U.S. patent application number 11/286307 was filed with the patent office on 2007-06-07 for structural insulated panel construction for building structures.
Invention is credited to Hossein Borazghi, John Hughes, Paul Jack Moellendick, Don Stanley.
Application Number | 20070125042 11/286307 |
Document ID | / |
Family ID | 38117343 |
Filed Date | 2007-06-07 |
United States Patent
Application |
20070125042 |
Kind Code |
A1 |
Hughes; John ; et
al. |
June 7, 2007 |
Structural insulated panel construction for building structures
Abstract
A structural insulated laminated construction panel for building
structures is described. The panel comprises a rigid core material
layer of expanded polymeric material having opposed flat parallel
surfaces. An outer skin is adhesively secured to one of the flat
surfaces and an inner skin is adhesively secured to the other of
the flat surfaces. The core material layer has a density of about 2
lbs/cubic foot. The core material is preferably an expanded
polystyrene material. A building structure is constructed from such
panels used as exterior and interior wall panels, floor panels and
roof panels.
Inventors: |
Hughes; John; (Farmington
Hills, MI) ; Borazghi; Hossein; (L'lle-Bizard,
CA) ; Stanley; Don; (San Diego, CA) ;
Moellendick; Paul Jack; (Davidson, NC) |
Correspondence
Address: |
DAVID M. CARTER;CARTER SCHNEDLER & MONTEITH, P.A.
56 CENTRAL AVENUE, SUITE 101
P.O. BOX 2985
ASHVILLE
NC
28802
US
|
Family ID: |
38117343 |
Appl. No.: |
11/286307 |
Filed: |
November 22, 2005 |
Current U.S.
Class: |
52/782.1 |
Current CPC
Class: |
E04B 1/14 20130101; B32B
2262/101 20130101; B32B 27/065 20130101; B32B 2307/72 20130101;
E02D 27/01 20130101; B32B 2266/0228 20130101; E04C 2/296 20130101;
B32B 2307/3065 20130101; B32B 2307/558 20130101; B32B 2607/00
20130101; B32B 2266/08 20130101; B32B 2419/00 20130101; B32B 17/04
20130101; B32B 27/32 20130101; B32B 2307/304 20130101; B32B 5/18
20130101; B32B 7/12 20130101; B32B 2307/712 20130101 |
Class at
Publication: |
052/782.1 |
International
Class: |
E04C 2/00 20060101
E04C002/00 |
Claims
1. A structural insulated laminated construction panel for building
structures, said panel comprising a rigid core material layer of
expanded polymeric material having opposed flat parallel surfaces,
an outer skin adhesively secured to one of said flat surfaces and
an inner skin adhesively secured to the other of said flat
surfaces.
2. A structural insulated laminated construction panel as claimed
in claim 1 wherein said core material layer is a rigid sheet of
expanded polystyrene.
3. A structural insulated laminated construction panel as claimed
in claim 2 wherein said core material layer has a density of about
2 lbs/cubic foot.
4. A structural insulated laminated construction panel as claimed
in claim 2 wherein said outer skin is a glass fiber-reinforced
plastic and constituting an outer surface of said construction
panel.
5. A structural insulated laminated construction panel as claimed
in claim 2 wherein said outer and inner skins are adhesively
secured by an adhesive film bonded to said at least one of said
flat surfaces.
6. A structural insulated laminated construction panel as claimed
in claim 2 wherein said construction panel is a continuously
laminated panel forming a complete exterior wall of a building
structure and having a height of up to about 12 feet and a
thickness of from about 2 inches to 9 inches.
7. A structural insulated laminated construction panel as claimed
in claim 2 wherein said construction panel is an exterior wall
panel, said outer skin permitting the attachment of facing tiles or
siding by the use of screw fasteners, or the application of
exterior or paint, polymer concrete, said interior skin having a
fire-retardant material incorporated therein.
8. A structural insulated laminated construction panel as claimed
in claim 2 wherein said construction panel is an exterior building
panel, said outer skin being adapted to retain paint or elastomeric
roof material.
9. A structural insulated laminated construction panel as claimed
in claim 8 wherein there is further provided a conduit in said
rigid core material disposed for receiving wiring therein.
10. A structural insulated laminated construction panel as claimed
in claim 2 wherein two of said panels are interconnected together
along a straight flat connecting end edge thereof, one of said flat
connecting end edges having at least one elongated projecting
tongue element of plastics material secured therein and projecting
along said end edge, the other of said flat connecting end edge
having an elongated slot therealong and positioned to receive said
tongue therein, and a structural adhesive suitable to weld
fiber-reinforced plastics for securing said tongue into said slot
to interconnect said two connecting end edges together.
11. A structural insulated laminated construction panel as claimed
in claim 10 wherein said projecting tongue is an elongated flat
rigid plastic strip, there being two of said strips each adhesively
secured in a routed channel along opposed outer edges of said one
of said flat connecting end edges and under an end portion of said
outer and inner skins and defining a projection projecting
outwardly of said connecting end edge, there also being two of said
elongated slots disposed along opposed outer edges of said other of
said flat connecting end edge and under an end portion of said
outer and inner skins thereof for receiving a respective one of
said projections therein.
12. A structural insulated laminated construction panel as claimed
in claim 11 wherein there is further provided a bead of flexible
sealant material disposed along said connecting end edges between
said projections and slots, said sealant material, together with
said interconnection of said projection in said slots, constituting
a thermally insulated structural sealed interconnection.
13. A structural insulated laminated construction panel as claimed
in claim 2 wherein two of said panels are interconnected together
along a straight flat connecting end edge thereof, said inner and
outer skins having a projecting connecting end portion extending
beyond said flat connecting end edge, a straight rectangular tube
of fiber-reinforced plastic is dimensioned for close fit between
said flat connecting end edge of said two of said panels and having
opposed flat end walls thereof disposed flush under said projecting
connecting end portions of said two panels, and a structural
adhesive suitable to weld olefin based plastics securing said
projecting connecting end portions to respective ones of said
opposed flat end walls.
14. A structural insulated laminated construction panel as claimed
in claim 13 wherein there is further provided a bead of flexible
sealant material disposed between each of said flat connecting end
edges and opposed flat side walls of said rectangular channel, said
sealant material, together with said interconnected projecting end
portions of said skins with said channel, constituting a sealed
structural interconnection of said two panels, said tube being
adapted to receive piping or wiring therein.
15. A structural insulated laminated construction panel as claimed
in claim 2 wherein said construction panel is an exterior
rectangular wall panel, said outer skin having a projecting
connecting end portion extending beyond a lower flat edge surface
of said panel for interconnection with attachment means connected
to a sill plate of a foundation wall.
16. A structural insulated laminated construction panel as claimed
in claim 15 wherein said attachment means is comprised by an
elongated rectangular tube secured to said sill plate, said tube
having opposed top and bottom parallel flat walls and opposed
parallel flat end walls, said lower flat edge surface of said panel
resting on said top flat wall of said tube with said projecting
connecting end portion of said outer skin extending over an
exterior one of said opposed parallel end walls and secured thereto
by fastening means.
17. A structural insulated laminated construction panel as claimed
in claim 16 wherein said elongated rectangular tube is a
fiber-reinforced plastic tube, said fastening means is comprised of
structural adhesive suitable to weld olefin based plastics, and
fasteners for connecting said projecting connecting end portion to
said exterior end wall of said channel.
18. A structural insulated laminated construction panel as claimed
in claim 16 wherein floor joists are supported on said sill plate
adjacent said interior skin of said exterior rectangular wall
panel, each said joist being provided at a free end thereof with a
connecting plate for interconnecting said joist to said interior
skin and sill plate by the use of fasteners.
19. A structural insulated laminated construction panel as claimed
in claim 17 wherein said structural adhesive is a 3M
Scotch-Weld.TM. adhesive, said fasteners being screw or rivet
fasteners.
20. A structural insulated laminated construction panel as claimed
in claim 16 wherein said elongated rectangular tube is a wire or
plumbing conduit.
21. A structural insulated laminated construction panel as claimed
in claim 2 wherein said construction panel is a floor panel, a slot
routed in said rigid core material adjacent a straight end wall
thereof and immediately under said outer skin thereof, said slot
being dimensioned to receive a top flange section of a steel I-beam
therein, said floor panel resting on a bottom flange section of
said I-beam, and a structural adhesive between said top flange
section and said outer skin within said slot for interconnection
thereof.
22. A structural insulated laminated construction panel as claimed
in claim 21 wherein there is further provided elongated support
tubes secured over said bottom flange section of said I-beam, said
floor panel resting on said support blocks.
23. A structural insulated laminated construction panel as claimed
in claim 22 wherein said support tubes are hollow tubes formed of
fiber-reinforced plastic and which also serve as conduits for
wiring or plumbing.
24. A structural insulated laminated construction panel as claimed
in claim 21 wherein at least one free end of said I-beam is
disposed on a sill plate of a foundation and connected thereto by
fastening means, and further connecting means to connect said fee
end to said interior skin of an outside wall constructed with one
or more of said panels.
25. A structural insulated laminated construction panel as claimed
in claim 24 wherein there is further provided a hurricane anchoring
system secured to a house support beam on which said I-beam are
secured, or directly to said I-beam to thereby anchor same.
26. A structural insulated laminated construction panel as claimed
in claim 24 wherein said further connecting means is a right-angle
metal bracket having a flange thereof connected to said inner skin
by fasteners and the other right angle flange connected to a web of
said I-beam.
27. A structural insulated laminated construction panel as claimed
in claim 2 wherein said construction panel is a floor panel, said
panel being secured to a top flange of one or more I-beams
supported thereunder, and fasteners extending through said top
flange and said inner skin of said floor panel.
28. A structural insulated laminated construction panel as claimed
in claim 2 wherein said construction panel is an exterior
rectangular wall panel, said outer and inner skins having a
projecting connecting end portion extending beyond a lower flat
edge surface of said panel for interconnection with opposed side
walls of a rectangular bottom plate of fiber-reinforced plastic
material connected to a sill plate of a foundation wall, and a
structural adhesive suitable to weld olefin plastics disposed
between said projecting connecting end portions of said inner and
outer skins and said opposed side walls.
29. A structural insulated laminated construction panel as claimed
in claim 28 wherein said rectangular bottom plate is an elongated
hollow tube, a plurality of aligned holes formed in a top and
bottom wall of said tube, said holes formed in said top wall being
larger to provide access to said holes in said bottom wall where
fasteners are disposed for securing said tube over floor sheeting
supported thereunder.
30. A structural insulated laminated construction panel as claimed
in claim 29 wherein said floor sheeting is secured over flooring
joists resting on a foundation wall and connected to said
foundation wall through a sill plate.
31. A structural insulated laminated construction panel as claimed
in claim 29 wherein said hollow tube is a conduit for receiving
wiring or piping therethrough.
32. A structural insulated laminated construction panel as claimed
in claim 29 wherein there is further provided fasteners for
securing said projecting connecting end portion of said inner and
outer skins to said opposed side walls of said hollow tube.
33. A structural insulated laminated construction panel as claimed
in claim 2 wherein said construction panel is an exterior
rectangular wall panel having connecting means at a lower edge
thereof, and a connecting means at an upper edge thereof for
receiving fasteners extending through joist hangers and floor
sheeting extensions of floor sheeting secured to floor joists
secured by said hangers to a top portion of said exterior
rectangular wall panel.
34. A structural insulated laminated construction panel as claimed
in claim 33 wherein said connecting means at said upper edge of
said wall panel is an elongated composite fiber-reinforced plastic
(FRP) channel having a flat bridge wall and opposed parallel
depending connecting arms embedded in said expanded polystyrene
core with said connecting arms disposed in slots formed immediately
behind said inner and outer skins from said upper edge and said
bridge wall resting on said upper edge of said core, and means to
secure said FRP channel to said upper edge.
35. A structural insulated laminated construction panel as claimed
in claim 34 wherein there is further provided an elongated bottom
plastic plate of rectangular cross-section secured over said floor
sheeting extensions and aligned with said exterior rectangular wall
panel for receiving a connecting means of an upper exterior wall
panel to be secured thereto and in alignment with said exterior
rectangular wall panel therebelow.
36. A structural insulated laminated construction panel as claimed
in claim 35 wherein said connecting means is a connecting channel
formed by projecting connecting end portions of said inner and
outer skins of said upper exterior wall panel extending beyond said
lower edge thereof, said plastic plate being received in said
connecting channel and secured thereto by fastening means.
37. A structural insulated laminated construction panel as claimed
in claim 36 wherein said fastening means is a structural adhesive
suitable to weld olefin based plastics and fasteners extending
through said projecting connecting end portions of said inner and
outer skins and opposed side walls of said plastics plate.
38. A structural insulated laminated construction panel as claimed
in claim 37 wherein said plastic plate is a hollow tube for
receiving wiring or piping therethrough.
39. A structural insulated laminated construction panel as claimed
in claim 38 wherein said structural adhesive is a two-part
structural strength adhesive formed with a polyurethane liquid and
an epoxy.
40. A structural insulated laminated construction panel as claimed
in claim 2 wherein said panel is provided with connecting means
secured to opposed outer edges thereof, said connecting means being
constituted by elongated composite fiber-reinforced polymer
material (FRP) channels, each channel having a flat bridge wall and
opposed parallel right-angle connecting arms, said connecting arms
being disposed in slots formed behind said inner and outer skins
from said outer edges with said bridge wall resting on said outer
edge of said core, and means to secure said FRP channels to said
outer edges, said edges constituting reinforced edges.
41. A structural insulated laminated construction panel as claimed
in claim 40 wherein said means to secure is constituted by one of
said fasteners, or a two-part structural adhesive Scotch-Weld.TM.,
or both.
42. A structural insulated laminated construction panel as claimed
in claim 40 wherein said panels are rectangular panels, some of
said panels are exterior vertical wall panels interconnected to
form a first floor area of a building and are connected at upper
ones of said reinforced edge thereof to end portions of horizontal
floor panels also having reinforced edges, said floor panels
forming on an inner side thereof a ceiling for said first floor
area and on an upper side thereof a floor for an upper floor area,
and further exterior vertical wall panels disposed over said end
portions of said floor panels in alignment with said exterior
vertical panels of said first floor area, said exterior panels and
floor panels being connected at their matting ends and end portions
by connecting plates and angles formed of fiber-reinforced
thermoplastic material and bridging said matting ends by fastening
means.
43. A structural insulated laminated construction panel as claimed
in claim 42 wherein said fastening means is constituted by
fasteners and said structural adhesive, said fasteners extending
into said opposed depending connecting arms of said FRP channels of
said panel.
44. A structural insulated laminated construction panel as claimed
in claim 40 wherein said flat bridge wall and connecting arms are
fiber-reinforced to permit the retention of fasteners to secure
component parts thereto.
45. A structural insulated laminated construction panel as claimed
in claim 40 wherein some of said panels have at least one angled
outer edge thereof.
46. A structural insulated laminated construction panel as claimed
in claim 45 wherein some of said panels are gable wall panels.
47. A structural insulated laminated construction panel as claimed
in claim 40 wherein said flat bridge wall is a beveled bridge wall
to constitute a beveled FRP channel.
48. A structural insulated laminated construction panel as claimed
in claim 47 wherein said beveled FRP channel is secured to a top
outer edge of said panel constituting an exterior wall panel to
provide interconnection with a further one of said panel
constituting and angled roof panel, and fastening means to secure
said angled roof panel to said flat beveled bridge wall.
49. A structural insulated laminated construction panel as claimed
in claim 48 wherein said fastening means is constituted by
fasteners and a structural adhesive suitable to weld olefin base
plastics.
50. A structural insulated laminated construction panel as claimed
in claim 49 wherein said structural adhesive is a two-part
structural strength adhesive formed with polyurethane liquid and
epoxy.
51. A structural insulated laminated construction panel as claimed
in claim 40 wherein said panels are vertical wall panels, some of
said vertical wall panels forming right angle corners of a building
structure, and right angle connectors for interconnecting said
vertical wall panels at said right angle corners.
52. A structural insulated laminated construction panel as claimed
in claim 51 wherein said right angle connectors are elongated
connectors formed of composite fiber-reinforced polymer
material.
53. A structural insulated laminated construction panel as claimed
in claim 52 wherein said right angle corners are formed by a
vertical protrusion column of fiber-reinforced plastics material
and of square cross-section defining opposed elongated flat walls,
a first vertical panel forming said right angle corner being
disposed in abutment with one of said opposed flat walls, and a
second of said vertical panels disposed at right angle to said
first vertical panel and in abutment with an adjacent one of said
opposed flat walls, an outer one of said right angle connectors
embracing the other two outer ones of said opposed flat walls and
having an extension edge portion extending over a longitudinal edge
portion of said outer skin of said first and second vertical
panels, fasteners interconnecting said extension edge portion to
said longitudinal edge portion of said first and second vertical
panel and extending into a connecting arm of said FRP channel, and
a structural adhesive suitable to weld olefin based plastics
interposed on an inside face of said outer one of said rigid angle
connectors, and an inner right angle connector secured to said
first and second vertical panel inner skin along an inner corner
thereof.
54. A structural insulated laminated construction panel as claimed
in claim 53 wherein said protrusion column is a hollow column, said
inner right angle connector being secured to said first and second
vertical panel by fasteners extending into connecting arms of said
FRP channel of each panel with said structural adhesive disposed on
an inside face thereof.
55. A structural insulated laminated construction panel as claimed
in claim 52 wherein said rigid angle corners are formed by abutting
an outer vertical edge of a first panel with a side end edge
portion of a second panel disposed at right angles thereof, an
outer one of said rigid angle connectors embracing an outer corner
formed by said first and second panels and extending over a
longitudinal edge portion of said outer skin of said first and
second vertical panels, fasteners interconnecting said outer right
angle connector to said first and second panels and extending into
a connecting arm of said FRP channels, and a structural adhesive
suitable to weld olefin based plastics interposed on an inside face
of said outer right angle connector, and an inner right angle
connector secured to said first and second vertical panel inner
skin along an inner corner thereof.
56. A structural insulated laminated construction panel as claimed
in claim 55 wherein said inner right angle connector is secured
along said inner corner by fasteners extending into said inner skin
and into the connecting arm of said FRP channel of said first
panel, said structural adhesive being disposed on an inside face of
said inner right angle connector.
57. A structural insulated laminated construction panel as claimed
in claim 2 wherein two of said panels are vertical rectangular wall
panels, said panels having outer straight edges, a vertical one of
said outer edges being mitered at a 45.degree. angle, said mitered
outer edges of said two panels being interconnected together in
facial contact by two elongated right angle connectors formed of
composite fiber-reinforced polymer material, connecting slots
formed in said core material in said outer mitered edges
immediately behind said inner and outer skins, said elongated right
angle connectors forming two right angle flanges received in
respective ones of adjacent slots when said mitered outer edges are
placed in said facial contact, and a structural adhesive suitable
to weld olefin based plastics interposed in said slots to connect
said right angle connector therein.
58. A structural insulated laminated construction panel as claimed
in claim 57 wherein there is further provided fasteners disposed in
said inner and outer skin adjacent said connector flanges and
engaged in said flanges.
59. A structural insulated laminated construction panel as claimed
in claim 20 wherein an opening is formed in said panel, a composite
fiber-reinforced polymer material (FRP) channel disposed about said
opening, said FRP channel having a flat bridge wall and opposed
parallel right angle connecting arms, said bridge wall extending
the full width of said panel and said connecting arm overlapping
said inner and outer skins about said opening, and fastening means
to secure said FRP channel in said opening.
60. A structural insulated laminated construction panel as claimed
in claim 59 wherein said fastening means is constituted by
fasteners disposed in said connecting arms and a structural
adhesive suitable to weld olefin based plastics disposed behind
said connecting arms.
61. A structural insulated laminated construction panel as claimed
in claim 60 wherein said structural adhesive is a two-part
structural strength adhesive formed with polyurethane liquid and
epoxy.
62. A structural insulated laminated construction panel as claimed
in claim 60 wherein said opening is a window opening.
63. A structural insulated laminated construction panel as claimed
in claim 60 wherein said opening is a rectangular door opening or
window opening and wherein a thermoplastic header is embedded in
said wall panel adjacent a top edge of said opening, and one or
more composite fiber-reinforced plastic studs embedded into said
panel along opposed side edges of said opening, said header being
connected to an upper end of said reinforced studs.
64. A structural insulated laminated construction panel as claimed
in claim 60 wherein said panel is further provided with an
elongated composite fiber-reinforced polymer material (FRP) channel
secured along a top and bottom edge thereof, each channel having a
flat bridge wall and opposed right-angle connecting arms, said
connecting arms being disposed in slots formed behind said inner
and outer skins from said outer edges with said bridge wall resting
on said outer edge of said core, and said structural adhesive
securing said connecting arms in said slots.
65. A building structure comprising a plurality of structural
insulated laminated panels interconnecting together, each said
panels having a rigid core material layer of expanded polystyrene
having opposed flat parallel surfaces, an outer skin and an inner
skin adhesively laminated to a respective one of said surfaces,
said panels having connecting means secured to at least one of
outer edges thereof and constituted by an elongated composite
fiber-reinforced polymer material (FRP) channel to provide
connection to said panel.
66. A building structure as claimed in claim 65 wherein said FRP
channel has a flat bridge wall and opposed parallel right-angle
connecting arms, said connecting arms being disposed in slots
formed behind said inner and outer skins from said outer edge with
said bridge wall resting on said outer edge of said core, and a
structural adhesive suitable to weld olefin based plastics disposed
in said slots, said at least one outer edge being a reinforced
edge.
67. A building structure as claimed in claim 65 wherein said core
material layer is a two inch thick material having a density of
about 2 lbs/cubic foot.
68. A building structure as claimed in claim 65 wherein said outer
skin is a continuous sheet of fiber-reinforeced plastic and
constituting an outer surface of said construction panel.
69. A building structure as claimed in claim 65 wherein said outer
and inner skins are adhesively secured by an adhesive film bonded
to said at least one of said flat surfaces.
70. A building structure as claimed in claim 65 wherein said
construction panel is a continuously laminated panel forming a
complete exterior wall of a building structure and having a height
of up to about 12 feet and a thickness of from about 2 inches to 9
inches.
71. A building structure as claimed in claim 69 wherein said inner
skin is adhesively secured by an adhesive film-bonded to said at
least one of said flat surfaces.
72. A building structure as claimed in claim 71 wherein said outer
and inner skin are adhesively secured by controlled heat lamination
with said core material layer.
73. A building structure as claimed in claim 71 wherein said inner
skin comprises a fire-retardant material skin.
74. A building structure as claimed in claim 65 wherein said
plurality of panels comprise vertical exterior wall panels, floor
panels and roof panels interconnected together through said
connecting means, said exterior wall panels being immovably secured
by attachment means to a sill plate of a foundation wall, said
foundation wall supporting floor joists connected to said
attachment means, said floor joists being secured to one or more
building support means, and a seismic anchor device secured to said
one or more support means and anchored in a bearing soil.
75. A building structure as claimed in claim 74 wherein said
seismic anchor device comprises a support base, a vertical cylinder
secured to said base, an adjustable post adjustably connected with
said vertical cylinder, a connecting member at a free top end of
said adjustable post for connection to said one or more support
beams, an anchor rod having anchoring means for anchoring in said
bearing soil and connected at a fee end thereof to a heavy-duty
spring secured to said vertical cylinder.
Description
TECHNICAL FIELD
[0001] The present invention relates to a structural insulated
laminated construction panel for the construction of building
structures.
BACKGROUND ART
[0002] Building structures have been known for many years and
wherein they are constructed using prefabricated panels which are
assembled and interconnected on site to construct a building, such
as a residential or commercial building. Some building structures
utilizing panels have several disadvantages in that most of these
panels are constructed with conventional building materials
fabricated from wood or metal and this results in panels which are
heavy and difficult to manipulate and therefore heavy machinery is
required for the manipulation and installation thereof. Although
such panels may be of high strength, they have further
disadvantages in that they are not waterproof or mold-proof, they
do not provide adequate insulation and are not very resistant to
hurricane force winds. They are also expensive to fabricate and the
erection thereof is relatively slow due to the fact that these
panels are of a small size and are labour intensive to install.
Concrete panels also have the same disadvantages and are expensive
to transport. Therefore, there exists a need to provide
construction panels which overcome these disadvantages.
[0003] Reference is made to U.S. patent application Ser. No.
11/006,707, which was filed on Dec. 8, 2004, in the name of Hossein
Borazghi, one of the co-inventors of this application, and entitled
"Process and machine for producing lightweight thermoplastic
composite products in a continuous manner". The process and machine
as disclosed in that patent now makes it possible to produce
lightweight thermoplastic composite panels in a continuous manner
and in widths heretofore not possible. Traditionnally, these
composite materials have been produced in molds and ovens of large
dimension. Accordingly, this innovation has made it possible to
manufacture panels having ideal characteristics for the
construction of building structures and wherein such panels could
be manufactured economically in any desired length and widths of up
to about 12 feet.
SUMMARY OF INVENTION
[0004] It is therefore a feature of the present invention to
provide a structural insulated laminated construction panel for the
construction of building structures which overcome the problems of
the prior art as mentioned hereinabove.
[0005] Another feature of the present invention is to provide a
structural insulated laminated construction panel for building
structures and wherein the panels are of a high strength,
water-proof, mold-proof, highly insulated, lightweight, easy to
assemble, high resistant to wind force, high impact resistant and
which may be used for the construction of permanent residential
structures or emergency structures wherein structures can be
erected quickly and at low cost.
[0006] According to the above features, from a broad aspect, the
present invention provides a structural insulated laminated
construction panel for building structures and wherein the panel
comprises a rigid core material layer of expanded polymeric
material having opposed flat parallel surfaces. An outer skin is
adhesively secured to one of the flat surfaces and an inner skin is
adhesively secured to the other of the flat surfaces.
[0007] In another broad aspect of the preset invention, the
structural insulated laminated construction panel is provided with
connection means secured to at least one of the outer edges thereof
and formed by an elongated composite fiber-reinforced polymer
material channel to provide connection to the panel.
[0008] According to a still further broad aspect of the present
invention these panels may be constructed of any desired length and
of a width of up to 12 feet and a thickness of from about 2 inches
to 9 inches.
[0009] According to a still further broad aspect of the present
invention the core material is expanded polystyrene and the density
of the core material is of about 2 lbs/cubic foot for a two inch
thick core.
BRIEF DESCRIPTION OF DRAWINGS
[0010] A preferred embodiment of the present invention will now be
described with reference to the accompanying drawings in which:
[0011] FIG. 1 is a cross-section view of a structural insulated
laminated construction panel of the present invention;
[0012] FIG. 2 is an exploded view, partly fragmented, showing the
lamination of the structural panel;
[0013] FIG. 3 is an exploded view of a fragmented portion of the
panel showing an electrical conduit or chase formed in the core of
the panel;
[0014] FIG. 4 is a perspective view showing an in-line panel
connection where opposed side edges of two panels are
interconnected together;
[0015] FIG. 5 is a simplified section view showing two panels
interconnected by the method of FIG. 4;
[0016] FIG. 6 is a perspective view showing another embodiment of
how two panels are interconnected together with a straight
rectangular channel interposed in the interconnection joint for use
as an electrical or plumbing conduit;
[0017] FIG. 7 is a simplified section view showing the
interconnection of FIG. 6;
[0018] FIG. 8 is a fragmented side view showing a panel of the
present invention used as an exterior wall panel secured to a
foundation sill and wherein the panel has a rectangular channel
secured to a lower edge thereof;
[0019] FIG. 9 shows the construction panel used as a floor panel
and wherein two panels are shown interconnected to a steel
I-beam;
[0020] FIG. 10 is a side view showing a floor panel of the present
invention supported over a steel I-beam and secured thereto;
[0021] FIG. 11 is a fragmented side view showing the construction
panel of the present invention used as a floor panel and also as an
exterior wall panel and both interconnected to a foundation sill
plate;
[0022] FIG. 12 is a fragmented side view showing an exterior wall
panel constructed in accordance with the present invention and
connected on top of a floor attached to joists and interconnected
to the sill plate through the floor and joists;
[0023] FIG. 13 is a fragmented perspective view illustrating how
the plastics rectangular channel is connected to a floor
surface;
[0024] FIG. 14 is a fragmented cross-section view illustrating the
attachment of the rectangular channel to the floor surface;
[0025] FIG. 15 is a fragmented section view showing the
construction panel of the present invention used as an upper
exterior wall panel and connected on top of a lower exterior
construction panel through a channel and an extension of a floor
board of a second floor;
[0026] FIG. 16 is a perspective view of a joist hanger of a type
well known in the prior art and utilized in the assembly of FIG.
15;
[0027] FIG. 17 is an enlarged cross-section view showing the
interconnection of the two exterior vertical wall panels as
illustrated in FIG. 15;
[0028] FIG. 18 is a fragmented section view showing two exterior
vertical wall panels with a first floor joist structure
therebetween and wherein these are interconnected together by
composite fiber-reinforced polymer channels embedded in the end
edges of the panels and an outer fiber-reinforced thermoplastic
connection plate and inner right angle connectors;
[0029] FIG. 19 is a fragmented section view showing two exterior
construction panels of the present invention connected to a
conventional floor joist structure of a first floor;
[0030] FIG. 20 is a fragmented perspective view showing a gable
wall constructed with the construction panel of the present
invention and with the composite fiber-reinforced polymer channels
being used as a cap for the gable wall and a support for flooring
and ceiling sheeting material;
[0031] FIG. 21 is a fragmented section view showing the
construction panels of the present invention being used as roof
panels and exterior wall panels having a bevel composite
fiber-reinforced polymer channel in a top edge thereof to support
and attach the roof panel thereto;
[0032] FIG. 22 is a fragmented perspective view showing roof panels
constructed in accordance with the present invention and secured to
the exterior wall of FIG. 21 and to a gable end wall;
[0033] FIG. 23 is a top cross-section view, partly fragmented,
showing a first embodiment of a corner connection using reinforced
angle connectors and an embedded hollow column of plastics or
composite materials;
[0034] FIG. 24 is a view similar to FIG. 23 but showing two
exterior vertical wall panels interconnected together at a corner
in an overlap configuration;
[0035] FIG. 25 is a view similar to FIGS. 23 and 24 but showing two
exterior vertical panels provided with vertical mitered end edges
and embedded reinforced angle connectors which are not visible form
outside or inside the building structure when the panels are
connected together at their mitered edges;
[0036] FIG. 26 is a fragmented perspective view showing a window
opening formed in a vertical wall panel with a composite
fiber-reinforced polymer material channel secured about the
opening;
[0037] FIG. 27 is a fragmented perspective view showing a vertical
wall panel constructed in accordance with the present invention and
wherein the opening is reinforced by a thermoplastic header and
reinforced thermoplastic studs on either side of the opening and
wherein a composite fiber-reinforced polymer material channel is
secured about the opening in a manner similar to FIG. 26; and
[0038] FIG. 28 is a side view, partly fragmented, illustrating the
construction of a seismic anchor device capable of being attached
to a support beam to which are connected the floor panels, wall and
roof panels through the various connectors whereby to construct a
panelled building structure which is substantially hurricane and
earthquake proof.
DESCRIPTION OF PREFERRED EMBODIMENTS
[0039] Referring now to the drawings and more particularly to FIGS.
1 to 3, there is shown generally at 10 a structural laminated
construction panel for building structures and constructed in
accordance with the present invention. The panel comprises a rigid
core 11 of expanded polymeric material, and preferably, but not
exclusively, a fire resistant expanded polystyrene and which
defines opposed flat parallel surfaces 12 and 12'. A core 11 of one
inch thickness has a density of about 2 lbs/cubic foot and
excellent insulating properties.
[0040] A continuous outer skin 13 is secured to the outer surface
12 by an adhesive film 14 bonded to the outer surface 12 under
controlled heat conditions with the apparatus as disclosed in the
aforementioned pending U.S. patent application. The outer skin 13
is a reinforced thermoplastic composite glass fiber sheet and this
provides for the attachment of surfacing tiles, concrete polymer,
exterior paint and siding by the use of screw fasteners. A
paint-ready veil 17 may be applied to the outer skin 13, as shown
in FIG. 2, to accept paint or elastomeric roofing material if the
panel is being utilized as a roof panel or wall panel.
[0041] An inner skin 15 is bonded to the inner surface 12' by an
adhesive film sheet 16 or other binder means. The inner skin
preferably has a fire-rated material added to it.
[0042] An electrical conduit or chase 18 is hereinshown can be cut
out of the core material 11, as shown in FIG. 3, to provide for
wiring or plumbing in such panels, being vertical wall panels or
floor panels. These conduits would be provided at a specific
location whereby they may be accessible from the outer surface of
the panels by simply drilling a hole, such as hole 19, therethrough
to provide for the connection of electrical outlets or plumbing
outlets. However, in most instances, the plumbing piping would be
run in conventional interior walls of the building structure. It is
also conceivable that additional inner and outer skins could be
laminated to provide different effects or for attaching different
types of facing materials or finished coatings thereto.
[0043] The construction panel 10 of the present invention is
laminated in a continuous process and accordingly can have any
length. Also, the width of the panel can vary up to 12 feet and the
thickness of the core material can be in the range of from about 2
inches to 9 inches. By simple adjustment to the laminating machine
as described in the aforementioned patent application, the machine
can be easily adapted to construct panels of different sizes and in
very short periods of time.
[0044] Referring now to FIGS. 4 and 5, there are shown two
construction panels 10 and 10' constructed in accordance with the
present invention and interconnected together along opposed
straight flat connecting end edges 20 and 20' respectively. One of
the panels, herein panel 10, is provided with an elongated
projecting tongue element 21, of fiber-reinforced FRP plastics or
other suitable similar material, secured in an elongated slot 22
cut in the core material by a hot knife or other tool, and
immediately behind the outer and inner skins 13 and 15 and retained
therein by a structural adhesive suitable to weld fiber-reinforced
plastics to fuse the tongue element 21 with the inner and outer
skins. The elongated projecting tongue 21 projects outwardly of the
end edge 20.
[0045] As hereinshown the other end edge 20' is also provided with
slots 22' formed adjacent its outer skin 13' and inner skin 15' and
these slots 22' receive the extension portion 21' of the tongues
21. A similar structural adhesive is disposed in the slots 22'. As
also hereinshown, the end edges 20 and 20' are provided with an
elongated slot 23 routed therein whereby to receive a bead of
flexible sealant material 24 to provide a thermally insulated
structural sealed interconnection when attached together as
illustrated in FIG. 5. As hereinshown, when the connection is made,
the tongues are not visible from the exterior wall surfaces with
the exception that a partition line will be visible between the
adjacent outer and inner skins.
[0046] Referring now to FIGS. 6 and 7, there is shown a further
interconnection of two adjacent vertical wall panels constructed in
accordance with the present invention. In this particular
embodiment, the inner and outer skins 13 and 15 of each of the
panels are laminated with a projecting connecting end portion 30
and 30', respectively, of both of these panels 10 and 10' and
extending beyond the flat connecting end edges 20 and 20' thereof,
respectively. A straight rectangular fiber-reinforced plastic tube
31 is dimensioned for close fit between the flat connecting end
edges 20 and 20' of these two panels and is provided with opposed
flat end walls 32 which are disposed flush under the projecting
connecting end portions 30 and 30' and in abutment with the flat
connecting end edges 20 and 20', as illustrated in FIG. 7. A
structural adhesive as above-described is used for securing the
projecting connecting end portions to respective ones of the
opposed flat end walls 33 of the tube 31 and this adhesive is
designated by reference numeral 34 wherein two beads thereof are
disposed longitudinally over these end walls 33.
[0047] The adhesive 34 is a two-part adhesive consisting of a
polyurethane liquid and/or an epoxy and is fabricated by the 3M
Corporation under the trade mark Scotch-Weld.TM.. It is an adhesive
that can bond many low surface energy plastics including many
grades of polypropylene, polyethylene and TPOs without special
surface preparation. It also sets at room temperature. The tube 31
thus forms part of the wall structure and can be used as an
electrical and/or plumbing conduit in which is disposed piping 36
or wires 35, as shown in FIG. 7. The tube 31 also provides load
bearing quality to the panel for concentrated loads from above. It
is also pointed out that the cavities formed under the projecting
end portions of the inner and outer skins may be formed by simply
routing out the core material a depth which is approximately half
the width of the channel 33 and therefore the extensions 30 and 30'
need not be formed during lamination of the panel. The flexible
sealant 24 can also be applied directly on the flat connecting end
edges 20 and 20' of the two panels 10 and 10' to provide a good
thermal seal therebetween.
[0048] Referring now to FIG. 8, there is shown a conventional floor
system bearing directly on a sill plate 40 secured to a foundation
wall 41 projecting from a ground surface 42. This drawing
illustrates an exterior wall panel 10 constructed in accordance
with the present invention connected to the sill plate 40 and
providing continuity of insulation and seal around the perimeter of
a building structure supported on the foundation wall. As
hereinshown, the rectangular exterior wall panel 10 is routed along
its bottom flat edge surface whereby the outer skin 13 projects
along a lower edge 13' thereof and extends over a side wall 43 of
an elongated rectangular tube 44 constructed of fiber-reinforced
plastics FRP material and secured to the sill plate 40 by a bolt 45
or other suitable fastener anchored in the concrete foundation. The
elongated rectangular tube 44 has opposed top and bottom parallel
flat walls 46 and 46' and opposed parallel end walls 47 and 47'.
The lower flat edge surface of the panel 10 rests on the flat top
wall 46 of the tube 44 with the projecting connecting end portion
13' of the outer skin extending over the exterior end wall 47 of
the tube and secured thereto by a fastening means which includes
fasteners such as screw or rivet fasteners 49 and structural
adhesive disposed over the top wall 46 and opposed outer end wall
47 of the tube member. This adhesive is disposed thereon prior to
setting the panel over the tube after the tube is secured to the
sill plate by the fastener 45. This structural adhesive is of the
type as described hereinabove which is suitable to weld
olefin-based plastics.
[0049] As also shown in FIG. 8, floor joists 50 are supported on
the sill plate 40 and about the inner surface or inner skin 15 of
the vertical wall panel 10. Each of the joists 50 are provided at a
free end 51 thereof with a connecting plate 52 of a type well known
in the art and by the use of fasteners 53 the joists 50 are
connected to the vertical structural panel 10 and to the sill plate
40. Accordingly, it can be seen that the vertical wall panel 10 is
rigidly anchored to the sill plate 40 and into the foundation and
as well to the floor joists 50. A floor covering 54, such as
plywood sheeting, is secured over the floor joist and adapted to
receive thereover a finishing floor material such as hardwood,
carpeting, tiles, etc.
[0050] Referring now to FIG. 9, there is shown the structural
insulated and laminated construction panel 10 of the present
invention as used as a floor panel 10''. There are shown herein two
of these floor panels 10'' secured to an I-beam 55. To secure the
panels 10'' to the I-beam, a slot 56 is routed in the rigid core
material 11 of these two floor panels adjacent the end walls 20 and
20' thereof and immediately under the outer skin 13 of the floor
panels. These slots 56 are dimensioned to receive a top flange
section 57 of the steel I-beam 55 which herein constitutes a
support beam. Each of the floor panels 10'' rests on the bottom
flange 58 of the I-beam through support blocks 59. There is
hereinshown a support block 59 secured to each side of the web 60
of the I-beam and they rest on the flange sections of the flange 58
and connected thereto by a transverse connector 61. These support
blocks are hereinshown as elongated hollow fiber-reinforced plastic
tubes 59 of rectangular cross section and also serving as conduits
for wiring and/or plumbing.
[0051] As shown in FIG. 11, one free end of the I-beam 55 has its
bottom flange 58 resting on the sill plate 40 and secured thereto
by a fastener 62 extending through the flange 58. An angled plate
63 is also secured to the web 60 of the I-beam and has its right
angle flange 63' connected to the inner skin 15 of the outer
vertical wall panel 10 by fastener 64. A seismic or hurricane
anchoring system may also be secured to the I-beam as will be
described later.
[0052] The wooden floor joist structure as shown in FIG. 8 is
usually spaced at the standard 24 inch maximum spacing whereas with
the I-beams the spacing therebetween can extend up to 4 feet. Under
the floor joist and the foundation wall there may be provided a
full basement or a crawl space and this is obvious to a person
skilled in the art. It is also pointed out that the structural
adhesive as above referred to is also inserted in the slots 56
which connect to the top flange of the I-beam to secure them in the
slots and this welds the two materials together. The size of the
I-beam 55 is selected depending on the span and the load conditions
required for 4 feet maximum spacing between these types of support
beams.
[0053] Referring now to FIG. 10 there is shown another example of
how a floor panel 10'' may be connected to the I-beam 55. As
hereinshown, the I-beam is simply secured to the panel through its
inner skin 15 by fasteners 65. Again, a structural adhesive may be
disposed over the top face of the top flange 57 of the I-beam.
[0054] Referring now to FIG. 12, there is shown another embodiment
of an exterior wall configuration where the floor joist 50 rests
directly and over the sill plate 40 of the foundation wall 41. The
outer wall construction panel 10 is constructed as previously
described with reference to FIG. 8 and an elongated rectangular
hollow fiber-reinforced plastic tube 44 is connected along the
lower edge surface 48 thereof. As hereinshown this tube 44 is
secured directly on the outer sheeting 54 of a plywood floor sheet
secured over the floor joist 50 and extending to the outer end of
the floor joist and the outer rim board 67. An insulation 68 is
disposed over the back face of this rim board and between the
joists as is conventional in building construction.
[0055] As shown in FIGS. 13 and 14, this elongated fiber-reinforced
plastic tube 44 is provided with a plurality of aligned holes 69
and 70 formed in the top and bottom walls 46 and 46' thereof. The
hole 69 in the top wall is larger to provide access to the holes 46
in the bottom wall where fasteners are disposed, such as the
fasteners 71 as shown in FIG. 14. Accordingly, these fasteners 71
do not interfere with piping or wiring that may be disposed within
these hollow tubes 44.
[0056] Referring now to FIGS. 15 to 17, there is shown an example
for the construction of a two-storey building wherein there are two
exterior wall panels 10 and 10''' disposed in alignment one on top
of the other and interconnected together. The lower vertical
exterior wall panel 10 is herein provided along a top edge 75
thereof with an elongated composite fiber-reinforced polymer (FRP)
channel 76. This channel is laminated by polypropylene and
fiberglass fibers co-mingled together and formed by the process and
machine described in the aforementioned U.S. application by forming
rolls whereby to form a channel which has a flat bridge wall 77 and
opposed parallel depending connecting arms 78 as clearly
illustrated in FIG. 17. The top edge 75 of the lower wall panel 10
is routed to form a cavity therein to receive this FRP reinforcing
channel therein. This channel is again secured along the top edge
of the lower panel by the structural adhesive as previously
described. Fasteners 79, such as screws or rivets, may also be
inserted along the projecting edges of the outer and inner skins 13
and 15, as hereinshown.
[0057] The floor sheeting 54, secured to the joists 50, extends
over the top edge 75 of the lower panel 10 and over the flanges 81
of the hanger connector 80 illustrated in FIG. 16 and used to
support the joist 50 and forms a floor sheeting connecting
extension 82. Before the upper wall panels 10''' are secured over
the bottom exterior wall panels 10, the flooring 54 is completed to
the outer edge of the bottom panel to form this connecting
extension portion. The connecting extension portion 82 is secured
to the bridge wall 77 by adhesive and further fasteners 83
extending into the reinforced top edge of the lower panel 10.
[0058] The top outer vertical walls 10''' forming a second floor,
can now be installed. To do this installation it is first necessary
to secure the elongated rectangular fiber-reinforced plastic tubes
44 over the connecting extension floor portion 82 by means of the
fasteners 71 as previously described. The routed lower edge of the
top panel 10''' is then positioned over the channel and secured
thereto by the fasteners 49 and the structural adhesive as
previously described.
[0059] Referring now to FIG. 18, there is shown the construction
panel of the present invention used as a floor panel 90 interposed
between two vertical outer wall panels constructed in accordance
with the present invention. All of these panels are provided with
an elongated composite fiber-reinforced polymer channel 76 as
previously described and these are shown at 76 and 76' for the
vertical wall panels 10 and 10''', respectively, and at 76'' for
the horizontal floor panel 90. Such a panel arrangement provides
good insulation and sound barrier at the intersection of the walls
and floor panels. The thickness of the floor panel 90 and the size
of the embedded FRP channels is relative to the molding conditions
and the span of the floor panel 90. The floor panel 90 forms a
ceiling 91 on a lower side thereof for a first floor area 92 and
forms a floor support surface 93 on the top side thereof for a
second floor area 94. The skins applied to these panels suit the
condition of their use wherein the lower surface 91 would most
likely be applied a paint and the upper surface will be applied a
floor covering.
[0060] A fiber-reinforced plastic elongated connecting plate 95 is
disposed exteriorly of the exterior walls 10 and 10''' and the
outer edge of the floor panel 90 and spans this outer edge area, as
hereinshown. This fiber-reinforced plastic plate 95 is secured to
the FRP channels by fasteners 96 and structural adhesive of the
type as previously described. On the inside of the building
structure elongated angle brackets 97 are secured between the floor
panel and the vertical walls and these are also formed of
fiber-reinforced thermoplastic material. Again, fasteners 98 and
the structural adhesive is used to effect this interconnection.
Accordingly, it can be seen that the two vertical wall panels 10
and 10''' and the horizontal floor panel 90 are rigidly and
immovably secured together.
[0061] FIG. 19 depicts a platform frame method of a conventional
floor construction comprising joists 50 resting on the upper end of
the lower outer vertical wall panel 10. As hereinshown, the lower
outer vertical wall panel 10 is provided with an FRP channel 76
embedded along its upper edge in a manner as previously described.
This FRP channel is provided to receive fasteners from the rim
board 67 and the joist 50. These fasteners are not shown herein but
are obvious to a person skilled in the art.
[0062] A batt insulation 68 is disposed behind the rim board 67 and
between the joists 50 to provide thermal insulation.
[0063] The floor joist 50 with its rim board 67 extends to the
outer face of the lower vertical wall panel 10 and a
fiber-reinforced plastic tube 44 is secured over the floor board 54
spanning the floor joist in: the same manner as previously
described with reference to FIGS. 12 and 13 whereby to connect the
upper outer vertical wall panel 10''' thereto.
[0064] FIG. 20 illustrates an exterior wall panel 100 having a
gable top end configuration as depicted by reference numeral 101.
Again, an FRP channel 76 is embedded along the upper sloped outer
edge 102 of the gable end portion 101. As also shown herein, an FRP
channel 76' may also be secured in a horizontal plane against an
interior surface 103 of the structural panel constructed in
accordance with the present invention, and herein panel 100. This
FRP channel 76' serves as a support for constructing a floor. The
channel 76' is secured by fasteners such as bolt fastener 104 and
applied through the wall panel 100. The heads 105 of these bolts
would be covered or hidden on the exterior wall 106 by the use of a
trim board. Ceiling boards such as gypboards 107 would then be
secured to the lower flange 78 by screw fasteners 108 and the upper
floor sheeting 109 would be secured to the top flange 78' of the
channel 76' also by the use of fasteners such as screw fasteners
109. Trusts, not shown could be supported therebetween.
[0065] Referring now to FIGS. 21 and 22, there are shown the panel
of the present invention being used as a roof panel 110 having a
rake and eave connection. For this application the FRP channel 76''
is provided with a bevel web 77' disposed at an angle for the slope
of the roofing panel 110. Bolt fasteners 111 would be disposed
along the top surface 112 of the roof panel and extend into the web
77' for connection thereto. Compressible washers may be used to
seal the bolts to the outer skin to make them water-tight. To seal
the outer edge of the roof panel 110 suitable capping 113 is
applied whereby to conceal the FRP channel 76 embedded therein.
Glue would be applied to the outer surface of the web 77' prior to
the installation of the panel to provide a secure bond with the
inner skin 15. The outer skin 13 would be selected depending on the
roofing material to be secured thereto.
[0066] FIG. 22 is a perspective view of a rake wall and gable wall
connection. As hereinshown the roof panel 110 is secured along the
FRP channel 76 of the gable wall 100 by the use of suitable
fasteners 114 and to the FRP channel 76 of the right-angle outer
vertical wall panel 10. Again, structural glue would be applied
over these channels before setting the roof panel 110 thereon.
[0067] FIGS. 23 and 24 show three different variations of corner
connections wherein the panels are interconnected at right angles
to one another to form a corner of a building structure. As shown
in FIG. 23, the exterior wall panels 10 are provided with FRP
channels 76 embedded in their vertical outer edges thereof and a
vertical column 115 constructed of fiber-reinforced plastics
material is disposed in contact with the outer edges of the two
panels 10 adjacent respective side walls 116 thereof. As
hereinshown the column is a hollow column whereby to provide a
conduit for piping or wiring. It could also receive insulation
therein or anchors and concrete. Structural adhesive may also be
provided between the column and the vertical edges of the
panels.
[0068] To interconnect this corner column structure together, there
is provided a large outer right angle connector 117 formed of FRP
material and interconnected to some of the walls 116 of the column
115 and extending there beyond to connect to the right angle
connecting arms or flanges 78 of the channel 76 by the use of
fasteners 118. Again a structural adhesive is interposed on the
inside of this exterior bracket. On the inside of the right angle
corner panel structure a small elongated right angle bracket 97, as
previously described, is connected to the panels and the right
angle connecting arms 78 of the channel 76 in a manner as
previously described.
[0069] FIG. 24 shows an arrangement wherein the end edge of an
outer vertical panel 10 is disposed in abutment against a side edge
of the other right angle panel 10. These panels are interconnected
using the same right angle connectors 117 and 97 as described with
reference to FIG. 23 and secured in the same manner. As hereinshwon
one of the panels may also be routed at an end portion thereof
whereby to provide a skin extension 13'' which can extend over the
FRP channel 76 of the other panel and interconnected thereto by
glue and the fasteners 118.
[0070] Referring now to FIG. 25, there is shown another corner
connection wherein the panels 10 have a mitered end edge 120 and
120', respectively. These miters extend at a 45.degree. angle
whereby when abutted with one another form a right angle corner. In
this particular embodiment the panels are interconnected together
in facial contact by two elongated right angle FRP internal
connectors 121 and 121' disposed in connecting slots 122 formed
behind the inner and outer skins 13 and 15 in a manner as
previously described and secured therein by the use of the
structural glue. Structural glue is also applied along the mating
mitered faces 120 and 120'. Accordingly, these connectors are
concealed and cannot be seen from the exterior or interior of the
building structure. Suitable fasteners 123 are used to further
secure these panels together as shown.
[0071] Referring now to FIGS. 26 and 27, there is shown vertical
wall panels 10 in which window openings 125 are cut therein. An FRP
channel 126 is secured within the opening and the bridge walls 78
thereof are secured to the outer and inner skins of the panel by
the structural adhesive and fasteners 127 in a manner as previously
described. The bridge wall 77 spans the entire width of the panel
10. As hereinshown, the opening forms a window opening and a window
frame is then installed within the FRP channel frame 126 by using
conventional fasteners and insulation material. These panels are
manufactured with these FRP channels installed and therefore a
building structure can be erected very quickly by simply connecting
the panels together and then installing the windows into these
prepared openings.
[0072] FIG. 27 shows a window or a door opening 128 which is
reinforced with a thermoplastic header 129 and one or more
composite fiber-reinforced studs 130 embedded into the panel 10
along opposed side edges of the opening 128. The header 129 is
secured to an upper end of these reinforced studs 130. As
hereinshown, the panel 10 is also provided with FRP channels 76
along the top edge and bottom edge thereof to provide
interconnection with other panels or building materials.
[0073] Referring to FIG. 28, there is shown the construction of a
seismic anchor device 135 which may be secured to one or more
support beams 136 to anchor them into a bearing soil 137. This
seismic anchor device comprises a support base 138 with a vertical
cylinder 139 being secured thereto. An adjustable post 140 is
threadably connected to the vertical cylinder 139 and provides
adjustability. A connecting flange 141 is secured to the top end of
the adjustable post 140 for connection to one or more support beams
136. An anchor rod 142 which is provided with a helical screw vane
143 is driven into the bearing soil at a predetermined depth to
provide a secure anchor. Other form of anchoring means may be
provided such as for anchoring in rock, or other soil compositions.
A heavy-duty spring 144 is connected at a free end 145 of the rod
142 to provide a damping effect should there be an earthquake or
should the building structure be subjected to hurricane forces. It
is pointed out that all of the panels with their interconnections
as described above are indirectly connected to the support beam or
beams 136 and an entire building structure would be anchored by the
use of one or more of these seismic anchors 135.
[0074] It is within the ambit of the present invention to cover any
obvious modifications of the preferred embodiment as described
herein and relating to the structural insulated and laminated
construction panel 10 of the present invention provided these
modifications fall within the scope of the appended claims. For
example, various types of skins may be laminated on opposed sides
of the core and these building panels can be constructed of
different lengths and shapes depending on the architectural design
of a building to be constructed thereby. The FRP channels can also
vary in sizes depending on panel widths and lengths and thickness,
may be provided with openings formed therein. The core material can
also be fitted with various inserts before lamination provided
these inserts can withstand the temperature of the laminating
machine. Also, one can appreciate that because of the light weight
of these panels an entire building structure can be erected with
minimal labour cost and because of the ease of interconnecting
these panels, it is not necessary to have high-skilled labour to
construct a building structure. A single panel can form a complete
exterior wall of a building structure. Also, such structures can be
erected in very short time periods and are therefore suitable for
the construction of temporary shelters and low-cost housing. The
strength of these panels as well as their water-proof and
mold-proof and good insulation make it attractive for the
construction of building structures, either residential or
commercial in hot climate areas and areas subjected to high winds
and hurricanes. These panels are also resistant to high-impact
forces such as flying building material and are relatively
puncture-proof against such materials when projected thereagainst.
It is also foreseeable that these panels can be used for the
construction of foundations and basement floors.
* * * * *