Note: Descriptions are shown in the official language in which they were submitted.
~3~ 1874~706D
This is a division of our copending Canadian
Patent Application No. 438,703 filed October 11th, 1983.
This invention relates to a new and improved un-
derfloor wiring system for a cellular flooring system which
isolates one or more distribution channels from remaining
channels.
It is well known in the art to utilize a corruga-
ted metal sheet having alternating valleys and crests connected
by inclined webbing in conjunction with an attached lower metal
plate to create a plurality of spaced, parallel conduits or
cells. The cells are used to receive service lines (e.g. power,
electronics, communication and the like). It is also well known
that separation of these services is highly desirable, both for
safety reasons and so that each can be separately maintained
without risk of interference with the others. In addition to
providing a separa-te conduit for each service, it is also highly
desirable to provide access to all the services at one location.
Further, providing an overlying trench having transversely ori-
ented passageways which are connected with the conduits in a
manner so that certain conduit passageway channels are isolated
from other such channels is also desirable for reasons listed
below.
Finally, it is highly desirable to surround channels
containing high voltage lines or other potentially heat
generating service lines with as much concrete as possible to
increase the fire resistant qualities of an entire structure.
This goal has not been addressed or achieved by any known prior
art devices.
There have been many attempts to achieve the above-
mentioned goals but all have a number of shortcomings. U.S.
Patents 3,303,264, 3,417,191 and 3,932,696 represent devices in
which two parallel cells can be accessed by a single access
housing. A problem with those devices is that they are not
adaptable for uses where more than two services are required.
Additionally, each of those devices requires access openings in
the corrugated sheet which reduces the structural integrity of
the flooring.
One solution to the need for additional cells is
disclosed in U.S. Patents 3,592,956 and 4,194,332. Those
patents describe a typical corrugated sheet having crests,
valleys and a base plate which is modified by providing a cover
over selected valleys to create additional cells. The problems
remain, however, of obtaining access to the original crest
cells without punching holes into the corrugated sheet and of
providing a number of cells in a relatively small space.
Another known solution provides additional cells at
predetermined locations by providing a smaller crest having
vertical sidewall webbing rolled into a valley of the sheet
between two adjacent crests. Openings are provided in the
smaller central crest and in the inclined webbing of each
adjacent crest to provide access at a single location. A
problem with that system is that each piece must be properly
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cut and positioned so as to line up the smaller crest. Also,
there are often many left-over pieces when the sheets are cut
because of the irregular pattern of crests and valleys in the
corrugated sheets.
U.S. Patent 3,721,051 discloses a bottomless trench
assembly which isolates the cell-passageway channels from other
such channels. However, since the trench has no base, time
consuming barriers must be added along the side rails of the
trench to prevent concrete from flowing through the valley
portions of a corrugated sheet into the trench passageways.
Additionally, the service lines are placed directly on the
crest portions of the corrugated sheet and which oEfers little
resistance to fire.
In addition to the problems mentioned above, the
references cited above utilize a base plate secured under the
corrugated sheet which transforms each crest into an enclosed
conduit or cell. In use, the conventional corrugated cellular
raceway units are secured in place and a layer of concrete is
poured over them. Service lines are then, typically, fed into
the cells through access housings left at pre-determined
locations in the concrete. The insulating covers on the lines,
or even the lines themselves, are sometimes damaged in the
weeding process by being pulled across sharp metal edges.
Additionally, the feeding process is a tedious and time
consuming process which tends to unnecessarily increase
building costs.
Fabrication costs are increased by the necessity of
providing knockout plugs or having openings punched at
differing predetermined locations on various corrugated
sheets. The provision of plugs and openings at precise
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1874-706D
locations requires each sheet to be punched according to i-ts
particular position on a floor plan. The sheets must be indi-
vidually placed according -to the plan and when -the sheets are
inadvertently mixed up, time consuming on-site adjustments must
be made. Also, the delay in shipment of any single sheet may
halt the progress of an entire operation.
The present invention provides in a cellular floor-
ing system of the type having a plurality of longi-tudinally ex-
tending parallel conduits provided on a first horizontal level,
at least a portion of said conduits being formed by portions of
corrugated metal decking sheets supported by supporting beams of
a floor, and having a plurallty of parallel passageways extending
transversely with respect to said conduits and provided on a sec-
ond horizontal level disposed vertically above said first level,
said passageways crossing over said conduits and each having a
generally rectangular area where the passageways and conduits are
juxtaposed and may communicate with one another through an open
portion therein to allow for substantially restricted vertical
access between the passageways and conduits, the improvement
which comprises separate isolating means in the form of a plate
adapted to be positioned in the rectangular area and acting as a
barrier between the juxtaposed passageways and conduits, said is-
olating means also having at least one portion thereof removed
to allow for access between at least one passageway and a single
conduit.
We also prefer to provide an overlying trench com-
prised of a plurality of vertical wall members having a base
sheet attached thereto to form the passageways oriented trans-
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versely with respect to the conduits. We prefer to provide a
base sheet having a gap therein posi-tioned over divided valleys
in the sheet to allow unrestricted access between the conduits
and passageways. A cover is also provided for the trench.
We prefer to utilize a trench having a base sheet
so that concrete can flow beneath the trench into the undivided
valleys in the corrugated sheet thereby providing a struc-ture of
greater strength and one which offers greater resistance to fires.
We prefer to provide a trench which is manufactured in
standard modular lengths which can be easily assembled and
attached to the top of the corrugated sheets at the job site.We
~u~ler pxe-Eer to provide an isolating means which locks the dividing
or separating member of the corrugated sheet to the trench.
In one embodiment, we prefer to utilize an isolating
means in the form of a cross-shaped plate member. Longitudinally
extending portions of the plate provide a cover for the
U-shaped dividing member in the gap area of the trench base and
transversely extending portions provide a base in the gap area
for a central trench passageway. An opening is provided in the
center of the cross-shaped member to allow access between the
isolated center conduit defined by the shaped members and the
center trench passageway.
In construction, we prefer to first place corrugated
sheets on the floor's supporting beams in a manner whereby the
valleys open upwardly away from the supporting beams and the
crests open downwardly toward the support beams. We prefer to
provide identical sheets in modular lengths so that any
individual sheet may be placed at any location without regard
to a floor plan. The sheets are positioned end to end to
provide a plurality of spaced-apart, continuous, parallel
valleys across the floor. As the floor is closed in, it may be
necessary to cut some of the sheets to the proper length.
Next, we prefer to make a determination as to which valleys
will be utilized as service raceways. Longitudinally extending
dividing members are then placed end to end in the chosen
valleys in order to create a plurality of open, parallel
conduits in each of the chosen valleys. Dividing members can
be designed to provide two or more conduits in any single
valley and are preferably provided in modular lenghts
corresponding to the lengths of the corrugated sheets. We then
prefer to attach a cross-shaped isolating member to the
dividing member in the area where an overlying trench will be
required. Then modular lengths of the trench are positioned
and attached together so that the trench gap is aligned over
the isolating member. The isolating member engages the
interior wall members of the trench, thereby aiding in aligning
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it in its proper position and in securing it in place. If
possible, we prefer to place all the service lines into their
respective conduits and passageways beEore they are covered and
a layer of concrete is poured over the sheet in order to
eliminate the "feeding" process described above. We then
prefer to provide access housings, also having isolated means,
in desired locations and covers over the exposed portions of
the divided valleys of the corrugated sheet thereby enclosing
the service lines in their cells and passageways. A cover is
only provided for those valleys being utilized as cells. Since
no base sheets are provided on the corrugated sheets, trapping
pockets of air in unused cells is prevented. By leaving the
underside of the sheets exposed, heat can be swiftly radiated
away from the sheets to the adjacent free flowing air, making
the system less likely to fail in the event of a fire than a
conventional cellular flooring unit. Access to the cells may
be provided by utilizing either spaced-apart covers or covers
having openings therein. No holes or openings are required in
the corrugated sheet
It service lines are not placed in the cells before
they are enclosed, we prefer to place a string or wire in each
conduit before it is covered to facilitate feeding the lines at
a later time. The end of a service line is tied to the string
or wire at one access opening and pulled through the enclosed
cell from a second openingO
In another embodiment, we prefer to provide a
corrugated metal sheet having generally alternating crests and
valleys of equal width on one edge of the sheet, with the
opposite edge of the sheet rolled to have a plurality of
narrower crests therein. ye prefer to provide a cover plate
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over the valleys between these narrower crests and on each side
thereof to create a plurality of closed parallel cells. vie
prefer to provlde the cells along an edge of the sheet to allow
for easier matching of sheets should cutting of the sheets be
required.
In the accompanying drawings we have illustrated
certain present preferred embodiments of our invention in
which:
Figure 1 is an isometric end view in exploded form
showing a corrugated metal sheet, "U" shaped dividing member
and cover means;
Figure 2 is a cross-sectional view of the structure
shown in Figure 1 as assembled showing three separately
enclosed cells formed from a single valley;
Figure 3 is a cross-sectional view of another
embodiment showing four separately enclosed cells formed by a
"W" shaped dividing member;
Figure 4 is a cross-sectional view of yet another
embodiment showing two separately enclosed cells formed by an
"I" shaped dividing member;
Figure 5 is an isometric view of a sheet having a
wide valley to provide cells with larger cross-sectional areas;
Figure 6 is a cross-sectional view showing a sheet
having a plurality of narrow crests at one end thereof and a
cover means to utilize the valleys between and adjacent to said
narrow crests as enclosed raceway cells;
Figure 7 is an isometric view of a sheet having a
single valley and spaced-apart covers;
Figure 8 is an isometric view of portions of two
interconnected corrugated sheets and associated "U" shaped
dividing member;
Figure is an isometric view of an overlying trench
unit;
Figure 10 is an isometric view in exploded Eorm of a
mounting tray and associated electrical receptacles; and cover
plate;
Figure 11 is an isometric view of a service access
housing unit;
Figure 12 is an isometric view of a cross-shaped
isolating member; and
Figure 13 is an isometric view partly in section o,
an entire cellular flcoring system showing the interconnection
of components shown in Figures 8 through 12 and a partly broken
away covering means therefore.
Referring specifically to Figures 1 and 2, a
corrugated metal sheet 10 is provided. Sheet 10 is formed to
have a symmetrical pattern of spaced-apart crests 12 and
valleys l with inclined webbing 16 connecting adjacent valleys
and crests. We prefer to roll shallow valleys or stiffening
ribs 18 in each crest 12 to provide greater stiffness in sheet
10. We also prefer to provide a plurality of embossments 17 on
the inclined webbing 16 to provide greater mechanical retention
with a layer of concrete (not shown) which is poured over the
corrugated sheet 10. In the center of each valley 14 we prefer
to provide a small ridge 20 to cooperate with a corresponding
ridge 22 located on the base portion 23 of "U" shaped dividing
or separating member 26. This arrangement provides one means
for properly positioning dividing member 26 within valley 14.
ividing member 26 is a "I" shaped channel having a
base portion 2B and two substantially vertical wall portions
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30. Divlding member 26 can be fabricated out of any suitable
material such as metal or plastic. Dividing member 26 can be
secured to a valley 14 by any suitable means, such as self-
taping screws or by locking it into an access housing (not
shown), and serves to provide three open parallel conduits in
any chosen valley. The height of the vertical wall portions 30
is preferred to be slightly greater than the depth of a valley.
In use, corrugated sheets 10 are positioned and
connected together to form a sub-flooring supported by
supporting beams. Once it is determined where service lines
will be required, a separating or dividing member 26 is placed
into the appropriate valley 14 or valleys. Once the separating
memker 26 is in place, the valley will contain three parallel
conduits 1, 2 and 3 having open top surfaces. it this point in
time it is preferred to place all of the service lines
carefully into their selected conduits. This process is far
more efficient than "feedingl' and pulling the lines through
enclosed cells as is the current practice. If the lines are
not placed prior to enclosing the cells, we prefer to place
strings to facilitate the feeding process when the lines are
required. An access housing may then be placed over each
access location. As mentioned, the access housing may be
utilized as a means to secure the dividing member and covers to
the sheet.
A cover 32 fabricated from any suitable material is
provided to enclose the lines or strings in their respective
cells 1, 2 and 3. In this embodiment, we prefer to provide a
cover having two elevated offsets 34 to receive the wall
portions 30 of separating member 2~ when assembled. This
arrangement provides another means for properly positioning
10 .
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dividing member 26 within valley 14. OEfsets 34 also serve to
increase the stiffness of the cover. Ihe edges 33 or cover 32
are supported by edges 15 of the crest 12 located on each side
of the valley 14 chosen as a service raceway. Access to the
cells can be provided in any of a number of ways. One way is
to proviae cover sheets 32 having generally semi-circular cut
outs 36 on their front and rear edges so that circular and oval
access openings to cells 1, 2 and 3 will be formed when two
cover sheets are placed end to end as shown in Figure 1.
Alternatively, cover sheets may be provided having access
openings therein as shown in Figure 5 or openings may be
provided between cover sheets as shown in Eigure 7. In each
case, access to all of the adjacent cells 1, 2 and 3 is
provided from a single localized region. No holes or openings
are required in sheet 10. Finally, a layer of concrete is
poured over sheets 10 and the covered cells to complete the
floor.
Referring specifically to Figure 3, a substantially
"W" shaped separating or dividing channel 40 is provided to
cooperate with valley 14 of corrugated sheet 10. Corrugated
sheet 10 can be identical to the corrugated sheets shown in
Figures 1 and 2. ridge 20 is provided in sheet 10 to receive
corresponding ridge 44 formed into the central portion of "W"
shaped member 40 as shown. Once separating member 40 is in
place, four open, parallel conduits 45, 46, 47 and 48 are
formed. After service lines are placed, a cover 50 is provided
to enclose the service lines into their respective cells. We
prefer to provide a cover having edges 53 supported on the
edges 15 of crests 12 and having three elevated offsets 52 to
receive the wall portions of separating member 40 as shown.
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Access openings (not shown) can be provided in cover 50 in the
same manner as described above or spaced-apart covers may be
utilized.
In E`igure 4, an "I" shaped dividing member 58 is
provided to create two parallel enclosed cells 62 an 64 out of
valley 14 of corrugated sheet 10. Again corrusating sheet 10
is identical to the sheets shown in the previous figures. In
this embodiment, the base portion 5~ of dividing member 58 is
formed to receive ridge 20 of valley 14. A cover 60 having
edges 71 supported on edges 15 of crests 12 and having elevated
offset 70 to receive member 58 is provided. Access openings
(not shown) may also be provided.
Figure 5 shows a sheet 100 rolled to have a plurality
of spaced-apart parallel crests 102 and at least one valley 104
having a width greater than the width of said crests with
inclined webbing 106 connecting adjacent crests and valleys.
Embossments 107 are provided on the webbing 106 to increase the
sheet's mechanical retention with a layer of concrete (not
shown) which is poured over the sheet. We prefer to provide
shallow valleys or stiffening ribs 108 in crests 102 to
increase the stiffness of the metal sheet 100. We also prefer
to provide a pair of spaced-apart ridges 105 in valley 104 to
aid in aligning and securing a separating member to said
valley. This arrangement provides yet another means for
properly positioning a dividing member 110 within a valley 10~.
In Figure 5 a "U" shaped dividing member 110 is
shown, but any of the above described separating members can be
adapted for use with sheet 100. The base portion 115 and wall
portions 114 of dividing n;ember 110 are formed to Eit securely
between ridges 105 as shown. A ridge 112 is provided in the
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base portion 115 of the separating memker 110 to provide
adequate space for the member to be placed over a portion of
corrugated sheet 100 which has been welded or bolted to a lower
supporting keam. By providing a separating or dividing member
in a relatively wide valley, cells having a larger cross-
sectional area can be created for applications in which such
added space is required.
A cover 120 is also provided having edges 121
supported on the edges 103 of crests 102. Shallow valleys or
stiffening ribs 122 are provided to add stiffness to the cover
120 and to contact and seal dividing member 110, as shown to
create three enclosed parallel cells 126, 127 and 128. Access
openings 125 are provided in the cover 120 above each cell.
In Figure 6, a sheet 80 is provided having generally
alternating crests 82 and valleys 84 of equal width on one edge
of the sheet with the other edge of the sheet 80 having a
plurality of narrower crests 86 therein. The valleys which
form cells 90, 91 and 92 adjacent to narrower crests 86 provide
open parallel conduits in a reduced space to receive a desired
number of service lines. After the lines are placed, a cover
88 is secured over the valleys to create a plurality of
enclosed parallel cellular raceways. Three such cells 90, 91
and 92 are shown in Figure 6. Cover 88 is provided with a
plurality of small crests or stiffening ribs 94 to increase the
metal's stiffness and to receive crests or ribs 86 of
corrugated sheet 80. Each end 89 of cover 88 is formed to
receive the edge 96 of adjacent crests 82. Small valleys or
stiffening ribs 98 are also provided in crests 82 to increase
the stiffness of corrugated sheet 80 and embossments 87 in
webking 83 provide greater mechanical retention with a layer of
13.
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concrete. In this embodiment of our invention, we prefer to
provide the cells on one edge of corrugated sheet 80 to
eliminate inadvertent cutting of the wrong side of the sheet 80
should cutting of the sheet be required to fill in floof space
requiring less than the full width of a sheet.
Figure 7 shows a sheet 15 havinq a single valley
portion 154. The valley 154 is provided with a pair of spaced
apart ridges 155 to aid in aligning and securing a separating
member to the sheet. Embossments 157 are provided on the
webbing 156 to increase the sheet's mechanical retention with a
layer of concrete which is poured over the sheet. Shallow
valleys or stiffening ribs 158 are provided in the sheet to
increase the stiffness of the metal.
A "I" shaped dividing or separating member 160 is
shown which separates valley 154 into three open parallel
conduits. The base portion 165 and wall portions 164 of the
separating member are formed to fit securely between ridges 155
as shown. A ridge 162 is provided in the base portion of the
separating member 160 for the reasons discussed above (see
description of Figure 5).
Two cover sheets 170 are shown each having elevated
offsets 174 to receive wall portions 164 of the dividing
member. As a result, three enclosed cells 180, 181 and 182 are
formed. Shallow valleys or stiffening ribs 171 are provided in
cover sheets 170 to increase their stiffness. The outside
edges 172 of cover sheets 170 are bent upwardly to allow for
easy installation and removal. Access to the enclosed cells is
permitted throuqh an uncovered portion of the sheet 150 between
the spaced-apart covers 170. An access housing is attached
directly over this uncovered portion prior to the pouring of
14.
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concrete over the sheet and covers.
Referring specifically to Figure 8, two corrugated
sheets 200 are shown. Mach sheet is formed to have a
substantially symmetrical pattern of spaced-apart crests 202
and valleys 204 with inclined webbing 206 connecting adjacent
valleys and crests. Shallow valleys or stiffening ribs 208 are
provided in each crest portion 202 to increase stiffness of the
sheets. Embossme`nts 207 are provided on webbing 206 for
reasons stated above and a ridge 210 is provided in the center
of each valley 204 to cooperate with a corresponding ridge 212
located in the base portion of "U" shaped dividing member
218. An elevated offset 201 at one edge of a first sheet 200
is sized to receive a smaller offset 203 formed on the opposite
end of a second sheet 200 thereby providing a means to
interlock a plurality of sheets 200 together over the entire
flooring area within the structure.
Dividing or separating member 218 is a "U" shaped
channel having a base portion 220 and wall portions 222. The
wall portions 222 are formed to have wings 224 extending
outwardly therefrom. As will be described in greater detail
below, extending wings 224 on separating member 218 are
utilized to secure other components of the cellular flooring
system together and to provide a central conduit 226,
preferably utilized for electrical power, which has no exposed
sharp metal edges which might cut into the power lines. Three
conduits 226, 227 and 228 are fornled into a single valley 204
when dividing member 21B is positioned therein.
Figure g shows a single trench unit 230 which rests
transversely across crest portions 202 of sheets 200. Two or
more trench units 230 having a modular length may be coupled
2~3
together in an end to end relationship as shown in Figure 13,
or a single trench unit may be designed to have the proper
length. Trench unit 230 is comprised o two outer vertical
wall members 232 and 234 and two inner vertical wall members
236 and 238, It is also contemplated that two or more wall
members could be substitituted by modified dividing members
similar to those described above. Wall members 232, 234, 236
and 238 are each height adjustable and are provided in a
parallel spaced-apart relationship so as to provide three
parallel passageways 240, 242 and 243, each passayeway having
an open top and bottom surface. The bottom surface of
passageways 240, 242 and 243 is closed by attached base sheet
2~6. As shown in the drawing, a gap 248 is provided in the
base sheet at one end of trench unit 230 to provide
unrestricted vertical access between conduits 226, 227 and 228
(shown in Figuee 8) and passageways 240, 242 and 243. Trench
unit 230 is positioned on the crest portions 202 of sheet 200
so that its vertical wall members 232, 234, 236 and 238 extend
transversely with respect to conduits 226, 227 and 228 and so
that gap 248 is positioned directly above said conduits. Gap
248 is created by removing at least a portion of the wall area
of the passageways 240, 242 and 243 and conduits 226, 227 and
228 in the region where the passageways are juxtaposed to the
conduits. If more than three passageways are required in the
trench unit 230 additional interior wall members may be
employed. A trench cover 250 (shown in Figure 13) is removably
attached over the entire length of the trench thereby fully
enclosing passageways 240, 242 and 243. The final height of
the trench can be adjusted by manipulating the wall members to
accommodate any desired flooring thickness. Adjustments are
16.
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made so that cover 250 is level with a layer of concrete which
is provided over the corrugated sheets 200.
Figure 10 is an isometric view in exploded form of a
mounting tray and associated electrical receptacle and cover
plate referred to as mounting unit 255. The mounting tray 260
generally has the shape of an inverted "U" shaped channel
having a top portion 270 and generally downwardly extending
side portions 280. Lower extending edges 282 of side portions
280 are folded inwardly and upwardly through 180 of arc and
are spaced at a distance to receive and ensage extending wings
224 of "U" shaped dividing member 218 (Figure 8). An inwardly
extendins tab 284 is provided at each end of side portions 280
approximately half way down from top 270. Tabs 284 are
utilized to support the weight of tray 260 onto the extending
wings 224 described above. It can be seen that tray 260 can
easily be snapped onto separating member 218 at any point along
its length where outlet receptacles might be required. Folded
edges 282 prevent upward movement and tabs 284 prevent downward
motion. Tray 260 can be moved longitidinally on dividing
member 218 by sliding it on wings 224 thereby permitting easy
alignment of the tray to a final position. Tray 260, in
addition to providing a mounting bracket, also serves as an
isolating means separating the power lines from other
services. As will later be described, tray 260 is covered by
an access housing which permits access to all of the
conduits. An access opening 290 is provided in top portion 270
of tray 260 to receive electrical outlets and the like. The
central portions of sides 280 of the tray extend upwardly above
the top 270 and then outwardly to provide surfaces 286 which
are used for mounting standard receptacle components 294 as
17.
shown. Edges 292 of the top surface 270 adjacent to opening
29C are formed upwardly so that no sharp metal edyes extend
into conduit 226 (Figure 8). In fact, the entire cellular
flooring system is designed so that no sharp edges can contact
or damage the service lines placed into conduits or
passageways. A standard cover plate 295 may be provided to
enclose the space surrounding receptacles 294.
In Figure 11 an access housing unit 300 is shown.
The housing has a body portion 302 formed from sheet metal and
a height adjustable top plate 310 for covering an opening
provided in the housing. The body portion is designed to span
across conduits 226, 227 and 22& as shown in Figure 13 and is
secured at ends 304 and 306 thereof to a crest 202 adjacent to
said conduits. As mentioned, the body portion has an opening
in its top surface to provide access to the underlying service
lines which are placed in conduits 226, 227 and 228 and top
plate 310 is height adjustable so that it can be leveled with a
layer of concrete which is poured over corrugated sheets 200.
Figure 12 is an isometric view of a cross-shaped
isolating plate member 320. ~lember 320 has longitidunally
extending portions 330 and transversely extending portions 340
extending outwardly from a central access opening 350.
Portions 330 each have downwardly extending edges 332, a
portion of which is folded inwardly and upwardly to provide a
snap on engaging means to secure portions 330 to outwardly
extending wings 224 of aividing member 218 in -the same manner
as edges 282 of mounting tray 260 decribed above in Figure 6.
Portions 330 provide a cover for conduit 226 in the portion of
trench 230 where gap 2~8 is provided in trench base sheet
246. TransverSely extending portions 340 of member 320 provide
18.
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a base for the portion of trench passageway 240 which crosses
over gap 24~ in base sheet 246. Isolating member 320 therefore
isolates conduit 226 and passageway 240 fxom âll other conduits
and passageways. Access opening 350 provides vertical access
only between conduit 226 and passageway 2~0. Upwardly
extending edges 352 of isolating member 320 are provided
adjacent to access opening 350. Edses 352 are folded over to
provide a snap-on engaging means for attaching said edges to
inwardly extending portions 237 and 239 provided at the base of
interior wall members 236 and 238 shown in Figure 9. There-
fore, isolating member 320 serves to isolate conduit 226 and
passageway 240 and to lock trench 230 to separating or dividing
member 218. Further, isolating member 320 eliminates any
possibility of misalignment of dividing member 218 relative to
the trench passageway 240.
It is contemplated that various other isolating
members could be designed in accordance with the teachings of
the present invention. In one such variation, a substantially
square plate member having three approximately spaced access
openings arranged diagonally therein, could effectively isolate
each of three connected conduit-passageway pairs from the
others. In this case, the two outermost openings could be
formed by cutting away two diagonally opposed corner portions
of the plate.
The isolating means of the present invention is
preferably in the form of a plate and is adapted to be placed
in gap 248 and acts as a barrier to prevent access between
vertically juxtaposed passageways and conduits. By removing at
least one portion of the isolating means, access between at
least one passageway and only a single conduit may be
19 .
provided. By providing isolating means having a plurality of
portions removed therefrom, such as cross-shaped isolating
member 320, at least one of the removed portions, opening 325,
for example, allows for access between only a single passageway
240 and single conduit 226. The remaining removed portions,
such as the spaces between longitudinally extending portions
330 and transversely extending portions 3~0, allows for access
between the remaining passageways and conduits. By removing
selected portions from the isolating means access may be
selectively provided between any single passageway and any
single conduit or between any number of passageways and any
number of conduits, as desired. It is normally desirable to
isolate at least one passageway and one conduit having access
thereto from the remaining passageways and conduits so that
electrical power lines, for example, may be segregated from
other types of service lines such as communication lines.
Referring now to Figure 13 a completely assembled
cellular flooring system is illustrated. A plurality of
corrugated sheets 200 are attached together as described in
Figure 8. A "U" shaped dividing member 218 placed into valley
204 provides three parallel conduits 226, 227 and 228; each
conduit having an open top surface. An isolating member 320 is
placed over conduit 226 in the center of the location where the
overlying trench 230 will be provided. A trench unit 230
having a base sheet 246 and an open top surface is placed over
isolating member 320 so that transversely extending portions
340 of member 320 span the gap 248 in base sheet 246 and so
portions 237 and 239 of interior trench wall 236 and 238 extend
across and engage portions 352 of isolating member 320. It is
to be understood that the trench and dividing member are locked
20.
together by the isolating member by means oE a sin,ple snap on
process and that all of the above components are provided in
standard modular lengths and, therefore, are easily assembled
at the job site.
A single trench comprised of one or n;ore trench units
230 preferably extends from one end of a structure to another
serves as the main feeder for all service lines. If more than
one trench unit is utilized two or more trench units 230 can be
easily coupled together in an end to end relationship with
clips 350 as shown. A gap 248 need only be providea in the
trench base sheets which cross over divided or separated
valleys; otherwise, trench base 2~6 extends the full length of
the trench wall members. Outer trench walls are attached to
the crest portions 202 of corrugated sheets 200 by sheet metal
screws or any other suitable means.
Once the valleys are separated and the trench is in
place, we prefer to place all of the service lines into their
respective passageways and conduits to avoid the feeding
process described above. Receptacle mounting units 255
containing any desired outlet hardware are then snapped onto
the separating member 128 at all desired locations along the
separatd valley. Access housings 300 are mounted over the
mounting units 255 onto crests 202 as shown. All remaining
exposed conduits are covered by covers 360. Covers 360 have
two sets of spaced-apart depressions 362 therein formed to
receive the wings 224 of separating n,ember 218 to aid in
properly aligning the covers 360 over the conduits and to help
cover the sharp metal edges of the wings. Ends 36~ of covers
360 are slightly elevated so that they may overlap the base
portion of the access housing 30G and outer trench walls 232
~3~
and 234, again covering sharp metal edges. Top covers 250 are
also provided on trench 230.
prom the foregoing description of the current
invention, it is our desire to make clear that we prefer to
provide standard sized corrugatd sheets which may be fabricated
in quantity, com,pactly nestled, shipped in bundles, installed
as received from the factory and which may be placed at any
location without regard to a floor plan. Of course, cutting of
the sheets may be required to fill in the exact dimensions as
the floor is closed. We also prefer to provide standardized
dividing members, isolating plates, trench members, access
housings and covers to be used in conjunction with the
sheets. Since no special fabrication is required, each of the
above components can be efficiently mass produced at a reduced
cost. We provide further cost savings by placing service lines
into open conduits before they are covered, thereby eliminating
the need for fishing the lines through enclosed cells.
Eliminating the fishing process reduces the risk of damaging
the lines and reduces the wiring time.
c provide an unaerfloor wiring system in which a
relatively small number of standard components can be easily
assembled in the field and each of which can be fabricated out
of sheet metal rather than more expensive castings. my
utilizing only valleys for service raceways, we have eliminated
the need for a base sheet attached beneath the corrugated
sheet. This reduces trapped air spaces and reduces the
likelihood and severity of fires. We provide access to a
plurality of services at a single access location while keeping
desired service lines isolated from others. ye provide a
trench which has a base sheet except for where the trench
~3~
crosses over the service conduits to allow concrete to flow
under the trench into the valleys not being utilized by
raceways. Providing concrete around the conduits and
passageways provides grea-ter fire protection than flooring
systems which utillze bottomless trenches because those systems
place service lines directly on the crests where there is
nothing to prevent rapid construction oE heat throughout the
corrugated sheet.
While we have illustrated and described certain
present preferred embodiments of the invention and methods of
practicing the same it is to be understood that the invention
is not limited thereto and may be otherwise variously practiced
within the scope oE the following clai~sO
