WO2022018307A1 - Construction procedure, construction system and prefabricated construction plates for carrying out this procedure - Google Patents

Abstract

The invention relates to a construction procedure in which a parametric cutting method is applied which, starting from a three-dimensional digital development of the construction to be carried out or digital volumetry, allows the surfaces of said digital volumetry to be broken down into a succession of construction plates provided with means for transmitting information, in such a way as to facilitate factory production, efficient transport to the destination location and automated or manual recomposition and mechanisation on site in order to carry out the construction. The invention also relates to a construction system that makes it possible to carry out the above-mentioned procedure and the prefabricated construction plates suitable for carrying out such a procedure.

Description

DESCRIPTION

Construction procedure, construction system and prefabricated construction plates to carry out said procedure

The present invention refers, in a first aspect, to a construction procedure that allows to carry out a sustainable, industrialized and automated execution of any type of construction through the use of prefabricated construction plates equipped with means of transmitting information to one or more devices over a wired or wireless connection. The present construction procedure applies a parametric method of cutting that, starting from a three-dimensional digital development of the construction to be carried out, called here digital volumetry, allows the surfaces of said digital volumetry to be broken down into a succession of constructive plates equipped with means transmission of information, so as to facilitate production in the factory, efficient transport to the place of destination and recomposition and mechanization in an automated or manual manner on site in order to carry out the construction.

In a second aspect, the invention provides a construction system that allows carrying out the aforementioned procedure. Finally, in a third aspect, the invention relates to prefabricated construction plates adapted to carry out such a procedure.

Therefore, the present invention finds its application in construction, more specifically, in relation to prefabricated and modular construction systems linked to the loT (for its acronym in English, "Internet of things" - Internet of things) and intelligence artificial.

In the present description, by the concept "prefabricated construction plates equipped with means of transmitting information to one or more devices by a cable or wireless connection", also called here "interactive multi-link plates", it will be understood in reference to construction plates prefabricated that are detectable (readable), localizable and controllable through a loT communications network and that allow the traceability, virtualization and automation of the construction process of the invention, improving its efficiency and reducing the accumulation of errors, so common in the traditional processes.

Thus, in particular, the multilink interactive plates of the invention allow the development of any type of surface or three-dimensional element for construction, either by l the combination of surfaces with different degrees of inclination or by the connection of these surfaces with other prefabricated systems outside the invention. Consequently, the interactive multilink plates facilitate the construction of floor, floor, wall, roof, ceiling surfaces, enclosures, partitions, furniture and any other type of structural or non-structural surface necessary for the construction and its machining to other complementary elements, such as pillars, beams, carpentry, tensors, anchors, substructures, installations, finishes, etc..., allowing to meet the needs of any project, from the simplest to the most complex, with dry joints and allowing subsequent disassembly if necessary. necessary. The multi-link interactive panels incorporate loT (internet of things) to be readable, locatable and controllable through a loT communications network and thus allow traceability, virtualization and automation of construction processes.

In short, the present application redefines both the construction systems and the construction processes for the integral realization of constructions in a fast, dry, precise, simple and safer way for assembly workers than traditional systems, also allowing their disassembly for subsequent reuse if necessary or desirable.

The construction sector continues to be, today, an outdated industrial model, weighed down by low levels of productivity, traditional ways of operating and with a high impact on the environment and climate change. Unlike other sectors, such as the manufacturing industry, transport or services, it has not yet made its technological transition towards automation and the use of data to generate a new relationship space between companies and consumers, and increase optimization and control of its processes; just as it has not adapted its construction techniques to be able to join the circular economy.

Construction procedures are the processes, systems and methods available to carry out a work following an ordered set of construction rules and practices according to the experience and technical and scientific knowledge of the sector.

The current state of the art includes different types of construction procedures and methods such as traditional, structural panels, wood, prefabricated modules, industrialized, bidirectional and three-dimensional construction, among others. In turn, there is a diversity of elements that are used in these construction procedures, such as plates, slabs, parts, models and types of houses and buildings, all prefabricated, which are made from different materials such as aluminum, steel, plates, wood and concrete, among others, the latter being the most used in practice.

Traditional construction allows freedom of design, but requires craft execution processes that are not very productive. Industrialized construction increases productivity, but restricts creativity because it works based on mass-produced modules.

The current and modern construction has as a challenge the implementation in the management and development of construction procedures, the use of digital technology, artificial intelligence, robotics and the internet of things (loT), which represents an evident novelty in the sector that is gradually adapting to these transformations and encouraging innovators to develop smart and more sustainable construction methods.

In this sense, a few years ago, the use of sensor technology and connectivity in the management of buildings by BMS (Building Management Systems) systems, equipped with software and hardware that carry out the supervision and control, has been put into practice. control of certain buildings, defining itself as the comprehensive automation system for real estate through loT.

The current loT platforms for buildings and infrastructures allow the building equipment that remains distributed to be connected with devices and sensors that use a wide variety of protocols, which send the data they generate to services and applications located in the cloud, to be subsequently analyzed by Business Intelligence (Bl) systems, analytics, and dashboards.

On the other hand, the artificial intelligence used in the construction sector will allow the use of data collected from models, simulations and even through physical elements, such as sensors, within the already completed constructions, in order to transform the construction process. design or, at least, innovate with each new construction project. Thus, a new perspective is offered from which to imagine how to take advantage of existing information, data, both from previous modeling, and data from buildings already built. For example, document W02005113912A1 describes a construction system based on prefabricated plates for the construction of walls, floors and ceilings and whose elaboration is carried out in factory molds. The plate combines a strong peripheral structure comprising U-shaped channels, mesh and poured mass concrete. These plates can be used to make floor slabs, tiles, non-structural and load-bearing single panels, and double-closure panels with an intermediate layer of thermal insulation. The invention incorporates connection elements welded to the inner periphery of the channels and may also comprise insulators.

Document ES 2569130B1 also describes prefabricated modular construction elements and a modular construction system that uses said elements for the construction of buildings of any use independently or in association both on the same plane and at different heights, such elements being self-supporting.

On the other hand, the use of artificial intelligence and IoT elements has been launched in other industrial fields, for example as described in document US10540641 B2, which refers to a system that includes devices and sensors associated with a construction site for a project, where a computing device communicates with devices and sensors and includes a storage medium and a processor. The storage device stores software instructions to control the processor which, when executed by the processor, configure the processor to obtain a predetermined build schedule with terms for the project.

In view of the state of the art, the present invention provides innovative elements and presents functional advantages by facilitating an intelligent construction procedure that is based on the decomposition into pieces of a constructive volume from a parametric geometric system that proposes the use of plates specific multi-link interactions and which, related to loT elements and artificial intelligence, provide the procedure with greater precision, traceability and control. Likewise, the present invention provides multi-link interactive plates that include a series of joining means for machining or joining other plates of the invention or any other construction element by dry joint, facilitating the machining of the grid of connection points and making the assembly solid as a whole. Another advantage of the present invention is based on the fact that it allows the designer freedom of choice and allows the reuse of multi-link interactive panels, being able to develop fixed or temporary installations for any use. The invention also promotes lower production costs, greater speed in the execution of the works, optimizes the quality of their finish, reduces occupational risks and provides a high-strength monolithic structure based on multi-link interactive plate joints.

Thus, according to the first aspect, the present invention provides a construction method that includes the following stages: i) creation of a three-dimensional digitized design of a construction to be carried out by means of a data acquisition module that acts dynamically Real time; ii) decomposition or exploded view of the digitized design, by means of a parametric exploded view method, carried out in an intelligent exploded view module, which breaks down all the volumetry surfaces of the digitized design into a series of prefabricated, transportable and machinable interactive multi-link plates, arranging the plates of a network of inter-plate connection points distributed over all their surfaces in an aligned and/or three-fold manner and each of the plates including at least one loT communication element; iii) generation of a construction project in a control unit from the breakdown and real-time dynamic information received from the data acquisition module, including the construction project: a) the mechanization of the multilink plates, for which which the control unit includes signal adaptation devices configured to transform the orders of the control unit into signals understood by the machinery destined to machine the multi-link plates, introducing the loT communication devices in them and b) execution of the assembly subproject by means of the control unit to recompose at the destination, with the prefabricated multi-link interactive boards, the digitized design in stage i).

The interactive multi-link boards mentioned and used in the method of the invention can be made of any material, with any measurements and placed in any position or degree of inclination, being made up of two surfaces (surface and bottom) and four sides. As mentioned, these interactive multi-link plates have a network of inter-plate link points spread over all their surfaces in an aligned and/or three-fold manner in order to join each other defining any desired three-dimensional or two-dimensional structure, supporting such structure, and/or to couple other construction elements.

In a preferred embodiment of step ii) of the method of the invention, to provide the interactive multilink boards with a network of link points, these are distributed according to one or more of the following:

• at least one attachment point at each vertex and/or at a certain distance (x,y) from it on one or both faces of the plate and/or on its sides;

• at least one attachment point at the geometric center and/or at a certain distance (x, y) from it on one or both faces of the plate and/or on its sides.

These attachment points can be shaped to receive any appropriate connection means with another plate, for example bolts, screws, threaded rods, magnets, or any type of dry connection, which can be through or non-through connection means.

The selection of the link grid of the multilink plate in step ii) thus generates a three-dimensional matrix of link points, and, therefore, it is possible to reproduce said matrix of link points in the different multilink plates. Thus, each matrix of connection points generates a specific family of plates to be used for the breakdown of stage ii) described above. Therefore, a plurality of typological variants of multi-link interactive panels are grouped within a family that can be used for different uses, be made of different materials and with different dimensions and connection point configurations, being necessary that at least one be kept for that the plate can be considered multilink and maintain its machining capabilities, in any case maintaining the proportional relationships between its shapes, dimensions and position of the connection points, thus guaranteeing the compatibility and joining capacity between the different typological variants of the multi-link plates of the same family.

The interactive multilink board thus allows defining the laws under which the parametric method of quartering must operate. The multi-link interactive panels can be applied to any type of construction, for example floor elements, floors, walls, floors, technical ceilings, partitions, enclosures, furniture and the like, as well as solidary three-dimensional sets, giving rise to constructions of a residential nature, industrial, commercial, recreational, civil, public, private, etc.

Furthermore, since each of the multi-link interactive boards has at least one loT communication element, it is possible to digitize, automate and optimize all phases of construction.

As used herein, particularly in relation to multi-link interactive boards, the IoT term "Internet of Things" refers to any object (eg a device, a sensor, etc.) that has an addressable interface (eg , Internet Protocol (IP) address, Bluetooth ID, Near Field Communication (NFC) identifier, etc.) and can transmit information to one or more devices over a wired or wireless connection . An IoT object can have a passive communication interface, such as a Quick Response (QR) code, Radio Frequency Identification (RFID) tag, NFC tag, or the like, or an active communication interface, such as a modem. a transceiver, a transmitter-receiver or the like. Similarly, an IoT object may have a particular set of attributes (for example, a device status or category, such as whether the IoT device is powered on or off, open or closed, idle or active, available for task execution, or occupied, and so on; a cooling or heating function, an environmental monitoring or recording function, a light-emitting function, a sound-emitting function, etc.) that can be integrated into and/or controlled/monitored by a central processing unit (CPU), a microprocessor, an ASIC, or the like, and configured for connection to an IoT network, such as a local ad-hoc network or the Internet.

In particular, in the method of the invention, the interactivity of the multilink interactive board is achieved through the incorporation of at least one active or passive loT communication device, which allows digitizing, automating and optimizing all the phases of the procedure here described. The loT device also enables both product and process traceability monitoring and interoperability with digital and electromechanical devices, based on Device-to-Device, Device-to-Cloud, Device-to-Gateway and Back-end communication models. End Data-Sharing, for example, which makes it possible to automate and optimize all phases of construction or maintenance, allowing to define digital twins of the construction in real time in order to assess the development of the procedure described here, as well as to perform other functions, for example related to the maintenance, storage and transport of the multilink plates, etc.

In stage i) described above, a three-dimensional digitized design of a construction to be carried out is created by means of a data acquisition module that acts dynamically in real time.

The data acquisition module has means to collect, store and transmit data from sensors, loT devices, databases or libraries in real time (firebase) from different sources of information and means to send said data to the intelligent breakdown module already the central control unit. The data acquisition module can process related static or dynamic information that helps to optimize each phase of the construction process, for example: parameters of environmental regulations and building codes; productivity levels of the production machinery of each manufacturer, stock of each manufacturer, manufacturing shifts, purchase orders, etc.; e-loT sensors of the machinery, real-time data of each component of the construction system that is produced and of defective elements, etc.; external factors such as traffic conditions, road closures, weather conditions; - machinery available in real time; maintenance alerts, regulatory change alerts, etc.

In stage ii) described, an intelligent exploded module applies a parametric exploded method that breaks down all the volumetric surfaces of the digitized design in stage i). The parametric exploded method is based on a system of parametric equations.

In this regard, the parametric equations represent a surface in space by means of values that cover an interval of real numbers, by means of a variable, called a parameter, considering each coordinate of a point as a dependent function of the parameter. Thus, the parametric exploded method of the procedure of the invention allows the introduction of various parameters, such as spatial limits, volumes, forces, etc., specific to each project to obtain the optimal digital volumetric exploded view and perform the pertinent structural calculation.

The parametric exploded method, based on the parameters provided, performs the exploded view of the surfaces based on the families of multi-link interactive plates, checks the joint relationships, applies the stability restrictions between the elements and provides the best exploded solution. possible, through the intelligent cutting module.

The verification of the union relationships will serve to verify, for example, that all the surfaces obtained with interactive multi-link plates have enough inter-plate connection points to join the surface and that all the elements machined to the interactive multi-link plates are located on these connection points. Checking the link relationships may involve moving elements to be located within the link point grid and removing or placing link elements to link the multilink plates, among others.

The stability constraints are based on the stability relationships stipulated in the user manuals and their cross-reference with the project-specific data and acting forces. The stability restrictions will depend on the mechanical resistance of each multi-link interactive plate, on the function of the surface they make up, on the loads to which said surface will be subjected and on the position of the supports. For example, if a roof is made with a layer of multi-link wooden plates, the distance between the roof supports will depend on the snow load, the wood used, etc.

The parametric exploded method allows obtaining several exploded options, which can vary from the optimal one to obtain the least number of different multilink interactive boards, to the optimal one to preserve the original design. In both cases, always with the limitation of the geometry of the three-dimensional matrix of connection points.

Thus, the parametric method of cutting, once the data of the project that affect the manufacturing, stability and assembly of the construction, for example spatial limits, forces, function, use of the construction, permanent or temporary loads, geotechnical study of the terrain, etc., performs the following operations: - Defines a coordinate origin for the three-dimensional digitized design (orthogonal to the slope plane of the surface), and other coordinate origins as necessary. For example, a coordinate origin is defined for the digitized design adapted to the structure in floors and walls and, where appropriate, also adapted to the floor if it has finishing elements;

- Generates an exploded matrix for each family of multilink boards, breaking down each surface of the digitized design based on such families;

- Checks the link point grid, verifying that there are enough link elements to support the surfaces and that all the elements machined to the interactive multi-link plate are located on their link points;

- Applies the stability restrictions of each surface, verifying that the stability relationships for the surfaces of each typological variant and the stability relationships of the three-dimensional design and all the elements that compose it will withstand the external forces to which the surface will be subjected. construction;

- Performs the count of multilink interactive plates according to the typological variants and the count of the joining elements according to type.

With this information, the intelligent cutting module prepares a specific cutting project for each project adjusted to the appropriate manufacturing, transport and assembly criteria for each type of surface.

Therefore, the intelligent exploded view module receives and analyzes a data file that defines a digital volumetry (3D) made up of construction elements and/or a set of them. The digital volumetry can be, for example, a digital data file, such as a building information modeling (BIM) data file or a computer-aided design (CAD) data file. The digital volumetry (3D) can also contain identification labels that incorporate information, for example about the function and material of each element.

In addition, the intelligent layout module can receive and analyze project-specific data such as location, permanent or temporary actions, use, etc., data that can become restrictions when performing the layout. Likewise, the intelligent cutting module can receive and analyze data from applicable regulations, for example referring to environmental regulations or building codes, among others, data that can become restrictions when performing cutting.

For all this, the intelligent quartering module stores and executes algorithms based on heuristic rules, fuzzy logic techniques and artificial intelligence and that can be programmed based on knowledge of the parametric method of quartering or be learned by the system itself through neural networks. Thus, the intelligent quartering module can store and execute control algorithms based on Soft Computing techniques, it can use decision rule engines composed of variables and linguistic rules, it can be based on a fuzzy inference system that defines the variables and fuzzy rules to use and Grid-type learning rules that automatically induce new rules from the input information.

Through the application of such algorithms, the intelligent exploded view module classifies the elements that are part of the digital design and determines which of them will be made with which family or families of multi-link interactive boards of the invention and, where appropriate, which other elements must be joined with them, it performs the breakdown of the elements based on the typological variants of the interactive multi-link panels specific for each one of them and their dimensional varieties, it chooses the most optimal breakdown based on the conditions initially introduced that affect manufacturing, stability and assembly of the construction, performs a verification analysis of the tie point frames, performs a verification analysis that the stability restrictions are met, and performs a regulatory analysis to verify that the construction conforms to the relevant requirements.

In one embodiment, the smart stripping module may include means for displaying the volumetry decomposition and resulting stripping in a graphical user interface. In some embodiments, the smart stripping module may further display the operations performed during the decomposition process in the graphical user interface, making it easy to view each operation as a separate graphical representation. In some embodiments, the smart exploder module may further display the logical relationships in the graphical user interface as a separate graphical representation. In some embodiments, the intelligent plotting module may generate the plotting in a data format (zeros and ones). In stage iii) described above, a construction project is generated in a control unit based on the layout made by the intelligent layout module and the real-time dynamic information received from the data acquisition module. To do this, the central control unit includes means for storing and processing the exploded view received from the intelligent exploded view module and means for contrasting said exploded view with the information received from the data acquisition module in order to prepare a construction project. and transmitting the relevant construction orders to the construction assembly machinery.

In one embodiment, the control unit includes the following modules:

A project module that includes means of managing static information referring to the project data, such as spatial limitations, the use of the construction, permanent or temporary forces and loads to which it will be subjected, study of the geological characteristics of the soil and the like;

A management module that includes means of registering users, manufacturers, machinery, clients, partners, materials, costs, times, supplies, taxation, legality, standards, monitoring to provide resources for each project, for example the necessary labor, stocks , estimation of times and the like;

A security module to manage user permissions, access to information, protection measures against malware threats and communication protocols, among others;

A visualization module to visualize the construction project in two and/or three dimensions with different levels of abstraction, for example to visualize simulations of exploded views, and/or to visualize real-time monitoring of the construction process in all its phases. The display module can display this information in the form of a diagram, graph, table, two- or three-dimensional drawing, for example;

A control module of physical components, where the physical components are constituted by the machinery and the interactive multilink plates, this control module presenting wireless communication means to communicate with loT communication devices arranged in the machinery and in the interactive multilink plates and capable of issuing and receiving information actively or passive, wireless means of communication configured for IoT devices to interact with other agents, such as people or other remote IoT devices;

- Means of adaptation of signal and communication configured to transform the commands of the central unit to signals understood by the physical components.

Wireless means of communication allow the central control unit to command the machinery and for it to communicate directly with other components of the construction system according to Device-to-Device, Device-to-Cloud, Device-toGateway and Back-end connectivity models. End Data-Sharing. In this way it is achieved, for example, that the intervening assembly machinery is autonomous (for example cranes, machining machines, etc.), since they receive orders from the control unit and execute them without external assistance. Likewise, the control unit can program a concatenated order of events where each machine notifies the start and end of its work and automatically gives way to the action of another machine.

The wireless communication means may constitute an addressable interface (for example, an Internet Protocol (IP) address, a Bluetooth identifier (ID), a near field communication (NFC) identifier, an RFID tag identifier, etc. ) to transmit information through the central control unit.

In the case of the machinery for the production of multi-link interactive plates, for example, based on the layout received from the intelligent layout module, the control unit can send orders to the cutting tools equipped with numerical control or CNC, being able to produce any type of multi-link interactive panel.

Likewise, in reference to the aforementioned assembly subproject, the control unit sends orders, through the means of signal adaptation and communication, to the assembly machinery to recompose at the destination, with the prefabricated multi-link interactive plates, the digitized design in stage i). Optionally, the control unit generates maintenance notifications based on the information prescribed by the manufacturer/assembler or the loT incorporated in the multi-link interactive panels. Also optionally, if necessary, the central control unit will command the assembly machinery to disassemble the construction.

In a second aspect, the invention provides a construction system to carry out the process described above. Thus, the construction system of the invention comprises the following elements: a) A data acquisition module of a three-dimensional digitized design of a construction to be carried out that acts dynamically in real time and includes means to collect, store and transmit data from sensors, loT devices, databases or libraries in real time from different information sources to an intelligent cutting module and a control unit; b) An intelligent exploded view module for the decomposition or exploded view of the digitized design by means of a parametric exploded view method, the intelligent exploded view module decomposing all the volumetry surfaces of the digitized design in a series of prefabricated, transportable and mechanizable multi-link interactive plates, arranging the plates of a network of inter-plate connection points distributed over all their surfaces in an aligned and/or three-fold manner and each of the plates including at least one loT communication element; and c) A control unit connected to the intelligent exploded view module and to the data acquisition module that generates a construction project from the exploded view and the real-time dynamic information received from the data acquisition module, where the control unit includes signal adaptation devices configured to transform unit commands into signals understood by the machinery intended to machine the multi-link plates, inserting the loT communication devices into them, and by the machinery to carry out the construction, management means of the static information referring to the project data, user registration means, manufacturers, machinery, clients, partners, materials, costs, times, supplies, taxation, legality, regulations, follow-ups to provide resources to each project and means of visualization to visualize the construction in two and/or three dimensions.

According to the third aspect, prefabricated construction plates adapted to carry out the described procedure and for use in the described system, called here interactive multi-link plates, are also an object of the invention.

These multi-link interactive plates are made up of two surfaces (upper and lower) and side surfaces and have a network of inter-plate connection points spread over all their surfaces in an aligned and/or three-fold manner in order to join to each other defining any desired three-dimensional or two-dimensional structure, joining such structure, and/or to couple other construction elements.

In one embodiment, the grid of connection points is made up of at least one connection point at each vertex or at a certain distance (x,y) from it on one or both faces of the plate and/or on its sides and/or by at least one attachment point at the geometric center or at a certain distance (x, y) from it on one or both faces of the plate and/or on its sides.

These connection points are shaped to receive any appropriate connection means with another plate, for example bolts, screws, threaded bars, magnets, or any type of dry connection, which may be through or non-through connection means.

The multi-link interactive panels can be applied to any type of construction, for example floor elements, floors, walls, floors, technical ceilings, partitions, enclosures, furniture and the like, as well as interconnected three-dimensional sets, giving rise to constructions of a residential nature, industrial, commercial, recreational, civil, public, private or other, utilitarian (objects), etc.

The combination of multi-link interactive plates and their associated connection elements allow the creation of sets in two and three dimensions according to different configurations.

Thus, in an example of an embodiment, the combination of several multi-link interactive plates results in a surface where said multi-link interactive plates are placed end-to-end and are joined together by means of the joining elements on the grid of connection points to transmit the loads of one plate to another and form solidary surfaces.

This combination of plates forming one surface can be combined with others forming an arrangement in aligned layers, superimposing one layer on the other aligning the edges, or overlapping, offsetting one layer with respect to the previous one in one or more directions. Likewise, combinations can be made with multi-link interactive panels of the same or different types, thus forming a multi-layer structure. It should be noted that the three-dimensional matrix of connection points guarantees the compatibility and union capacity between different types of interactive multi-link plates.

In another example, solidary three-dimensional assemblies are formed based on multi-link interactive plates by combining surfaces formed by multi-link interactive plates with different degrees of inclination. For example, sets can be obtained solidary three-dimensional connecting multi-link interactive plates arranged horizontally with multi-link interactive plates arranged vertically and/or with inclined multi-link interactive plates. In turn, each surface of the three-dimensional set can be single or multilayer.

It should be noted that, since the grid of tie points is spread over all the surfaces of the multi-link smart board, both on its perimeter, inside and on the side, total freedom of positioning and combination is allowed. For example, if interactive multi-link plates are laid out horizontally to create structural surfaces such as slabs, walls of interactive multi-link plates can be joined, aligned or not; If multi-link interactive plates are arranged vertically to create structural surfaces such as walls, floors or other elements such as stairs can be machined at any position or height.

The invention makes it possible to obtain results comparable for all purposes to a traditional construction in terms of freedom of design, shape, arrangement of pillars, size, number of floors, use, resistance and finishes and to a prefabricated dry joint construction, in terms of the ability to reuse, disassemble and transport, with the particularity that, unlike these conventional constructions, a completely different configuration can be made with the parts of the recommended system. This makes it possible to guarantee that the construction is 100% reusable in another location and 100% adaptable to the new context and the needs of the new project, without any additional cost beyond the expenses derived from transport, on-site assembly and plate production. new if necessary.

The invention as it has been described also allows exploiting the capabilities of the implementation of the new collaborative work methodologies for the creation and management of construction projects that have emerged in recent years, such as Building Information Modeling (BIM) and the implementation of autonomous systems thanks to loT technology and artificial intelligence integrated in the system components, which allows the creation of perfect and synchronized digital models, the introduction of technology and robotics in the production, assembly, use, maintenance and disassembly phases and the control of the traceability of the processes, in order to correct the unproductiveness, inefficiency and loss of information throughout the entire production process, the precision errors of the execution and the lack of quality controls so common in current construction .

Claims

1. Construction procedure that includes the following stages: i) creation of a three-dimensional digitized design of a construction to be carried out by means of a data acquisition module that acts dynamically in real time; ii) decomposition or exploded view of the digitized design, by means of a parametric exploded view method, carried out in an intelligent exploded view module, which breaks down all the volumetry surfaces of the digitized design into a series of prefabricated, transportable and machinable interactive multi-link plates, arranging the plates of a grid of inter-plate connection points distributed over all their surfaces in an aligned and/or three-fold manner and each of the plates including at least one loT communication element; iii) generation of a construction project in a control unit from the breakdown and real-time dynamic information received from the data acquisition module, including the construction project: a) the mechanization of the multilink plates, for which which the control unit includes signal adaptation devices configured to transform the orders of the control unit into signals understood by the machinery destined to machine the multi-link plates, introducing the loT communication devices in them and b) execution of the assembly subproject by means of the control unit to recompose at the destination, with the prefabricated multi-link interactive boards, the digitized design in stage i).

2. Construction method according to claim 1, characterized in that, in step ii), in the grid of connection points the connection points are distributed according to one or more of the following:

• at least one attachment point at each vertex and/or at a certain distance (x,y) from it on one or both faces of the plate and/or on its sides;

• at least one attachment point at the geometric center and/or at a certain distance (x, y) from it on one or both faces of the plate and/or on its sides.

3. Construction method according to claim 2, characterized in that , based on the grid of links of the multilink plate, a three-dimensional matrix of link points reproducible in the multilink plates is generated and each matrix of link points generates a family of plates that groups together various specific typological variants to be used for the breakdown of stage ii) described above.

4. Construction method according to claim 1, characterized in that the at least one loT communication device is of the active or passive type and allows digitizing, automating and operating with digital and electromechanical devices, based on Device-to-Device communication models. , Device-to-Cloud, Device-to-Gateway and Back-End Data-Sharing.

5. Construction method according to claim 1, characterized in that the data acquisition module has means for collecting, storing and transmitting data from sensors, loT devices, databases or libraries in real time and for sending them to the intelligent breakdown module already the central control unit to which it is connected

6. Construction procedure according to claims 1 to 2, characterized in that specific parameters are introduced in the parametric exploded method and the exploded surfaces are performed based on the families of multi-link interactive plates, performing the following operations:

- Defines a coordinate origin for the three-dimensional digitized design (orthogonal to the slope plane of the surface), and other coordinate origins as necessary;

- Generates an exploded matrix for each family of multilink boards, breaking down each surface of the digitized design based on such families;

- Checks the link point grid, verifying that there are enough link elements to support the surfaces and that all the elements machined to the interactive multi-link plate are located on their link points;

- Applies the stability restrictions of each surface, verifying that the stability relations for the surfaces of each typological variant and the Stability relationships of the three-dimensional design and all the elements that compose it will withstand the external forces to which the construction will be subjected;

- Performs the count of multilink interactive plates according to the typological variants and the count of the joining elements according to type.

7. Construction system to carry out the procedure according to any of claims 1 to 6, characterized in that it is made up of the following elements: a) A data acquisition module of a three-dimensional digitized design of a construction to be carried out that acts dynamically in real time and includes means to collect, store and transmit data from sensors, loT devices, databases or libraries in real time from different sources of information to an intelligent cutting module and a control unit; b) An intelligent exploded view module for the decomposition or exploded view of the digitized design by means of a parametric exploded view method, the intelligent exploded view module decomposing all the volumetry surfaces of the digitized design in a series of prefabricated, transportable and mechanizable multi-link interactive plates, arranging the plates of a network of inter-plate connection points distributed over all their surfaces in an aligned and/or three-fold manner and each of the plates including at least one loT communication element; and c) A control unit connected to the intelligent exploded view module and to the data acquisition module that generates a construction project from the exploded view and the real-time dynamic information received from the data acquisition module, where the control unit includes signal adaptation devices configured to transform unit commands into signals understood by the machinery intended to machine the multi-link plates, inserting the loT communication devices into them, and by the machinery to carry out the construction, management means of the static information referring to the project data, user registration means, manufacturers, machinery, clients, partners, materials, costs, times, supplies, taxation, legality, regulations, follow-ups to provide resources to each project and means of visualization to visualize the construction in two and/or three dimensions.

8. Construction system according to claim 7, characterized in that the control unit includes the following modules:

A project module that includes means of managing the static information referring to the project data;

A management module that includes means of registering users, manufacturers, machinery, clients, partners, materials, costs, times, supplies, taxation, legality, regulations, monitoring to provide resources for each project;

A security module to manage user permissions, access to information, protection measures against malware threats and communication protocols;

A visualization module to visualize the construction project in two and/or three dimensions with different levels of abstraction, for example to visualize simulations of exploded views, and/or to visualize real-time monitoring of the construction process in all its phases;

A control module of physical components, where the physical components are constituted by the machinery and the interactive multilink plates, this control module presenting wireless communication means to communicate with loT communication devices arranged in the machinery and in the interactive multilink plates and capable of actively or passively emitting and receiving information, wireless means of communication configured for loT devices to interact with other agents, such as people or other remote loT devices;

Signal and communication adaptation means configured to transform the orders of the control unit into signals understood by the physical components.

9. Prefabricated construction plates to carry out the procedure according to claims 1 to 6 and for use in the system according to claims 7 to 8, characterized in that they are made up of an upper surface, a lower surface and lateral surfaces and have a grid of inter-plate connection points spread over all its surfaces in an aligned and/or three-fold manner in order to join one another defining any three-dimensional structure or desired two-dimensional, supporting such a structure, and/or to couple other constructive elements, and including each of the plates at least one loT communication element.

10. Prefabricated construction plates according to claim 9, characterized in that the grid of connection points is made up of at least one connection point at each vertex and/or at a certain distance (x,y) from it on one or both sides of the plate and/or on its sides and/or by at least one attachment point at the geometric center and/or at a certain distance (x, y) from it on one or both faces of the plate and/or on its sides.