TR2023002888A2 - REVERSIBLE AND DIY MODULAR SHELTER SYSTEM CONSISTENT OF L-SHAPED MODULES - Google Patents

Abstract

The present invention is based on anthropometric ?Modular/Dimensional Coordination and grid system? The form and distinguishing characteristic of the main element of the modular system that sits on it is L-Shaped, and it consists of two planes: the L-Shaped Base L-Module (1) and the Ceiling L-Module, which simultaneously carries the horizontal-base component on one wing and the vertical structure component on the other wing. It is mobile without being fixed to the biaxial, multifunctional Lock cavity/reservoir (7), which is based on the principle of integrated connection/passing with each other through the Groove (14) and Gasket Lath (12), which form the joint/edge geometry of the (2) and embedded in the frame (15). 'L-Module Jointing System' with 'Compression Locking Technique and system' based on the principle of locking accessory connection elements (3, 4, 8) with a series of hierarchical relationships. and ?Super-Insulation? of system modules. Produced with the 'Accordion Insulation Padded Composite Sandwich Panel Technique' with the Accordion Insulation Pad (9), which is obtained with the origamic folding technique, which makes it light and durable thanks to its structural filling function, which also makes it special and easy to stack, store, carry and transport. Offering unique logistics advantages in its processes; It does not require heavy machinery either during transfer or installation, is light enough for two people to easily carry and install, and can be easily transferred to many disaster areas quickly and in large numbers, especially in cases of acute shelter need as a result of natural disasters; It can be easily installed and dismantled not only by experts but also by unqualified people, and is connected to each other without requiring any tools other than a key turner; allowing multiple functions and spatial typology creation in living and business areas such as accommodation, mobile office, warehouse/storage, exhibition, theater/film stage; ecological, environmentally friendly, sustainable, user-friendly; An orderly and harmonic jointing system in which "all the elements are in mutual interaction", in other words, where each element can be combined with the other at many points, and a transformable, reversible, DIY (DIY) includes the application of modular shelter construction technique/system.

Description

DESCRIPTION REVERSIBLE AND DIY MODULE SHELTER SYSTEM CONSISTING OF L-SHAPED MODULES Technical Field The present invention relates to a modular and reversible plug-in shelter system consisting of L-shaped modules. The present invention enables the installation of a rectangular structure with a minimum of 4 L-Modules in order to construct it modularly in terms of ease and speed of assembly; offers unique logistic advantages in storage, transportation and shipping processes due to ease of stacking; can be easily assembled and disassembled with unskilled labor and a very simple locking connection mechanism; can meet multiple functions and needs in various living areas such as shelter, warehouse/storage, exhibition, theater stage; environmentally friendly, sustainable, user-friendly, lightweight (does not require heavy construction equipment); has a special insulation technique; is based on a unique anthropometric "Modular/Dimensional Coordination and grid system"; is characterized by an "L-Module Joining Technique", which connects these modules to each other without requiring any tools other than a key converter, and the "Accordion Insulation Padded Composite Sandwich Panel Technique"; is related to a modular shelter system where "all elements interact with each other", in other words, each element can be joined to each other from many points, an orderly and harmonic jointing system and a transformable, reversible, DIY modular shelter system. Previous Technical Modular Structures emerged in architecture centuries ago. Modules fulfill the need to subdivide structural elements for easier, faster and cheaper manufacturing, transportation and assembly of structural units. In other words, in modular systems, structural parts must be subdivided into smaller, easier-to-manage units. The term module was first used and defined by the ancient Roman architect Vitruvius. According to him, a module is "the smallest possible unit in which each element/structure of a temple can be analyzed." Contemporary architect Mete Tapan defines the Module as "a dimensional size or unit of measurement used in architecture to regulate the RATIOS of various parts of a STRUCTURE and to provide a dimensional order between the structural components." The technique developed based on the multiples of a selected basic module in order to ensure coordination between the dimensions of the components that form a structure both vertically and horizontally, and the dimensions of various spaces, structural elements and reinforcements in the same structure is called "Modular/Dimensional Coordination". With Modular Coordination, optimum utilization of labor and ease of transportation are provided, labor is reduced in assembly and material loss is minimized. Modular structures are standardized and allow millions of production. An architecture based on structural elements that can be easily reproduced by existing technology and rapidly produced with "templates/molds" defines our modular construction understanding to this day. Modular structures were further developed for speed and perfection in the industrial age. For example, Conrad Washsmann's "General Panel System" (USZ355192A) was developed for the mass production of modular houses. This system is a closed system consisting of 10 types of modular panels and a 4-way connector connecting them. The panels are prefabricated finished parts and are assembled to form the body of the structure by interlocking the connections on the lateral edges of the panels. Today, in the digital age, CAD/CAM (Computer Aided Design/Computer Aided Manufacturing) design and manufacturing technologies allow for a different modularity solution. For over 30 years, CAD has replaced traditional drawing, design and form-finding techniques. Although advanced 3D modeling software allows the creation and processing of complex geometries, each innovative form/typology requires the development of a new joining technique and related intermediate connection elements or components such as connectors and fixtures. And almost every developed modular technique or method requires the use of heavy construction equipment such as cranes (most of them). The connector mechanism that connects modular structural units and provides a transportation method is also a technique that is dependent on the use of heavy construction equipment - despite its many positive aspects. system, while it consists of a large number of prefabricated interconnectable modular budding units - if we do not take into account the fact that it consists of quite complex assembly and connection elements - it is a method that is "transportable using the intermodal transportation system" as stated in the patent document and that assembly with heavy construction equipment is mandatory. Increasing raw material and logistics prices, climate and environmental problems, energy problem, increasing world population, migration problem, broken supply chain after the pandemic, expert/skilled worker problem, individuality of form and mass mass production, increasing demand for more affordable solutions, and the Circular economy and Green Economy period focusing on the solution of all these problems necessitate a universal "new modular" standardization. The expectation of norms and standardization in a digitalizing world has never been as urgent as it is today. Dimensions, qualities and construction costs and their reduction are increasing and gaining importance in the architecture industry. Developing products and materials require different processing parameters. The size limitations defined by the transportation and digital production environment still need to be respected. This information framework based on different parameters, regulations and criteria necessitates the creation of new generation unifying units, while at the same time, the struggle to minimize production time and costs encourages us to search for new ways to reduce human labor. In addition to all this, another indispensable criterion now guides our modern life: a renewable and/or recyclable material/module system produced with environmentally friendly, clean energy. While many modular systems, techniques or methods offer solutions to one or more of these problems at the same time, very few are both environmentally friendly and recyclable, or in technical terms, "reversible" modular systems. For example, in this context, the modular construction system in the US patent document numbered US9631358B1 claims to meet a need such as reducing construction costs by offering the advantage of completing a structural project from the ground up with unskilled labor, but this does not provide a solution to the current and future major problems mentioned above. The basic modular approach of the last two patent document examples is space frame systems, where linear elements are brought together at a connection point at the extreme ends of the steel profiles. The space frame structure must then be covered with other types of cladding such as metal/wood panels, glass or other types of materials. And almost every space frame introduces a new level of three-dimensional complexity. Modules take into account that architecture is never made up of continuous masses of materials, but rather consists of multiple components. While the module of the industrial age was the product of monotonous mass production, the module of the digital age must incorporate differentiation within the series. A module is initially represented as a kind of class that defines its elements, topological relations, and degrees of freedom. Each module is part of a larger, self-similar structure that addresses multiple requirements such as program, structural and material properties, geometry, and manufacturing constraints. Interaction and feedback can move in both directions, from the general form to the component and vice versa. A module never works alone, but as a collection of many instances. The whole thus emerges from the interaction of a series of individual objects. The modular structures of the digital age, despite the fact that it allows to manage complex geometries with automated CAM (Computer Aided Manufacturing) processes, must take into account the "World Overshoot Day", which becomes more serious every year. In other words, the day when our consumption exceeds the world's self-renewal rate in 0 years", the World Overshoot Day has been determined as July 28 in 2022. This phenomenon, which is on the agenda as a serious threat to humanity and the world, is a serious warning to all humanity, especially designers and developers, that we do not have unlimited resources and that we need to use the existing resources, namely raw materials, more consciously by producing solutions that will ensure maximum efficiency and long-term functionality. In this context, one of the most important goals of today's architectural approaches and circular economy and green economy in developed countries is to design and produce "Reversible Buildings". It should not be forgotten that in architectural design processes, methods and techniques come before anything else. According to "REVERSIBLE BUILDING DESIGN GUIDELINES and PROTOCOL" prepared by Dr. Elma DurmiseVic; "Reversibility is defined as the process of transforming buildings or dismantling them without damaging their systems, products and materials. The building design that can support these processes is the reversible (circular) building design and can be seen as the key catalyst of the Circular Economy and Green Economy in construction. Reversible Building Design is therefore seen as a design that takes into account all life cycle stages of the building and focuses on future usage scenarios. Design solutions that can guarantee a high reusability potential of the building, systems, products and materials and have a high transformation potential are defined as reversible. An important element of Reversible Building Design is the dismantling/dismantling design that allows easy modification of spatial typologies and dismantling of building parts. " In reversible buildings, "dismantling (disassembly), adaptability and reuse (Reuse) "constitute the core of the three dimensions of reversibility and therefore determine the spatial and structural levels of reversible buildings. The less effort required to transform a building and the greater the variety and number of modification options (building reuse options), the higher its transformation potential. Three basic types of transformation have been defined: 1) Mono-functional transformation.' Buildings in this category have the capacity to transform the building typology within a single function. In other words, they can only repeat themselves. 2) Trans-functional transformation.' Buildings in this category have the capacity to transform from one function to another; for example, an office can be transformed into a flat and a classroom without extensive restructuring procedures and effort. 3) Transformable (Multidimensional Transformation): They are completely transformable structures, which can be transformed from one function to another and can also be extended, reduced or moved to another place. Unlike traditional structures, where the design is concerned with functional, technical and physical composition (composition/arrangement), the design of Reversible Structures takes into account functional, technical and physical separation. The most important issue affecting the disassembly potential of structures is the number of relations. In terms of reversibility, "functional separation" is an important criterion. The second important criterion is systematization. Systematization means the basic aggregation of materials to fulfill a certain function. In reversible modules, the independence of assembly sequences, the geometry of the product edge and the typology of connections directly determine the level of damage to the ultimately recovered building products and materials. Today's modular frame systems are load-bearing systems and are generally frame systems made of steel material. Columns and beams under the effect of load are subject to moment, normal force and shear force. The normal force effect is dominant in columns compared to beams. Such load-bearing systems are superior to column-free systems consisting of only beams. The walls used in frame systems have no load-bearing feature, surround, wrap, create and divide the volumes of the structure and are generally used to protect against external effects. In traditional wood frame systems, walls/surfaces are created by nailing slats to the surface and plastering it (Baghdadi) or covering it with wooden timber such as paneling. In prefabricated frame systems, multi-layered "sandwich plates" produced with materials such as concrete, plaster, metal, glass are used in the form of large panels by assembling them on site with tools such as nails, screws, etc. In modular wall structure elements, very different connection/assembly techniques are used. As is known, integrated connections are connections where the geometry of the component edges creates a complete connection. Two basic types of integral connections can be distinguished (i) overlapping and (ii) interlocking. Overlapping connections are generally used as connections between vertical facade components or between vertical and horizontal components. Their disassembly depends on the type of material used in the connection, the assembly order, the hierarchical position of the components and their relations with other components. And as is known, the life cycle of the combined materials, the type of material, the geometry of the product edge and the type of connection affect the assembly/disassembly orders. There are generally two major assembly/disassembly orders, parallel array and sequential array. The interlocking connection in block wall applications -as in the LEGO example- is an internal connection where the component edges are shaped differently and the geometry of the edges only allows sequential assembly. Finally, today, as an alternative to modular systems, there is a tendency towards more compact container shelters that are produced as prefabricated in one piece. These are used especially in construction sites as worker shelters and as temporary disaster shelters in disasters such as earthquakes. Foldable and expandable ones generally offer solutions in the mobile Tiny House market. The biggest problem of containers is logistics. The need for heavy construction equipment such as cranes is mandatory in all stages of production, stocking, storage, transportation and installation. Although foldable container solutions have been produced to reduce the volume they occupy during storage and transportation, these are still solutions that require cranes or need to be carried on large trailers at every stage from the factory to installation. For example, although the foldable shelter solution in the US patent document numbered USl 1555305B2, the Extendable height container and shelter in the US patent document numbered US9080326B2, and the US patent document numbered U88166715B2, which must be carried on a chassis that can be pulled by a trailer truck, and the foldable modular shelter solution in the US patent document numbered U88166715B2 are solved as modular containers, heavy construction machinery and equipment, and even qualified experts are always needed. The complex production process of foldable and expandable container systems and technical details such as high-strength hinge systems and hydraulic arms are also technological parameters that increase production costs. Brief Description of the Invention The purpose of the present invention is to produce a shelter that can be easily transferred to a large number of disaster areas quickly and in large numbers, especially in cases of acute shelter need as a result of natural disasters; that can be easily installed not only by experts but also by unqualified persons, has simple and minimum connection components/elements; that does not require heavy construction equipment, is light enough to be easily carried and installed by two people, and can be locked with a simple tool and can be easily dismantled by reverse operation; that allows the creation of multiple functions and spatial typologies in living and working areas such as shelter, mobile office, warehouse/storage, exhibition, theater/film stage; has high insulation properties; is comfortable, ecological, both environmentally friendly and user-friendly, and truly sustainable; It is related to a DIY reversible construction technique/system consisting of L-shaped modules, which allows the production of a large number of typological forms, with an orderly and harmonic joining and locking system and transformable "all elements of which are in mutual interaction". Detailed Description of the Invention The things that have been done to achieve the purpose of the invention are shown in the attached figures and from these figures; Figure-1. Perspective view embodying the main form and characteristic of the L-Shape, which is the basic element feature of the "L-Module Joint System" of the present invention and consisting of both vertical and horizontal structure components (2 planes), the Floor and Ceiling L-Module, and the joint morphology and connection technical features (product edge geometry, connection typology, holes, pits, socket, etc.); Figure-2. Perspective view embodying the accessory connection elements (Lock tongue, key, dowel) of the "Compression locking technique" of the "L-Module Joint System" of the present invention and the Lock cavity/chamber, which is the working area of the technique; Figure-3. Perspective view of the present invention, embodying the Accordion Insulation Pad, which is the insulation and filling core in the middle layer of L-Modules produced with the Composite Sandwich Panel Technique; Figure-4. Perspective view of the present invention, "L-Module Connection System", the most basic one-unit joint established with two Base L-Modules and identical Ceiling L-Modules, that is, the geometric order and assembly sequence (cluster formation process) within the hierarchy to be followed by its elements/modules, their unification/interlocking, systematization, and the locking with accessory connection set (Lock tongue, key, dowel) after the module cluster is formed, as a stage (A, B, C, K) embodied; Figure-5. The morphology and geometric position of the biaxial and multifunctional Lock cavity/chamber carved into the frame, which is symmetrically located with correlated repetitions with the modular coordination system, within the frames forming each plane structure edge of the L-Modules of the present invention, "L-Module Connection System" Perspective view that concretizes the 3D virtual animation and its relationship with the relevant accessory connection elements (lock latch, key, dowel) separately (A, B, C); Figure-6. The central horizontal section perspective view embodying the morphology of the biaxial multifunctional Lock cavity/chamber, which is symmetrically located within the frames forming each plane structural edge of the L-Modules of the present invention, "L-Module Connection System" and its relationship with the Lock tongue, long and short key accessories; namely the hierarchical relationships between the lock-connection components, the interface geometry, the type and technique of the connections; Figure-7. The central horizontal section perspective view embodying the morphology of the biaxial multifunctional Lock cavity/chamber, which is symmetrically located within the frames forming each plane structural edge of the L-Modules of the present invention, "L-Module Connection System" and its hierarchical relationships with the dowel connection accessories, the interface geometry, the type and technique of the connections; Central horizontal section perspective view embodying the technique; Figure-8. The central horizontal section perspective view of the present invention, "L-Module Connection System, how the mechanism of how the biaxial multifunctional lock cavity/chamber, which is embedded in the frames of the modules that are the basic element and are facing each other during the side-by-side, end-to-end connection, is interlocked with the lock tongue and long key that are inserted and placed inside it and then how it is pulled/compressed to lock, in other words, the hierarchical relations between the L-module connection and connection components, the functional connection/separation, the assembly sequence within the hierarchy and the locking mechanism are gradually shown; Figure-9. The central horizontal section perspective view of the present invention, which shows the turning and compression/pulling of the key head and the key head into the hole after the side-by-end, end-to-end L-Module connection/connection on the same plane. The perspective section view which concretizes the locking by being seated, from the outside and inside (only via the lock mechanism) in stages; Figure 10. The perspective section view which concretizes the corner connection/connection of two perpendicular plane L-Module, the hierarchical relations between the connection components, the functional combination, the assembly sequence within the hierarchy and the locking mechanism by showing them in separate stages from the inside and outside; Figure 11. The perspective section view which concretizes the L-Module Connection System of the present invention, enables the spatial area to be enlarged with other L-Modules, due to the fact that a unit shelter formed as in Figure 4 can be assembled and the L-Modules assembled as in Figure 1-6 can be assembled perpendicular to each other; and those assembled perpendicular to each other can be assembled side by side; in other words, the perspective view that concretizes the ability to change the place of L-Module elements and the geometric order and assembly sequence (cluster formation process and systematization) to be followed by L-modules and I-Module within the hierarchy without a locking stage; Figure 12. The view of the present invention, which gradually shows the construction technique of the Insulation Pad, which provides both insulation and fills by being placed in the gap between the frame mesh, i.e. the grid, in the middle layer of the modules produced with the "Accordion Insulation Pad Composite Sandwich Panel Technique" in the "L-Module Connection System"; Figure 13. Perspective view of the present invention, which gradually embodies the Insulation Pad, which provides both insulation and filler function in the "L-Module Joint System", and thus the resulting "Accordion Insulation Padded Composite Sandwich Panel" module (B) and its technique on the I-Module; Figure-14. The perspective view of the present invention, which embodies the steps of filling the Insulation Pad, which both provides insulation and acts as a filler in the "L-Module Joint System", with perlite granules and placing these perlite-filled pillow cores in the Base L-Module; Figure-15. The side view of the present invention, which embodies the steps of filling the Insulation Pad, which both provides insulation and acts as a filler in the "L-Module Joint System", can easily be made in curved forms; Figure-16. The perspective view of the present invention, "L-Module Combination System and the formation of two unit (two-room) shelter and its modular network (systematization and clustering) in two stages - without locking - concretizing; Figure 17. The perspective view of the present invention, "L-Module Combination System and the formation of three unit (two-room) shelter and its modular network (systematization and clustering) in two stages - without locking - concretizing; Figure 18. The perspective view of the present invention, "L-Module Combination System and the formation of four unit (three-room) shelter and its modular network (systematization and clustering) in two stages - without locking - concretizing; Figure 19. The perspective view of the present invention, "L-Module Combination System and the formation of Cradle Roof Sleeping Unit; and the perspective view that concretizes the interface geometry of the specific L-Module sub-elements, the hierarchical relationships between the elements, the assembly sequence and the modular network (systematization and clustering) in a stepwise manner -without locking- Figure-20. The formation of the Mansard Roof Sleeping Unit corresponding to two units in the Modular Coordination System of the present invention, "L-Module Combination System"; and the perspective view that concretizes the interface geometry of the specific L-Module sub-elements, the hierarchical relations between the elements, the assembly sequence and the modular mesh (systematization and clustering) in a gradual manner -without locking-; Figure-21. The isometric view that concretizes the main form and edge geometry of the Hexagonal Shelter Unit, which is completely identical to the 6 modules of the "L-Module Combination System" of the present invention; Figure-22. The perspective view of the present invention, "L-Module Combination System," which embodies the modular structure of the Hexagonal Shelter Unit established with 6 identical Hexagonal L-Modules; in other words, the geometric order and assembly sequence (cluster formation process) within the hierarchy to be followed by its elements/modules, their unification/interlocking, systematization, and module clustering gradually without a locking stage; Figure-23. The comparative view of the most basic one-unit joint established with the "L-Module Combination System", which embodies the area/volume covered by its installed state with two identical Base L-Modules and Ceiling L-Modules, and the area/volume covered by the stacking/storage form of its state before installation; Figure-24. The comparative view of the total area/volume of the installed form of 8 one-unit shelters established with two identical Base L-Modules and Ceiling L-Modules of the present invention, "L-Module Combination System," and the area/volume covered by the stacking/storage form of its state before installation; Figure-25. The comparative view of the installed form of 10 Crib Roof Sleeping Units established with two identical Triangular Base L-Modules and one Roof L-Module of the present invention, "L-Module Combination System," and the area/volume covered by the stacking/storage form of its state before installation; Figure-26. The comparative view of the total area/volume covered by the installed state of 6 Mansard Roof Sleeping Units established with two identical Truncated Triangular Base L-Modules and Mansard Roof L-Modules of the present invention, "L-Module Combination System," and the area/volume covered by the stacking/storage form of its state before installation; Figure-27. The perspective view of the present invention, "L-Module Combination System," consisting of configuration/transformation options with different sizes and functional area features obtained by changing the place of the sub-module elements in the L-Module family, collectively concretizing some of the shelters in different spatial typologies; The parts in the figures are numbered one by one and the corresponding numbers are given below: 1) Base L-Module lk) Door Base L-Module 2) Ceiling L-Module 2p) Windowed Ceiling L-Module 3) Lock tongue 3d) Lock tongue Key Socket 4u) Long Key 4k) Short Key ) Key Head 5y) Key Head Socket 6) Key Tip 7) Lock cavity/chamber 8) Dowel 9) Accordion Insulation Pad 9a) Insulation Pad Air Holes 9p) Perlite Granule 9s) Insulation Pad Septum 9y) Strip Tape ) Frame Lock-Connection Hole 11) Panel Lock-Connection Hole 12) Seal Strip (Passing Strip) 13) Seal Strip Lock-Connection Hole 14) Groove (Interlocking groove) ) Frame (Structure system) 16) Panel 17)Half I-Module 18) Triangular Base L-Module 19) Roof L-Module ) Truncated Triangular Right Base L-Module 20p) Truncated Triangular Right Base with Window L-Module 21) Truncated Triangular Left Base L-Module 21p) Truncated Triangular Left Base with Window L-Module 22) Mansard Roof L-Module 23) Single Shelter Unit 24) Crib Roof Sleeping Unit ) Mansard Roof Sleeping Unit 26) Hexagonal L-Module 27) Hexagonal Shelter Unit In accordance with the preferred embodiment of the present invention; The subject of the invention is "Reversible and DIY Modular Shelter System consisting of L-shaped modules" in its most basic form, - Based on an anthropometric "Modular/Dimensional Coordination and grid system"; - The main element of the modular system has an L-shaped form and distinctive characteristics, and it includes the integrated connection/interlocking of 4 "identical" "interacting" L-Modules in their most basic form in 2 pairs, - Locking of L-Modules by compressing them with keys inserted into the double-plane, multi-functional Lock cavity/chamber, - and the application of the Accordion Insulation Pad (9) obtained by folding, and the clustering and systematization of shelters made with the module sub-elements produced with the composite sandwich panel technique providing high quality and healthy insulation, and the configurations and performative combinations of modular elements. The specification subject to the invention, each technique/component or component group is explained under a separate title for ease of reading: This technique subject to the invention is based on the principle of dividing a hollow cube structure consisting of 6 surfaces and walls into 4 parts, or in other words, constructing it with 4 module parts. Thus, we encounter L-shaped morphologically identical formations (l, 2) that have two perpendicular planes and are connected to each other at the corners, in other words, that carry both vertical and horizontal structural components. (Figure-l and Figure-4) While this form morphologically covers the entire surface of a cube (vertical structural component), it covers half of the adjacent vertical surface (horizontal structural component) at the corner. Thus, the resulting Base L-Module (l) can stand without needing any support. When we place the Ceiling L-Module (2), which we can describe as turning the Base L-Module (l) upside down, on this Base L-Module (l) without any assembly, we can obtain a formation with a half-ceiling and standing by the effect of gravity. In other words, the composition/arrangement principle is also quite simple. When we realize this composition with 2 pairs of L-Modules in a mutual and symmetrical manner, we can easily obtain a spatial structure with 6 closed surfaces. When we make this technique and make the module weights with a weight and thickness that can withstand lateral forces (for example with concrete), we can obtain a structure that can stand completely by the effect of gravity without using any connection apparatus or stabilizer. The subject of the invention is that a small shelter can be easily built with 4 semi-identical module parts of this technique. Instead of making module units smaller, creating a small number of "easy to manage" large units provides fast assembly capability. This feature is provided by the L-shaped main form of the modules, the geometry of the edges of the modules, the interface design, the integrated connection type assembly sequence or relationship. Thanks to the L-shaped Module; a high-performance modular shelter solution that is easier to store, transport and assemble/disassemble, faster and cheaper is achieved. In the technique in question, since our main purpose is to realize a light and yet durable L-Module that does not require heavy construction equipment, the "L-Module Jointing System" has been developed to provide a connection/interlocking resistant to especially lateral forces such as pushing, pulling, shaking after the integration of the L-Modules. While developing this technique, our source of inspiration was the joining system of the skull bones. As it is known, the Parietal (side) cranial bones rise from right to left and twist and fuse/articulate strongly with an interlocking/interlocking called cranial suture at the top midline. The "L-Module Jointing System" in question has found its final solution by being inspired by this existential principle. The technique in question is an integrated connection system/technique characterized by the fact that two different types of (semi-identical) L-Module elements (1, 2) are placed perpendicular to each other horizontally from the top, and in the vertical plane they pass/interlock from the side, in other words, they are locked with an "Accessory connection" after the process (Figure-8, 9, 10). The L-Modules of the technique in question are basically composed of two different identical modules (1, 2) and the geometric interface and edge geometry that provide the interlocking of these two, in other words, the joint morphology. The wall edges of both different types of identical modules have the feature of Groove (Interlocking groove) (14) all around, which we can morphologically call a female socket. This edge geometry is captured by the dimensions of the panels (16) laminated from bottom to top to the frame (15) forming the structure of the module walls produced with the composite sandwich panel technique, as seen in Figure-13 (Figure-13). This method, which is also carried out without any additional processing (e.g. cutting-sawing, carving-scraping), also reduces the labor cost. In plastic-based composite productions, this groove (14) morphological formation is shaped with a mold. Again, on each identical module, there is also a Seal Strip (12), which we can call a male protrusion morphologically. This seal strip can be fixed or portable. It can be fixed in place during module clustering or systematization. It is believed that being fixed prevents the friction and thus damage of the stacked L-Module surfaces, especially during transportation. It is also useful because it functions as a wedge/separator. While the Seal Strip (12) is located on the inner surface parallel to the edges on the opposite sides of the Base L-Module (1) only on the horizontal plane, it extends continuously along the inner surface of the vertical wall and ceiling of the Ceiling L-Module (2) and is located on the opposite sides, parallel to the edges (Figure-1). This male and female morphological interlocking feature (12, 14) is repeated in the geometry, morphology, depth/thickness and width of all modules without the slightest modification. This geometric feature reduces the complexity required to half-join all the lower L-modules, provides simplicity and convenience, and also eliminates the need for manual work, shortens the assembly time, provides rapid installation and thus reduces the total cost. The Seal Strip (12) is a free connection element used by being embedded externally into the groove (14) before the connection in both horizontal plane (horizontal structure component) connections and end-to-end module connections (sequential alignment connections on the same axis and plane) (Figure-4B). In the technique which is the subject of the invention, as seen in Figure-1, during the modular stacking, the Seal Strip (12) extending along the vertical and horizontal inner wall surface of the Ceiling L-Module (2) and the Groove (Interlocking Groove) (14) extending along the side-outer and top-outer edges of the vertical wall of the Base L-Module (1, 1k) overlap and slide into them. (Figure-4G, 41) The Groove (14) on the bottom-outer edge of the Ceiling L-Module (2) passes from above onto the Seal Strip (12) on the inner surface of the horizontal plane of the Base L-Module (1, 1k) facing the ceiling and the connection is completed by fixing. (Figure-4H, 4K) In the technique which is the subject of the invention, the interlocking of identical L-Modules, i.e. their integrated connection (1 with 1, 2 with 2) They can be connected in different variations such as symmetrically and reciprocally on the horizontal components from the midline of the horizontal plane (Figure-4B, 4C and Figure-41, 41); again on the horizontal plane from the outer edge and outside the L-Module corner (Figure-11); edge to edge (Figure-16) or back-edge (Figure-18). In all other connections except the connection of the Base (1) and Ceiling (2) L-Modules, the integrated connection is achieved by passing the mobile Seal Strip (12) externally into the grooves (14) on the edges of the connected L-Modules as in Figure-4B. In the technique in question, since these two morphological integrated connection/interlock formations (12, 14) on L-Modules provide a closed integrated connection within themselves during clustering and systematization, in the formation of a unit shelter (23), especially in daily temporary uses, it may be sufficient to make only a single accessory connection lock (3, 4) in the symmetrical joints of the horizontal components of the Ceiling L-Modules (2). In other words, it does not even require the use of other accessory connection elements (3, 4, 5, 8) in other joint interfaces. Even the feature of the shelter formed with this single connection to stand firmly without falling apart or separating distinguishes the technique in question from many modular systems. Accessory connection elements (3, 4, 5, 8) are elements that strengthen the systematizations that form the structure, stitching and stiffening it almost inseparably, as in the skull. For this reason and for ease of follow-up, the description and specifications of these elements will be made under a separate heading. The other sub-module components of the "L-Module Jointing System", which is the subject of the invention, are 2 identical Triangular L-Modules (18) and 1 Roof L-Module (19) which are basically L-shaped, forming the Cradle Roof Sleeping Unit (24) and 2 identical Truncated Triangular Right Base L-Modules (20, 20p), 2 identical Truncated Triangular Left Base L-Modules (21, 21p) and 2 identical Mansard Roof L-Modules, which are basically L-shaped, forming the Mansard Roof Sleeping Unit (25). (22) These two spatial typological forms (24, 25) are not very comfortable on their own, except in emergencies, difficult climate and natural conditions, and wetness caused by rain and snow. They can be used as an alternative to simple and traditional shelter solutions such as tents, which are not very successful in protecting people from cold and therefore hypothermia, storms, floods, etc. (Figure-19, Figure-20), and they can also be used to create roof compositions in order to increase the functional area by being included in shelter systematizations in different derivatives and configurations, integrated with the basic L-Module elements, which are the subject of the invention. (Figure-27) Another sub-module component of the "L-Module Jointing System", which is the subject of the invention, is the Hexagonal Shelter Unit (27) and is completely identical to the L-Modules of other typological forms that emerge with modular systematization, unlike the L-Modules (Figure-21). This module also carries 1 vertical and 1 horizontal structural component. Under normal conditions, constructing a structure with a hexagonal base form is quite complex due to this form and consists of a total of 8 surfaces/sections, roughly 6 vertical and 2 horizontal structural components. The Hexagonal Shelter Unit (27) of the system, which is the subject of the invention, is easily installed with a total of 6 L-Modules (Figure-22). Because especially the base and ceiling structural components are one piece or multiple pieces. Instead of being in pieces, it can be constructed in 3 identical pieces that are completely identical to each other. This both provides ease of assembly and eliminates the risk of making mistakes, and ensures a perfect result quickly. As mentioned before, it is also easy to open gaps such as doors and windows from the desired place later. Because the entire module family consists of a single identical L-Module. The subject of the invention, "L-Module Jointing System", roughly and in its simplest form, a cube structure (Hexagon mentioned above) that we can build in 6 stages with 6 parts/sections, is reduced to 4 parts and 4 stages, while a speed of 1/3 is gained in every process from production to transfer, from transfer to assembly, and especially thanks to their ability to be stacked one inside the other, bottom to bottom, a unique logistic advantage is provided even compared to foldable container systems. Because in order to make a container shelter solution foldable or expandable, the minimum wall thickness is at least 2 times more than the thickness of the L-Module subject to the invention. Therefore, even if the container is folded, the volume it occupies is approximately 2 times more than the volume occupies when stacked by L-Modules. It will be 1.5 times more. The shelter variations and derivatives made with the "L-Module Jointing System", which is the subject of the invention, are concretized in Figures-23, 24, 25, 26 in a way that will reveal this logistic advantage. Even in the Single Shelter Unit (23), when disassembled, at least 66.66% of the space is gained in the base comparison even without taking into account the empty areas in front of the inner corner of the L shape for a single module. As the number of Units to be carried or transferred increases, for example, in the case of the establishment of 8 Single Shelter Units (23) as seen in Figure-24, this logistic advantage increases 4 times. For example, while only 2 container shelters can be carried by a truck with dimensions of 2.6 X 13.5 m, the inventive "L-Module Jointing System" can carry at least 25 Single Shelter Units (23), 16 Twin Shelter Units (23+23). With this feature, the need for storage space after production is significantly reduced, while a unique logistic advantage is achieved in disaster situations requiring acute intervention. In the inventive "L-Module Jointing System", L-Modules are produced especially and primarily from wood, the only renewable construction material in the world. Wood, due to its structure, is both lighter and more durable than other construction materials of the same dimensions (e.g. steel). Its flexibility is another structural advantage. In this case, it can be produced approximately 3 times lighter than containers produced with metal materials. The inner and outer surfaces of the sandwich panels of L-Modules are laminated with single-piece industrial chipboards. This composite sandwich panel lamination technique stiffens the modules with a carrier structural frame mesh and significantly increases durability. Again, this weight advantage can be easily maintained in L-Modules, which are produced with a composite technique, especially from recycled plastic. And this feature creates an alternative to technical solutions that can be considered primitive, such as tents. Because of this lightness, it does not require any heavy construction equipment, can be easily carried by two people, and when evaluated together with the low number of parts in the assembly line, simplicity of assembly and ease of use, a shelter solution that is even faster than a tent is obtained. The subject of the invention is the "L-Module Jointing System and L-Modules, can be easily customized, as in Figure-4, a window opening can be opened in the desired area of the Ceiling L-Module (2p) wall. This can be produced prefabricated or it can be opened later in accordance with the modular coordination system when needed. (Figure-19, 20) This process done later never weakens the modules structurally. Because L-Modules get all their strength from the integrity/compactness of the corner structure where 2 planes (vertical and horizontal structural components) come together, just like in the keel of a ship. As it is known, the weakest points of prefabricated modular solutions are the connection/joining points. In the "L-Module Jointing System", the corners actually hold the shelter upright. For this reason, it is different and advantageous compared to other modular systems. Both electricity, water and drain installations can be easily adapted to the L-Modules. L-Modules corresponding to sections such as bathrooms and WCs can be easily adapted and transformed in accordance with wet floor standards. In the "L-Module Jointing System", which is the subject of the invention, the wall thicknesses of the L-Modules can be easily reduced and added according to requests and expectations. Adaptations/productions can be made that correspond to different levels of (increased or decreased) solidity and strength expectations. Dimensions can be scaled, smaller or larger L-Modules can be produced. For children, even L-Modules can be produced in small sizes from wood, and in mini sizes as toy versions with molded plastic raw materials. As the dimensions and wall thickness increase, apart from the necessity of heavy construction machinery, it does not require any modifications other than morphologically making size adjustments, especially in the accessory lock connection (3, 4, 7, 8) system. In the "L-Module Jointing System", which is the subject of the invention, curved typological forms can also be easily adapted. There is no need to make a separate foundation for the ground for shelters built with the L-Module family, because the components that will form the floor slab of a shelter are automatically within the Base L-Modules (1, 1k). In order to provide a water level, the shelter can be easily built directly on these planks by placing planks, for example, in a way that will lift it off the ground. These and other similar features have not been included in the file, as they do not change the basic elements of the "L-Module Jointing System", which is the subject of the invention, and in order not to make the patent file more complicated. The elements of the invention are the other complementary technical arrangement of the "L-Module Jointing System", the Compression Locking Technique, and accessory connection elements. (3, 4) The most important feature of this technique, the subject of the invention, is that all lock connection elements (3, 4, 8) except the lock cavity/chamber (7) can be used mobile, externally and preferably. In other words, none of the relevant accessory connection elements (3, 4, 8) are fixed in place before the L-Module assembly sequence and systematization. The subject of the invention is the morphological joint formation Locking cavity/chamber where the "Compression Locking Technique" functions. (7) This morphological space/cavity is a repetitive space carved into the structural studs (15) that work simultaneously on two axes, have 3 functions, surround the L-Module bodies. As seen in the 3D virtual animation in Figure-2, it is located exactly in the center of the vertical axis of the stud (15) and is repeated in correlation with the Modular Coordination Grid System specific to the modular structure system of the invention (Figure-1, Figure-4A, Figure-13). It is a space with 2 blind wells, having 2 entrances (entry holes) on 2 planes/surfaces (Figure-5, Figure-6A). These 2 entrance holes (10, 11) are on two adjacent perpendicular surfaces/planes of the frames (15) (Figure-5). While the Frame Lock-Connection Hole (10) is located on the outward facing edges of the frames (15) that form the structure of the L-Module bodies and are located in the middle layer of the sandwich panel wall, in other words, it is located within the Groove (14) line on the side outer edges of the modules; the Panel Lock-Connection Hole (11) is located on the inner surfaces of this frame (15) mesh (Figure-13A) that surrounds the edges of the L-Module bodies and the continuation (projection) of this hole continues on the panel laminated on the frame. (Figure-13B and Figure-1, 9, 10) The only difference between these two entrance holes is the morphology of the mouth of the Frame Lock-Connection Hole (10) and the Key Head Slot (5y) (Figure-5B) where the key is pushed and seated after the tightening process by turning the Short Key (4k) and which has the function of preventing the key from returning. This Key Head Slot (5y) which fulfills the function of preventing the key from returning after tightening, has the same morphological formation on the module panels; that is, it is also located at the mouth of the Panel Lock-Connection Hole (l 1) (Figure-9, 10). The morphology of this Lock cavity/chamber (7), which we can call the working area of the "Compression Locking Technique", which is the subject of the invention, is arranged/carved in a way that both the lock tongue (3), the key (4u, 4k) and the dowel (8) can fit (Figure-5, 7A). Therefore, it is a 3-function cavity. These accessory connection elements (3, 4, 8) can be easily combined in a way that will meet the expectations of different levels of strength and durability. For example, as seen in Figure-4D, while using 2 lock tongues (3) and 2 keys (4u and 4k) fixing them on the same connection line, 4 dowels (8) can be used. The number of dowels (8) can be reduced or the locking bolt (3) can be reduced to one or the entire locking bolt (3) and key (4) combination can be used. In this way, a kind of stitching is made internally along the joint line; in other words, locking can be done from multiple points, just like the cranial suture of the skull. The subject of the invention, "Compression Locking Technique", which we can call the working cell, this Lock cavity/chamber (7) is quite simple and easy to apply on L-Modules during production in today's computer-aided production age. It is not as complex as the lock apparatus used in the assembly of conventional sandwich panels, and there is no extra assembly stage to place this apparatus inside the panel, that is, it does not require extra labor. Therefore, the cost of part production and assembly is also low. It is easy and practical to use, disassemble, change the places and directions, and change the numbers and combinations of the accessory connection elements (3, 4, 8) during assembly/installation (Figure-5, 6). In L-Module assembly variations or spatial typology transformations, the lock axes/directions and locations can be easily determined. Since it can be changed (Figure-6, Figure-7), it raises the level of adaptability, which is one of the most important criteria of reversibility in structures, and disassembly standards without damaging the modules. Since reversible structure design is a design process that takes into account all life cycle stages of the structure and focuses on future usage scenarios, the subject of the invention, "Compression Locking Technique", significantly increases the transformation potential in structures. Because the less effort is required to transform a structure, the higher the functional independence and exchangeability of the elements, the higher the transformation potential. In the subject of the invention, "Compression Locking Technique", the hierarchical relationship between the elements, the assembly sequence and the working mechanism are as follows: After the L-Modules to be joined and the joining lines are planned in advance, the direction of the joining movement is decided (Figure-8, 9, 10). In other words, from top to bottom vertically, or from front to back horizontally (transversely) or from right to left (or vice versa)? According to these parameters, first the Lock Bolt (3) is inserted through the Lock/Connection Holes (10, ll) and placed in the Lock cavity/chamber (7) (Figure-6B and Figure-8A). The placed Lock Bolt (3) is inserted through the Lock/Connection Hole (10, ll) in the open vertical axis with the key (4u/4k), and the Lock Bolt is passed through the Key Slot (3d) and placed in the Lock cavity/chamber (7) and thus one end of the Lock Bolt (3) is fixed in the relevant module (Figure-6C, 6D and Figure-SB, 8C). Then the other L-Module to be combined is brought close and inserted through the Lock/Connection Holes (10, l 1) on itself, through the half-moon shaped Lock Tongue Key Slot (3d) on this fixed-end Lock Tongue, pushed/slided and fitted into place (Figure-8D, Figure-lOA(i), B(i)). After the two L-Modules are combined, the exposed end of the Lock Tongue (7) is passed through the Lock Tongue Key Slot (3d) with the key (4u/4k) inserted through the exposed Lock/Connection Hole (10, l 1), but it is not fully fitted into the Lock cavity/chamber (7) as in the previous process (Figure-8D, 8E and Figure-9A). If the tightening process is not deemed necessary, it can be pushed all the way and placed in the Key Head Slot (5y) (Figure-10B, 10C). Then, the key (4u) is connected tightly to each other by turning it 90O with a tool that grasps the square key head (5) (it is not deemed necessary to show it in order not to create confusion in the shape, to facilitate understanding and because it does not change the basic elements of the technique) until there is no gap between the two L-Modules (Figure-SF, 9A, 9B). In the last step, as seen in Figure-9B and Figure-9C, the relevant key (4u, 4k) is pressed from above towards the Lock cavity/chamber (7) and placed in the Key Head Slot (5y), thus the connection is both compressed and completely locked. The third element of the accessory connection elements, the dowel (8), has the functions of facilitating the assembly of the module mesh, aligning the two planes that meet in the midline joints, and providing support and reinforcement against stretching, rather than locking. An important feature of the invention "L-Module Jointing System" is the Accordion Insulation Pad (9) and its production technique (Figure-3, 12C), which allows us to produce lightweight and high-strength L-Modules as well as composite sandwich panels with high insulation and no harm to human health. As can be easily understood from its name, Accordion Insulation Pad (9) is obtained by origami folding technique (Figure-12A, 12B). It can be produced from recycled paper or recycled plastic, corrugated paperboard or corrugated plastic sheet, and even very thin metal sheet. This origami folding technique and production process is an easy, practical and cheap method. While transforming a 2-dimensional object into a 3-dimensional one by just folding it. (Figure-12A, 12B), in the middle of the geometric form of the folding and the morphological structure of the resulting 3-dimensional volume, a double-walled and very porous air space (9a) is obtained. (Figure- 12C). These Insulation Pad Air Pores (9a) form compartments/air chambers with triangular borders within themselves, just like the "septum" structure that separates organs or cavities into sections in living anatomy and creates thin curtain partitions. As it is known, the air space created in the intermediate layer, as in double-glazed applications, provides quite good insulation on its own. Since there will be no heat transfer in the absence of the substance, thermal conductivity levels decrease significantly. The lower the dry air space volume, the higher the efficiency. Therefore, the Accordion Insulation Pad (9) obtains this high insulation feature thanks to the Insulation Pad Septum (9s) that separates the middle layer into triangular prism shaped air chambers; in other words, from its geometric structure consisting of multi-chambered Insulation Pad Air Pores (9a). This insulation feature increases even more in those produced from corrugated paper cardboard or corrugated plastic sheet. Because these corrugated sheets also contain air pores between the grooves in their own structure. In this case, a 3-layer, multi-chambered, wavy air gap weave/structure emerges. The subject of the invention "Accordion Insulation Pad, (9) technique, this Insulation Pad Septum, (9s) has another advantage that it also serves as a filler in the sandwich panel system (Figure-13). In the components known as American Door System in the market, this filler function is performed by paper honeycombs. In most sandwich panel systems, including those with wood particle board laminates, plastic foams such as EPS, XPS, which also have insulation properties, serve as this filler. However, most of these are not ecological and recyclable, and at the same time, they are solutions that can be harmful to health due to their chemical properties. The subject of the invention "Accordion Insulation Pad, (9) is folded and formed, and then placed directly in the gaps surrounded by the grid mesh of the frame (15) forming the structural structure of the L-Module wall panels, as shown in Figure-13A. As seen, it is placed as it is and the process is completed by laminating the last panel, which is the third layer of the sandwich panel. This process is repeated for both planes/structure components of each L-Module. Thus, "Accordion Insulation Pad 21, 22, 26) are produced. Another important advantage of the "Accordion Insulation Pad (9)", which is the subject of the invention, is that it has (Figure-14). It is also an important advantage that it can be used by pouring/emptying freely as it is, without requiring any chemical binder or freezer for this filling process. After applying double-sided tape (9y) perpendicularly to the folding lines of the folded "Accordion Insulation Pad (9)" (Figure-14A), one of the open mouths of the Air Pore of the Insulation Pad (9a) is taped (Figure-14B) and then filled with fine perlite granules (9p) (Figure-14C) and the filling process is completed by taping the other open pores (Figure-14D). (This taping process is not required in Accordion Insulation Pads made of thin metal sheet.) After filling the air pores (9a) separated by septums (9s) with perlite granules (9p) with this very simple method, the Accordion Insulation Pads (9) are placed in the spaces surrounded by the grid mesh of the frame (15). (Figure-14E), after the panel is closed, this multi-chambered/compartmental filling is trapped and remains as it is thanks to the septums. While the Insulation Pad Septums (9s) provide topological homogeneity as they limit the pores, they also act as a curtain that prevents the granule pile from collapsing and dispersing just like the bee's honey is filled into honeycombs. Thus, while a "Super-Insulated" sandwich panel system is obtained, the sandwich filling is also strengthened with the mass of this filled granule pile. Materials in the category of super insulation materials such as "fine perlite" differ from their counterparts (glass wool, rock wool, EPS, etc.) with their extraordinarily low thermal conductivity values. Moreover, perlite is abundant in our country, so much so that 75% of the world's reserves are found in Turkey. A sandwich L-Module made with perlite filling is almost 5 times less costly and 4 times lighter than glass wool, and provides much superior "super-insulation". Moreover, it is ecological, environmentally friendly because it is obtained from volcanic rocks, that is, it is not harmful (eg: non-carcinogenic), rodents and insects cannot live in it, and it does not require the use of toxic chemicals such as pesticides to protect the panels. It is fireproof, resistant to very high temperatures and very light. The subject of the invention, "Accordion Insulation Pad Composite Sandwich Panel Technique", another important advantage is that it can be easily adapted to curved typological forms and changing wall thicknesses as embodied in Figure-15. This advantage is achieved thanks to the origami folding technique of the Accordion Insulation Pad (9) that can be adapted to every form and the resulting Septums (9s) and the feature of easily filling the Insulation Pad Air Pores (9a) with perlite granules (9p) as mentioned above. As it is known, the affordable high volume production of sandwich panels with complex curvature and variable thickness requires quite difficult and complicated processes and techniques. The technique and system in question of the present invention is based on the multiples of the base module on which all L-Module elements are sized. It includes a 3-dimensional fixing/grid system developed. This Modular Coordination and grid system includes a relationship in which all sub-modules from Triangular L-Module (18) to Hexagonal L-Module (26) are placed on each other and interact with each other in a unique geometric space. Thus, it becomes easily possible to construct non-orthogonal typological forms in modular form, including curved/curved surfaces, tapering, twisting, polygonal (Figure-22) etc. Thanks to this Dimensional Coordination, it is possible to eliminate fractional element and module sizing, customize modules (make them specific to the person/project), make optimum use of production labor and provide logistic conveniences, reduce labor in assembly due to wasted time, increase assembly speed and accuracy by minimizing the possibility of making errors, and minimize material loss. And also this "Modular/Dimensional Coordination and grid system, can be easily scaled (Scaling) as it is in 3D space - without any modification or revision in the technique - and by reducing the dimensions of all L-module sub-elements, for example, it can be turned into a modular toy for children - and moreover wooden. By increasing the dimensions even further, it is possible to build huge hangars, temporary exhibition spaces, etc. The frame (15) mesh that forms the structure of L-Modules is also placed in accordance with this Modular Coordination and grid system. Therefore, performative combinations can be made along these grids. Therefore, countless alternative modular clusters and systematizations can be made without any problems (Figure-27). The only condition for this is to have specialized sub-assemblies for alternative combinations as mentioned above. In order to make L-Modules and to make these connections, it is sufficient to pre-carve the lock cavity/chamber (7) in the intermediate profiles forming the frame network. These and similar other features have not been included in the file since they do not change the basic elements of the "L-Module Jointing System", which is the subject of the invention, and in order not to enlarge the patent file. As can be seen in the formation of the combination/derivative option of the "Single Shelter Unit (23) and Hexagonal Shelter Unit (27)", which is the subject of the present invention (reversible) structure system and embodied in Figure-27, the advantage of the "Dimensional coordination system" and the L-Module Jointing System, which are oriented towards mathematical perfection, in managing complex geometries, helps us to redefine the boundaries of modularity, to establish new relationships between form definition and geometry. As it is known, the modification of the structural units of the systems changes the system it belongs to and therefore the structure and architecture of the city, and therefore its culture. The technique(s) subject to the present invention will also provide high performance (efficiency) in addition to high reversibility potential. As is known, "performance" is a term and concept that offers an alternative to optimization. Although structural optimization, in particular, is usually aimed at a single parameter or aspect of a project, increased performance is achieved when multiple requirements of a project are in a state of balance. This performance that can be achieved with the present invention is provided by "all elements being in mutual interaction". This means orderliness and harmony; it can help meet the need for a versatile and interrelated complete component system/structure technique. Some adaptations and modifications of the described arrangements can be made, and they can be produced with different materials and techniques. Therefore, it is accepted that the arrangements discussed above are explanatory and not restrictive. Any reference in this specification to any previous publication (or information derived from it) or to any known subject matter is not, and should not be taken as, an acceptance or denial of the previous publication or any form of recommendation. Any content that is known and disclosed constitutes a part of the general knowledge in the field of study to which this specification relates.TR TR TR TR TR TR

Claims (5)

1. The form and distinctive characteristic of the main element of the modular system is L-shaped; It has an L-Shaped Base L-Module (1, 1k) consisting of two planes perpendicular to each other, carrying the horizontal base on one wing and the vertical structure component on the other wing; It has an L-Shaped Ceiling L-Module (2, 2p), which consists of two planes perpendicular to each other, carrying the horizontal-ceiling on one wing and the vertical structure component on the other wing, simultaneously; It has an L-Shaped Triangle L-Module (18) consisting of two planes perpendicular to each other, simultaneously carrying a horizontal-base on one wing and a vertical triangular structure component on the other wing; It has the L-Shaped Roof L-Module (19), which consists of two planes perpendicular to each other, carrying the oblique (slanted) structure component on both wings at the same time; It has an L-Shaped Truncated Triangle Base L-Module (20, 20p, 21, 21p) consisting of two planes perpendicular to each other, which simultaneously carries a horizontal base on one wing and a vertical truncated triangular structure component on the other wing; It has an L-Shaped Mansard Roof L-Module (22), which consists of two planes perpendicular to each other, simultaneously carrying a horizontal-ceiling on one wing and an oblique (slanted) structure component on the other wing; It has an L-Shaped Hexagonal L-Module (26) consisting of two planes perpendicular to each other, carrying a horizontal-parallel edge base on one wing and a vertical structure component on the other wing; 2. According to claim 1, the geometry of the wall edge of each module has the feature of being surrounded by grooves (engagement grooves) (14), which we can call morphologically as female slots; Again, on the inner surface of each module, which we can call morphologically male protrusion, on the Base L-Modules, it is only on the horizontal plane on two opposite edges and parallel to the edges, while on the Ceiling and Roof L-Modules, it is on the inner surface of the vertical wall and ceiling, extending from end to end and on two opposite edges. , has the Seal Bar (12) located parallel to the edges; Apart from the basic connection of the Base (1, 1k) and Ceiling (2, 2p) L-Modules, all other connections such as back-to-back, side-by-side, width-to-side, etc. are modularized by externally inserting the Mobile Seal Bar (12) into the Grooves (14) on the edges of the L-Modules. The integrated connection is created; The edge geometry of all L-Module sub-elements is basically arranged/designed on the principle of integrated connection or interlocking of these two Grooves (14) and fixed or free Gasket Strip (12), and the geometry of the component edges forms a complete connection; L-Module is an internal structure that can be made in many different ways by changing the location of the sub-components, offers different size and functional area configuration / transformation options, and can be easily transferred to many disaster areas quickly and in numbers, especially in cases of acute shelter need as a result of natural disasters. Offer a unique logistics advantage thanks to its stackable feature, on top of the Base L-Module (1), which can be easily installed not only by experts but also by unskilled people, and can stand alone without the need for any support even on sloping ground, this Base L-Module can be turned upside down. “L-Module Jointing System”, which is based on the principle of overlapping/joining the Ceiling L-Module (2), which can be described as; 3. Each element arranged according to claim 1 and claim 2 works on a specific technique for the technique that is the subject of the invention, and determines the mesh of the framework (15) system, that is, the grid system, which forms the structure of each module and all kinds of dimensioning, and thus determines the grid system of each sub-module and It has an anthropometric "Modular/Dimensional Coordination and grid system" that allows the lock-connection system to interact; 4. After the integrated connection or interlocking of each sub-element of the "L-Module Jointing System" arranged according to claim 1, claim 2 and claim 3, it is carved into the framework (15) and arranged to work on two different axes. Input/exit holes (10, 13) on the Slots (14) on the edges of the L-Modules and the corresponding (passing) Seal Strip (12) and on the panel edges, repeated in a number and manner in accordance with the "Modular/Dimensional Coordination and Grid System" It also has a double-axis multifunctional locking cavity/reservoir (7) with entry/exit holes (11) into which the accessory connection elements (3, 4, 8) can enter and exit without being fixed; The Lock Latch (3), which is placed in this Lock cavity/chamber (7) by inserting it from the Lock/Connection Holes (10, 11, 13), is inserted through the other (open) hole (10, 11, 13) which is perpendicular to the hole where this Lock Latch is placed. , which is placed in the Lock cavity/chamber (7) after being passed through the half-moon-shaped Lock Stud Key Slot (3d) thanks to its specially shaped key tip (6), thus fixing one end of the Lock Stud (3), and also the Lock Cavity. After turning the Key Head (5) 900° without fully seating the lock cavity/chamber (7), it pulls and tightens the lock tongue, and therefore the module to which it is connected, towards the direction in which it is turned, and then is pushed towards the Lock cavity/chamber (7) and into the Key Head Slot (5y). It has a long (4u) and a short key (4k) that completely locks the integrated connection when inserted; and also has the dowel (8), which is inserted into the Lock cavity/chamber (7), which is optional and used in a mobile manner, and which functions to facilitate the assembly of the module mesh, that is, the assembly, to align the two planes that meet in the midline joints, and to be a support and strengthener against stretching. “Compression Locking 5. It is compatible with the mesh of the frame (15) system, that is, the grid system, which forms the structure of each module arranged according to claim 3, and fills the space between these grids; Obtained by origamic folding technique; It can be folded not only in straight but also in curved forms, and can be produced from recycled paper or recycled plastic, corrugated paper, cardboard or corrugated plastic sheet or even thin metal sheet metal to be lightweight; When folded, a double-walled and very porous air space (9a) is obtained in the middle of its morphological structure; It also functions as structural filling thanks to the Insulation Pillow Septum (9s), which separates the triangular prism-shaped air chambers that form the morphology of the middle layer as a result of the folding technique; It has the Accordion Insulation Pillow (9), which after a series of processes can be filled with perlite granules (9p) in the air pores (9a) separated by septums (9s), thus providing “Super-Insulation”; and Accordion Insulation Pillow, produced by the technique of laminating the Accordion Insulation Pillow (9) with the double-sided panel (16) after placing it in the gaps between the mesh of the frame (15) system, that is, the grid system, and which is very light and durable, as in any of the above claims. A DIY, reversible modular shelter technique/system consisting of modules.