Customizable Stackable Modular Construction System

Abstract

A customizable, stackable, modular construction system having interconnected panels coupled mechanically using compatible coupling elements to assemble three-dimensional structures. Includes optional architectural components and electrical components. Electrical components are coupled with electrical wiring to a power source which is compatible with other electronic components such as Bluetooth enabled devices for remote control, light source, fans, electronic sensors, buzzers, photovoltaic panels, motors and batteries, amongst others. Architectural components, accessories and themed construction panels built from a variety of materials are coupled to create a modular construction that embodies different structural shapes and resembles a variety of architectural styles or scenes customized per the builder's preference.

Description

CROSS-REFERENCE TO RELATED APPLICATIONS

This application claims benefit to U.S. Provisional Patent Application No. 62/753,944 filed on Nov. 1, 2018 entitled “Customizable Stackable Modular and Electronic Construction Toy,” which is incorporated herein by reference for all purposes.

FIELD OF THE INVENTION

The invention relates to a customizable, stackable, modular construction system. In particular, a construction system that includes panels that interconnect mechanically using compatible coupling elements as well as including optional architectural and electrical components coupled with electrical wiring to a power source. When themed panels are coupled, the modular construction embodies different structural shapes and resembles a variety of architectural styles or scenes customized per the builder's preference.

BACKGROUND OF THE INVENTION

The use of construction systems as a holistic educational platform, for architecture, engineering, history, culture, arts, math, science, technology, programming, electronics and imaginative building amongst other fields.

SUMMARY OF THE INVENTION

The stackable modular construction system disclosed herein encourages engineering building and culturally inspired imaginative interaction via thematically designed basic modules comprised of mechanically interlocking wall panels coupled to a floor panel. Each panel includes two opposing surfaces, a thickness and at least three edges. At least one panel includes one trussed edge rim on all or portions of its edge's length. A trussed edge rim is configured by a series of repetitive alternating polygons. Trussed edge rims are configured such that panels may be connected mechanically between their trussed edges to form structures and/or scenes. In some embodiments, each edge of each panel is a trussed edge providing multiple ways of mating the modules when stacking or side by side. Its design facilitates assembly, structural integrity and maximum flexibility. Accordingly, the stackable modular construction system is easy to manipulate, assemble and disassemble.

The stackable modular construction system described herein comprise at least one basic module. Additional modules can be stacked upon each other and/or placed side by side to create a multiple story structure. When stacked, each basic module can be rotated relative to other modules below or above expanding re-construction-ability and encouraging design experimentation. Additionally, each stackable modular construction system packs in a compact and flat manner for easy storage, customization and transportation.

Any embodiment of the stackable modular construction system can be customized with a diversity of optional components and accessories which include but are not limited to a diversity of architectural components, electrical components, panel surface materials, accessories and embellishment elements all of which are compatible and connect with at least one stackable modular construction system component.

Architectural components may include but not limited to window and door accessories, stairs, elevators, and towers amongst others. Electrical components include but not limited to light source, fans, electronic sensors, buzzers, photovoltaic panels and motors amongst others coupled with electrical wiring to a power source such as a battery component and a hub. Electrical components may include a controller that allows a Bluetooth enabled device to remotely control other electrical components and/or a programmable controller equipped with sets of digital and analog input/output pins that may be interfaced to various expansion boards and circuits.

The stackable modular construction system is further customized by a diversity of surface materials and surface treatment of its wall and floor panels. These include but are not limited to illustration via print or tactile embossment, debossing, magnetic receptive material or coated with a smooth surface which allows non-permanent markings and erasing by its user. To further customize and embellish the structure, adhesive or magnetic accessory items can optionally be added to the face(s) of panels.

These and other features of the disclosed invention will be described in further details below in conjunction with the following drawings.

DESCRIPTION OF DRAWINGS

The present invention is illustrated by way of example, and not by way of limitation, in the figures of the accompanying drawings. In the following example illustrations, a stackable modular construction system of square polygon floor panel, represents a Middle Eastern architectural style. Whereas in the illustrations comprising a stackable modular construction system of hexagonal polygon base floor, a defense tower is represented. The disclosure's illustrations are not necessarily drawn to scale.

FIG. 1 depicts an exploded isometric view of modules showing how the modules can rotate relative to each other and then stacked together.

FIG. 2 depicts an isometric view of a square based construction example.

FIG. 3 depicts an isometric view of a hexagonal based construction example.

FIG. 4 depicts an example of interlocking wall panels with corresponding polygonal floor base shaped as a square. The square floor-based wall panels depict possible coupling slots, kerf cuts combinations, grid patterned perforations for attachments such as electrical and architectural components, possible openings and patterned surface designs or illustrations. A corresponding square-based floor panel showing example of protruding tabs, possible openings and patterned surface designs or illustrations.

FIG. 5 depicts an example of interlocking wall panels with corresponding polygonal floor base shaped as a hexagon. The hexagon floor-based wall panels depict possible coupling slots, kerf cuts combinations, grid patterned perforations for attachments such as electrical components, possible openings and patterned surface designs or illustrations. A corresponding hexagon-based floor panel showing example of protruding tabs, possible openings and patterned surface designs or illustrations.

FIG. 6 depicts example of kerf cuts combinations on wall panels.

FIG. 7 depicts an example of coupling of wall panel's slots with floor panel's protruding slabs.

FIG. 8 depicts examples of wall panel's optional ledges to provide additional support for the floor panels.

FIG. 9 depicts examples of possible truss designs. A series of repeating polygonal shapes alternating up and down in order to couple between modules.

FIG. 10 depicts examples of customizing architectural component accessory. This particular illustration depicts a typical Middle Eastern window, it's component parts and elevations.

FIG. 11 depicts the assembly steps of a typical Middle Eastern accessory window unto a basic module.

FIG. 12 depicts examples of customizing architectural component accessory. This particular illustration depicts a typical Middle Eastern wind tower, it's component parts and elevations.

FIG. 13 depicts the assembly steps of a typical Middle Eastern accessory wind tower unto a basic module.

FIG. 14 depicts an example of a customizing architectural component accessory. This particular illustration depicts a typical stair's component parts.

FIG. 15 depicts an example of a customizing electrical component accessory integrated in a wall panel. This particular illustration depicts a light source, wiring and power source components and their installation when attached to the grid like and pass through wall panel's perforations.

FIG. 16 depicts one example of the basic module's assembly by interlocking and coupling of wall and floor panels.

FIG. 17 depicts a second example of the basic module's assembly by interlocking and coupling of wall and floor panels.

FIG. 18 depicts the stacking of a four basic module assembly by coupling all edges of the corresponding polygonal shaped modules. A Middle Eastern styled stackable modular construction system is illustrated.

FIG. 19 depicts an isometric view of a four basic module assembly. A Middle Eastern styled stackable modular construction system is illustrated.

FIG. 20 depicts a basic module with electronic components attached onto the grid-like slots of the wall panel. An exterior wall directly mounted electric component comprising a wiring that passes through a wall opening to connect to an interior wall mounted power source battery. The power source battery is further connected to an interior wall mounted electric component in its housing.

FIG. 21 depicts a basic module with electronic components attached onto the grid-like slots of the wall panel. An interior wall mounted electric component in its housing connected by wiring to a power source battery. The power source battery is further connected via wiring that passes through a wall opening to connect to an electric component directly mounted to an exterior wall.

FIG. 22 depicts one of the two attachment methods for an electronic component to attach to the modular construction system's wall panel. The attachment is possible mechanically directly onto the panel. If electrical component is mounted on an exterior wall panel face, then its wiring passes through a wall opening on to its power source when the power source is attached to an interior wall.

FIG. 23 depicts one of the two attachment methods for an electronic component to attach to the modular construction system's wall panel. The attachment is possible via an electronic component housing which attaches with its protruding tabs onto the grid-like slot perforations slots in the wall panels.

FIG. 24 depicts three sets of electric wiring components. Each wiring includes at least one coupling feature such as a receptacle (female component) that can accept a plug (male component) from another electric component and/or a plug (male component) that can accept a receptacle (female component) from any other electric component.

FIG. 25 depicts an LED light electric component with its housing and protrusion tabs for coupling onto a wall panel.

FIG. 26 depicts a button electric component with its housing and protrusion tabs for coupling onto a wall panel.

FIG. 27 depicts a switch electric component with its housing and protrusion tabs for coupling onto a wall panel.

FIG. 28 depicts a buzzer electric component with its housing and protrusion tabs for coupling onto a wall panel.

FIG. 29 motor a button electric component with its housing and protrusion tabs for coupling onto a wall panel.

FIG. 30 depicts a Bluetooth enabled electric component with its housing and protrusion tabs for coupling onto a wall panel.

FIG. 31 depicts a temperature sensor component with its housing and protrusion tabs for coupling onto a wall panel.

FIG. 32 depicts a light sensor component with its housing and protrusion tabs for coupling onto a wall panel.

FIG. 33 depicts a touch sensor component with its housing and protrusion tabs for coupling onto a wall panel.

FIG. 34 depicts a sound sensor electric component with its housing and protrusion tabs for coupling onto a wall panel.

FIG. 35 depicts an LCD RGB display electric component with its housing and protrusion tabs for coupling onto a wall panel.

FIG. 36 depicts a base shield hub expansion board which allows the interconnection of multiple electric components in a central hub to a common power source. This base shield hub expansion board is optionally or temporarily coupled to a programmable controller equipped with sets of digital and analog input/output pins that may be interfaced to various electric components. The programmable controller is in a housing comprising protrusion tabs for coupling onto a wall panel.

FIG. 37 depicts a base shield hub expansion board coupled to a programmable controller further coupled via wiring to a power source and to an electric component.

FIG. 38 depicts a disconnected and then connected light source electric component with its wiring connectors to couple with a power source battery. The electric component connectors are coupled to the components using a receptacle and plug. Components can be either coupled directly to a battery component or a base shield hub or can be coupled via one or more wiring electrical connector components.

FIG. 39 depicts a disconnected and then connected sound sensor electric component with its wiring connectors to couple with a power source battery. The electric component connectors are coupled to the components using a receptacle and plug. Components can be either coupled directly to a battery component or a base shield hub or can be coupled via one or more wiring electrical connector components.

FIG. 40 depicts a series of elevations demonstrating the versatility of module stack ability of different numbers of basic modules assembled. All examples depict different height Middle Eastern styled stackable modular constructions.

FIG. 41 depicts some of the possible exterior elevation combinations of a two basic module assembly. A Middle Eastern styled stackable modular construction is illustrated.

FIG. 42 depicts some of the possible exterior elevation combinations of a three basic module assembly. A Middle Eastern styled stackable modular construction is illustrated.

FIG. 43 depicts some of the possible exterior elevation combinations of a four basic module assembly. A Middle Eastern styled stackable modular construction is illustrated.

FIG. 44 depicts some of the possible exterior elevation combinations of a five basic module assembly. A Middle Eastern styled stackable modular construction is illustrated.

DETAILED DESCRIPTION

The present disclosure will now be described in detail with reference to two preferred embodiments, thereof as illustrated in the accompanying drawings. Numerous details are explained in order to provide a thorough understanding of the present invention. It will be apparent, to one skilled in the art, that the present invention may be practiced without some or all of the specific details. In other instances, well known processes and components have not been described in detail in order to not obscure the understanding of the present invention.

Each basic module is comprised of one polygonal shaped floor panel 100, 102 and a plurality of wall panels 101,103. Each panel comprises of two opposing surfaces and at least three edges with a thickness. The number of wall panels on each basic module correspond to the number of sides of its polygonal floor panel shape. For example, with a square or rectangular floor panel FIGS. 1, 2 & 4 there will be four side wall panels 101 whereas with a hexagonal floor panel FIGS. 3 & 5 there will be six side wall panels 103 to that basic module.

Basic modules can have additional removable accessories, architectural 104 and electric components 105 attached to them such as ladders, stairs 106, elevators, wind towers 107, railings, balconies, terraces, windows 108, doors, towers, thematic background sceneries and electronics amongst others.

The floor panels can be shaped in any polygonal shape, such as a triangle, square 100, rectangle, pentagon, hexagon, octagon 102, etcetera depending on the architectural style the structure is representing. At least one of the floor panel's polygonal side edges will have one or more protruding tabs 109 compatible with slots 110 at the corresponding side wall panels. These slots and tabs serve as a fastener free mechanical coupling between floor and wall panels FIG. 7.

Each floor panel may be solid or may include one or more openings of different size and shape which allows the placement and attachment of additional architectural 111 and electronic components 112 such as but not limited to a ladder, a mechanical or electrical elevator, pulley system, balcony, terrace, wind tower 107 amongst others. Additional openings in the floor panel may be for embellishment or to allow for the optional fitting of electrical wiring and electrical components to be coupled directly or indirectly to another electrical component, electrical wiring or to a power source.

In an embodiment, the floor panel's surface may be printed, etched, carved, painted, drawn, embossed, debossed, engraved or by means of any other technique to produce a graphic or tactile image and/or design 113. These images and designs are one of the ways the modular construction system is customizable.

In another embodiment, the floor panel surface can allow non-permanent and erasable coloring and recoloring by its users using a non-permanent marker, which stimulates creativity and enables further customization of the structure.

In yet another embodiment, the floor panel's surface can be of a magnetic receptive material, magnetically attracting a magnetic accessory or component.

The amount of wall panels per basic module depends on the polygonal shape of the floor panel it is coupled with. Each wall panel will have at least one kerf cut 114 approximately half way down or up the wall panel's height. These kerf cuts are of a width substantially equal to the thickness of the panel.

Some of the kerf cuts will run from the top side and others from the bottom side of the wall panels. Every wall panel may have a single kerf cut or one of the following four combinations of kerf cuts: two kerf cuts running from the top side 115, two kerf cuts running from the bottom side 116, one kerf cut running from the top side and the second running from the bottom side 117 or a kerf cut running from the bottom side and the second from the top side (opposite to the previous wall panel) 118. These kerf cuts allow a fastener free assembly by sliding and interlocking wall panels to each other FIG. 6. All wall panels can be mixed and matched to create different design variations.

The lower portion of some of the wall panels may have slots 110 sized to be compatible with the floor panel's protruding tabs 109. These wall panel's slots and floor panel's tabs also serve as fastener free mechanical coupling element FIG. 7. Additionally, wall panels may have ledges 119 on the lower portion of the interior side in order to provide additional support for the floor panel FIG. 8.

Each wall panel comprises at least one trussed edge 120, on all or portions of the edge's length. Said trussed edge design is comprised by a series of repeating polygonal shapes such as triangles, squares, octagons, hexagons or any other polygonal shape of varying size and proportions alternating up and down on its horizontal axis. This series of repeating polygons which make up the truss design provides and improves significantly the structural stability of the structure.

The truss design is configured such that wall panels may be stacked and/or connected mechanically by mating with compatibly trussed panels, providing multiple ways of mating the modules when stacking. FIG. 9. The trussed edges provide structural stability and serve as a self-locking mechanism when the basic modules are stacked on top of each other.

The size and design of the polygons that define the truss can vary depending on the architectural style the structure is representing FIG. 9. But the same truss shape and size is used for the basic modules that stack on top of each other within the same modular construction system.

Each wall panel may be solid or may include one or more openings of different size and shape for doors 121, windows 122 and/or for access inside 123. These openings also allow the placement and attachment of additional architectural 124 and electronic components such as but not limited to a ladder, a mechanical or electrical elevator, pulley system, balcony, window box, terrace, wind tower etc. Additional openings in the wall panel may be for embellishment or to allow for the optional fitting of electrical wiring and electrical components to be coupled directly or indirectly to another electrical component, electrical wiring or to a power source 125. In particular, wires of the electronic components are passed through openings of different shapes, which may be, but not necessarily, organized in a grid like manner. These openings could be circles, triangles, squares, etc. big enough to allow the pass through of wires in order to connect to other electrical components.

In an embodiment, the wall panel's surface may be printed, etched, carved, painted, drawn, embossed, debossed, engraved or by means of any other technique to produce a graphic or tactile image and/or design 126. These images and designs are one of the ways the modular construction is customizable.

In another embodiment, the wall panel's surface can allow non-permanent and erasable coloring and recoloring by its users using a non-permanent marker, which stimulates creativity and enables further customization of the structure.

In yet another embodiment, the wall panel's surface can be of a magnetic receptive material, magnetically attracting a magnetic accessory or component.

For the basic module's construction, approximately half of the wall panels are assembled by sliding two wall panels of opposing kerf cuts, at a time, in order to interlock each other FIGS. 16 & 17 step 1. Then, the floor panel's protruding tabs couple into the wall panel's slots FIGS. 16 & 17 step 2. The remaining wall panels are slid into each other via the opposing kerf cuts interlocking all of the wall panels and coupling to the floor panel FIGS. 16 & 17 step 3 & 4. The optional ledges on the lower portion of the interior side of some of the wall panels provide additional support for the floor panel. The basic module assembly resembles an open top box of different polygonal shaped floor base.

The basic modules with the same polygonal floor base shape and mating truss design and proportions are able to be stack on top of each other creating a multi-story structure FIG. 18.

The truss design of the panels of these modules, typically located but not limited to the upper and/or lower rim of the wall panels serves as a self-locking mechanism on all sides of the polygon once the modules are stacked. When modules are stacked, the truss design prevents relative lateral movement of one module relative to its upper or lower module, locking it in place on every direction within each individual polygonal shape that make up the truss design FIG. 18.

The basic modules with the same polygonal floor base shape and mating truss design, dimension, contour and proportions which are stacked on top of each other may be rearranged in sequence and/or rotated on its vertical axis FIG. 1 to create a multitude of different design variations to the structure FIG. 19, 40, 41, 42, 43, 44.

The panels may be perforated in portions or all of its surface with equally spaced small perforations in a grid like pattern 127. This grid like pattern adapts to the flexible placement and attachment of the optional architectural and electronic components and/or accessories within the panels FIG. 15.

Additional architectural components enhance the basic module and customize the architectural design of a specific modular construction system to resemble a specific architectural style typical of a specific region or country. For example, if the modular construction system resembles a Middle Eastern architectural style then it would include additional architectural components such as “Roshan” styled windows, Middle Eastern style doors or wind towers amongst others FIGS. 10 & 12.

There are other basic additional architectural components such as ladders, stairs, elevators, wind towers, railings, balconies, terraces, windows, doors, towers, thematic background sceneries and others that are shared between different architectural styles. FIG. 14.

All additional customizing architectural components may assemble, attach, adhere and stack the same way as the basic modules by way of kerf cuts, tabs, slots and/or mating truss. Additional adherence comprises adhesion, static electricity, magnetic attraction, or mechanical attachment FIGS. 11 & 13.

Some of the accessories to further customize the modular construction system include, but are not limited to, furniture, human figures, animal figures, food, tools, household appliances, trees, flowers, light fixtures, containers or any other object of utilitarian or decorative design that are in-line with the particular architectural style of the structure it is representing.

Electric components are optionally integrated in the modular construction system in order to customize and integrate programmable electricity-based components transforming the modular construction system from a solely mechanical construction system into a platform for learning the application and programmability of electronic components 128, microcontrollers 129, Bluetooth 130 enabled technology and Internet of Things amongst others. The optional attachment of different electronic components is possible directly onto a modular construction system panel 131 or via an electronic component housing 132 which attaches to the equally spaced small slot perforations in a grid-like pattern 127 on the modular construction system's panels FIG. 15, 20, 21, 22, 23. The electrical component housing 132 comprises at least one protrusion tab 133 sized and shaped to engage with a mechanically compatible slot 127 or feature of one of the stackable modular construction system's panels. This grid-like slot pattern 127 adapts to the flexible placement of the electronic components within the modular construction elements. The optional integration of electronic components within the modular construction system enhances the usability encouraging the education of engineering concepts such as programming and electronics.

The modular construction system can be fitted with electrical wiring 134 that allows a variety of different electrical components to be coupled directly or indirectly to another electrical component, wiring and/or to a power source FIG. 38, 39. Each wiring includes at least one coupling feature. In one embodiment it could be a receptacle 135 (female component) that can accept a plug 136 (male component) from another wiring or any other electric component. In another embodiment it could be a plug 136 (male component) that can accept a receptacle 135 (female component) from another wiring or any other electric component FIG. 24.

Electric components include, but are not limited to, light source 137, button 138, switch 139, buzzer 140, motor 141, Bluetooth enabled devices 130 to remotely control the building or electronic sensors such as temperature sensor 142, light sensor 143, touch sensor 144, sound sensor 145, humidity sensor, fan and display 146, amongst others FIG. 25-35.

At least one receptacle 135 is provided on the housing or directly on the electric component so to electrically connect the electric component with a battery, base shield hub expansion board 147, or power source. All electric components can be operated by coupling it to either a battery component 148, a base shield hub expansion board component or another power source to supply its power. The base shield hub expansion board FIG. 36 allows the interconnection of multiple electric components in a central hub to a common power source and a programmable controller 149 equipped with sets of digital and analog input/output pins that may be interfaced to various electric components.

Within each electric component is a printed circuit board (PCB) 150 with the electric circuitry necessary to couple the electric component with the power source. These electric components can be interconnected in a variety of different ways. Each component can be either coupled directly to a battery component or a base shield hub expansion board or can be coupled via one or more wired electrical connector components FIG. 37.

The modular construction system may be made out of a semi-rigid or rigid material such as but not limited to wood, laminated wood, rigid foam, extruded polystyrene foam, plastic, foam-board, melamine board, dry erase board, white board, cardboard, paper, magnetic receptive material, magnetic material or metal.

In order to further customize the modular construction system, the surfaces of all or some of the modular construction elements may be printed, etched, carved, painted, drawn, embossed, debossed, engraved or by means of any other technique to produce a graphic or tactile design and/or image. These illustrations and/or designs may represent or simulate different design characteristics typical to the cultural region the specific modular construction system is representing amongst others. The modular construction system surface's may also allow for the user to non-permanently affix embellishment features to the structure.

In some instances, some or all of the modular construction system's elements may be coated with a smooth surface which allows non-permanent markings and erasing of markings of any color. The use of non-permanent markers or crayons, which markings adheres to the surface without binding or being absorbed by the surface, allows for unlimited coloring, drawing, erasing and decorating of the modular construction system.

In yet other instances, portions or all of the panels' surfaces can be of a magnetic receptive material, magnetically attracting and binding by attraction to its surface a magnetic accessory or component.

The wall panels of each basic module can be separated into individual components facilitating its assembly, disassembly. Additionally, it packs in a compact and flat manner for easy storage, customization and transportation

While this invention has been described using several preferred embodiments designs, there are additional possible embodiments, alterations, permutations, and substitute equivalents, which fall within the scope of this invention. It should be noted that there are many alternative ways of implementing the methods and components of the present invention.

Claims

1. A stackable modular construction system, comprising:

at least one basic module comprised by a plurality of panels,

wherein each module comprises at least three interlocking wall panels and at least one polygonal shaped floor panel,

wherein each panel comprises of two opposing surfaces and at least three edges with a thickness,

wherein the panels may comprise one or more openings of different sizes and shapes as decoration or to allow access, in addition to the placement and attachment of accessories, architectural and/or electronic components and/or the pass through of wiring and/or utilities,

wherein the amount of wall panels in a module correspond to the number of sides of its polygonal floor panel shape,

wherein the floor panel may comprise at least one protrusion tab extending from one of its edges having a width substantially equal to the thickness of the panel and a length, corresponding and compatible for coupling to the length and width of the at least one slot in a wall panel.

wherein a wall panel may comprise at least one slot having a width substantially equal to the thickness of the panel and a length, corresponding and compatible for coupling to the length and width of the at least one protrusion tab extending from a floor panel.

wherein a wall panel may comprise at least one ledge parallel and in proximity to one of its edges on which the floor panel rest by gravity.

wherein each wall panel comprises at least one kerf cut parallel and in proximity to a panel's edge with a width substantially equal to the thickness of the panel and a length half way the panel's height.

wherein the wall panels slide along such kerf cuts in order to interlock mechanically with other wall panels.

wherein each wall panel comprises at least one trussed edge, on all or portions of the edge's length,

wherein said trussed edge is comprised by a series of repeating polygonal shapes of varied size and proportion alternating up and down,

wherein said series of repeating polygons which make up the truss design are configured such that wall panels may be stacked and/or connected mechanically by mating with compatibly trussed panels.

wherein the lower trussed edge of an upper stacked module's wall panel is received by the upper trussed edge of the lower stacked module's wall panel.

wherein the stacked modules self-center when edged trusses mate and prevent movement in all directions of the horizontal plane relative to another module staked above and/or below.

and,

wherein modules with trussed edged panels of approximately the same design, dimension and contour may be stacked upon each other by the pairing of their trussed edges along the entire lengths or portions of their trussed edges, to form complex three-dimensional structures or scenes.

2. A stackable modular construction system according to claim 1,

wherein the number of polygons on a trussed edge is equal to 1 n where n is an integer greater than or equal to 1,

wherein the number of polygons on a trussed edge is greater than 1, the adjacent polygons alternate orientation, mirror imaged on a horizontal axis.

3. A stackable modular construction system according to claim 1, wherein each edge of each wall panel is a trussed edge.

4. A stackable modular construction system according to claim 2,

wherein the modules may be rearranged in sequence and/or rotated on its vertical axis to create a multitude of different design variations to the structure.

5. A stackable modular construction system according to claim 2,

wherein at least one panel comprises a certain number of equally spaced small slot perforations in a grid-like pattern in portions or in all of the panel's surface capable of attaching architectural and/or electronic components, wiring and/or accessories to the panel's face.

6. A stackable modular construction system according to claim 2,

further comprising at least one architectural component and/or accessory item that is capable of attaching or adhering to at least one panel face,

wherein said attachment or adherence to the panel face comprises adhesion, static electricity, magnetic attraction, or mechanical attachment,

wherein the architectural component attachment and/or accessory item comprises ladders, stairs, elevators, wind towers, railings, balconies, terraces, windows, doors, towers, lamp, furniture, human or animal figure, tool, appliance, trees, vegetation, light fixture, container, an interior decoration element, thematic background sceneries, scenery embellishment or any other object of utilitarian or decorative design.

7. A stackable modular construction system according to claim 2,

further comprising at least one electronic component and/or accessory item that is capable of attaching or adhering to at least one panel face; and,

electrical wiring and/or circuitry extending to at least one connector,

wherein said attachment or adherence to the panel face comprises adhesion, static electricity, magnetic attraction, or mechanical attachment,

wherein said electronic component comprises a light source, fan, multiple sensors, buzzer, photovoltaic panel, motor, switch, wiring, programmable controller, power source, receptacle, plug and/or Bluetooth enabled components.

8. A stackable modular construction system according to claim 7,

wherein said electrical component and/or accessory item comprising electrical wiring and/or circuitry extending to at least one connector is compatible with a connector of a power source.

9. A stackable modular construction system according to claim 8,

wherein said power source is a battery.

10. A stackable modular construction system according to claim 8,

wherein said power source comprises a battery and a controller that allows a Bluetooth enabled electronic component to be remotely controlled.

11. A stackable modular construction system according to claim 7,

wherein the at least one connector is compatible with a connector of an electronic component.

12. A stackable modular construction system according to claim 7,

wherein said electronic component comprises at least two connectors that allow coupling an electronic component to a power source.

13. A stackable modular construction system according to claim 7,

wherein one of said connectors is a receptacle and the other is a plug.

14. A stackable modular construction system according to claim 8,

wherein said electronic component connected to a power source is a programmable controller equipped with sets of digital and analog input/output pins that may be interfaced to various expansion boards and circuits.

15. A stackable modular construction system according to claim 7,

wherein said electronic component is having a housing,

wherein the housing comprises at least one protrusion tab or slot, sized and shaped to engage with a compatible tab, slot or feature of one of the modular construction system's panels.

16. A stackable modular construction system according to claim 2,

wherein the stackable modular construction system is formed from a semi-rigid or rigid material.

17. A stackable modular construction system according to claim 2,

wherein at least one panel comprises a surface material coated with a smooth surface which allows non-permanent markings and erasing.

18. A stackable modular construction system according to claim 2,

wherein at least one panel comprises a material that will magnetically attract a magnetic or magnetically receptive portion of an accessory item to a face of the panel.

wherein at least a portion of at least one face of a panel comprises a magnetic receptive material, wherein a magnetic portion of an accessory item will bind to an exterior or interior surface of the panel by attraction to the magnetic receptive material.

19. A stackable modular construction system according to claim 2,

wherein at least one panel comprises a graphic or tactile illustration, printed, affixed, etched, carved, painted, drawn, embossed, debossed and/or engraved.

wherein when different modules are stacked or placed side by side, sail illustrations, embossed, debossed or solid faces on adjacent module's panel faces form a contiguous illustrated scene and/or completes an architectural style structure.

20. A stackable modular construction system according to claim 2,

wherein the wall panels can be separated into individual components facilitating its assembly, disassembly and flat-pack storage.