to the sliding block assembly 72 in order to effect sliding disengagement
of sliding block assembly portion 72a and 72b.
[0038] Fig. 7 illustrates an alternate embodiment of the apparatus of the present invention
in the form of an alternate top view of the sliding block assembly illustrated in
Fig. 5. In Fig. 7, the pairs of mating surfaces 82 are not perpendicular to the faces
84 and 86 of the sliding block assembly 72, and, thus, the sliding block assembly
72 will only slidingly disengage in one direction in response to a trans-barrier force.
[0039] Fig. 8 is a plan view of the sliding block assembly 72 of an alternate embodiment
of the present invention where the sliding block assembly portion 72a and the sliding
block assembly portion 72b are joined by a single dovetail joint 74.
[0040] Fig. 9 is a plan view of an alternate embodiment of the sliding block assembly 72
of the present invention wherein the sliding block assembly portion 72a and the sliding
block assembly portion 72b are joined in a joint 88 comprising a pair of walls 90
having bulbous ends 92 with the walls 90 and ends 92 being received within complementary
channels 94 in sliding block assembly portion 72b.
[0041] Fig. 10 is a plan view of an alternate embodiment of the sliding block assembly 72
of the present invention wherein the sliding block assembly portion 72a is joined
with the sliding block assembly portion 72b by a joint 88 comprising a single wall
90 having a bulbous end 92 with the wall 90 and the end 92 being received within a
complementary channel 94 in sliding block assembly portion 72b.
[0042] Fig. 11 is a plan view of an alternate embodiment of the sliding block assembly 72
of the present invention wherein the sliding block assembly portion 72a and the sliding
block assembly portion 72b are joined by a joint 96 comprising a tangential rod 98
joined to the remainder of sliding block assembly portion 72a by a neck 100 with the
tangential rod 98 being received within a complementary channel 102 in sliding block
assembly portion 72b.
[0043] Fig. 12 is a plan view of an alternate embodiment of the sliding block assembly 72
of the present invention wherein sliding block assembly portion 72a and sliding block
assembly portion 72b are joined by a joint 104 which comprises a pair of walls 106
of generally T-shaped cross-section with the walls 106 being received within complementary
channels 108 in sliding block assembly portion 72b.
[0044] Fig. 13 is a plan view of an alternate embodiment of the sliding block assembly 72
of the present invention wherein the sliding block assembly comprises a generally
C-shaped metal channel 110 and a mating block 112 slidable within the channel 110.
The mating block 112 is joined to a base sliding section 114 at a neck 116. The neck
116 slidingly engages the free ends 118 of the C-shaped channel 110.
[0045] Fig. 14 is a perspective view of an alternate embodiment of the sliding block assembly
72 of the present invention. In the embodiment illustrated in Fig. 14, the sliding
block assembly portion 72a has embedded therein a pair of linear bearing housings
120 presenting inner races 122. The linear bearings 120 and their associated inner
races 122 are open to the faces 84 and 86 of the sliding block assembly 72. Slidingly
received within the inner races 122 are linear bearing cores 124. The linear bearing
cores 124 are attached by extensions 126 through slots 128 to sliding block assembly
portion 72b. Preferably, the extensions 126 are embedded in the sliding block assembly
portion 72b to rigidly affix the linear bearing cores 124 with respect to the sliding
block assembly portion 72b.
[0046] The alternate embodiment illustrated in Fig. 14 is particularly useful in obviating
any effects of plastic creep or excessive frictional wear which may be experienced
by some materials from which the sliding block assembly 72 may be manufactured. Such
plastic creep or frictional wear could occasion misalignment with consequent jamming
or loose fitting of the sliding block assembly portion 72a with sliding block assembly
portion 72b.
[0047] Fig. 15 is a plan illustration of an alternate embodiment of the present invention
with a portion of an associated door shown in phantom.
[0048] In Fig. 15, a portion of a flexible door 202 is shown in phantom having a leading
edge segment 204 attached at the bottom 203 of the flexible door 202. The leading
edge segment 204 extends the full width of the flexible door 202 (not shown) and is
attached to a guide follower 206.
[0049] The guide follower 206 includes a C-shaped door bracket 208. Door bracket 208 comprises
a base section 210 having integrally formed depending arms 212, 213 and, depending
in facing relationship respectively from depending arms 212, 213 are facing arms 214,
215. Facing arms 214, 215 are of appropriate length to leave a gap 216 therebetween.
Thus, there is defined a cavity 218 which is bounded by the depending arms 212, 213,
facing arms 214, 215 and base section 210, with access to cavity 218 being available
through gap 216. On facing arm 214 is affixed a sliding block 220 within cavity 218,
and a similar sliding block 222 is affixed to the lower portion of the boundary of
cavity 218 provided by base section 210.
[0050] Guide follower 206 also includes a rail bracket 230. Rail bracket 230 includes a
guide follower arm 232 on which are mounted a pair of rollers 234, and a rail base
member 236. Depending substantially perpendicularly from rail base member 236 is a
generally T-shaped sliding member 238. Sliding member 238 is comprised of a generally
horizontally oriented bar 240 and depending generally vertically in opposing directions
from the end of bar 240, distal from rail base member 236, are sliding block support
members 242 and 244. Sliding block support member 242 carries thereon a sliding block
246 which is affixed in facing relationship to sliding block 220; sliding block support
member 244 has affixed thereon a sliding block 248 in facing relationship to sliding
block 222.
[0051] Cavity 218, sliding member 238, and sliding blocks 220, 246, 222, 248 are all appropriately
sized to present sliding blocks 220 and 246 in facing relationship and substantially
intimate contact, and sliding blocks 222 and 248 in facing relationship and substantially
intimate contact when door 202 is in proper operating position with respect to rail
bracket 230. When in such operating position, there exists a gap between sliding block
support member 242 and base section 210 as well as a gap between sliding block support
member 244 and its adjacent facing arm 215. These gaps, and the loose fit of bar 240
within gap 216 facilitate reassembly of guide follower 206 by tilting rail bracket
230 with respect to door bracket 208 while inserting sliding member 238 and its associated
sliding block support members 242, 244 within the gap 216 and the cavity 218, then
allowing rail bracket 232 to tilt in the opposite direction to the insertion-imposed
tilt to bring the associated members in the alignment illustrated in Fig. 15 for operation
of door 202.
[0052] Thus, when a lateral force (e.g., in a direction perpendicular to the plane of Fig.
15) is applied to leading edge segment 204 of flexible door 202, door bracket 208
and rail bracket 230 are slidably disengaged from each other, which disengagement
is facilitated by the low coefficient of friction material of which the sliding blocks
220, 246 and 222, 248 are preferably manufactured. Thus, injury to door 202 is minimized.
[0053] A strap, substantially the width of depending arms 212, 213 may be wrapped about
door bracket 208 while rail bracket 230 is inserted therein as illustrated in Fig.
15 in order to ensure that inadvertent sliding disengagement of door bracket 208 and
real bracket 230 is not occasioned by vibration, inadvertent nudging of leading edge
segment 204, or the like. Preferably, such a strap would be secured in its wrapped
position about door bracket 208 by a releasable fastener, such as hook-and-eye fastening
lands, or the like.
[0054] The placement of sliding blocks 220, 246 and 222, 248 is selected appropriately that
when door 202 and guide follower 206 are in proper operating engagement with ancillary
operating parts (not shown) there are opposing moment arms applied to door bracket
208 and rail bracket 230 which urge sliding blocks 220 and 246 together as well as
urge sliding blocks 222 and 248 together.
[0055] It is to be understood that, while the detailed drawings and specific examples given
describe preferred embodiments of the invention, they are for the purpose of illustration
only, that the apparatus of the invention is not limited to the precise details and
conditions disclosed, and that various changes may be made therein without departing
from the spirit of the invention which is defined by the following claims.
1. An apparatus for controlling passage through an opening comprising a movable barrier
means for selectively blocking said opening;
at least one guide means for guiding said movable barrier means;
and at least one guide follower means for effecting operative connection between said
movable barrier means and said at least one guide means, said at least one guide follower
means being attached to said movable barrier means and operatively interactive with
said at least one guide means to control movement of said movable barrier means;
each of said at least one guide follower means comprising a first portion attached
to said movable barrier means and a second portion, said first portion and said second
portion being separable in response to application of a predetermined force to said
first portion transverse to said movable barrier means.
2. An apparatus for controlling passage through an opening as recited in Claim 1 wherein
said movable barrier means generally moves in a plane to effect said blocking;
and said first portion and said second portion interfit to define at least one pair
of mating surfaces, each of said at least one pair of mating surfaces being transverse
to said plane, said at least one pair of mating surfaces being oriented to allow disengagement
of said first portion and said second portion in two directions, said two directions
being transverse to said plane.
3. An apparatus for controlling passage through an opening as recited in Claim 2 wherein
each of said at least one guide follower means further comprises a frangible pin means
for securing said first portion to said second portion, said frangible pin means intersecting
at least one of said at least one pair of mating surfaces, said frangible pin means
being configured to fail in response to said application of said predetermined force.
4. An apparatus for controlling passage through an opening as recited in Claim 2 wherein
each of said at least one guide follower means further comprises temporary holding
means for maintaining a predetermined relative orientation of said first portion and
said second portion, said temporary holding means ceasing to maintain said predetermined
relative orientation in response to said application of said predetermined force.
5. An apparatus for controlling passage through an opening as recited in Claim 1 wherein
said movable barrier means has a width and said movable barrier means includes a leading
edge segment, said leading edge segment extending substantially across said width;
said first portion being attached to said leading edge segment.
6. An apparatus for controlling passage through an opening as recited in Claim 2 wherein
said movable barrier means has a width and said movable barrier means includes a leading
edge segment, said leading edge segment extending substantially across said width;
said first portion being attached to said leading edge segment.
7. An apparatus for controlling passage through an opening as recited in Claim 3 wherein
said movable barrier means has a width and said movable barrier means includes a leading
edge segment, said leading edge segment extending substantially across said width;
said first portion being attached to said leading edge segment.
8. An apparatus for controlling passage through an opening as recited in Claim 4 wherein
said movable barrier means has a width and said movable barrier means includes a leading
edge segment, said leading edge segment extending substantially across said width;
said first portion being attached to said leading edge segment.
9. An apparatus for controlling passage through an opening as recited in Claim 1 wherein
said movable barrier means generally moves in a plane to effect said blocking; and
said first portion and said second portion interfit to define at least one pair of
mating surfaces, each of said at least one pair of mating surfaces being transverse
to said plane, said at least one pair of mating surfaces being oriented to allow disengagement
of said first portion and said second portion in one direction, said direction being
transverse to said plane.
10. An apparatus for controlling passage through an opening as recited in Claim 9
wherein each of said at least one guide follower means further comprises a frangible
pin means for securing said first portion to said second portion, said frangible pin
means intersecting at least one of said at least one pair of mating surfaces, said
frangible pin means being configured to fail in response to said application of said
predetermined force.
11. An apparatus for controlling passage through an opening as recited in Claim 9
wherein each of said at least one guide follower means further comprises temporary
holding means for maintaining a predetermined relative orientation of said first portion
and said second portion, said temporary holding means ceasing to maintain said predetermined
relative orientation in response to said application of said predetermined force.
12. An apparatus for controlling passage through an opening as recited in Claim 9
wherein said movable barrier means has a width and said movable barrier means includes
a leading edge segment, said leading edge segment extending substantially across said
width;
said first portion being attached to said leading edge segment.
13. An apparatus for controlling passage through an opening as recited in Claim 10
wherein said movable barrier means has a width and said movable barrier means includes
a leading edge segment, said leading edge segment extending substantially across said
width;
said first portion being attached to said leading edge segment.
14. An apparatus for controlling passage through an opening as recited in CLaim 11
wherein said movable barrier means has a width and said movable barrier means includes
a leading edge segment, said leading edge segment extending substantially across said
width;
said first portion being attached to said leading edge segment.
15. An apparatus for accommodating application of a force in excess of a predetermined
magnitude to preclude damage to a closure assembly, said closure assembly including
a generally planar movable barrier means for controlling access through an opening
and at least one guide means disposed about said opening for guiding said movable
barrier means, the apparatus comprising at least one guide follower means for operably
connecting said movable barrier means and said at least one guide means, each of said
at least one guide follower means including a first portion attached to said movable
barrier means and a second portion operatively interactive with said at least one
guide means, said first portion and said second portion being separable upon said
application of said force in excess of said predetermined magnitude in a direction
transverse to said movable barrier means.
16. An apparatus for accommodating application of a force in excess of a predetermined
magnitude as recited in Claim 15 wherein said first portion and said second portion
interfit to form at least one pair of mating surfaces, each of said at least one pair
of mating surfaces being transverse to said movable barrier means, said at least one
pair of mating surfaces being oriented to allow disengagement of said first portion
and said second portion in two directions, said two directions being transverse to
said plane.
17. An apparatus for accommodating application of a force in excess of a predetermined
magnitude as recited in Claim 15, wherein the apparatus further comprises a frangible
pin means for securing said first portion and said second portion, said frangible
pin means intersecting at least one of said at least one pair of mating surfaces,
said frangible pin means being configured to fail upon said application of said force
in excess of said predetermined magnitude.
18. An apparatus for accommodating application of a force in excess of a predetermined
magnitude as recited in Claim 15, wherein the apparatus further comprises temporary
retaining means for maintaining a predetermined relative orientation of said first
portion and said second portion, said retaining means being configured to cease maintaining
said predetermined relative orientation upon said application of said force in excess
of said predetermined magnitude.
19. An apparatus configured for maintaining a barrier in a position against a trans-barrier
force less than a predetermined magnitude, said barrier having associated structure
means for cooperating with the apparatus to define said position, the apparatus comprising
a guide follower means attached to said barrier and operatively interacting with said
structure means for defining said position, said guide follower means comprising a
first portion attached to said barrier and a second portion operatively interactive
with said structure means, said first portion and said second portion being in an
interfitting relation and defining at least one pair of mating surfaces, each of said
at least one pair of mating surfaces being transverse to said barrier and oriented
to allow sliding disengagement of said first portion and said second portion in response
to application of a trans-barrier force to said barrier in excess of said predetermined
magnitude.