CA2436989A1 - 3-d construction modules - Google Patents

Abstract

A 3D construction module comprising at least one vertically upstanding panel with first and second mesh layers oriented generally transversely and longitudinally. The first and second mesh layers have at least one rod member mounted to said panel and are vertically spaced from each other. The rod members form a first horizontally projected retention cell to restrict translation of a bar held in said retention cell between said first and second mesh layers. A
third mesh can also be provided to form a second retention cell between said second and third mesh layers. The first and second retention cells restrict translation movement longitudinally and transversely of a vertical reinforcement member held in said first and second retention cells, and restrict rotation of the vertical reinforcement member about both a longitudinal axis and a transverse axis of the said 3D construction module. Horizontal reinforcement meshes are features of the invention. Other features of the invention include a trough for holding melted panel material, connectors for connecting rods to panels and associated stopper members. Also included are bracers for joining connectors and other devices related to panel connections.

Description

Field of the Invention [001) The present invention relates to the field of construction, and in particular to the construction of poured-in-place reinforced concrete walls and other structural elements, and to their construction with 3D form modules. These modules can be prefabricated both prior to transportation to a construction site and directly on the construction site prior to installation into the design position. .
io Background (002) At the present time, the most advanced method of making reinforced concrete walls and similar structural elements, uses 3D prefabricated construction modules comprising parallel panels spaced from each other. The modules also include transverse elements in the form of grids or meshes preferably horizontally oriented is and fixed to the panels; and include connectors joining transverse elements and panels. The transverse elements usually have stopping details, which usually serve as support for panels. These 3D prefabricated construction modules can be made at a location remote from the construction site or directly on the site where they are eventually installed in the location desired for the building of wall or other structural 2o elements.

(003] The 3D prefabricated construction modules can be longitudinally and vertically interconnected to provide a continuous form in the space between a series of interconnected pairs of panels. This form space can be filled with unhardened 2s concrete then allowed to harden to produce a structural element such as a wall.
Typically the panels remain in place after the concrete has hardened and the panels provide added qualities for the structure as a whole, including providing sound and heat insulation. The panels may themselves thereafter be covered on their outward facing surfaces with a protective covering layer such as drywall, cement board, 30 plaster, stucco and so on.

[004] It is common for the panels to be made of lightweight materials such as foamed plastics (eg. foamed polystyrene).

[005] There are numerous criteria to be concerned about in the design of such prefabricated construction modules. For example; the 3D prefabricated module usually must be able to support appropriate reinforcement members (eg. rebar), including usually both horizontal and vertical reinforcement members. To date, most of the known designs for reinforcement support are complex and costly to io implement.
[006j Also, it should be noted, that there is a high consumption of labor when connecting 3D prefabricated construction modules and reinforcement member (ie.
rebar) extensions from concrete structures beneath the modules, such as is foundations, in order to provide continuous reinforcement. In most of the building systems using 3D prefabricated construction modules, installation is performed in a way akin to a "shish kebob" rodding.
[007] Another design criterion for such 3D prefabricated modules is the requirement 20 of both panels and the stabilizing or bracing members, to be able to withstand the relatively high hydrostatic pressures that can develop when the form is filled with unhardened concrete. Additionally, it is desirable to minimize the extent of the thermal bridge that can be created between one side of the 3D prefabricated construction module and the other, or between the inner form space and the external 2s side of the 3D prefabricated construction module by such components as the stabilizing members. Furthermore, the technique of concrete placement itself and its further hardening allows the creation of a 3D pattern on the surface of the concreted structures: Thus, it is also desirable to have a module with at least one panel, which would have a negative pattern. After concrete hardening the panels could easily be 3o removed leaving positive 3D pattern on the surface of the concreted structure.

[008 Other design criteria include the desirability of having modules that are relatively easy to: inter-connect to each other; secure to supporting elements such as footings; and be easily transported to a construction site. It is also desirable to have 3D prefabricated construction modules that can be readily put into operation s without a large amount of time and cost being expended.
[009] Also, a particular concern regarding fire proofing of a structural element arises when plastic materials are used as materials for the panels and are retained on the structural element after it has been created. It is well known that fire and its to associated heat can have a negative impact on structural stability of a concrete wall, and on the ability of the wall or other element to contain the fire. There is a tendency of such panels to melt when subjected to heat on one side of a wall caused by a fire in the vicinity of the wall. The liquid material from the panel then can flow toward the frre source and ignite. This can cause the fire to move along a path directly toward is the waN and can create an intense fire situation right at or in the immediate vicinity of the wall. This of course has an extremely detrimental effect, both on the structural stability of the wall, as well as its ability to contain the fire.
Accordingly, it is desirable to minimize the potential damage that can be done by the panels, when they are subjected to heat for a fire source.
Summary of the Invention (0010, In one aspect of the present invention, there is provided a 3D
construction module comprising: a) a vertically upstanding panel oriented generally longitudinally;
b) first and second mesh layers oriented generally transversely and longitudinally, 2s each of said first and second mesh layers comprising at least one rod member mounted to said panel, said first and second mesh layers being vertically spaced from each other; said at least one rod member of said first mesh layer configured to co-operate with said at least one rod member of said second mesh layer to form a first horizontally projected retention cell to restrict translation of a bar held in said 3o retention cell between said first and second mesh layers; whereby said first retention cell forms a generally vertically oriented opening for receiving a vertical reinforcement member and said retention cell restricts translation movement longitudinally and transversely of a vertical reinforcement member held in said retention cell.
[0011] In another aspect of the present invention, there is provided a panel for use in a 3D construction module, said panel comprising: a body with a thickness, said body having a pair of opposed, generally parallel and flat, longitudinal surfaces;
a plurality io of spaced openings passing through said body, said openings arranged in a first row of openings, said first row of openings being oriented at angle to said longitudinal surfaces.
(0012] Ln another aspect of the present invention, there is provided a panel for use in is a 3D construction module, said panel comprising: a body with a thickness, said body having a pair of opposed, generally parallel and flat, longitudinal surfaces;
a plurality of spaced transverse openings passing through said body, said openings arranged in a first row of openings and a second row of spaced openings, said second row of openings being vertically spaced on said body from said first set of openings and 2o generally: parallel to said first row of openings, and being longitudinally oft-set from said first row of openings.
[0013] In another aspect of the present invention, there is provided a connector to connect a panel to a rod member, said connector having a cap portion with a first 2s central longitudinal axis arid a body portion with a second longitudinal axis being displaced from said first longitudinal axis, said body portion having a cavity adapted to engage a rod member.
[0014] In another aspect of the present invention, there is provided a bracer for 3o securing two connectors together, said bracer comprising a generally C-shaped body having a medial portion and first and second spaced leg portions, each of first and second leg portions having an inner face, the inner face of said first leg portion being positioned opposite to the inner face of said second leg portion, each said inner face having a blade forming a tapping tool, wherein when a blade is in contact with a connector, and said connector is rotated, said blade forms a helical indentation in an outer surface of said connector to secure said blade on said connector.
[001.5a In another aspect of the present invention, there is provided a 3D
construction module comprising: first and second vertically upstanding, spaced apart panels oriented generally longitudinally; first and second mesh layers oriented generally transversely and longitudinally, each of said first and second mesh layer comprising io at least one rod member mounted to each of said first and second panels, said first and second mesh layers being vertically spaced from each other; said at Least one rod member of said first mesh layer configured to co-operate with said at least one rod member of said second mesh layer to form a first horizontally projected retention cell to restrict translation of a vertical reinforcement bar held in said retention cell is between said first and second mesh layers; c) a vertical reinforcement bar held in said retention cell; whereby said retention cell forms a generally vertically oriented opening for receiving said vertical reinforcement member, said retention cell restricts translation movement longitudinally and transversely of a vertical reinforcement member held in said retention cell.
(0016] In another aspect of the present invention, there is provided a 3D
construction module comprising: a) first and second vertically upstanding, spaced apart panels oriented generally longitudinally; b) first and second mesh layers oriented generally transversely and longitudinally, each of said first and second mesh layer comprising 2s at least one rod member mounted to each of said first and second panels, said first and second mesh layers being vertically spaced from each other; said at least one rod member of said first mesh layer configured to co-operate with said at least one rod member of said second mesh layer to form a first horizontally projected retention cell to restrict translation of vertical reinforcement bars held in said retention cells 3o between said first and second mesh layers; c) a first vertical reinforcement bar held, respectively, in said first retention cell; whereby said first and detention cells form first and second generally vertically oriented openings for receiving respectively, said first and second vertical reinforcement members, said first and second retention cells respectively restricting translation movement longitudinally and transversely of said first and second vertical reinforcement members held in said retention cell;
d) a horizontal reinforcement mesh comprising first and second reinforcement bars s oriented generally longitudinally, said first and second horizontal reinforcement bars being interconnected by at least one transverse connecting rod member, said horizontal reinforcement mesh being received between said first and second panels with said first and second horizontal reinforcement bars being oriented generally longitudinally and said first horizontal reinforcement bar being in abutment said first io vertical reinforcement bar so as to tend to push said first vertical reinforcement bar transversely outward toward said first panel.
[4097] In another aspect of the present invention, there is provided a combination of a panel and a trough element for use in a 3D construction module, said panel made is of a meltable panel material and comprising a body with a thickness, said body having a pair of opposed, generally parallel and flat, longitudinal surfaces and a base; a trough element affixed to said base of said panel, said trough having a reservoir of sufficient size to hold the material of said panel when said panel is subjected to sufficient heat from a heat source, to melt said panel material, said Zo panel material flowing into said reservoir when melted by said heat source.
[0018] In another aspect of the present invention, there is provided a construction combination comprising: a) a mesh comprising a first longitudinal rod member and a plurality of transverse rod members connected to said longitudinal rod member;
b) a 2s stopper member for each of said plurality of transverse rod members, each stopper member having a leg portion and a first flange portion, and an axial passageway through said leg portion and said first flange portion, said passageway for freely receiving a rod member there through, said stopper member movable axially on said rod member, said first flange portion adapted to be moved into abutment an inner 3o surtace of a panel, said leg portion adapted to be moved into abutment with said longitudinal member, whereby said flange member can co-operate with connector connecting said panel with a transverse rod to properly position said connector and can co-operate with said panel to properly position said inner surface of said panel relative to said longitudinal member..
[0019] In another aspect of the present invention, there is provided a connector to connect a panel to a rod member, said connector having a cap portion, a first body portion having an outer surface shaped as a truncated cone portion, said first body portion having its outer surface narrow towards a connection with a second body portion, said second body portion having an outer surface that is generally cylindrical, said second body portion having a inner cavity adapted to engage a rod to member.
[0020 In another aspect of the present invention, there is provided a 3D
construction module comprising: first and second mesh layers oriented generally transversely and is longitudinally, each of said first and second mesh layers comprising a plurality of transversely oriented, and spaced transverse rod members, each of said transverse rod members having an end adapted for mounting to a panel, said plurality of transverse rod members being interconnected to first and second longitudinally oriented and spaced longitudinal rod members, said first and second mesh layers 2o being vertically spaced from each other; at least one of said transverse rod members and one of said first and second longitudinal rod members of said first mesh layer configured to co-operate with at feast one of said transverse rod members and one of said first and second longitudinal rod members of said second mesh layer to form a first horizontally projected retention cell to restrict translation of a bar held in said 2s retention cell between said first and second mesh layers; whereby said first retention cell forms a generally vertically oriented opening for receiving a vertical reinforcement member and said retention cells restrict translation movement longitudinally and transversely of a vertical reinforcement member held in said retention cell.
[0021, In another aspect of the present invention, there is provided a stopper member comprising : a cylindrical body portion having a first end and a second end, io and having a first axial passageway open from said first end and said second end; a first flange member formed on said body at said first end; a second flange member formed on said body at said second end; a second body portion joined to said first body portion at said second end, said second body portion having a second axial passageway that is narrower than said first axial passageway, said second body portion having a first generally cylindrical portion adjoining said second flange member, and a truncated conical flange portion, said truncated conical flange portion and said second flange member providing a cavity therebetween for holding at least one rod member therebetween.
[0022] In another aspect of the present invention, there is provided a system for creating a concrete form comprising said first and second panels arranged such that said first and second panels are in longitudinal, upstanding and abutting alignment, said first panel unit has a leading side face and said second panel having a trailing is side face, each of said leading side face and said trailing side face being generally in abutment with each other, each of said leading side face and said trailing side face having a centrally positioned, elongated groove, and said system further comprising a separate elongated plate member, and said leading face has on one side of said groove a side flange portion, and said trailing face as an opposed side flange portion 20 opposite to said side flange portion of said leading face, and wherein when said panels are disconnected, the width of said groove is smaller than the width of said plate and' said side flange portions are angled toward each other, and wherein when said plate is inserted into said groove portions to put said first and second panel in abutting alignment, said grooves are widened, to permit said plate to be received 2s therein, and said side flanges are displaced outwards to provide face to face mating alignment of said side flanges.
[0023) In another aspect of the present invention, there is provided a method of fabricating a 3D construction module comprising: a) providing a vertically upstanding 3o panel oriented generally longitudinally; b) securing first and second mesh layers to said panel such that they are oriented generally transversely and longitudinally, each of said first and second mesh layers comprising at least one rod member mounted to said panel, and said fast and second mesh layers being arranged in vertically spaced relation to each other; c) arranging said at least one rod member of said first mesh layer and said at least one rod member of said second mesh layer to form a first horizontally projected retention cell to restrict translation of a bar held in said retention cell between said first and second mesh layers; whereby said first retention cell forms a generally vertically oriented opening for receiving a vertical reinforcement member and said retention cell restricts translation movement longitudinally and transversely of a vertical reinforcement member held in said retention cell.
io [0024~In another aspect of the present invention, there is provided a stopper member in combination with a connector: said connector having a leg portion adapted to connect to a rod member; said stopper member comprising: a body portion having a first end and a second end, and having a first axial passageway ~s open from said first end and said second end; a second body portion having a third end and a fourth end, said second body portion joined at said third end to said first body portion at said second end of said first body portion, said second body portion having a second axial passageway extending befinreen said third end and said fourth end, that ~s narrower than said first axial passageway, said second axial passageway 2o being in communication with said first axial passageway from said third end to said second end; said leg portion of said connector receivable into said first axial passageway of first body portion of said stopper at said first end to engage an end of a rod member receivable in said second axial passageway and extending from said fourth end, past said third end and said second end into said first axial cavity; said 2s connector and said stopper member adapted to hold a panel member and thereby connect said rod member to said panel member.
[0025] In another aspect of the present invention, there is provided a connector for securing a rod member to a panel, said connector having a leg portion to be received 3o through said panel to engage said rod member, said leg portion having a blind opening to a cavity for receiving said rod member therein to secure said leg portion to said rod.

[0026] In another aspect of the present invention, there is provided A method of forming a construction element such as wall comprising: a)prefabricating fast and second construction modules, each of said modules comprising a pair of spaced s apart panels oriented longitudinally, said pair of panels being interconnected by at least one mesh layer between said panels; b)installing said first and second construction modules in longitudinal alignment; c) installing vertical reinforcement in said first and second construction modules; d)installing horizontal reinforcement in said first and second construction modules; e) filling said first and second io construction modules with unhardened concrete.
Brief Description of the Drawings [0027] In Figures which illustrate by way of example only embodiments of the is invention:
[0028] Figure 1 is a schematic perspective view of an embodiment of the invention;
[0029] Figure 1 a is a horizontal projection of the mesh layers x and y of Figure 1;
[0030] Figure 1 b is a horizontal projection of alternate mesh layers x and y, in accordance with another embodiment;
[0031] Figure 1 c is a horizontal projection of alternate mesh layers x and y, in 2s accordance with another embodiment;
[0032] Figure 2A is a front elevation view of a panel in accordance with another embodiment of the invention;
[0033] Figures 2B and 2C are side elevation views at 2B and 2C respectively, in Figure 2A;

[0034] Figures 2D and 2E are cross sectional views at 2D-2D and 2E-2E
respectively in Figure 2A;
[0035] Figure 3 is a cross section view of a connection between a transverse rod of a 3D prefabricated construction module in and a connector installed into an opening of a perforated panel of Figures 2A -2E, in accordance with an embodiment of the invention;
to [0036] Figure 3A is a side view of a connector, partially cut away in section to show a blind cavity in accordance with an embodiment of the invention;
[0037] Figure 3B is an end view of the connector of Figure 3A;
is [0038] Figures 4A-4C are perspective views of three trough members that can be utilized in embodiments of the invention;
[0039] Figure 4D is a side cross sectional view of a part of a wall and floor system utilizing the trough member of Figure 4C;
[0040] Figure 5 is a perspective view of a transverse and longitudinal elements of the 3D prefabricated construction module in an embodiment of a mesh layer that can be used in a:3D prefabricated construction module in accordance with the invention;
2s [0041 ] Figure 5A is an enlarged view of the part of the mesh of Figure 5, as illustrated at 5A in Figure 5;
[0042] Figure 5B is a plan view of a detail to produce a transverse component used to make the mesh of Figure 5;
[0043] Figure 5C is a plan view of the component made from the detail of Figure 5B, having been modified for use in the mesh of Figure 5;

[0044] Figure 5D is a plan view of a stopper component, part of the mesh of Figure 5;
[0045] Figure 5E is a cross sectional view at 5E-5E in Figure 5D;
[0046]Figure 5F is a plan view of the mesh of Figure 5, shown without stopper components;
[0047] Figure 5G is a plan view showing a first mesh as depicted in Figure 5F
and a io second mesh , similar to the mesh of Figure 5F (shown in broken lines in Figure 5G) that can be utilized together in a 3D prefabricated construction module in accordance with an embodiment of the invention. Also, cells formed by these meshes are shown with installed vertical rebar;
Is [0048] Figure 5H is a perspective view, partially broken away, of a 3D
prefabricated construction module with transverse and longitudinal elements in a form of mesh shown in Figures 5, 5F, 5G in accordance with an embodiment of the invention.
Also this module employs components shown in Figures 2A, 3A, 3B, 4A, 4B, 4C, 5D, 5E;
20 [0049] Figure 51 is a side elevation view of the 3D prefabricated construction module of Figure 5H. In broken lines, an axis of cells formed by transverse and longitudinal elements in the form of a mesh layer for installation of the vertical rebar is shown;
[0050] Figure 5J is a top plan view of the 3D prefabricated construction module of 2s Figure 5H;
[0051] Figure 6A is a perspective view of the 3D prefabricated construction module of Figure 5H, with vertical reinforcement bars shown installed in cells formed by transverse and longitudinal elements;
[0052] Figure 6B is a front elevation view of the 3D prefabricated construction module of Figure 6A;

[0053] Figure fiC is a side elevation view of the 3D prefabricated construction module of Figure 6A;
[0054] Figure 6D is top plan view of the3D prefabricated construction module of Figure 6A;
[0055] Figure 6E is a cross section view of a fragment of the module of Figure fiA;
io [0056] Figures 7A and 7B are plan views of additional components that can be implemented with the 3D prefabricated construction module of Figures 5H and Figure 6A as horizontal reinforcement;
[0057] Figure 7C is a side elevation view of the 3D prefabricated construction module is of Figure-5H and Figure 6A, implementing the component of Figure 7A;
[0058] Figure 7D is a plan view-of the 3D prefabricated construction module of Figure 7C;
20 [0059] Figure 7E is an enlarged end elevation view fragment at 7E-7E in Figure 7D;
[0060]Figure 8A is a front view of a bracer used in joining 3D prefabricated construction modules;
2s [0061]Figure 8B is a cross section view at 8B-8B in Figure 8A;
[0062] Figure 8C is a cross section view at 8C-8C in Figure 8A;
[0063] Figure 9 is a perspective view of an alternate transverse and longitudinal 3o elements of the 3D prefabricated construction module, attached to the part of a perforated panel, of an embodiment of another mesh that can be used in a 3D
prefabricated construction module;

[0064j Figure 9A is a plan view of part of the module of Figure 9;
[0065j Figure 9B is a cross section view at 9B-9B in Figure 9A;
s [0066] Figure 9C is a side elevation view of a 3D prefabricated construction module employing the component of Figures 2A, 3A, 3B, 4A, 4B, 4C, 7A, 7B, 9, 9A and 9B, and vertical reinforcement installed into the cells formed by transverse and longitudinal elements;
io [0067] Figure 9D is a plan view of the 3D prefabricated construction module of Figure 9C;
[0068j Figure 10 is a perspective view of transverse and longitudinal elements in an is embodiment of another mesh layer that can be used in a 3D prefabricated construction module in accordance with another embodiment of the invention;
[0069) Figure 10A is a plan view of part of the component of Figure 10;
20 [0070]Figure 10B is a cross section view at 10B-10B in Figure 10A;
[0071jFigure 10C is a side elevation view of a 3D prefabricated construction module with vertical reinforcement installed into cells formed by transverse and longitudinal elements; in a 3D prefabricated construction module that employs the component of 2s Figures 2A, 3A, 3B, 4A, 4B, 4G, 7A, 7B, 10, 10A and 10B;
[0072j Figure 10D is a plan view of the 3D prefabricated construction module of Figure 10C;
30 [0073j Figure 11 is a plan view of transverse and longitudinal elements in an alternate mesh to the mesh illustrated in Figure 5, 5f~, 5F, 10 for use in the prefabricated construction module;

is [0074] Figure 11A is a side elevation view of a 3D prefabricated construction module with vertical reinforcement installed into cells formed by transverse and longitudinal elements, the 3D prefabricated construction module employing the component of s Figures 2A, 3A, 3B, 4A, 4B, 4C, 7A, 7B, 11;
[0075] Figure 11 B is a plan view of the 3D prefabricated construction module of Figure 11A;
to [0076] Figure 12 is a plan view of transverse and longitudinal elements in a form of mesh alternate to the mesh illustrated in Figure 5, 5G, 5F, 10, 11;
(0077] Figure 12A is a side elevation view of a 3D prefabricated construction module with vertical reinforcement installed into cells formed by transverse and longitudinal is elements; the3D prefabricated construction module employing components of Figures 2A, 3A, 3B, 4A, 4B, 4C, 7A, 7B, 12;
[0078] Figure 12B is a plan view of the 3D prefabricated construction module of Figure 12A;
[0079] Figure 13 is a plan view of transverse element in a form of an alternate mesh illustrated in Figures 9 and 11 for use in the 3D prefabricated construction module;
[0080] Figure 13A is a side elevation view of a 3D prefabricated construction module 2s with vertical reinforcement installed into cells formed by transverse and longitudinal elements; the 3D prefabricated construction module employing components of Figures 2A, 3A, 3B, 4A, 4B, 4C, 7A, 7B; 13;
[0081]Figure 13B is of a plan view of the 3D prefabricated construction module of 3o Figure 13A;

(0082] Figure 14 is a plan view of transverse and longitudinal elements of an alternate mesh to the mesh illustrated in Figure 5, 5G, 5F,10, 11, 12;
[0083] Figure 14A is a side elevation view of a 3D prefabricated construction module with vertical reinforcement installed into cells formed by transverse and longitudinal elements and horizontal reinforcement installed into space between vertical rebar, the 3D prefabricated construction module employing components of Figures 2A, 3A, 3B, 4A, 4B, 4C, 14;
io [0084] Figure 14B is a top plan view of the 3D prefabricated construction module of Figure 14A;
[0085] Figure 15 is a plan view of transverse and longitudinal elements in a form of mesh that is an alternate to the mesh illustrated in Figure 14;
is [0086) Figure 15A is a side elevation view of a 3D prefabricated construction module with vertical reinforcement installed into cells formed by transverse and longitudinal elements and horizontal reinforcement installed into space between vertical rebar, the3D prefabricated construction module employing components of Figures 2A, 3A, 20 3B, 4A, 4B, 4C, 15;
[0087] Figure 15B is a top plan view of the 3D prefabricated construction module of Figure 15A;
2s (0088) Figure 16A is a plan view of transverse and longitudinal elements in a mesh of a form alternate to the mesh illustrated in Figure 12, 13, 14, 15;
[0089, Figure 16B is a plan view of transverse and longitudinal elements in a mesh of a form alternate to the mesh illustrated in Figures 11, 16A;
[0090]Figure 17 is an enlarged cross section view of a fragment of a construction module illustrating the connection of the construction module panels in Figure 2D, 2E

1?
and one of the ends of the transverse rod of Figure 5C of a mesh of Figures 16A or 16B used with a connector as shown in Figure 3A in accordance with an embodiment of the invention;
(0091]Figures 17A, 17B, 17C illustrate 3D prefabricated construction modules with one side adapted for use in erecting one short ledge on reinforced concrete walls.
[0092] Figures 17D, 17E, 17F illustrate 3D prefabricated construction modules with two sides adapted for use in erecting two short side ledges on reinforced concrete io walls.
[0093] Figure 18 is a perspective view of an alternate arrangement of transverse and longitudinal elements forming a mesh for a construction module in accordance with another embodiment of the invention;
is [0094] Figure 18A is an enlarged perspective view of part of the mesh of Figure 18;
(0095] Figure 18B is a cross section view of a component of the mesh of Figure 18;
(0096] Figure 18C is an end view of the component of Figure 18B taken in the 2o direction 18C in Figure 188;
[0097] Figure 18D is an end view of the component of Figure 18B taken in the direction 18D in Figure 18B;
2s [0098] Figure 18E is a side view of a connector, partially cut away in section in the vicinity of a blind cavity, the connector being for use as a component of the construction module used with the mesh of Figure 18A in accordance with an embodiment of the invention;
30 [0099] Figure 9 8F is an end view of the connector of Figure 18E;

[00100] Figure 18G is a side elevation view of a construction module using the connectors illustrated in Figure 18E and the mesh with components of Figures 18, 18A, 18B;
s [00101] Figure 18H is a cross section view of a fragment of a construction module illustrating a connection of the construction module panel in Figure 2D, 2E
and one of the ends of the transverse rod of Figure 5C comprising part of a mesh as illustrated in Figures 18 with connector in Figure 18E;
to [00102] Figure 181 is a top view of a construction module with installed vertical and horizontal reinforcement rods.
[00103, Figure 19 is a perspective view of a foundation with reinforcement installed in a cavity to receive vertical reinforcement from the construction module formed in is accordance with the invention;
(00104] Figures 20A and 20B are perspective views illustrating part of the fabrication process for erecting a reinforced concrete wall with construction modules;
20 [00105] Figures 20C to 20F are enlarged top plan views showing the connection of one pane( of a module to a second panel of another module;
[00106] Figure 20G is an enlarged bottom view showing the panel connections of one module to another module;
[00107] Figures 20H is a front view showing the continuation of the process of reinforced concrete wall erection including installation of bracer members to connect panels;
[00108] Figure 201 is a front view showing the continuation of the process of reinforced concrete wall erection including installation of vertical reinforcement into construction modules;

[00109) Figure 20J is a perspective view of a single construction module similar to Figure 6A, partially broken away, and mounted on a footing and having vertical reinforcement bars with ends installed into the groove of the foundation cavity to provide.overlapping with rebar extensions of foundation for the integrity of the reinforced concrete wall and foundation;
[00110) Figure 20K is a front view illustrating the continuous of the process of the reinforced concrete wall erection in Figures 201 illustrating installation of horizontal to reinforcement into joined construction modules;
[00111) Figure 20L is an enlarged cross section view at 20L-20L in Figure 20K
illustrating the completion of the installation process of detail 7A or 7B as horizontal reinforcement of the erected reinforced concrete wall;
[00112] Figure 20M is a front view showing the continuation of the process of the reinforced concrete wall erection in Figures 20K illustrating the installation of concrete in a wall form made from construction modules, the top edge of concrete placement is shown in waved broken line;
[00113) Figure 20N is a cross section view at 20N-20N in Figure 20M, showing the reinforced concrete wall made from the construction modules shown in Figure erected on the foundation;
2s [00114) Figure 200 is a front view of showing the continuation of the process of reinforced concrete wall erection in Figures 20M, illustrating installation of vertical and aftenivards horizontal reinforcement into joined construction modules mounted on the construction modules forming the first part of reinforced concrete wall of Figure 20M. Modules are connected both longitudinally and vertically to other 3o modules, to build on the wall of Figure 20M;

[00115] Figure 20P is a cross section view of the reinforced concrete wall at 20P in Figure 200;
[00116] Figure 20Q is an enlarged view of detail 20Q in Figure 20P;
s Detailed Description [00117, With reference to Figure 1, a schematic representation of part of a 3D
construction module 100 is shown. Module 100 is preferably pre-fabricated prior to io delivery to a construction site or directly on the construction site prior to installation into the design position, and comprises a pair of panels 110a, 110b (only portions 112a and 112b being shown in Figure 1 ). Panels 110a, 110b held in spaced apart relation by means of transverse elements in the form of pairs of transverse rod members.114x, 114y and 1142 each pair positioned in one of three vertical layers x, Zs y and z.
[00118] The transverse rods each have stopper elements 116 mounted perpendicularly to the longitudinal axis of the transverse rods. The transverse rods ends are fixed to the panels 110a and 110b (although Figure 1 does not show the 2o attachment mechanism). The end of the transverse rods (referenced collectively as 114) can be attached to the panels 110 as described below, or in other conventional ways.
[00119) Stoppers 16 mounted on the transverse rods (shown schematically) can 2s be pressed against the inward surface of each panel or pressed into the body of each panel and abutted with the end of a connector of the attachment mechanism of the transverse rods 114 (connectors are not shown in Figure 1 ).
[00120] In addition to transverse rods 114x, 114y and 114z, longitudinal rods 122x, 122y and 1222 are provided in each mesh layer x, y and z. Rods 114 are rigidly joined to rods 122 at their crossing locations by any conventional method, preferably spot welding. Together longitudinal rods 122 and transverse rods 114 form layers of the transverse and longitudinal elements comprising meshes 123x, 123y, and 123z, each layer being vertically spaced from ~ther layers.
s [00121] Rods 114 and rods 122 are typically made from any suitable material, such as plastics, composite materials, preferably from steel rods having cross sections with diameters in the range from 2 to 8 mm.
[00122] The rods 122 and 114 are arranged to create meshes that take advantage io of the basic principle of a three-point force application to be able to resist translations along both the transverse axis M and longitudinal axis N, and rotations about the M
and N axes.
[00123) Adjacent horizontal mesh layers 123x, 123y and 123z are installed in such is manner, as depicted for example in Figure 1 a, so that the crossing of transverse and longitudinal rods of combined adjacent layers (eg: the mesh layers of layers 123x and 123y) one located above the other, form retaining cells 125. The cells 125 provide a space for the vertical positioning of vertical re-bar members 120.
Vertical re-bar members 120 are positioned so as to provide proper reinforcement to the 2o concrete wall or other structural element.
[00124] By providing three layers, each pair of adjacent layers (ie: x , y;
and y; z) provide for in effect a holding or pinning of each vertical member 120 that resists translation movement in both the N and M directions, as well as rotational movement 2s around the M and N axes.
[00125) Although the horizontal projection of transverse and longitudinal members of two adjacent layers (eg. 123x, 123y) onto a horizontal surface / plane is a rectangle, other geometrical configurations can be employed, such as for instance: a 3o triangle, a trapezium and so on.

[00126 Each arrangement of mesh layers, depending on its design specifications, can define the cell for vertical rod positioning from one, two, three and four sides: In Figure 1A, each mesh layer defines the cell 125a only from two sides; the combination of two adjacent layers positioning the rods on the four sides of a s rectangle.
[00127] In an embodiment shown in Figure 1 B, the horizontal projection of transverse and longitudinal members of two adjacent mesh layers onto a horizontal surface or plane is a triangle thus creating retention cells 125b.
to [00128] It should be noted that the cells could be created between two adjacent mesh layers using only a single, generally transversely oriented rod if at least one of the rods has portions which have longitudinal extension portions. For example, one of the rods could be a straight rod in one mesh layer X. In the vertically adjacent is layer Y, the other could be generally vertically aligned above it, but have a semi-circular portion that creates a cell 125c in a horizontal plane projection between the straight rod in the first layer X and the semi circular portion in the second layer Y, as shown in Figure 1 C.
20 [00129] It should be appreciated that the orthogonal reference directions, longitudinal, transverse and vertical are not necessarily orientations relative to flat ground.
[00130] With reference now to Figures 2A, 2B, 2C, 2D, 2E, a panel 210 that can be 2s used as a component in a 3D prefabricated construction module is illustrated. Panel 210 is perforated with a plurality of openings 211 which are formed in a pre-determined pattern, as detailed hereafter. Preferably the diameter of openings 211 is 8-12mm (1/3" -'/2") 30 [00131] Panel 210 is preferably made from expanded or extruded polystyrene with a density of 20-35 kglm3. Other typical materials from which panel 210 can be made include other expanded plastics, as well as cement bonded particle boards, cement boards, OSB and other materials, the technical characteristics of which allow them to be used as panels to forming monolithic walls or other structural members.
Panel 210 will be usually formed of a standard width and height (normally the width is s about 4' (1200mm) and the height is 8' (2400mm)).
[00132] As is evident from Figures 2B, 2C, 2D and 2E, vertically extending grooves or channels 213 are formed in side faces 215. Grooves 213 preferably have a depth of about 'h" - 3/" (12 - 20mm). Also, preferably the side faces of end tongues and io grooves are deflected from being perpendicular to exterior faces 217 by an angle of between 0-15°.
[00133] As shown in Figures 2A, the openings 211 are formed by the crossing locations of the lines formed into parallelograms, which are deflected from the is horizontal face to the angle of 0-1 °, and from vertical face by an angle of in plus or minus 0-10°. Figures 2D and 2E illustrate the panel cross sections on sections through the openings 211. The perforation of the panel 210 o form openings 211 can be performed in numerous known ways and methods such as, for example by drilling, piercing and so on.
[00134] With reference now to Figure 3, a generally mushroom-shaped connector 236 is illustrated joined with the end portion 314a of the transverse rod of the transverse element. Connector 236 is another component that can be used for fabrication of 3D prefabricated module. The end surface of the leg 235 of the 2s connector 236 abuts with a stopper 316 that is joined with transverse rod 314.
[00135] With reference to Figure 5B, a rod 314 is shown with extruded ends 314c that are preformed on transverse rod 314. A plane connecting ends 314c with the middle portion of ends 314b serves as a stopper during installation of a stopper like 3o stopper 316 or other similar washer in the shape of a flat push-on washer, flat nut etc. Afterwards, extruded ends 314c are formed with the shape of a tap or self-threading tool for thread cutting in plastic nuts (see Figure 5c, 314a) - in this case the inner cavity of connector 236. Also, it should be noted, that the plane for abutment of the stopper 316 may be arranged without extruding the end portion 314c - in this case the end of rod 314a may be pre-formed in the shape of tap or thread cutting tool for plastic nuts with thread cutting.
[00136] Returning to Figure 3, cap portion 237 of connector 236 preferably presses against the outer surface of the panel 210 providing pressure transfer between the panels and transverse rods 314. This pressure is exerted on the each panel by the io hydrostatic forces from poured concrete to provide a connection mechanism between each connector 236 and transverse rod 314. In general, connector 236 is a "blind" cavity self-threaded nut and is aggregated with a washer of a larger diameter than leg 235.
is [00137] With reference now to Figures 3A, a mushroom-shaped connector 236, is illustrated partly cut-away. Connector 236 is also preferably used in the 3D
prefabricated construction module of the present invention. The connector 236 is preferably made from any plastics or suitable composite material, and which can provide for a strong threaded connection with the transverse rod of the construction 20 module that can withstand a tensile load of 120-250 kg.
[00138] Connector 236 is made most preferably from glass fiber reinforced polypropylene. Cap portion 237 of the mushroom-shaped connector preferably has a diameter of 45-70mm and thickness 2-4mm. Connector 236 will have rotational 2s features (typically on the face of the cap portion 237) that permit the connector to be rotated co-axially with its leg 235 about a longitudinal axis of the leg. Such features can for example permit a mechanical tool such as a socket driver or a drill with a nozzle to be used to rotate the connector 236.
30 [00139] A cylinder portion of the leg 235 preferably has a diameter 8-12mm and length 30-40mm. As well there is a "blind" cavity or opening 239 in the form of cylinder in the leg preferably with a depth in the order of 30-40mm. The inner diameter of the "blind" cavity is preferably from 2.8 to 8 mm; which is 70-85%
of the diameter of the end shape of the tap or self-threading tool for plastic nuts, of the connecting transverse rod (not shown in Figures 3A or 3B). The "blind" cavity acts as a nut for joining the end of the transverse rod 114 of the mesh layer 123.
[00140] Part of the leg 235 of connector 236 is in the form of a truncated cone 241 has an angle of the line of deflection forming the cone to the base of the cone of preferably about 30-60°. Preferably the height is in the range of 10-20mm.
io [00141] The cone portion 241 is intended for deformation of the walls in the openings 211 of the perforated polystyrene panel and for the plugging of those openings during fabrication of the construction module. The cone portions 241 of connectors 236 on two adjacent panels can also be employed to connect two panels 1s with bracers by providing a "wedge" effect that draws the two adjacent panels together. This latter feature is explained further hereafter [00142] The connection of two panels 210 by rotation of mushroom-shaped connectors 236 linked by a bracer 480 (see Figure 8), is assisted by the formation of 20 an indentation on the outer surface of the leg 235 in the shape of a helical spiral.
The spiral indentation on the outer surface matches the helical indentation step on the inner wall of the "blind" cavity 239 of the connector, which is formed by the tapping action of the end of the transverse rod in the blind cavity while connecting the connector and transverse rod.
[00143] With particular reference to Figure 3B, mushroom-shaped connector 236 has its cap portion 237 in the shape of a cylinder with a longitudinal axis B2, formed with eccentricity relative to axis B1 of the shaft portion 241, and leg portion 235. It should be noted that the shape of shaft portion 241, and leg portion 235, are made 3o by the consecutive connection of two figures of rotation: a hollow cylinder and a truncated cone.

[00144] The effect provided with such a connection and arrangement, is that when connector 236 is used for connecting with the horizontal meshes of the 3D
prefabricated construction module, and which resists the hydrostatic pressure exerted on the panels caused by unhardened concrete, it enhances the strength of the connection between the connector 236 and the transverse rod 114:
[90145] The axis of the cap B2 is displaced from the leg's axis B1 by the small value "e". In the preferred embodiment for cap portion 237 having outer diameter to approximately 54mm, distance "e" would be approximately one millimeter.
(00146] To elaborate further, the effect of providing the center-lined axial displacement is the following. Loading received by the cap 237 from unhardened concrete hydraulic pressure is not aligned or centered with axis of the central line B1, is but is mainly aligned with axis B2. This created a moment or torsion between the cap portion 237 and the leg portion 235. This torsion is passed from the leg 235 to the end of the transverse rod 114. It results in more tightening between the leg 235 and the end of the transverse rod 114. Accordingly, the advantages are in the fact, that compared with the physical specifications required of a connector where there is no 2o eccentric displacement, in a connector having axis displacement, the thread size can be lessened and the thickness of the leg portion 235 can be lessened, while providing the same bearing capacity.
[00147] As mentioned above, it is quite typical for panels used in the 3D
2s prefabricated construction modules to be made of foamed polystyrene or similar foamed plastic materials or other non-flammable materials. In fact, such materials are non-flammable themselves, but some of the raw materials comprising such panels are flammable, although relatively difficult to ignite unless brought into direct contact with a source of fire or flame. Thus it is desirable to keep such material 3o away from contact with the fire source. Foamed polystyrene panels consist of 95-98% air and 2-5% polystyrene. During a fire, when the air temperature in the vicinity of a structural element such as a wall reaches 250°C, polystyrene associated with the wall often becomes a melt. This liquid polystyrene melt leaks down the concrete wall surface, and upon reaching the fire source, ignites and increases the heat load on the concrete surfaces such as the surface of a reinforced concrete wall.
This will s of course decrease the fire resistance of the wall and be detrimental to its structural integrity.
[00148] With reference to Figures 4A-4C, three examples of trough elements 300A; 300B and 300C that can be used with the panels (like panels 210 in Figure io 2A) of the 3D prefabricated constructions modules of the invention, are illustrated.
Each trough element 300A-C can be employed with panels, such as for example panels 210 illustrated in Figure 2A, so that when the panel is subjected to melting, the melted polystyrene or other plastic material can be captured in the reservoir of the trough. Troughs 300A-300C would be made from a suitable fire resistant is material like tin, galvanized steel or hydrophobic cardboard (only for use in the building with concrete floors) and in use would have their ends blocked so as to trap the melt therein. The ends of the reservoir would typically be blocked by the same material as used for trough.
20 [00149] The size of the trough and its reservoir is chosen to be able to hold the necessary volume of melt. By way of example, for a trough holding a polystyrene panel, a trough reservoir with a volume of polystyrene equal to 2-5% of the total volume of the panel would be suitable. Typically, the height of trough wall facing the fire source is from 2 to 5% of the total height of floor concrete wall.
[00150] ~ As a result of the use of troughs 300A-300C, melted polystyrene will not reach the fire source, which would increase the heat temperature and impact duration on the reinforced concrete wall.
[00151] The use of a trough 300C is shown in Figure 4D. When air temperature reaches up to 150°, foamed polystyrene of the construction module panels begins to reduce its volume (shrinking). As shown, an air gap 303 is provided between the drywall panel or cement sheet 305 and reinforced concrete wall 307, which would prevent the reinforced concrete wall 307 from heating from the fire to the same extent as would otherwise be the case if the fire moved directly to the wall.
As shown, melt 309 is captured in the reservoir of trough element 300C.
[00152 Trough elements 300A-C can be mounted on a perforated polystyrene panel like panel 210, during prefabrication of the construction module in the manufacturing plant environment. However, they can also be delivered on the io construction site and for example, fixed to the footing of underlying flooring; and then the panel can placed into the trough element thereby framing the lower end of the panel, when making the 3D prefabricated construction module used in construction of a wall.
is [00153 ' With reference now to Figures 5, 5A-5F, a transverse element of the 3D
prefabricated construction module in a form of horizontal mesh layer 323 is illustrated. Transverse rods 314 of the mesh are preferably made from smooth round rod (sometimes from stainless steel, but preferably from galvanized black steel or zinc-coated black steel) and are connected to longitudinal bars 322 made from 2o steel wire by conventional methods including preferably spot welding.
Preferably meshes are galvanized or zinc-coated after spot welding. Figure 5B illustrates a blank used for making a member 314, and has an extruded end portion 314c at each end. The ends are extruded prior to forming the end portions in the shape of a tap or a self-threaded tool for plastic nut (as shown as 314a in Figure 5C). It is intended 2s that the outer diameter of the tap end portion will preferably be 85-115%
of the outer diameter of the medial portion of the rod 314b; furthermore preferably the rod 314b diameter is in the range of 4.0 - 7.Omm and the extruded end portion 314a has a diameter in the range of 3.4 - 6.Omm.
30 [00154 As shown in detail in Figure 5A, a stopper eleri~ent 316 is provided on the end portion 314a and the stopper 316 abuts against the outward facing edge of medial portion 314b. Thus stopper element 416 can act as a stopper for the mushroom-shaped connector during fabrication of the 3D prefabricated construction module. Thus, when a connector 236 is tightened on a transverse rod like rod 314, it can be tightened until it abuts into the stopper 316. A portion of a panel like panel s 210 is then held between stopper 316 and a connector 326. The leg of connector 236 abuts into stopper 316.
[00155] Stoppers 316 are preferably constructed in the form of push-nuts as illustrated in Figures 5A, 5D; 5E and are mounted on the end portions of the io transverse rods. Also, other similar devices such as push-lock washers, flat washers and so on, can be used as stoppers. Once mounted on end portion 314a and put into abutment with medial portion 314b, the movement of stopper 316 in both transverse directions is resisted (i.e. stopper 316 is transversely fixed on rod 314).
is [00156] The stoppers are used during the fabrication of the 3D
prefabricated construction module shown on Figure 5H. The stoppers are required for controlling the installation accuracy of the horizontal meshes and the position of the perforated panels relative to each other, and consequently the accuracy of the compliance with the specified design of the reinforced concrete wall or other structural element.
[00157] As shown in detail in Figures 5D and 5E, stoppers 316 are formed in the shape of round type push nut fasteners preferably with outer diameter 15-30mm and inner diameter equal to diameter of the extruded end of the transverse rod.
Preferably the thickness is about 0.5mm..The stopper is pushed or screwed on the 2s extruded end portion 314a of the transverse rod with rolled profile in the form of a tap or self-thread tool for plastic nut until abutment with non-extruded portion 314b of the transverse rod in accordance with Figure 5A.
[00158] Figures 5F and 5G show in plan view how meshes of two similar 3o configurations and different intervals between longitudinal rods 322 can be used in two adjacent mesh layers (as in layers x, y or y, z in Figure 1 ) to co-operate to provide retention cells 326 for holding vertical reinforcement members 320. By providing three such mesh layers, the vertical reinforcement members can be held from both translation movement in M and N directions as well as against rotational movement around M or N axes.
s [00159] With reference to Figures 5H, 51 and 5J, a 3D prefabricated construction module 200 is illustrated with the components described above. These components include panels 210, transverse and longitudinal elements in the form of mesh layers 323, each pair of adjacent 323 layers having transverse and longitudinal members io arranged for co-operatively holding and positioning vertical reinforcement members (shown in broken lines 120) as shown in Figure 5G. The components also include trough elements 300A and 300C, and stoppers 316 for the ends of the transverse rods in each of the mesh layers 323. It should be noted that connectors 326 and stoppers 316 are enlarged in Figure 5J for clarity.
is [00160] With reference to Figures 6A-6E the 3D prefabricated construction module 200 of Figure 5H-5J is shown modified with vertical reinforcement members 120 installed. In Figures fiA-6E, a module 400 has panel members 410 separated by mesh layers 423. Mesh layers 423 comprise transverse rods 414 fixedly secured to 20 panels with stoppers 416 and connectors 436. Longitudinal rods 422 combine with rods 414 to create retention cells 425 for supporting vertical reinforcement members 420. Mushroom-shaped connectors 436 in accordance with Figure 3B have been installed in panel openings in accordance with Figure 2A. Figure 6E
illustrates how retention cells 425 formed with rods 414x, 414y and 422x, 422y, between layers 2s 423x, 423y and with rods 414y, 4142 and 422y, 4222, between layers 423y, 423z co-operate to hold rods 420, generally as described above. The mushroom-shaped connectors 436 are installed with row displacement. In the center of each mushroom-shaped connector 436, an opening is shown in Figure 6B which provides a feature :to permit rotation of the mushroom-shaped connector by means of 3o electrical screw driver, electrical drill or the like.

[00161] With reference to Figures 7A-7E, other modifications of the 3D
prefabricated construction module 400 of Figures 6A, 6B, 6C, fiD, 6E are illustrated.
Module 500 is constructed much the same as module 400, using rods 514 and 522 to provide mesh layers that are connected with stoppers 516 and connectors 536 to s panels 510. In these embodiments, module 400 is modified to provide a module which is the same as 3D prefabricated construction module 400 but which additionally employs horizontal reinforcement meshes 560 or 562. In Figure 7A, a mesh 560 is shown consisting of two rods 564 of horizontal reinforcement material.
Preferably the reinforcement rods are made of steel and have a diameter of about 5-io 12mm, with a length of usually about 1500 -1800mm or 2700 - 3000mm.
[00162] In order to modify 3D prefabricated construction module 400 to module 500, the vertical reinforcement rods 120 are installed as shown in Figures 6A, 6B, 6C, 6D, 6E.
is OOL 1 s31 Afterwards, each layer is provided with meshes 560 or 562 shown in Figures 7A and 7B. The meshes 560 or 562 should be placed transversely into the space between closest vertical rods 120 of the construction module 500. The meshes are preferably installed at an angle to the longitudinal and transverse plane 20 or mesh layers 523:
[00164] It is to be noted that once installed in the right position, gravity acting of mesh 560 or 562 will tend to push rods 564 outwardly against the sides of vertical members 120, which are themselves retained by the mesh layers 523 comprising 2s longitudinal rods 122 and transverse rods 114. The pressure resulting from gravity acting on rods 564 and 566 of reinforcement meshes of the horizontal reinforcement results in forces being applied onto vertical reinforcement rods 120 ( as shown with arrows in Figure 7E). As a result, the vertical rods 120 occupy the most possible extreme outward position vertically which ensures the maximum bearing capacity of 3o the erected reinforced concrete wall with 3D prefabricated construction module 500.

With this, the required interval from surface of vertical rods 120 to the nearest surface of the erected reinforced concrete wall is provided.
[00165] Each mesh 560 is used for horizontal reinforcing of said 3D
prefabricated s construction modules 500, where the horizontal mesh layers (rods 114 and 122) are preferably inclined to the horizon die. from the horizontal plane parallel to the top and bottom faces of panels 510) in the range of 0.6-1.0°. This is required for providing the "continuous" reinforcement of the reinforced concrete wall with horizontal longitudinal rods overlapping of meshes 560. While utilizing these meshes 560, the to reinforcement rods 564 will overlap as the end portions 565 have rod ends placed one above the other. The rods of these meshes preferably should extend longer than the front face of the panels 510 by an amount of 30-60 rods diameters when meshes 560 are installed.
~s [00166] Because of the longitudinal sloping of mesh layers 523 of in the range of 0.6 to 1.0°, the end portions 565 can extend from the both side of the panels of the 3D prefabricated construction module, when they are installed. The mesh can also be impleri~ented in whole or part without extended ends.
20 (00167] In Figure 7B, an alternate reinforcement mesh 562 is shown which is intended for reinforcing of a 3D prefabricated construction module 500, where the horizontal mesh layers 523 are arranged horizontally or deflected from horizon for not more than 0.6°. While horizontal reinforcing of said 3D
prefabricated construction modules, the ends with length preferably in the range of 30-60 diameters of the 2s reinforcement rod of such reinforcement mesh will be arranged between the straight ends of the preceding reinforcement mesh. Thus the angled portion 563 permits the overlap of a reinforcement mesh 562 of one module, with the adjacent mesh 562 of a second abutting module. This mesh can extend from one side and from the both mesh sides.

[00168] With reference to Figures 8A-8C a plate-type panel bracer is shown for use in joining two adjacent mushroom-shaped connectors 326 of two adjacent 3D
prefabricated construction modules such as for example 3D prefabricated modules 200 in Figures 5H-5J. Connectors 236 are connected with each other during erection of, for example, a reinforced concrete wall. , [00169] Generally C-shaped bracer 480 has a cavity 483 formed by a body 485 with two legs 487. On the inner side of legs 487 is a blade element 481, which provides tapping tool to form the helical indentation on the cone-shaped surfaces of io the mushroom-shaped connector as described above. Thus, with clockwise rotation of connector 236, the blade 481 will circumscribe the helical indentation on the cone portion 241 (See Figures 3A and 3B), which prevents sliding of the plate-type metal panel bracer 480 during the joining two 3D prefabricated construction modules, as well as preventing polystyrene deformation caused by mushroom-shaped connector.
is If another type steel bracers is used, there is a risk that without having a cutting edge, upon reaching cone effect, the steel bracer permits sliding due to low sliding coefficient on the cone part of the connector (which is made from plastic, preferably from polypropylene reinforced by fiberglass). The result can be that the sliding of the connector on the bracer will cause deformation of the polystyrene bady of the panel.
[0.0170] ' With reference to Figures 9-9D another embodiment of the 3D
prefabricated construction module is illustrated. 3D prefabricated module 600 is like the previous modules including having panels 610, trough elements 300, connectors 636, a plurality of longitudinally spaced vertical reinforcement members 120 retained 2s by horizontal mesh layers 623, similar to the mesh layers in Figure 5.
However mesh layers 623 are formed from transverse rods 614 and a pair of spaced longitudinal rods 622 to form retention cells 625 (See Figure 9D). It will be observed from Figure 9C, that each mesh layer 623 is adapted to restrict on its own, the movement of vertical rod 120 in the N direction. Only movement of the rod 120 in the M direction is restrained by the interaction of successive adjacent mesh layers and the positioning of rods 614 on alternating, opposite sides of rod 120.

[00171) Also in Figures 9-9D an alternate stopper 616 is disclosed that can be used with the transverse rod 614, although other suitable stoppers can also be used.
Stoppers 616 are in the form of two, co-axially connected hollow cylinders.
Stopper 616 is preferably made from any suitable material and preferably of any type of s suitable plastic. Preferably stopper 616 has a cap portion 617 with a diameter 20-40mm, a leg 615 of length in the range of about 15-70mm, a cap 617 with a thickness of about 2mm. Preferably, the inner cavity diameter is about equal to the diameter of the horizontal mesh transverse rod 614. It should be noted, that stopper 616 could be used in for example the embodiment in Figure 18B, forming the inner io cavity similar to or like the said stopper illustrated in Figure 18B.
[00172) It should also be noted that in the 3D prefabricated construction module of Figure 9C and 9D, horizontal reinforcement meshes 660 constructed like the meshes 560 and 562, are employed, being installed in each horizontal layer.
Preferably these is meshes are made from longitudinal ribbed wire 664b with diameter 4-12mm and longitudinal smooth wire 664a with diameter 2.5-4.0 mm. Usually the smooth wire surface abuts to the inner surface of the panel 610 of the 3D prefabricated construction module.
20 [00173) In Figures 10-10D, another combination of longitudinal and transverse rods of a mesh layer 723 for a 3D prefabricated construction module is shown.
(n mesh 723, a hollow cylindrical stopper 716 comprises consequently connected hollow figures in a shape of flange 717, cylinder 713, flange 719 and a cylinder 715.
A stopper 716 is put on each end of the transverse rods 714 of the horizontal mesh 2s 723, through its cylinder opening, and stopper 716 moves into abutment with the longitudinal rods 722. It should be noted, that for the mesh 723, other types of stoppers can be used.
[00174] The transverse position of stopper 716 is maintained by rods 722 in one 3o direction, and by the leg portion to a connector 736 which will also be in abutment 3s with stopper 716. Connectors 736 are preferably attached to rods 714 as described above in relation to connectors 736.
[00175) Stopper 716 is also made from a suitable material including any suitable s type of plastic and preferably the flanges have a diameter of about 20-40mm, a leg length of about 15-40mm, and flange thickness of about 2mm. Again, the inner cavity diameter preferably is about equal to the diameter of the transverse rod, and can permit movement on the rod 714. It should be noted, that stopper 716 could be used in, for example, the embodiment in Figure 188, forming the inner cavity similar io to or like the said stopper illustrated in Figure 18B.
[00176) Figure 10C illustrates a 3D prefabricated construction module in accordance with another embodiment of the present invention, in which only one type of horizontal mesh 723 as illustrated in Figure 10 is used, and with installed is vertical rods of Figure 6 and reinforcing meshes of the horizontal reinforcement in accordance with Figures 7A or 7B is shown. A cell 725 for installation of vertical reinforcement rod 120 is provided by alternating transverse rods 714 between adjacent layers in the M direction. In the N direction, in each layer, longitudinal rods 722 co-operate with the flange 719 of a stopper to restrict movement, there being 2o sufficient spacing as a result of end portion 727 to allow a vertical rod 120 to fit between the rod 722 and flange 719.
[00177, Figures 11, 11A; 11B, 12, 12A; 12B, 13, 13A, 13B; 14, 14A, 14B; and 15, 15A and 15B illustrate further embodiments of 3D prefabricated construction 2s modules with transverse and longitudinal elements in the form of mesh layers used for holding and positioning vertical reinforcement members and horizontal reinforcement meshes.
[00178] In Figures 11, 11A, 11B, a 3D prefabricated module 1700 is shown using a 3o horizontal mesh 1723. Adjacent layers of rods 1722a act as stoppers and rods 1722b cooperate with transverse rods 1714 to form retention cells, similar to the cells 126 in Figure 1A. Meshes 1723 are installed by having each mesh layer positioned in a position that is rotated 180° around its longitudinal axis N relative to each adjacent mesh layer. The vertical reinforcement rods 120 are installed with horizontal reinforcement meshes, in accordance with Figure 6, and with reinforcement meshes of Figures 7A and 7B.
[00179 In Figures 12, 12A, 12B a 3D prefabricated module 2700 is shown using transverse and longitudinal elements in the form of horizontal mesh 2723.
Adjacent layers of rods 2722a act as stoppers and rods 2722b co-operate with transverse ~o rods 2714 to form retention cells, similar to cells 126 in Figure 1A:
Meshes 2723 are installed by having each mesh layer positioned in a position that is rotated 180°
around a vertical axis B, relative to each adjacent mesh layer. The vertical reinforcement rods 120 are installed with horizontal reinforcement meshes, in accordance with Figure 6, and with reinforcement meshes of Figures 7A and 7B.
~s [00180 In Figures 13, 13A, 13B a 3D prefabricated construction module 3700 is shown using transverse and longitudinal elements in the form of a horizontal mesh 3723. Adjacent layers of rods 3722a act as stoppers and rods 3722b co-operate with transverse rods 3714 to form retention cells 3725 (Figure 13B), similar to cells 20 126 in Figure 1A. Meshes 3723 are installed by having each mesh layer positioned in a position that is rotated 180° around a vertical axis B, relative to each adjacent mesh layer. The vertical reinforcement rods 120 are installed with horizontal reinforcement meshes, in accordance with Figure 6, and with reinforcement meshes of Figures 7A and 7B.
[00181) In Figures 14, 14A and 14B, a 3D prefabricated module 4700 is shown using a transverse and longitudinal elements in the form of a horizontal mesh 4723.
Adjacent layers of rods 4722a act as stoppers. Rods 4722b co-operate with transverse rods 4714 to form retention cells 4725 (See Figure 14B). It will be noted so from Figure 14B that longitudinally spaced two retention cells, have locations that alternate on opposite transverse sides of horizontal reinforcement members 4740.

Meshes 4723 are installed by having each mesh layer 4723 positioned in a position that is rotated 180° around a vertical axis B, relative to each adjacent mesh layer.
There are two sets of vertical reinforcement rods 120a and 120b each set being held on one side or the other of horizontal reinforcement rod 4740.
(00182] In Figures 15, 15A and 15B, a 3D prefabricated construction module is shown using a transverse element in the form of a horizontal mesh 5723.
Module 5700 is similar to module 4700, and adjacent layers of rods 5722a act as stoppers.
Kods 5722b co-operate with transverse rods 5714 to form a first series of retention io cells. Rods 5722c co-operate with transverse rods 5714 to form a second series of retention cells. It will be noted from Figure 15B that a first set of Longitudinally spaced two retention cells 5725a, have locations that alternate on opposite transverse sides of horizontal reinforcement member 5740a. A second set of longitudinally spaced two retention cells 5725b, have locations that alternate on is opposite transverse sides of horizontal reinforcement members 5740b. Meshes 5723 areinstalled by having each mesh layer 5723 positioned in a position that is rotated 180° around a vertical axis B, relative to each adjacent mesh layer. There are two sets of vertical reinforcement rods 120a and 120b each set being held on one side or the other of horizontal reinforcement rod 4740.
zo (00183] With reference to Figures 16A, 16B, 17,17A, 17B, 17C; 17D, 17E, 17F, other embodiments of the invention are shown provided for a 3D prefabricated construction module that can be used for erection reinforced concrete structures with extended details, such as a parapet, a cornice or one or more short ledges.
(00184] , With reference to Figure 16A, transverse and longitudinal elements in the form of a mesh 2023 are shown and which comprises longitudinal bars 2022a and 2022c which act as stoppers and bars 2022b which co-operate with bars 2314 to form retention cells, in a manner as described above. It will be noted that stopper o bar 2022a is positioned away from end portion 2314a, whereas bar 2022c abuts the end of potion 2314a on the opposite side of the mesh. These meshes are used in the 3D prefabricated construction modules for erection of walls with one side ledge (see Figures 17A, 178, 17C).
[00185] With reference to Figure 16B, transverse and longitudinal elements of a 3D prefabricated construction module in the form of a mesh 3023 is shown which is similar to mesh 2023 and comprises longitudinal bars 3022a and 3022c which act as stoppers and bars 3022b which co-operate with bars 3314 by off setting two meshes 3023 longitudinally to form retention cells. 1t will be noted that both stopper bars 3022a and 3022c are positioned away from end portion 3314a. These meshes are io used in the construction modules for erection of walls with two-side ledge (see Figures 17D, 17E, 17F).
[00186] Figure 17 illustrates the cross section of a fragment of a 3D
prefabricated construction module, where connectors 2326 can be used to connect a panel to the is end of transverse rod 2014 with abutment in the body of the transverse rod 2014b medial portion, where element 2022a is remote from end portion 2014a and act only as a support for the perforated panel 201 Oa, 2010b. This is useful for prefabrication of the construction module for erection of reinforced concrete structures with extended details, such as parapet, cornice or short ledge; for example the panel 2o material may comprise an additional thickness of panel wall 2010b, as illustrated in Figure 17. It should be noted that the rod 2014 has a relatively large diameter in its medial portion relative to its end, tapered portion. The plane at the end of medial portion, abutting the end portion of rod 2014 may serve as a stopper for connector 2326.
[00187] Figure 17A illustrates a cross-section of a 3D prefabricated construction module 2000 similar to module 200 modified with meshes 2023a and 2023b similar to meshes 2023 in Figure 16A. Module 2000 is used for erection of wails with one side short ledge. Perforated panel 2010a of non-standard thickness is used for 3o forming the ledge.

[00188] Figures 17B is a side elevation view of a reinforced concrete wall fragment with one side short ledge erected on a foundation with a 3D prefabricated construction module 2000. The ledge is reinforced with reinforcement bar detail 2020 and its exterior is finished with brickwork 2005.
s [00189] Figure 17C is a side elevation view of a reinforced concrete wall fragment with one side short stepped ledge erected on a foundation with a 3D
prefabricated construction module 2100 similar to module 2000 in Figure 17A and modified from module 200. The stepped ledge is formed with small panel sections 2010c;
2010d;
io 2010e with standard thickness. The ledge is reinforced with reinforced detail 2120 and formed with horizontal meshes 2123a, 2123b, 2123c, 2123d which are like meshes 2023.
[00190] Figures 17D is a cross section of a 3D prefabricated construction module Is 3000 similar to modules 200 and 2000 modified with meshes 3023a and 3023b similar to meshes 3023 in Figure 16B. Module 3000 is used for erection of walls with two side short ledge on opposite sides of the wall. Perforated panels 3010b of non-standard thickness and shape, and perforated panels 3010 of standard thickness are used in conjunction with panels 3010a for forming the ledges.
[00191] Figure 17E is a side view of a reinforced concrete wall fragment with two side short ledge erected on foundation with 3D prefabricated construction module 3100 modified with vertical reinforced rods 120a and 120b installed and horizontal reinforcement meshes 316. Ledge is reinforced with reinforced detail 3020.
This 2s Figure shows the first step of wall concreting when concrete is poured in the module cavity up to the top edge of the ledge.
[00192] Figure 17F is a fragment of a reinforced concrete wall erected with two side short ledges. After concrete hardening in Figure 17E, a portion of a panel 3010 3o with meshes 323 is removed. Concrete is placed to the entire height of the wall.

4~
Afterwards, the ledges can be used according to the design requirement, for example, brickwork 3105 or truss 3106 or pre-cast slab support.
[40193] With reference now to Figures 18-18F, another combination of transverse s and longitudinal elements of a 3D prefabricated construction module are shown.
The horizontal mesh layer 923 comprising rods 914 and 922 is used with stoppers 916 and connectors 936 (Figures 18E, 18F). Horizontal mesh 923 is made from transverse bars 914 are connected to longitudinal reinforcement bars 922 by conventional methods including preferably spot welding. During prefabrication of the io construction module; the stopper 916 is placed onto the ends of the transverse rods 914a until abutment with the longitudinal rod 922 as shown in Figure 18A and 18H.
[00194] As shown in detail in Figure 18A a stopper element 916 is provided and abuts against rod 922. Stopper 916 is constructed to co-operate with connector is to be mounted on the outer extended leg portion 935.
[00195] It will be observed that stopper 916 if formed with a large outer cylindrical cavity 990, which is adapted to receive the leg portion 935 of connector 936.
The end 935a of leg 935 of connector 936 usually abuts into the end wall 990a of the 20 cylinder cavity 990. Second, inner cylindrical cavity 991 permits the portions 914b and 914a of rod 914 to pass there through and into cavity 939 of connector 936, which is tapped in the same manner as connector 336 as described above.
[00196] The geometrical parameters of stopper 916, as well as material, can be 2s similar to the stoppers disclosed in Figures 9 and 10. It should be noted that the cylindrical cavity 991 with the smaller diameter permits positioning connector relative to the end of the transverse rod 914a and 914b. The end wall ~90a of cylinder cavity 990 acts as a stopper for rotation of connector 936 when connecting with the end of the transverse rod 914a. Usually the length of the leg 935 of the 3o connector 936, the thickness of the perforated panel and the geometrical sizes of the stopper 916 are chosen in a way, that the cylinder flange of the stopper 916 abuts to the perforated board, and another flange in the shape of truncated cone 998 abuts the longitudinal rod 922 of the 3D prefabricated construction module. Also, it is to be noted that the stopper 916 serves to assist in forming a cell for vertical reinforcement rods 920 installation, and after their installation, serves also as a positioner for installation of the horizontal reinforcement rods 940. Due to the conical shape of the flange 998 of stopper 916, the horizontal rods 940 slip inside and press the vertical rod 920 providing the best position for strengthening the reinforced concrete wall.
[00197] Also, said stopper detail permits easy unscrewing of the mushroom-io shaped connector and removal of the 3D prefabricated construction module perforated panel from an erected wall after wall concreting and concrete hardening.
(00198] With reference to Figure 18E, mushroom-shaped connector 936 is shown in details and is preferably made from any composite material, which provides is connection with the horizontal mesh transverse rod 914 with a tensile strength of 120-250 kg. It is made most preferably from glass fiber reinforced polypropylene.
Cap portion of the mushroom-shaped connector preferably has a diameter of 45-70mm and a width 2-4mm and typically is designed so that there are features that permit for rotation of the leg with utilization of a mechanical tool.
[00199] Preferably the first portion of the mushroom-shaped connector leg has a cylinder shape and diameter 8-12mm and length 30-40mm, as well as "blinds cavity in the form of cylinder with depth 30-40mm and diameter as 70-85% from diameter of the end of the transverse rod of the connecting mesh. The "blind" cavity acts as a 2s nut after joining the end of the mesh transverse rod. The cylinder portion of the connector is provided for connection with cavity 990. The second portion of the leg .
preferably has the form of a truncated cone 942 with the angle of the lirbe of deflection forming the cone to the base of the cone being an angle 5-10° and a height 30-40mm. The cone portion is intended for blocking the openings in the walls of the perForated polystyrene panel during prefabrication of the construction module.

[00200] The third leg portion 941 also preferably has a shape of the truncated cone, which has the angle of the line deflection forming the cone to the basis of the cone to 30-60° and height 10-20mm, and intended for deformation of the openings walls of the polystyrene perforated panel and blocking the openings walls of the perforated polystyrene panel during prefabrication of the 3D prefabricated construction module and tightening two consequently installed 3D prefabricated construction modules by means of utilization of the panels bracers.
[00201] Connection of two panels (rotation of said mushroom-shaped connector) is to accompanied by formation of indentation on the side surface of the said leg in the shape of helical spiral by means of threading tool of the panel flat connector; wherein preferably the spiral step matches the helical indentation step in the "blind"
cavity of the connector, which is formed while connecting the connector and horizontal mesh transverse rod.
[00202] Figure 18F shows mushroom-shaped connector 936 in end view, wherein the cap portion 927 of the cylinder is provided without eccentricity with respect to the shaft portion.
[00203] Figures 18E and 18F show connector 936 provided in the shape of torsion figure with the surfaces formed with polygonal line rotating around longitudinal, central axis of the connector 936. Gonnector 936 can be considered as a result of co-axial and consequent connection between the cylinder (cap portion), first truncated cone (front part of the leg portion), second truncated cone (medial part of 2s the leg portion) and cylinder with a cylinder "blind" cavity in it (back part of the leg portion).
[00204] The effect of using connector 936 is that during its joint action with the stopper component 916, the perforated panels of the 3D prefabricated construction 3o module can be easily removed after erection of the reinforced concrete wall for the next utilization. Also, this has a good effect for building concrete walls with prefabricated 3D construction module requiring an architectural surface. For this purpose, at least one perforated panel of the said construction module should have a negative 3D pattern on the surface facing another panel of the module. After s concrete hardening, said panel is removed and wall surface has a 3D positive pattern.
(00205] Figures 18G and 181 illustrate a 3D prefabricated construction module using connectors 936 and stoppers 916 and in which only one type of combination of io longitudinal and transverse elements in the form of horizontal meshes as per Figure 18 is used. Module 900 also utilizes installed vertical rods of Figure 6 and reinforcement rods similar to horizontal reinforcement rods in accordance with Figures 14A, 14B, 15A, 158. A cell 925 for installation of vertical reinforcement rod 920 is provided by the side surface of the truncated cone 998 of the stopper element is 916 and the side surface of flange 919.
(00206] in Figure 18H, the joining of the mushroom-shaped connector 926 with the horizontal mesh transverse rod end 914a in the stopper cylinder cavity 990 is shown in detail. This joining provides the possibility to remove the polystyrene~pertorated 2o panels after the erected reinforced concrete wall concreting. Additionally, utilization of stopper provides the sufficient reinforcement of the erected reinforced concrete ~r~all. It is advised to note, that embodiment of the present invention is possible also with the stopper details in accordance with Figures 9 and 10.
2s i00207~ With reference to Figures 19, 20A to 20Q, the basic process is shown of forming a reinforced concrete wall, which is erected on concrete footing 800 with 3D
prefabricated construction modules 200. With reference to Figure 19, the concrete footing with installed vertical extensions of reinforced rods is shown. The interval between rods in the longitudinal rows equals the distance between the center of the 30 cells of the 3D prefabricated construction module. The concrete footing has a cavity required for the connection of the reinforced concrete wall and concrete foundation.

Vertical reinforced rods 120 are installed in said cavity abutting the reinforcement extensions from footing providing overlapping of reinforcement and a strong connection between the wall and foundation. Overlapping usually has a length of 30-60 diameters of overlapping rods and preferably 40 diameters of the said rods.
In s order to make 3D prefabricated construction module installation easier, the vertical extensions should be higher than the vertical horizontal plane of the footing but less than the distance between top surface of footing and lower horizontal combination transverse and horizontal elements of the 3D prefabricated construction module.
Preferably, the reinforcement bar used for reinforcement of the reinforced concrete io walls has a diameter of about 10mm. Accordingly, the overlapping equals about 400mm. Considering that the lower mesh .layer of the 3D prefabricated construction module is preferably placed not higher than 100mm, extensions from footing should have length not less than 400mm and their upper end should not be higher than 100mm above top surtace of footing. The cavity depth should be not less than is 300mm.
[00208] The cavity width of the concrete footing is preferably equal or less than the thickness of the reinforced concrete wall erected with 3D prefabricated construction modules 200. The distance between longitudinal rows of the reinforcement 2o extensions should be in accordance with the distance between centers of longitudinal rows of the cells of meshes for installation of the vertical rods.
[00209] With reference to Figure 20A, a first panel 200a is attached to footing 800.
It should be noted that extensions of reinforced rods 802 are installed for overlapping 2s with the vertical reinforcement rods 120 (see Figure 20J). The extension lengths of bars 802 must provide the required overlapping with the vertical rods installed in the 3D prefabricated construction module, and the extensions top is located lower than the bottom of the lower horizontal mesh of the 3D prefabricated construction module.
30 [00210] As shown in Figure 20A connector plates 804 are then inserted in grooves 213 of the panels in 3D prefabricated construction module 200a and then, as shown 4~
in Figure 20B, a second 3D prefabricated construction module 200b is brought into connection with module 200x, by horizontal thrust of the 3D prefabricated construction module 200b towards the earlier installed 3D prefabricated construction module 200a, and lowering the 3D prefabricated construction module onto the footing reinforcement extensions 802. Thereafter, a third 3D prefabricated construction module 2000 can be added to the combination of 3D prefabricated modules 200a and 200b in the same manner.
[00211) To provide the overlapping with vertical reinforcement rods and footing io extensions, vertical reinforcement bars are installed in the groove or cavity 803 in parallel to the extension rods. Groove 803 is intended also for receiving the ends of reinforcement vertical rods. The groove width is typically not more than the thickness of the erected reinforced concrete construction.
is [00212) Figures 20C, 20D, 20E and 20F provide a detailed illustration of the sequence of steps for joining two panels 210a and 210b, which belong to two connecting 3D prefabricated construction modules. The arrangement of the joint between the panels when a strip or plate 804 having wedge-type surface on one side of the plate is introduced into a groove 213 in a pair of opposed panels can be 20 observed.
[00213) The plate 804 is preferably made from rigid material, for instance:
plastic, metal, composite material or waterproof cardboard. After its installation, the plate is held in the vertical groove of the panel. The plate can be held just because of friction 2s forces with groove walls, or it can be held with adhesives, pins or similar. The strip has wedge front or end portions only from one side of the strip.
[00214) As illustrated in Figures 20D-20F, when the plate is thrust into the grooves 214 of the panels, it the wedge portion contacts the inner edges of the vertical 3o groove. The effect is that the panel edges are deflected in the direction of the arrows 4s on Figure 20F. This continues until the end faces of the approaching panel meet the ends of the other panel.
[00215] In Figure 20F it will be observed that joined panels 210a, 210b have air gaps in the grooves 213, when the plate 804 is installed. This is optional for better connection.
[00216] In Figure 20G, an end fragment of two 3D prefabricated construction modules connected during erection of the reinforced concrete wall is illustrated.
io Connectors 236 are shown with cut helical groove on the connectors cone surface, the groove having been cut by panel bracer 480 shown on Figure 8A. Also, the cells for vertical reinforcement rods installation are shown. Also, the mushroom-shaped connector abutment into the panel plate-type strainer is shown, is [00217] With reference to Figure 20H, the installation of bracers 480 to firmly connect panels 210a, 210b and 210c is shown. Connectors 236 of panels 210c and 21 Ob are partly unscrewed anti-clockwise to permit the bracers 480 to be placed over the cone portions of the connectors 480, with this, ends of panels are not in abutment between themselves (see Figure 20E). After placing bracers on the 2o connectors of the panels 210b and 21 Oa, the connectors 236 are screwed back clockwise, causing the helical indentation in the cone portion to be established and abutment of the ends of the panels 210b and 210a as shown on Figure 20F. The effect is to draw the adjacent panels towards each other. Horizontal movement of the 3D prefabricated construction module is shown by a horizontal arrow. Also, a gap 2s between the third and the second connecting panels is shown; this gap disappears after installation of plate-type strainers on the mushroom-type connectors and following screwing of those, as shown in the joining of the first and the second 3D
prefabricated construction modules.

[00218] After installation of ail plate-type bracers, temporary scaffolding is provided (scaffolding is not shown) to verify the verticality of the modules and this permits the final preparation of the 3D prefabricated construction module for the period of concreting.
[00219] Figure 201 illustrates the installation of the vertical rod members 120 into the retention cells and into cavity of footing. Figure 20J provides a perspective view of a 3D prefabricated construction module placed on the concrete footing with installed vertical rods shown on Figure 6A, which are overlapped with reinforcement io extensions from footing on Figure 19. A portion of the perforated panel is cut away for clarity.
[00220] In Figures 20K and 20L, the installation of horizontal reinforcement members 540 is illustrated. In Figures 20M and 20N, the pouring into the cavity is formed between the panels is shown. The broken line shows the top level of concrete pouring to provide the overlapping of the vertical reinforcement rods of the reinforced concrete wall top layer.
[00221] Figures 200 to 20Q illustrate how the wall of Figures 20M and 20N can be 2o enlarged by assembling and connecting additional 3D prefabricated construction modules 200d, 200e and 200f above3D prefabricated construction modules 200a, 200b, and 200c and securing them with additional bracers 480, in the same manner described above.
2s [00222] Both horizontal reinforcement meshes and vertical rods are added to the combined wall form, which can thereafter be filled with unhardened concrete.
[00223] : There is another feature of some of the foregoing construction modules which has advantages over known module. Known types of prefabricated 3D
3o construction modules when used as a form, have mechanisms of connecting panels and transverse elements, which do not allow the creation of a pattern on the surface of a concrete wall. After removal of known panels following concrete hardening, connection mechanism elements will extend from the surface of the concrete wall.
This is also true of some embodiments referenced above. For example in the s module of Figure 3: it is easy to remove connector 236, but the rod end 314a will extend from the wall. Or in Figure 17, see connector 2336 and rod end 2014a.
Other known designs do not allow possibility to remove pane! without destroying it.
Even after such panel removal, connection element will extend from concrete surface.
However, as illustrated in Figure 18h, the connection mechanism allows easily to unscrewing connector 926, and the removal of the panel after concrete hardening.
Additionally there will be no extensions, only small openings on the wall surFace, which can be easily sealed at the finishing step. With this, a panel can make a negative pattern on the outside face of the wall and at the same time be used repeatedly. .

Claims (70)

1. A 3D construction module comprising:
a) A vertically upstanding panel oriented generally longitudinally;
b) First and second mesh layers oriented generally transversely and longitudinally, each of said first and second mesh layers comprising at least one rod member mounted to said panel, said first and second mesh layers being vertically spaced from each other;
said at least one rod member of said first mesh layer configured to co-operate with said at least one rod member of said second mesh layer to form a first horizontally projected retention cell to restrict translation of a bar held in said retention cell between said first and second mesh layers;
whereby said first retention cell forms a generally vertically oriented opening for receiving a vertical reinforcement member and said retention cell restricts translation movement longitudinally and transversely of a vertical reinforcement member held in said retention cell.

2. A 3D construction module as claimed in claim 1, further comprising a third mesh layer oriented generally transversely and longitudinally, said third mesh layer comprising at least one rod member mounted to said panel;
said first, second and third mesh layers being vertically spaced from each other;
said at least one rod member of said second mesh layer configured to co-operate with said at least one rod member of said third mesh layer to form a second horizontally projected retention cell to restrict translation of said vertical reinforcement member held in said second retention cell between said second and third mesh layers;

whereby said first and second retention cells form a generally vertically oriented opening for receiving said vertical reinforcement member therein and said first and second retention cells restrict translation movement longitudinally and transversely of a vertical reinforcement member held in said first and second retention cells and restrict rotation of said vertical reinforcement member about both a longitudinal axis and a transverse and of the said 3D construction module.

3. A 3D construction module as claimed in claim 2 where each of said first, second and third mesh layers comprises a generally transversely oriented rod member and a generally longitudinal oriented rod member fixedly attached to said transverse rod member;
and wherein said transverse rod member and said longitudinal rod member of said first mesh layer are configured to co-operate with said transverse rod member and said longitudinal rod member of said second mesh layer to form a first horizontally projected retention cell that is generally rectangular in shape, so as to restrict said translation and said rotation of said vertical reinforcement held in said first retention cell between said first and second mesh layers; and said transverse rod member and said longitudinal rod member of said second mesh layer are configured to co-operate with said transverse rod member and said longitudinal rod member of said third mesh layer to form a second horizontally projected retention cell that is generally rectangular in shape, so as to restrict said translation and said rotation of said vertical reinforcement member held in said second retention cell between said second and third mesh layers.

4. A 3D construction module as claimed in claim 4 further comprising a vertical reinforcement member held in said retention cell.

5. A 3D construction module as claimed in claim 2 further comprising at least one connector associated with said panel and each of said first, second and third mesh layers, each said at least one connector for engaging said at least said one rod member of each said first, second and third mesh layer to mount said first, second and third mesh layers to said panel in vertically spaced relation to each other.

6. A 3D construction module as claimed in claim 5 wherein said panel has a body and said at least one transverse rod member of at least one mesh layer has an end made as a machine tap that is received into said body of the panel and into an inner cavity in said connector, whereby rotation of said connector around a longitudinal axis of said transverse rod taps a helical groove in the inner cavity of said connector and draws said end of said at least one rod into said body of the panel.

7. A 3D construction module as claimed in claim 1, further comprising at least one connector associated said panel and with each of said first and second mesh layers for engaging said at least said one rod member of each said first and second mesh layers, each said at least one connector for engaging said at least said one rod member of each said first, and second mesh layers, to mount said first and second mesh layers to said panel in vertically spaced relation to each other.

8. A 3D construction module as claimed in claim 7 further comprising a stopper member mounted to each of said transverse rod members of said first, second and third mesh layers, said connector having a cap portion and a leg portion, the leg of said connector abutting the stopper member and said panel being substantially positioned between said cap portion of said connector and said stopper member.

9. A 3D construction module as claimed in claim 8 wherein each of said stopper members are transversely fixed in relation to their respective said transverse rod members, such that said stopper members co-operate with said connectors to position said mesh layers relative to an inner surface of said panel.

10.A 3D construction module as claimed in claim 9 wherein said stopper member comprises a flange member having a flange and an axial passageway for receiving said transverse member there through, said flange member movable axially on said transverse rod member, said flange being in abutment with an end of said leg portion of said connector and an inner surface of said panel, whereby said flange member will co-operate with said connector to properly connect with transverse rod of the mesh layer and with said panel to properly position said inner surface of said panel relative to said transverse and longitudinal rod members.

11.A 3D construction module as claimed in claim 10 wherein said connector is also adapted to engage said panel whereby said connector will resist transversely outward forces and moments exerted against said inner surface of said panel.

12.A 3D construction module as claimed in claim 11 wherein said connector has a blind cylindrical opening accessible from an inner surface of said panel, the shape of said connector being a figure of rotation of a line around a central transverse axis along said cylindrical opening, said shape of said connector comprising three consequently connected figures of rotation, comprising a first figure having a shape of a cylinder, a second figure having a shape of a truncated cone and a third figure having a shape of a cylinder; said first figure inhibiting displacement of said connector towards said inner surface of said panel.

13.A 3D construction module as claimed in claim 12 wherein said first figure of rotation is formed about a first axis, and said second and third figures of rotation are formed about a second axis, oriented parallel to said first axis, said first axis being spaced from said second axis.

14.A 3D construction module as claimed in claim 1 wherein said panel is made from a nonflammable material.

15.A 3D construction module as claimed in claim 1 wherein said panel is made from a meltable material.

16.A 3D construction module as claimed in claim 15 wherein said panel is made from extruded or expanded polystyrene.

17.A 3D construction module as claimed in claim 16 wherein said panel has a base and wherein said module further comprises a trough element affixed to said base of said panel, said trough having a reservoir of sufficient size to hold the material of said panel when said panel is subjected to sufficient heat from a heat source, to melt said panel material, said panel material flowing into said reservoir when melted by said heat source.

18.A 3D construction module as claimed in claim 15 wherein said panel has a base and wherein said module further comprises a trough element affixed to said base of said panel, said trough having a reservoir of sufficient size to hold the material of said panel when said panel is subjected to sufficient heat from a heat source, to melt said panel material, said panel material flowing into said reservoir when melted by said heat source.

19.A 3D construction module as claimed in claim 3 further comprising a vertically upstanding second panel oriented generally longitudinally; said at least one rod members of each said first, second and third mesh layers being are mounted to said second panel, wherein said first and second retention cells are positioned between said first and second panels.

20.A 3D construction module as claimed in claim 19 wherein said first and second mesh layers comprise a plurality of rod members mounted to said first and second panels, to provide for a plurality of longitudinally and transversely spaced retention cells in each of said first and second mesh layers.

21.A panel for use in a 3D construction module, said panel comprising:
a body with a thickness, said body having a pair of opposed, generally parallel and flat, longitudinal surfaces;

a plurality of spaced openings passing through said body, said openings arranged in a first row of openings, said first row of openings being oriented at angle to said longitudinal surfaces.

22. A panel as claimed in claim 21 wherein said plurality of openings further comprises a second row of spaced openings passing through said body, said second row of openings being vertically spaced on said body from said first set of openings, said second row of openings being oriented at said angle to said longitudinal surfaces of said body and parallel to said first row of openings.

23. A panel as claimed in claim 22 wherein said first row of openings are at a first even spacing, said first row being at a first longitudinal position on said body, and said second row of openings are evenly spaced at said first spacing, and said second row being at a second longitudinal spacing, such that said first and second rows of openings from a first parallelogram pattern on said body.

24. A panel as claimed in claim 23 wherein said plurality of openings further comprises a third row of spaced openings passing through said body, said third row of openings being vertically spaced on said body from said first and second sets of openings, said third row of openings being oriented at said angle to said longitudinal surfaces of said body and parallel to said first and second rows of openings, said second row being vertically positioned between said first and third rows of openings, and wherein said third row of openings are at a first even spacing, said third row being at a first longitudinal position on said body, and said third row of openings are evenly spaced at said first spacing, and said second row being at said first longitudinal spacing, such that said second and third rows of openings form a second parallelogram pattern on said body, oriented vertically opposite to said first parallelogram pattern.

25. A panel for use in a 3D construction module, said panel comprising:

a body with a thickness, said body having a pair of opposed, generally parallel and flat, longitudinal surfaces:
a plurality of spaced transverse openings passing through said body, said openings arranged in a first row of openings and a second row of spaced openings, said second row of openings being vertically spaced on said body from said first set of openings and generally parallel to said first row of openings, and being longitudinally off-set from said first row openings.

26.A panel as claimed in claim 25 wherein said first and second rows of openings are substantially evenly spaced at a constant spacing.

27.A connector to connect a panel to a rod member, said connector having a cap portion with a first central longitudinal axis and a body portion with second longitudinal axis being displaced from said first longitudinal axis, said body portion having a cavity adapted to engage a rod member.

28. A connector as claimed in claim 27 wherein said connector is made substantially from a suitable plastic.

29. A connector a claimed in claim 28 wherein the plastic is glass fiber reinforced polypropylene.

30. A bracer for securing two connectors together, said bracer comprising a generally C-shaped body having a medial portion and first and second spaced leg portions, each of first and second leg portions having an inner face, the inner face of said first leg portion being positioned opposite to the inner face of said second leg portion, each said inner face having a blade forming a tapping tool, wherein when a blade is in contact with a connector, and said connector is rotated, said blade forms a helical indentation in an outer surface of said connector to secure said blade on said connector.

31. A bracer as claimed in claim 30 in combination with a 3D construction module comprising a panel, a pair of transverse rods and two connectors, each said connector being mushroom shaped; said connectors are connected with transverse rods of the 3D construction modules; said body of said bracer being between an outer surface of the panel and the surface of the cap portion of each connector inward of the panel.

32.A bracer as claimed in claim 30 wherein said bracer is made substantially from a suitable metal.

33.A 3D construction module comprising:
a) First and second vertically upstanding, spaced apart panels oriented generally longitudinally;
b) First and second mesh layers oriented generally transversely and longitudinally, each of said first and second mesh layer comprising at least one rod member mounted to each of said first and second panels, said first and second mesh layers being vertically spaced from each other;
said at least one rod member of said first mesh layer configured to co-operate with said at least one rod member of said second mesh layer to form a first horizontally projected retention cell to restrict translation of a vertical reinforcement bar held in said retention cell between said first and second mesh layers;
c) a vertical reinforcement bar held in said retention cell;
whereby said retention cell forms a generally vertically oriented opening for receiving said vertical reinforcement member, said retention cell restricts translation movement longitudinally and transversely of a vertical reinforcement member held in said retention cell.

34.A 3D construction module comprising:
a) First and second vertically upstanding, spaced apart panels oriented generally longitudinally;
b) First and second mesh layers oriented generally transversely and longitudinally, each of said first and second mesh layer comprising at least one rod member mounted to each of said first and second panels, said first and second mesh layers being vertically spaced from each other;
said at least one rod member of said first mesh layer configured to co-operate with said at least one rod member of said second mesh layer to form a first horizontally projected retention cell to restrict translation of vertical reinforcement bars held in said retention cells between said first and second mesh layers;
c) a first vertical reinforcement bar held, respectively, in said first retention cell;
whereby said first and detention cells form first and second generally vertically oriented openings for receiving respectively, said first and second vertical reinforcement members, said first and second retention cells respectively restricting translation movement longitudinally and transversely of said first and second vertical reinforcement members held in said retention cell;
d) a horizontal reinforcement mesh comprising first and second reinforcement bars oriented generally longitudinally, said first and second horizontal reinforcement bars being interconnected by at least one transverse connecting rod member, said horizontal reinforcement mesh being received between said first and second panels with said first and second horizontal reinforcement bars being oriented generally longitudinally and said first horizontal reinforcement bar being in abutment said first vertical reinforcement bar so as to tend to push said first vertical reinforcement bar transversely outward toward said first panel.

35.A 3D construction module as claimed in claim 34 wherein each said second horizontal reinforcement bar is in abutment a second vertical reinforcement bar so as to tend to push said second vertical reinforcement bar transversely outward toward said second panel.

36. A combination of a panel and a trough element for use in a 3D construction module, said parcel made of a meltable panel material and comprising a body with a thickness, said body having a pair of opposed, generally parallel and flat, longitudinal surfaces and a base;

a trough element affixed to said base of said panel, said trough having a reservoir of sufficient size to hold the material of said panel when said panel is subjected to sufficient heat from a heat source, to melt said panel material, said panel material flowing into said reservoir when melted by said heat source.

37. A combination as claimed in claim 36 wherein said trough element is made from a metal.

38.A combination as claimed in claim 37 wherein said panel material is expanded or extruded polystyrene.

39. A construction combination comprising:

a) a mesh comprising a first longitudinal rod member and a plurality of transverse rod members connected to said longitudinal rod member;

b) a stopper member for each of said plurality of transverse red members, each stepper member having a leg portion and a first flange portion, and an axial passageway through said leg portion and said first flange portion, said passageway for freely receiving a rod member there through, said stopper member movable axially on said rod member, said first flange portion adapted to be moved into abutment an inner surface of a panel, said leg portion adapted to be moved into abutment with said longitudinal member, whereby said flange member can co-operate with connector connecting said panel with a transverse rod to properly position said connector and can co-operate with said panel to properly position said inner surface of said panel relative to said longitudinal member.

40.A combination as claimed in claim 39 wherein said leg portion abuts are end face of said stopper member to properly position said connector.

41.A combination as claimed in claim 39 wherein said leg portion has an end for abutting said longitudinal member and wherein said stopper member has a second flange portion mounted on said leg portion and being spaced from said end of said leg portion, said combination providing an opening between said second flange portion and said longitudinal member for receiving a reinforcement member therebetween, said second flange portion and said longitudinal member adapted to restrict transverse movement of said reinforcement member and position said reinforcement member relative to said panel.

42.A connector to connect a panel to a rod member, said connector having a cap portion, a first body portion having an outer surface shaped as a truncated cone portion, said first body portion having its outer surface narrow towards a connection with a second body portion, said second body portion having an outer surface that is generally cylindrical, said second body portion having a inner cavity adapted to engage a rod member.

43.A connector as claimed in claim 42 wherein said connector is made substantially from a suitable plastic.

44.A connector a claimed in claim 43 wherein the plastic is glass fiber reinforced polypropylene.

45.A 3D construction module comprising:

First and second mesh layers oriented generally transversely and longitudinally, each of said first and second mesh layers comprising a plurality of transversely oriented, and spaced transverse rod members, each of said transverse rod members having an end adapted for mounting to a panel, said plurality of transverse rod members being interconnected to first end second longitudinally oriented and spaced longitudinal rod members, said first and second mesh layers being vertically spaced from each other;

At least one of said transverse rod members and one of said first and second longitudinal rod members of said first mesh layer configured to co-operate with at least one of said transverse rod members and one of said first and second longitudinal rod members of said second mesh layer to form a first horizontally projected retention cell to restrict translation of a bar held in said retention cell between said first and second mesh layers;

whereby said first retention cell forms a generally vertically oriented opening for receiving a vertical reinforcement member and said retention cells restrict translation movement longitudinally and transversely of a vertical reinforcement member held in said retention cell.

46. A 3D construction module as claimed in claim 45, further comprising a third mesh layer oriented generally transversely and longitudinally, said third mesh layer comprising a plurality of transversely oriented, and spaced transverse rod members, each of said transverse rod members of said third mesh layer having an end adapted for mounting to a panel, said plurality of transverse rod members being interconnected to first and second longitudinally oriented and spaced longitudinal rod members said first, second and third mesh layers being vertically spaced from each other, At least one of said transverse rod members and one of said first and second longitudinal rod members of said second mesh layer configured to co-operate with at least one of said transverse rod members and one of said first and second longitudinal rod members of said third mesh layer to form a second horizontally projected retention cell to restrict translation of a bar held in said retention cell between said second and third mesh layers;

whereby said first and second retention cells form a generally vertically oriented opening for receiving said vertical reinforcement member therein, and said first and second retention cells restrict translation movement longitudinally and transversely of a vertical reinforcement member held in said first and second retention cells, and restrict rotation of said vertical reinforcement member about both a longitudinal axis and a transverse axis.

47. A 3D construction module as claimed in claim 46 wherein said transverse rod member and said longitudinal rod member of said first mesh layer are configured to co-operate with said transverse rod member and said longitudinal rod member of said second mesh layer to form a first horizontally project retention cell that is generally rectangular in shape, so as to restrict said translation and said rotation of said vertical reinforcement held in said first retention cell between said first and second mesh layers; and said transverse rod member and said longitudinal rod member of said second mesh layer are configured to co-operate with said transverse rod member and said longitudinal rod member of said third mesh layer to form a second horizontally projected retention cell that is generally rectangular in shape, so as to restrict said translation and said rotation of said vertical reinforcement member held in said second retention cell between said second and third mesh layers.

48. A 3D construction module as claimed in claim 47 wherein said longitudinal and transverse rod members of each mesh layer are rigidly interconnected to each other to provide a rigid mesh layer structure.

49. A 3D construction module as claimed in claim 48 further comprising a vertical reinforcement member held in said retention cell.

50. A 3D construction module as claimed in claim 49 further comprising a stopper member mounted to said end of each of said transverse rod members of said first, second and third mesh layers.

51. A 3D construction module as claimed in claim 49 wherein each of said stopper members is transversely fixed in relation to their respective said transverse rod members, such that said stopper members is adapted to co-operate with a connectors to position said mesh layers relative to an inner surface of a panel.

52. A 3D construction module as claimed in claim 51 wherein said stopper is in the form of washer having a cylindrical opening, said washer being threaded onto an end portion of said transverse member, said end portion having a helical thread.

53. A 3D construction module as claimed in claim 52 wherein said stopper member comprises a flange member having a flange and an axial passageway for receiving said transverse member there through, said flange member movable axially on said transverse rod member, said flange being in abutment with inner surface of said panel, whereby said flange member will co-operate with said connector and said panel to properly position said inner surface of said panel relative to said transverse and longitudinal rod members.

54. A stopper member comprising:
a cylindrical body portion having a first end and a second end, and having a first axial passageway open from said first end and said second end a first flange member formed on said body at said first end;
a second flange member formed on said body at said second end a second body portion joined to said first body portion at said second end, said second body portion having a second axial passageway that is narrower than said first axial passageway, said second body portion having a first generally cylindrical portion adjoining said second flange member, and a truncated conical flange portion, said truncated conical flange portion and said second flange member providing a cavity therebetween for holding at least one rod member therebetween.

55. A stopper member as claimed in claim 54 in combination with a connector for connection a panel to a rod member, said connector having a cap portion and an elongated body portion having an outer surface that is generally cylindrical, said elongated body portion having an inner cavity adapted to engage said rod member, said elongated body of said connector being receivable in said first axial passageway of said stopper member, said elongated body portion being movable into abutment with said second body portion of said stopper in said first axial passageway, wherein said transverse rod member is receivable through said second axial passageway of said second body portion, into said inner cavity of said connector, held in said first axial passageway of said stopper member.

56. A stopper member as claimed in claim 54 in combination with a panel member held between said cap portion of said connector and said first flange member.

57. A stopper member as claimed in claim 55 in combination with a reinforcement member held in said cavity between said second flange member and said truncated conical flange portion.

58. A system for creating a concrete form comprising said first and second panels arranged such that said first and second panels are in longitudinal, upstanding and abutting alignment, said first panel unit has a leading side face and said second panel having a trailing side face, each of said leading side face and said trailing side face being generally in abutment with each other, each of said leading side face and said trailing side face having a centrally positioned, elongated groove, and said system further comprising a separate elongated plate member and said leading face has on one side of said groove a side flange portion, and said trailing face as an opposed side flange portion opposite to said side flange portion of said leading face, and wherein when said panels are disconnected, the width pat said groove is smaller than the width of said plate and said side flange portions are angled toward each other, and wherein when said plate is inserted into said groove portions to put said first arid second panel in abutting alignment, said grooves are widened, to permit said plate to be received therein, and said side flanges are displaced outwards to provide face to face mating alignment of said side flanges.

59. A system as claimed in claim wherein said plate member is wedge shaped, so that when said plate member is received into said grooves, said side flanges are levered outward to provide for said meting alignment.

60. A method of fabricating a construction module comprising:
a) providing a vertically upstanding panel oriented generally longitudinally;
b) Securing fist and second mesh layers to said panel such that they are oriented generally transversely and longitudinally, each of said first and second mesh layers comprising at least one rod member mounted to said panel, and said first and second mesh layers being arranged in vertically spaced relation to each other;
c) arranging said at least ore rod member of said first mesh layer and said at least one rod member of said second mesh layer to fore a first horizontally projected retention cell to restrict translation of a bar held in said retention cell between said first and second mesh layers;
whereby said first retention cell fortes a generally vertically oriented opening for receiving a vertical reinforcement member and said retention cell restricts translation movement longitudinally and transversely of a vertical reinforcement member held in said retention cell.

61. A method as claimed in claim 60, further comprising:
a) securing a third mesh layer to said panel oriented generally transversely and longitudinally, said third mesh layer comprising at least one rod member mounted to said panel, such that said first, second and third mesh layers are vertically spaced from each other;
b) arranging said at least one rod member of said second mesh layer and said at least one rod member of said third mesh layer to form a second horizontally projected retention cell to restrict translation of said vertical reinforcement member held in said second retention cell between said second and third mesh layers;
whereby said first and second retention cells from a generally vertically oriented opening for receiving said vertical reinforcement member therein, and said first and second retention cells restrict translation movement longitudinally and transversely of a vertical reinforcement member held in said first and second retention cells, and restrict rotation of said vertical reinforcement member about both a longitudinal axis and a transverse axis of the said 3D construction module.

62. A stopper member in combination with a connector:
said connector having a leg portion adapted to connect to a rod member;
said stopper member comprising:
a body portion having a first end and a second end, and having a first axial passageway open from said first end and said second end;
a second body portion having a third end and a fourth end, said second body portion joined at said third end to said first body portion at said second end of said first body portion, said second body portion having a second axial passageway extending between said third end and said fourth end, that is narrower than said first axial passegeway, said second axial passageway being in communication with said first axial passageway from said third end to said second end;

said leg portion of said connector receivable into said first axial passageway of first body portion of said stopper at said first end to engage an end of a rod member receivable in said second axial passageway and extending from said fourth end, past said third end and said second end into said first axial cavity;
said connector and said stopper member adapted to hold a panel member and thereby connect said rod member to said panel member.

63. A connector for securing a rod member to a panel, said connector having a leg portion to be received through said panel to engage said rod member, said leg portion having a blind opening to a cavity for receiving said rod member therein to secure said leg portion to said rod.

64. A connector as claimed in claim 63 wherein said rod has a medial portion of a first diameter and an end portion of a second diameter that is smaller than said first diameter, such that said leg portion received said end portion of said rod member.

65. A connector as claimed in claim 64 wherein said medial portion acts as a stopper for said connector if said leg portion is brought into abutment with said medial portion.

66. A connector as claimed in claim 64 wherein said first end portion is formed as a machine tap, whereby the connection of said connector to said rod member is achieved by rotation of said connector drawing said rod member into said cavity to tap said inner cavity.

67. A connector as claimed in claim 66 wherein said medial portion acts as a stopper for said connector if said leg portion is brought into abutment with said medial portion.

68. A method of forming a construction element such as wall comprising:

a) prefabricating first and second construction modules, each of said modules comprising a pair of spaced apart panels oriented longitudinally, said pair of panels being interconnected by at least one mesh layer between said panels;
b) installing said first and second construction modules in longitudinal alignment;
c) installing vertical reinforcement in said first and second construction modules;
d) installing horizontal reinforcement in said first and second construction modules;
e) filling said first and second construction modules with unhardened concrete.

69. A method as claimed in claim 68 further comprising the step after (b) of connecting said first panels of said first module to the adjacent one of said panels of said second module.

70. A method as claimed in claim 68 further prefabricating a third construction module comprising a pair of spaced apart panels oriented longitudinally, said pair of panels being interconnected by at least one mesh layer between said panels; and after step (d) installing said third construction module above at least one of said first and second modules.