Multi-functional building wall module system

Abstract

A building wall module system (1) has a frame structure (2) comprising a wall side region (9), a wall cladding region (8), a passage region (6) between the wall side region (9) and the wall cladding region (8), and a rail system (12) extending above the passage region (6). In the application of a sliding door (4) inserted into the frame structure (2), the rail system (12) can move the sliding door (4) between a closed position, in which the sliding door (4) closes the passage region (6), and an open position, in which the sliding door (4) completely or partially opens the passage region (6). If the sliding door (4) is not to be used, a frame insert (22) can be inserted into the passage region (6). The frame insert (22) has connection elements which, in the inserted state, connect the frame insert to the frame structure (2) and, when removed, separate the frame insert from the frame structure (2).

Description

Technical Field

[0001] The technology described herein generally relates to the technical equipment of buildings. In particular, embodiments of this technology relate to a building wall module system and a method for adapting such a building wall module system to a building. Background Technology

[0002] Buildings can be equipped in various ways to define interior spaces or areas in a building plan or its use. It is also possible to determine how to allow or prevent people from entering a building or interior space, such as through doors, gates, or barriers. For example, it is known that when erecting building walls constructed of brick, concrete, and / or dry-layout materials (e.g., timber and / or metal structures combined with drywall), door frames (door borders) are installed in predetermined positions and doors are inserted therein. In such door systems, doors can be designed as stop doors with movable door leaves fixed to the door frame (border, door lining) in a rotatable manner using two or more hinges (door hinges), or as folding doors in which one or more door wings are divided into multiple parts by hinge bands or flexible strips that unfold from the closing plane when opened. Door systems with sliding doors are also known, which are fixed to a frame by tracks, with the door leaves suspended or inserted into the tracks and capable of lateral displacement. For example, EP2876241A1 describes a sliding door system in which the sliding door is movable between a closed position and an open position within a frame structure. In the closed position, the sliding door is flush with a wall surrounding it, and in the open position, a recess in the wall at least partially receives the sliding door. Summary of the Invention

[0003] The division of interior spaces or zones is determined by the aforementioned door system, and changes are typically only possible at significant cost. However, over time, the needs for interior design, door systems, and / or the living habits of occupants may change. Therefore, a technology is needed to adapt building equipment to these changes with low technical complexity.

[0004] One aspect of this technology relates to a building wall module system having a frame structure with fixed width, height, and depth. The frame structure has a first upright structure extending in a first plane and a second upright structure extending in a second plane, the second plane being substantially parallel to the first plane and having a defined distance from the first plane in the depth direction, thereby creating a gap between the two planes. The frame structure defines a wall side region, a wall cladding region, and a passage region located between the wall side region and the wall cladding region, with a guide rail system extending above the passage region arranged in the frame structure. On the two upright structures, a first lateral closed profile pair is arranged on the wall side region adjacent to the passage region, and a second lateral closed profile pair is arranged on the wall cladding region adjacent to the passage region. Furthermore, an upper closed profile pair is arranged on the two upright structures, the upper closed profile pair connecting the first and second lateral closed profile pairs substantially at right angles. These closed profile pairs surround the passage region. The second lateral closing profile pair and the upper closing profile pair each have channels for a sliding door that can open along its depth direction. Guide rails of the guide rail system are arranged in the upper region of the frame structure and extend substantially parallel to the upper closing profile pair. The guide rails are designed to support the sliding door between a closed position and an open position. In the closed position, the sliding door closes the passage area and presses against the closing profile pair; in the open position, the sliding door fully or partially opens the passage area and moves at least partially through the channels into the wall cladding area. The building wall module system also includes a frame insert with connecting elements that connect the frame insert, inserted into the passage area, to the frame structure and, when the inserted frame insert is removed, separate the frame insert from the frame structure.

[0005] Another aspect relates to a method for adapting a building wall module system to suit specific needs. This system has a frame structure with fixed width, height, and depth, installed within a building, configured for use with a sliding door that can open along its depth. Within the frame structure are defined: a wall side region, a wall cladding region, and a passageway region existing between the wall side region and the wall cladding region. Furthermore, a guide rail system for the sliding door is arranged therein, extending above the passageway region. A first lateral closing profile pair is arranged on the wall side region adjacent to the passageway region, and a second lateral closing profile pair is arranged on the wall cladding region adjacent to the passageway region. Additionally, an upper closing profile pair is arranged on the frame system, connecting substantially at right angles to the first and second lateral closing profile pairs; the lateral closing profile pairs surround the passageway region. The second lateral closing profile pair and the upper closing profile pair each have aisles for the sliding door. According to the method, a frame insert is provided, which is inserted into a channel region and connected to a frame structure from there. The frame insert includes a plurality of sub-components, each having at least one connecting element, through which the respective sub-component can be connected to the frame structure after being positioned relative to one of the closed profile pairs, wherein a sequence is determined for positioning and connection. The sub-components are inserted and connected according to the determined sequence.

[0006] The technology described herein provides a modular building wall system that must adapt to the changing needs of room use and / or the living conditions of occupants over time. The frame structure is prepared for applications where sliding doors are inserted into and used, and can be installed in a building in this manner. A guide rail system, for example, is already arranged in the frame structure, through which the inserted sliding door can move between a closed and open position. However, for various reasons, it may be desirable to use the modular building wall system without such sliding doors. In this case, a frame insert designed for the specific application can be used in the passageway area. Here, the sliding door can be stored in the wall enclosure area and in a deactivated state, but it can also be used only when needed. Therefore, the described technology provides the option of using a modular building wall system with either sliding doors or frame inserts.

[0007] Whether the sliding doors are retracted into the wall cladding area or used only when needed, the frame inserts used cover the frame structure in the passageway area. Wall panels are arranged on both sides of the frame structure, complementing its surroundings. The frame structure accessible or visible from the passageway area is covered by the frame inserts. Thus, the covered frame structure is not visible to the observer.

[0008] According to the technology described herein, one can choose not only whether a building wall module system with sliding door or frame inserts should be used, but also the type of frame insert. According to this specification, one can choose channel inserts, wall hole inserts, shelf inserts, pivot door inserts, sliding door inserts, wall inserts, and window inserts.

[0009] In at least some of the embodiments mentioned in this specification, an advantage is that the inserted frame insert can be removed again without damaging the frame structure. The frame insert is connected to the frame structure, for example, via connecting elements that extend from a gap in the frame structure. Therefore, the connecting elements are not visible from the outside and do not interfere with the appearance of the building wall module system or the frame insert. Furthermore, the connecting elements are particularly detachable (e.g., threaded, clampable, tensionable, and / or pluggable). Thus, the selection made can be cancelled again without causing damage to the building wall module system, which might subsequently require significant expense to remove.

[0010] In one embodiment, the frame insert has a first frame element insertable onto a lateral first closing profile pair, a second frame element insertable onto a lateral second locking profile pair, and a third frame element insertable onto an upper closing profile pair. Each frame element has at least one connecting element. These connecting elements allow the frame structure to be connected to the frame structure. These connecting elements are designed to allow connection to the frame structure from gaps in the frame structure, and in particular, these connections are detachable, allowing the frame element to be removed from the frame structure again. This multi-piece frame insert has the advantage of facilitating its installation.

[0011] In one embodiment, the frame insert is configured as a channel insert. First, second, and third frame elements collectively form an outer frame having an outer surface that, in the inserted state of the frame insert, surrounds the channel area along closed profile pairs and covers each closed profile pair at least toward the channel area. The outer surface of the outer frame is substantially planar. This channel insert conceals a frame structure that is accessible or visible from the channel area. Furthermore, for this channel insert, for example, the material and color design can be selected to match the spatial environment of the building's wall module system.

[0012] In another embodiment, the frame insert is constructed as a wall-hole insert. The frame insert has a wall hole and a wall component that, when the frame insert is inserted, fills the passage area from outside the wall hole. The wall component has a crossbeam, a bottom element, and a vertical post arranged at a defined height, the post extending between the bottom element and the crossbeam in two substantially parallel planes corresponding to the planes of the post structure. This wall-hole insert performs a dual function: on the one hand, it creates a wall hole, i.e., an opening in the wall, through which things can be passed; on the other hand, it also closes the passage area outside the wall hole by matching the wall component to the building's wall module system, particularly its depth. Those skilled in the art will understand that the wall hole can be selected in terms of size and location (e.g., height) as needed. Furthermore, the wall-hole insert also covers the frame structure in the manner described above; this characteristic also applies to the embodiments described below.

[0013] According to another embodiment, the frame insert is designed as a shelf insert. The frame insert has a rear wall and at least one tray (shelf bottom). If the frame insert is embedded in a building wall module system, the rear wall is connected to first, second, and third frame elements, and at least one tray is accessible from a side opposite the rear wall. In the inserted state, the frame insert closes the passage area. Shelf inserts prepared in this way can be flexibly designed, for example, by the number and arrangement of the trays. Those skilled in the art also know that the shelf insert can be more or less hidden or closed on its front side, for example, by means of a door, roller shutter, or curtain.

[0014] According to another embodiment, the frame insert is designed as a pivot door insert. The frame insert includes a pivot door and a fitting. In the inserted state of the frame insert, the pivot door is pivotally connected to one of the lateral frame elements by means of the fitting. This pivot door can be opened and closed in a known manner, simultaneously opening or locking the passageway area. Furthermore, the pivoting direction of the pivot door is flexible because the fitting can be disposed on the side of the wall cladding area or the side of the wall side area. Those skilled in the art also know that the pivot door insert is provided with a closing mechanism.

[0015] In another embodiment, the frame insert is configured as a sliding door insert. The frame insert includes a sliding door, specifically a horizontally movable sliding door consisting of a single door leaf. This sliding door is simpler to construct than an unfoldable sliding door for which a frame structure is prepared, and is also less expensive, especially since it is not unfoldable. For such a standard sliding door, the lateral second frame element has a vertical through-hole through which it can be guided within the wall cladding area, between two upright structures. The third frame element has a horizontal through-hole through which the standard sliding door can connect to a guide rail system and move along the guide rail system.

[0016] In another embodiment, the frame insert is configured as a wall insert. In its inserted state, the frame insert substantially completely fills and closes the channel area. The frame insert has vertical uprights, reinforcing elements, and a bottom profile. In its inserted state, the vertical uprights extend in two substantially parallel planes between the bottom profile and the upper closed profile pair, these planes corresponding to the planes of the upright structure. Therefore, the wall insert has a depth corresponding to the depth of the frame structure. The wall insert can be covered to fit the cover of the frame structure; depending on the type and extent of such fit, the wall insert itself may be invisible.

[0017] It is also advantageous for the frame inserts configured as wall inserts to be able to connect to the frame structure facing inwards. For this purpose, the frame insert, for example, has reinforcing elements that laterally abut the frame structure. These (adjacent) reinforcing elements have flanges through which the adjacent reinforcing elements can be connected to the frame structure. The bottom profile also has flanges at its lateral ends, through which the ends can be connected to the frame structure. Vertical uprights can be connected at their lower ends to the bottom profile and at their upper ends to the upper closed profile pair or around them to the frame structure.

[0018] According to another embodiment, the frame insert is designed as a window insert. The frame insert has a wall component and a window. The window has an open state and a closed state; in the open state, an opening in the wall component is open, thus opening a portion of the passageway; in the closed state, the opening is locked. When the window is in the inserted and closed states, the frame insert substantially completely fills the passageway area. Unlike the aforementioned pivot doors and sliding doors, the window does not allow anyone to pass through; instead, the window's size is determined to make it passable for relatively small objects (e.g., pets, autonomous vehicles (robots, drones)). Those skilled in the art will understand that the window can be selected in appropriate size and location (e.g., height). For pets and robots (e.g., vacuum cleaner robots), the window is positioned near the floor.

[0019] The window can be configured in various ways. In one embodiment, the window can be designed as a sliding window that can move horizontally or vertically. In another embodiment, the sliding window can be equipped with an actuator and a sensor system that automatically opens the window when, for example, a pet approaches, and closes the window when the pet moves away. For this functionality, the sensor system and the information carrier carried by the pet can be equipped with contactless communication technology (such as RFID radio technology). In another design, the window can be designed as a cover that can rotate horizontally or vertically, which can be locked and, for example, can be pushed open by a pet or robot in the unlocked state.

[0020] Building wall module systems can be used in place of traditional building walls. Therefore, building wall module systems are configured in a way that, depending on the application and building, they substantially correspond to the characteristics of traditional building walls in terms of load-bearing capacity (e.g., when used as supporting walls), fire resistance, sound insulation or noise reduction, thermal insulation, and burglar protection. For this purpose, not only the gaps in the frame structure but also the corresponding wall components for pivot doors, sliding doors, wall recesses, wall inserts, and window inserts can be equipped with fire-resistant, insulating, smoke-proof, intrusion-proof, and / or sound-insulating materials. Attached Figure Description

[0021] Hereinafter, different aspects of the improved technique are described in detail with reference to the accompanying drawings and embodiments. In the drawings, the same elements have the same reference numerals. Wherein:

[0022] Figure 1A A schematic side view showing an embodiment of a building wall module system, into which sliding doors can be inserted;

[0023] Figure 1B Showing through Figure 1A A schematic diagram of the horizontal cross-section of the frame structure shown;

[0024] Figure 1C Shown in Figure 1A A schematic perspective view of the frame structure shown in the figure;

[0025] Figures 1D to 1H Shown in Figure 1A A schematic diagram of the horizontal cross-section passing through the sliding door in the frame structure shown, and its working principle;

[0026] Figure 2A A schematic perspective view showing one embodiment of a frame structure with a border insert configured as a channel insert;

[0027] Figures 2B to 2D Show Figure 2A A schematic diagram of an embodiment of the border insert shown;

[0028] Figures 2E to 2H Show Figure 2A A schematic diagram of another embodiment of the border insert shown;

[0029] Figure 3A A schematic side view of an embodiment of a frame structure with a border insert configured as a wall hole insert is shown.

[0030] Figures 3B to 3D yes Figure 3A A schematic diagram of an embodiment of the border insert shown;

[0031] Figure 4A A schematic side view of one embodiment of a frame structure with a border insert configured as a shelf insert is shown.

[0032] Figures 4B to 4D Show Figure 4A A schematic diagram of an embodiment of the border insert shown;

[0033] Figure 5A A schematic perspective view showing one embodiment of a frame structure with a border insert configured as a pivot door insert;

[0034] Figures 5B to 5D Show Figure 5A A schematic diagram of an embodiment of the border insert shown;

[0035] Figure 6A A schematic perspective view showing one embodiment of a frame structure with a border insert configured as a sliding door insert;

[0036] Figures 6B to 6E Show Figure 6A A schematic diagram of one embodiment of the border insert shown;

[0037] Figure 7A A schematic side view of an embodiment of a frame structure with a border insert configured as a wall insert is shown.

[0038] Figures 7B to 7E Show Figure 7A A schematic diagram of one embodiment of the border insert shown;

[0039] Figure 8A A schematic side view illustrating one embodiment of a frame structure with a border embedding configured as a window embedding;

[0040] Figures 8B to 8EShow Figure 8A A schematic diagram of one embodiment of the border insert shown; and

[0041] Figure 9 A flowchart illustrating an embodiment of a method for adapting building wall modules to a building is shown. Detailed Implementation

[0042] exist Figure 1A , Figure 1B and Figure 1C The diagram illustrates one embodiment of the frame structure 2 of a building wall module system 1, which can be used in various applications according to the techniques described herein. In one embodiment of the building wall module system 1, a sliding door 4 can be inserted into the frame structure 2; Figures 1D to 1H A schematic diagram showing the horizontal cross-section of the sliding door 4 passing through the frame structure 2 and its working principle. Other embodiments of the building wall module system 1 are also included. Figure 2A As shown in Figure 8.

[0043] Building wall module system 1 is designed to replace building walls constructed in buildings using brick, cast-in-place concrete, and / or dry-structure construction methods (e.g., wood, plastic, composite, and / or metal structures combined with, for example, gypsum board). This structural form is known to those skilled in the art. For example, see reference to... Figure 1C The building wall module system 1 is shown in the xyz coordinate system. It has a width B in the x-direction, a depth T in the y-direction, and a height H in the z-direction. The building wall module system 1 extends in a plane spanned by the x-axis and z-axis. The building wall module system 1 is installed substantially vertically (upright); therefore, terms used in this specification such as "vertical," "horizontal," "upper," "lower," "bottom," etc., refer to the installed building wall module system 1.

[0044] In one embodiment, the building wall module system 1 can be inserted into or replace an interior wall of a building, for example, to separate the private interior area of ​​a residence from the (non-private or semi-private) exterior area (e.g., a house or staircase) in a multi-family home. In such apartments or detached buildings, the building wall module system 1 can also be used to partition interior spaces. Similarly, the building wall module system 1 can be used, for example, as an interior wall in office buildings, hotels, etc.; in a hotel, the building wall module system 1 can also, for example, separate two adjacent rooms. In another embodiment, the building wall module system 1 can be a building wall, for example, which can separate the interior area of ​​a non-public building (e.g., a residence, hotel, office building, etc.) from a public exterior area (e.g., a road or public space). It will be appreciated by those skilled in the art that the techniques described herein are not limited to specific applications.

[0045] In the illustrated embodiment, frame structure 2 has an upper crossbeam 18, multiple bottom profiles 19, uprights 16, reinforcing elements 14, closed profiles 10a, 10b, 10c, and a guide rail system 12. The uprights 16 extend substantially vertically between the upper crossbeam 18 and the bottom profiles 19, and the reinforcing elements 14 are fixed to the uprights 16. Figure 1C As exemplarily shown, the bottom profile 19 can be designed as a U-shaped profile with a base plate and side tabs. The bottom profile 19 has a depth selected according to the depth of the building wall module system 1. Two uprights 16 are fixed opposite to each other on the bottom profile 19 and the upper crossbeam 18, wherein the spacing between the two uprights 16 is determined by the depth of the bottom profile 19. Reinforcing elements 14 connect adjacent pairs of uprights 16.

[0046] like Figure 1A As shown, the frame structure 2 has a passageway region 6, a wall cladding region 8, and a wall side region 9, wherein the passageway region 6 is arranged between the wall cladding region 8 and the wall side region 9. In the inserted state, the wall cladding region 8 and the wall side region 9 (on the corresponding sides away from the passageway region 6) are connected to the rest of the building. Closed profiles 10a, 10b, and 10c enclose the passageway region 6, wherein two closed profiles 10a are arranged vertically on the wall side region 9 and two closed profiles 10b are arranged vertically on the wall cladding region 8; two horizontal closed profiles 10c are directly or indirectly connected to the upper beam 18 and connect the closed profiles 10a and 10b to each other. The closed profiles 10a and 10b are connected to adjacent uprights 16 by reinforcing elements 14.

[0047] To illustrate that frame structure 2 is covered (covered) in the inserted state, Figure 1CThe diagram shows a wall panel 20 on one side of a frame structure 2, the wall panel being fixed to the frame structure 2. The wall panel 20 covers the surface above the wall cladding region 8, the wall side region 9, and the passage region 6. Those skilled in the art will understand that the wall panel 20 can be assembled from individual panels, and the frame structure 2 can be covered on both sides. In this way, cavities exist between the wall panels 20 in the wall cladding region 8 and in the wall side region 9, the cavities... Figure 1B and Figure 1C As can be seen in the diagram. In one embodiment, the passageway region 6 is constructed and sized such that a person can pass through it to reach from one side of the building wall module system 1 to the other. The wall cladding region 8 is constructed and sized such that, in the open position, it fully or partially accommodates the inserted sliding door 4 within its interior (cavity). For this purpose, aisles 10d are arranged between the closing profiles 10b. It is known to those skilled in the art that the dimensions of the building wall module system 1, particularly its height H and width B, can be matched to pre-defined values ​​specific to the building. For the passageway region 6, a standard width or minimum width can be pre-defined depending on the building. Because the wall cladding region 8 substantially fully accommodates the sliding door 4 in the open position, a minimum width for the wall cladding region 8 is also pre-defined.

[0048] Frame structure 2 can be used in conjunction with sliding door 4. Its structural principle and working principle are as follows: Figures 1D to 1H (These figures illustrate, respectively, horizontal cross-sections through the sliding door 4 and / or frame structure 2) as exemplarily described. The sliding door 4 has two door panels 4a, 4b and an actuator 7. In this embodiment, each door panel 4a has two lateral flanges 5a, 5b and a top flange. In the illustrated embodiment, each flange is shown as an L-shaped angle profile pointing at right angles from its respective door panel 4a, 4b toward the interior of the door. The actuator 7 is configured to move the door panels 4a, 4b toward and away from each other; Figure 1D In the middle, door panels 4a and 4b have a ratio relative to each other. Figure 1E Larger spacing in the middle.

[0049] Figure 1F The sliding door 4 is shown in the closed state. In this state, the actuator 7 moves the door panels 4a and 4b away from each other. Figure 1D In this configuration, flange 5a is fitted into closed profile 10a and flange 5b is fitted into closed profile 10b. Due to the functionality of moving the door panels 4a and 4b away from each other in this state, i.e., unfolding, the sliding door 4 can be unfolded in the depth direction and is referred to in particular as such in this specification ("unfoldable sliding door").

[0050] Figure 1GThe sliding door 4 is shown transitioning from a closed state to an open state (a similar situation occurs when it is closed). In this state, the actuator 7 pulls the door panels 4a and 4b toward each other. Figure 1E In this configuration, flange 5a is disconnected from closed profile 10a, flange 5b is disconnected from closed profile 10b, and the upper flange is disconnected from the upper closed profile 10c. Figure 1H A sliding door 4 in the open position is shown, wherein the sliding door is partially located within the wall cladding area 8. In one embodiment, to allow the sliding door 4 to move back and forth between the closed and open positions, the actuator 7 of the sliding door 4 is equipped as an electrically driven unit, which is operated by an access control system or building management system. In one embodiment, the sliding door 4 is particularly equipped with an electrical interface device for communicating with the access control system or building management system.

[0051] From combination Figures 1A to 1H Starting with the introduced frame structure 2, the following describes different applications and embodiments of the building wall module system 1. These applications and embodiments illustrate that the building wall module system 1 can be adapted to changing room usage requirements as needed. As mentioned above, the frame structure 2 is prepared for use with deployable sliding doors 4, for example, the frame structure may have already been installed during building construction. However, architects or construction workers may have concerns about the cost of deployable sliding doors 4 and / or the need for such sliding doors 4 in the building during the planning and construction phases. As an alternative, in this case, a frame insert 22 can be used in the passageway area 6, which is designed for the specific application and is, for example, less expensive. Nevertheless, the possibility of utilizing the building wall module system 1 with deployable sliding doors 4 at a later point in time is still retained.

[0052] exist Figures 2A to 2H In the exemplary application shown, building wall module system 1 provides access from one room to an adjacent room. For example... Figure 2A As shown, this passageway is freely passable without the need to open a door, for example. The passageway may also be referred to as a narrow passage or archway. In this application, such as... Figures 1D to 1H The sliding door 4 shown does not need to be inserted into the frame structure 2, but it can be inserted, for example, when the building wall module system 1 is already in use with the sliding door 4 (in lie with the removal of the sliding door 4) or when the building wall module system 1 is to be used with the sliding door 4 at a later time.

[0053] Figure 2A A schematic perspective view showing an embodiment of the frame structure 2 is provided with a border insert 22. Figure 2B A schematic perspective view of the border insert 22 is shown. Figure 2C A schematic side view of a border insert 22 is shown, which, for example, has two vertical border elements 22a, 22b and a horizontal border element 22c. Figure 2D A horizontal cross-section of the frame element 22 is shown, in which the arrangement of the frame elements 22a, 22b with respect to the closing profiles 10a, 10b can be seen. The frame elements 22a, 22b, 22c can be inserted into and connected to the frame structure 2 individually, for example, by means of the closing profiles 10a, 10b, 10c or by fixing (e.g., tightening) them around the frame structure 2.

[0054] The frame insert 22 is sized such that it can be inserted into the frame structure 2, connecting with and completely or partially covering the closing profiles 10a, 10b, and 10c in the inserted state. In one embodiment, the sizing is chosen such that the frame insert 22 completely or partially covers the inserted and covered frame structure 2; depending on the degree of coverage, an observer can see more or less of the frame structure. Because the frame insert 22 can be inserted into the already inserted frame structure 2 (since the sliding door 4 has been inserted or should be inserted in the future), the frame insert can also be removed from the frame structure 2 with relatively little effort.

[0055] The frame insert 22 is implemented in such a way that it possesses characteristics determined based on the existing building conditions; the frame insert, for example, can be matched to the spatial environment near the building wall module system 1. These characteristics may, for example, relate to the material, stability, surface texture, shape, and color of the frame element 22. The material may be metal, wood, plastic, carbon fiber, glass fiber, or a combination of these materials. For example, in... Figure 2A and Figure 2B In the middle, the border element 22b has a substantially smooth visible end face.

[0056] exist Figures 2E to 2H Another embodiment of the border insert 22 is shown. In this embodiment, the possibilities for inserting and connecting border elements 22a, 22b, and 22c are illustrated. Figure 2E A schematic side view of the border insert 22 is shown, in which multiple cutouts 27 are shown on the border elements 22a, 22b, and 22c. Details of the upper corner (upper right) of the border insert 22 are shown. Figure 2FAs shown in the side view. A pin element, hereinafter referred to as bolt 25, protrudes through a cutout 27 on the upper frame element 22c. Bolt 25 is secured in a fixed position on the frame insert 22, for example, on the upper locking profile 10c. Those skilled in the art will know that bolt 25 protrudes through each cutout 27 on the upper locking profile 10c. The positions where bolts 25 are fastened are fixed in the structural design drawing of the frame structure 2. Furthermore, in Figure 2F The image also shows a corner connector 21 that protrudes substantially at a right angle (about its longitudinal axis) from the frame element 22c and points downward. For this purpose, the (vertical) frame element 22b has a receiving portion into which the corner connector 21 can be inserted during assembly.

[0057] As in Figure 2G As shown in the enlarged illustration (cross-section perpendicular to the longitudinal axis of the closed profile 10c), each bolt 25 has a fastening element 29 on the inner side of the upper closed profile 10c, thereby connecting the upper closed profile 10c to the frame structure 2. Those skilled in the art will recognize that the frame elements 22a and 22b are also connected to the frame structure 2 by this combination of bolts 25 and fastening elements 29, respectively.

[0058] As in Figure 2G As exemplarily illustrated, the fastening element 29 can be implemented as a compressible unfolding clamp or a clamping spring made of metal, which is placed onto the bolt 25 prior to assembly. If the bolt 25 is moved into the notch 27, the unfolding clamp is compressed by the material surrounding the notch 27 of the corresponding frame elements 22a, 22b, 22c and is thus secured against movement. Those skilled in the art will recognize that this functionality can also be achieved by other types of connecting elements, such as clamping rings, leaf springs, or disc springs. Those skilled in the art will also recognize that this connection allows for the removal of the frame elements 22a, 22b, 22c from the frame structure 2 again; for example, the frame elements can be pulled out.

[0059] also, Figure 2G Two spring elements 23 are shown, located on the outer longitudinal edge of the closed profile 10c. The spring elements 23 are elastic elements made of plastic and / or metal, which can be compressed under pressure and debiased again when the pressure is reduced or removed, and substantially return to their initial shape. The spring elements 23 may, for example, comprise one or more helical springs made of metal; for example, multiple individual spring elements 23 may be arranged sequentially along the frame element 22c. In another embodiment, the spring elements 23 may be made of plastic and have a structure possessing the aforementioned elastic properties. It will be appreciated by those skilled in the art that the described embodiments of the spring elements 23 are exemplary, and the spring elements 23 are not limited thereto.

[0060] Figure 2H A side view of one embodiment of the bottom portion of the frame element 22b is shown. A recess 31 is shown at the indicated end of the frame element 22b, into which a complementary mating element of the frame structure 2 engages during assembly. The protruding rear portion of the frame element 22b is "suspended" and therefore can no longer be pulled forward. If the upper portion is then clamped or screwed, the frame element 22b is secured. This, for example, facilitates positioning of the frame element 22b and prevents it from being pulled out. Those skilled in the art will recognize that the frame element 22a can be designed similarly to the frame element 22b.

[0061] To insert the frame insert 22 according to one embodiment into the frame structure 2, the upper frame element 22c can first be inserted into the frame structure 2. This is achieved by aligning the cutout 27 of the frame element 22c with the bolt 25 of the closing profile 10c, and by moving the frame element 22c upward, thereby moving the bolt 25 into the cutout 27. The vertical frame element 22b is inserted such that its cutout 27 is aligned with the bolt 25 of the closing profile 10b, for example, by first aligning the cutout 27 of the frame element 22c with the bolt 25 of the closing profile 10b. Figure 2H The component near the bottom is positioned as shown, while the frame element 22b is held obliquely in the channel region 6. The frame element 22c is then pushed upwards, whereby the spring element 23 presses against and is compressed against the surface of the closed profile 10c, allowing the corner connector 21 to be positioned above the receiving portion of the (now vertically upright) frame element 22b. If the frame element 22c is subsequently released, the spring element 23 is de-biased and presses the frame element 22c downwards, thereby inserting the corner connector 21 into the receiving portion. Those skilled in the art will understand that the frame element 22a is used similarly.

[0062] Similarly, from the perspective of combination Figures 1A to 1H Starting with the framework structure 2 introduced, Figures 3A to 3D Another exemplary application of the building wall module system 1 is shown. In this application, a frame insert 22 is inserted into a passage area 6, the frame insert being designed as a wall hole insert. A wall hole is typically an opening in a wall through which things can be passed, such as food between a kitchen and a dining table, or medication between a pharmacy counter and a common area in front of the pharmacy. Such a wall hole can be closed and opened in various ways (e.g., via a cover, roller shutter, or one or more doors); the wall hole insert described herein can also be designed according to one of these types.

[0063] Figure 3A A schematic perspective view of an embodiment of a building wall module system 1 is shown, wherein a frame insert 22 (wall hole insert) is inserted into a frame structure 2. Figure 3B A schematic side view of an exemplary border insert 22 is shown. The border insert 22 has a wall hole 30 and a wall component 32, the wall hole 30 substantially occupying the upper half of the border insert 22 and the wall component 32 substantially occupying the lower half of the border insert 22. It will be appreciated by those skilled in the art that such proportions are exemplary and that different proportions may be chosen in another embodiment. Furthermore, those skilled in the art will recognize that the wall component 32 is appropriately framed according to its spatial environment.

[0064] In one embodiment, the border embedding 22 can be derived from the channel embedding (see...) Figures 2A to 2H The structure is constructed starting from the basic structure and includes two vertical frame elements 22a and 22b and one horizontal frame element 22c. These spring elements can be combined as follows: Figures 2A to 2H Inserted into frame structure 2 as described herein, including spring element 23, bolt 25, notch 27, and fastening element 29 shown and described therein. In the example shown, the upper halves of horizontal border element 22c and border elements 22a, 22b demarcate the wall hole laterally and upward. Wall component 32 demarcates the wall hole 30 downward.

[0065] The wall component 32 includes at least one crossbeam 36, a bottom element 42, and vertical posts 34. The crossbeam 36 extends substantially horizontally between frame elements 22a, 22b at a height selected or determined for the wall opening 30, and the vertical posts 34 extend between the bottom element 42 and the crossbeam 36. Similar to the posts 16 of the frame structure 2, the posts 34 may also be arranged in pairs, and reinforcing elements 40 may be arranged between adjacent posts 34. Those skilled in the art will appreciate that, for example, the number of posts 34 and the number of reinforcing elements 40 can be selected according to the intended use of the room.

[0066] Figure 3C The connection between the upright 34 and the adjacent reinforcing element 40, and the connection between the upright 34 and the bottom element 42, are shown in enlarged view. These connections can be established using connection techniques known to those skilled in the art, such as screws, rivets, welding, mating, and / or clamping.

[0067] The crossbeam 36 has a width in the x-direction and a depth in the y-direction. The width can be selected such that it is equal to the distance between the frame elements 22a and 22b, or longer than the distance between the frame elements by a defined value. In the last mentioned case, the depth of the crossbeam 36 can be greater than the depth of the wall hole 30, wherein the crossbeam 36 has recesses at its two longitudinal ends to partially accommodate the respective frame elements 22 and 22b, either alone or together with the corresponding closing profiles 10a and 10b. Figure 3DThis is illustrated by way of enlarged view. Those skilled in the art will understand that, for example, it can be based on... Figure 3D The tray (instead of the crossbeam 36) in the example configuration shown is mounted on the crossbeam 36. Those skilled in the art will also appreciate that the crossbeam 36 can be configured such that the tray is integrated into the crossbeam.

[0068] Again from the combination Figures 1A to 1H Starting with the framework structure 2 introduced, Figures 4A to 4D Another exemplary application of the building wall module system 1 is shown. In this application, a frame insert 22 configured as a shelf insert is inserted into a passageway area 6. In one embodiment, the shelf insert has a rear wall 46, which optically separates adjacent rooms. If acoustic separation is also required, the rear wall 46 can be designed according to acoustic angles (e.g., shape, thickness, and / or mass). At least one shelf bottom 44 (tray) can be embedded in the shelf insert, which is accessible from the entry side of the shelf insert. If multiple shelf bottoms 44 are used, they can be used in a flexible manner; Figures 4A to 4C An embodiment for use therein is shown. Those skilled in the art will appreciate that the shelf insert can also be used without the shelf bottom 44 and / or rear wall 46. Those skilled in the art will also appreciate that the shelf insert can be designed on the entry side such that a door, roller blind, or curtain can be installed there.

[0069] In one embodiment, the border insert 22 may be derived from the channel insert (see...). Figures 2A to 2H The structure is constructed starting from the basic structure and includes two vertical border elements 22a and 22b and one horizontal border element 22c. These border elements can be combined as follows: Figures 2A to 2H The components are inserted into the frame structure 2 as described therein, including the spring element 23, bolt 25, notch 27, and fastening element 29. Furthermore, the frame elements 22a, 22b contain means for allowing insertion of the shelf bottom 44, such as holes provided according to a fixing pattern, into which a pallet pin can be inserted to achieve a desired height. In another embodiment, the rear wall 46 may include means for mounting the shelf bottom 44. The means for mounting the shelf bottom 44 are well known to those skilled in the art.

[0070] exist Figure 4B Perspective view and Figure 4C In the side view, border elements 22A and 22B are as follows: Figure 2B and Figure 2C Arrange and fix it as described in the text. The horizontal cross-section of the shelf insert is in... Figure 4D As shown in the image.

[0071] Figures 5A to 5DAnother exemplary application of the building wall module system 1 is shown. In this application, a frame insert 22 is inserted into a passage area 6, and the frame insert is configured as a pivot door insert. The pivot door insert includes frame elements 22A, 22B, 22C, a pivot door 50, a fitting 52, and a closing and locking mechanism 54. If the pivot door 50 is fixed to the fitting 52, then the pivot door 50 can be opened in a fixed direction, wherein the fitting 52 serves as a fixing point; this is in Figure 5D The horizontal cross-section is shown by double arrow 56. Figure 5D As can also be seen, in this embodiment, accessory 52 is arranged on the side of the wall shell area 8; at least a portion of the closing and locking mechanism 54 is arranged opposite to the wall shell area 8 in the frame structure 2.

[0072] In one embodiment, the two vertical border elements 22a, 22b and the horizontal border element 22c of the border insert 22 are combined as follows: Figures 2E to 2H As described, it can be inserted into the frame structure 2, including the spring element 23, bolt 25, notch 27, and fastening element 29 shown and described therein. Depending on its weight, the pivot door 50 applies force to the fitting 52 and the frame element 22b. Those skilled in the art will understand that the frame element 22b is designed to meet this requirement; the frame element can be secured to the frame structure 2, for example, by additional connections (e.g., threaded connections); in one embodiment, the frame element may also be additionally anchored to the ground and / or ceiling.

[0073] Figures 6A to 6E Another exemplary application of the building wall module system 1 is shown. In this application, a frame insert 22 is inserted into a passage area 6, the frame insert being configured as a sliding door insert. The sliding door insert includes a sliding door 60, which is coupled with... Figures 1D to 1H The sliding door 4 described herein is designed as a simple, non-opening sliding door; for better distinction, the sliding door 60 is also referred to below as "standard sliding door 60". The standard sliding door 60 can be moved, for example, automatically or manually (with or without the assistance of an electromechanical actuator).

[0074] exist Figure 6A In the side view of the building wall module system 1 shown, a standard sliding door 60 is schematically shown in a partially open position. In this open position, a portion of the standard sliding door 60 is located within the wall cladding area 8, as also... Figure 6B As shown in the horizontal cross-section of the modular system 1 passing through the building wall, in the frame insert 22 (sliding door insert), according to Figure 6C Side view, Figure 6D Horizontal section diagram and Figure 6EIn the perspective view, the standard sliding door 60 is also shown in the open position. In the fully open position, the standard sliding door 60 is essentially located within the wall enclosure area 8 (except for a handle / latch that may be present on the side, through which the standard sliding door 60 can be moved by the user).

[0075] The sliding door insert also includes frame elements 22a, 22b, and 22c, wherein at least the lateral frame element 22b and the upper frame element 22c are adapted for use with a standard sliding door 60. Frame element 22b may, for example, be divided into two parts, thereby creating a vertical opening between these parts through which the standard sliding door 60 can be moved into the wall enclosure area 8; this is, for example, in… Figure 6B and Figure 6D As shown in the figure. Therefore, the frame element 22b covers the gaps that exist on both sides of the standard sliding door 60 between the frame structure 2 and the standard sliding door 60.

[0076] The standard sliding door 60 has guide elements designed to match / complement the guide rail system 12 present in the frame structure 2. The standard sliding door 60 can be inserted into the guide rail system 12 by means of these guide elements. The frame element 22c can be constructed in two pieces, thus creating a horizontal opening between these parts, along which the guide elements or the upper portion of the standard sliding door 60 can move; this is, for example, in… Figure 6E As shown in the diagram. Therefore, the frame element 22c also covers the gap that exists along the horizontal openings on both sides of the standard sliding door 60.

[0077] The border insert 22 in the illustrated embodiment also includes a locking mechanism 62, for example in Figure 6B and Figure 6C The locking mechanism 62 is shown in the figure. The locking mechanism 62 may have a pawl that protrudes from the end side of the standard sliding door 60 and can be activated, for example, by a handle on the standard sliding door 60. The frame element 22a is designed accordingly; the frame element has an opening, for example, at the height of the pawl, into which the pawl engages when the standard sliding door 60 is closed.

[0078] In one embodiment, the two vertical border elements 22a, 22b and the horizontal border element 22c of the border insert 22 are combined as follows: Figures 2E to 2H As described, they can be inserted into frame structure 2, regardless of whether the frame elements 22a, 22c are constructed as a single piece or as two pieces. These frame elements 22a, 22b, 22c can be inserted, for example, by means of spring element 23, bolt 25, notch 27 and fastening element 29 shown and described therein.

[0079] Another exemplary application of the building wall module system 1 is in Figures 7A to 7E As shown in the diagram. In this application, a border insert 22 is inserted into the channel region 6, the border insert being configured as a wall insert. The wall insert substantially completely fills the channel region 6 and thereby closes it. Figure 7A A schematic side view of a building wall module system 1 is shown, in which a frame insert 22, designed as a wall insert, is embedded in a frame structure 2. The frame insert 22 includes a vertical post 16a, a reinforcing element 14a, and a bottom profile 19a. These components of the frame insert 22 correspond in principle, function, and arrangement to the frame structure 2, for example, a combination of... Figure 1C The functions and arrangement of the components are described. For example, Figure 7B The perspective view of the frame insert 22 shows the arrangement of paired vertical posts 16a and the connection of two adjacent vertical posts 16a by reinforcing elements 14a. Those skilled in the art will appreciate that, depending on the requirements of the wall insert, other vertical posts 16a and reinforcing elements 14a may be provided besides those shown. Those skilled in the art will also appreciate that the wall insert may be lined on both sides by wall panels (adapted to its environment).

[0080] Figure 7C A magnified view shows the vertical post 16a connected to the bottom profile 19a at its lower end. The vertical post 16a can be connected to the bottom profile 19a before the frame insert 22 is inserted. The vertical post 16a can be screwed or welded to the bottom profile 19a, for example. Furthermore, in Figure 7C As shown, the bottom profile 19a has at least one flange 19b, through which the bottom profile 19a can be connected to the bottom profile 19 of the frame structure 2; the bottom profile 19 is designed accordingly for this purpose. The bottom profile 19a can be screwed, welded, clamped, and / or riveted to the bottom profile 19, for example. Figure 7C Two flanges 19b are shown as an example. Those skilled in the art will understand that the bottom profile 19a also has at least one such flange 19b at its other end. Therefore, the bottom profile 19a can be connected to the frame structure 2 at both ends.

[0081] Figure 7DThe upper end of the vertical upright 16a is shown in an enlarged view. A flange 16b is present on each vertical upright 16a, which can be connected to the upper closed profile 10c. The flange 16b is shaped to match / complement a pre-defined connection surface at the closed profile 10c. The flange 16b has, for example, at least one hole through which a screw or bolt can pass to connect the vertical upright 16a to the upper closed profile 10c. In the illustrated embodiment, the flange 16b has two holes. Through these connections, the frame insert 22 is connected to the frame structure 2 on its upper side in the inserted state. Those skilled in the art will appreciate that different connection techniques can be chosen instead of screws and holes.

[0082] Figure 7E The lateral ends of the reinforcing elements 14a are shown in enlarged view. These ends connect to the frame structure 2 or its vertical closed profiles 10a, 10b. A flange 14b is present on each reinforcing element 14a, which can (here) connect to the vertical closed profile 10b. The flange 14b is shaped to match / complement a pre-defined connection surface on the closed profile 10b. The flange 14b has at least one hole through which a screw or bolt can pass to connect the reinforcing element 14a to the vertical closed profile 10b. In the illustrated embodiment, the flange 14b has two holes. Through these connections, the frame insert 22 is laterally connected to the frame structure 2 in the inserted state.

[0083] If the wall insert is fitted into its environment in the inserted state, such as being covered accordingly, the wall insert may be invisible to an observer. For example, a wall insert can be installed when passage between adjacent spaces is not needed or when passage is no longer required. Conversely, if the wall insert is no longer desired at a later point in time, it can be removed again and the building wall module system 1 can be used according to other applications described in this specification. To remove the wall insert, for example, a smoothed transition (seam) from the wall insert to its environment can be exposed. Subsequently, one or more wall panels can be removed to allow access and removal of the vertical post 16a, reinforcing element 14a, and bottom profile 19a.

[0084] Another exemplary application of the building wall module system 1 is in Figures 8A to 8E As shown in the diagram. In this application, a border embedding 22 is inserted into the channel region 6, and this border embedding is constructed as a window embedding. The window embedding is similar to a combination... Figures 7A to 7EThe design of the wall insert described herein is therefore referenced to the embodiment therein regarding the vertical support 16a, the reinforcing element 14a, and its connection to the frame structure 2. However, at a location such as near the ground, the window insert has a window 80, which can be opened or closed as needed. The area surrounding the window 80 is referred to as the wall component 90. The window 80 may be, for example, a passageway for pets and / or autonomous driving devices (e.g., vacuum cleaning robots or other types of robots). Those skilled in the art will understand that the size and location of the passageway can be determined according to the intended use (household door and / or robot).

[0085] In the illustrated embodiment, window 80 is movable in the x-direction; thus, window 80 can be considered a reduced-size sliding door. To enable this mobility, guide rails 82 of a guide rail system are arranged in the frame insert 22. As shown, the guide rails 82 are arranged approximately horizontally. The guide rails 82 extend from the interior of the frame insert 22 into the wall shell region 8. This allows window 80 to be fully or partially displaced into the wall shell region 8 when open.

[0086] In one embodiment, the rail system includes an electromechanical actuator 84 that opens or closes the window 80 in response to a control signal. For this purpose, the rail system has a control device that supplies electrical power to the electromechanical actuator 84 and operates it. In another embodiment, the rail system may be connected to such a control device. The control device is preferably arranged in a frame insert 22 such that the frame insert 22 only needs to be connected to a power source to automatically drive the window 80. The power source may, for example, already be arranged in the frame structure 2.

[0087] The control device may include a radio communication device that communicates with radios mounted on the pet or robot. These radios may be constructed, for example, based on RFID radio technology. For instance, if the pet is within a radio range (or its radio component) defined for window 80, the control device generates a control signal that causes the electromechanical actuator 84 to open window 80. If the pet is outside the radio range, the control device causes window 80 to close. A similar operation occurs in a robot.

[0088] and combination Figures 7A to 7E Unlike the wall inserts described, this window insert has a horizontal beam 86 in the lower region. A vertical post 16a connects to the horizontal beam 86 at its lower end. The beam 86 is connected to the frame structure 2 in its environment via closed profiles 10b, 10c and / or other means. Figure 8CAs shown on the side of the window insert, the wall panel 88 is fixed to the crossbeam 86, the vertical post 16a, and / or the reinforcing element 14a. The wall panels 88 fixed to both sides of the window insert allow the window insert to artistically fit the surrounding building walls.

[0089] Figure 8D A side view shows window 80 and a guide rail system with guide rail 82 and electromechanical actuator 84. (Combined) Figure 8E As shown in the horizontal cross-section, it can be seen that window 80 can move between beams 86.

[0090] As described above, the building wall module system 1 can be adapted to meet the changing needs of the rooms and / or the living conditions of the occupants over time. The frame structure 2 prepares for the application of (expandable) sliding doors 4, which are inserted into the frame structure 2 and used, and can be installed in the building as shown. By understanding the above-described principle configuration and function of the frame insert 22, the following will combine... Figure 9 Perform for use from in Figures 1A to 1H This section introduces an exemplary method for adapting a building wall module system 1 to a frame structure 2. Figure 9 The method shown in the diagram begins in step S1 and ends in step S4. Those skilled in the art will understand that the division of these steps is exemplary, and one or more of these steps can be divided into one or more sub-steps.

[0091] To accommodate the building wall module system 1, one of the aforementioned frame inserts 22 can be selected. In step S2, the (selected) frame insert 22 is provided. The frame insert 22 can be inserted into the channel area 6 and from there connected to the frame structure 2. The provided frame insert 22 includes a plurality of sub-components, each having at least one connecting element, through which the respective sub-component, after being positioned relative to one of the aforementioned closed profile pairs, can be connected to the frame structure 2, wherein the order is determined for positioning and connection. Those skilled in the art will know that by selecting the frame insert 22, its sub-components (e.g., frame elements 22a, 22b, 22c or vertical post 16a, reinforcing element 14a, and bottom profile 19a) are also determined; to avoid repetition, reference can be made to the above-described embodiment of the frame insert 22 regarding the sub-components.

[0092] If the border embedding is provided in this manner, then the sub-components are inserted and connected according to a defined order. The insertion of the sub-components of the channel embedding, for example, involves... Figures 2E to 2HIntroduction. First, the upper frame element 22c is inserted into the frame structure 2, in which the cutout 27 of the frame element 22c is aligned with the bolt 25 of the closing profile 10c, and the frame element 22c is pushed upwards, causing the bolt 25 to move into the cutout 27. Then, vertical frame elements 22a and 22b are used, with their cutouts 27 aligned with the bolt 25 of the closing profile 10b. Here, the frame element 22c is pressed upwards, thereby pressing the spring element 23 against the surface of the closing profile 10c and compressing it, allowing the corner connector 21 to be positioned above the receiving portion of the (now vertically erected) frame element 22b. If the frame element 22c is subsequently released, the spring element 23 is de-biased and presses the frame element 22c downwards, thereby moving the corner connector 21 into the receiving portions of the frame elements 22a and 22b.

Claims

1. A building wall module system, comprising: A frame structure having a defined width, height, and depth, the frame structure having a first upright structure extending in a first plane and a second upright structure extending in a second plane, the second plane being parallel to the first plane and having a defined distance from the first plane in the depth direction, thereby forming a gap between the two planes, wherein: a wall side region, a wall cladding region, and a passage region existing between the wall side region and the wall cladding region are defined in the frame structure, and a guide rail system extending above the passage region is arranged. In this configuration, on the two upright structures, a first lateral closed profile pair is arranged adjacent to the passage area on the side of the wall, a second lateral closed profile pair is arranged adjacent to the passage area on the wall cladding area, and an upper closed profile pair is arranged. The upper closed profile pair connects the first lateral closed profile pair and the second lateral closed profile pair at right angles. The first lateral closed profile pair, the second lateral closed profile pair, and the upper closed profile pair surround the passage area. The second lateral closed profile pair and the upper closed profile pair each have aisles for sliding doors that can unfold along the depth direction. The guide rails of the guide rail system are arranged in the upper region of the frame structure and extend parallel to the upper closed profile pair, wherein the guide rails are configured to support the sliding door between a closed position and an open position, in which the sliding door closes the passage area and presses against the closed profile pair, and in the open position, the sliding door fully or partially opens the passage area and is at least partially pushed into the wall enclosure area via a passageway; and The building wall module system also includes a frame insert that is configured to cover the frame structure in the passage area when the sliding door is stored in the wall enclosure area and is in a deactivated state, or when the sliding door is used only when needed. The frame insert has a connecting element that connects the frame insert inserted into the passage area to the frame structure, and when the inserted frame insert is removed, the connecting element separates the frame insert from the frame structure.

2. The building wall module system according to claim 1, wherein, The frame insert has: a first frame element that can be inserted into the first lateral closed profile pair, a second frame element that can be inserted into the second lateral closed profile pair, and a third frame element that can be inserted into the upper closed profile pair, wherein each frame element has at least one connecting element.

3. The building wall module system according to claim 2, wherein, The at least one connector has a cutout in the frame element, into which a complementary pin element arranged on the frame structure can be inserted, and optionally a fastening element is provided to secure the pin element inserted into the cutout.

4. The building wall module system according to claim 3, wherein, The third frame element has an elastic element on its inner surface, wherein the elastic element is arranged such that it pushes the third frame element toward the first and second frame elements in the inserted state.

5. The building wall module system according to claim 4, wherein, The elastic element is a spring element.

6. The building wall module system according to any one of claims 2 to 5, wherein, The border insert is designed as a channel insert, wherein the first, second and third border elements together form an outer frame, the outer frame having an outer surface that surrounds the channel region along a pair of closed profiles in the inserted state of the border insert, and each pair of closed profiles is covered at least toward the channel region, wherein the outer surface of the outer frame is flat.

7. The building wall module system according to any one of claims 1 to 5, wherein, The frame insert is designed as a wall hole insert with a wall hole and a wall component. The wall component fills the channel area outside the wall hole when the frame insert is inserted. The wall component has a crossbeam, a bottom element, and a vertical post arranged at a defined height. The post extends between the bottom element and the crossbeam in two parallel planes, which correspond to the planes of the post structure.

8. The building wall module system according to any one of claims 2 to 5, wherein, The frame insert is designed as a shelf insert, which closes the channel area when the frame insert is inserted. The frame insert also has a rear wall and at least one tray. The rear wall is connected to the first, second and third frame elements, and the tray is accessible from the side opposite to the rear wall.

9. The building wall module system according to any one of claims 2 to 5, wherein, The frame insert is configured as a pivot door insert, which further includes a pivot door and a fitting, wherein the pivot door locks or opens the channel area in the inserted state of the frame insert, and the pivot door is pivotally connected to one of the lateral frame elements via the fitting.

10. The building wall module system according to any one of claims 1 to 5, wherein, The frame insert is designed as a sliding door insert, which also includes a sliding door. The second lateral frame element has a vertical through-hole, through which the sliding door can be guided between two upright structures in the wall enclosure area. The third frame element has a horizontal through-hole, through which the sliding door can be connected to a guide rail system and can be moved along the through-hole.

11. The building wall module system according to claim 1, wherein, The frame insert is designed as a wall insert, which completely fills and closes the channel area when the frame insert is inserted. The frame insert has a vertical post, a reinforcing element, and a bottom profile. The vertical post extends in two parallel planes between the bottom profile and the upper closed profile pair when the frame insert is inserted. The two parallel planes correspond to the planes of the post structure.

12. The building wall module system according to claim 11, wherein, The reinforcing element adjacent to the frame structure in the lateral direction has a flange, which enables the reinforcing element to be connected to the frame structure. The bottom profile has a flange at its lateral end, which enables the lateral end of the bottom profile to be connected to the frame structure. The vertical upright can be connected to the bottom profile at its lower end and to the upper closed profile pair at its upper end, or can be connected to the frame structure around the upper closed profile pair.

13. The building wall module system according to claim 1, wherein, The border insert is designed as a window insert having a wall component and a window, wherein the window has an open state and a closed state, wherein in the open state, an opening in the wall component and a portion of the channel area therefrom are open, and in the closed state, the opening is locked, wherein the border insert completely fills the channel area in both the inserted and closed states of the window.

14. The building wall module system according to claim 13, wherein, The window is designed as a sliding window that can be pushed horizontally or vertically, or as a cover that can be pivoted horizontally or vertically, wherein the window includes an electromechanical actuator that automatically opens and closes the window.

15. A method for adapting a building wall module system to suit specific needs, the building wall module system having a frame structure installed in a building and having a fixed width, height, and depth, the frame structure being configured for use with a sliding door capable of unfolding in the depth direction, wherein, The frame structure includes a wall side region, a wall shell region, and a passage region between the wall side region and the wall shell region. A guide rail system for an operable sliding door is arranged, extending above the passage region. A lateral first closing profile pair is arranged on the wall side region adjacent to the passage region. A lateral second closing profile pair and an upper closing profile pair are arranged on the wall shell region adjacent to the passage region. The upper closing profile pair connects the lateral first and second closing profile pairs at right angles. The lateral first closing profile pair, the lateral second closing profile pair, and the upper closing profile pair surround the passage region. The lateral second closing profile pair and the upper closing profile pair each have a passageway for the sliding door. The method includes: A frame insert is provided for covering a frame structure in a passageway area when the sliding door is stored in a wall-encased area and is in a deactivated state, or when the sliding door is only used when needed. The frame insert is to be inserted into the passageway area and connected to the frame structure from the passageway area. The frame insert includes multiple sub-components, each sub-component having at least one connecting element, through which the respective sub-component can be connected to the frame structure after being positioned relative to one of the closing profile pairs, wherein a sequence is determined for positioning and connection. Insert and connect the sub-components in the determined order.

16. The method according to claim 15, wherein, The frame insert includes a first frame element that can be inserted into a first lateral closed profile pair, a second frame element that can be inserted into a second lateral closed profile pair, and a third frame element that can be inserted into an upper closed profile pair, wherein the third frame element is inserted first, and the third frame element is pushed upward in order to insert the first frame element, thereby compressing at least one spring element, and releasing it after the first or second frame element is inserted, thereby de-biasing the spring element and pressing the third frame element onto the first or second frame element; The inserted and connected frame inserts can be removed from the frame structure by disconnecting the connecting elements; and / or The frame insert is configured as a channel insert, wall hole insert, shelf insert, pivot door insert, sliding door insert, wall insert, or window insert.

Images