RU36680U1 - BUILDING MODULE, WALL PANEL OF BUILDING MODULE AND CROSS CONNECTOR OF BUILDING MODULE - Google Patents

Description

BUILDING MODULE

WALL PANEL OF THE BUILDING MODULE AND SLIPPING CONNECTOR OF THE BUILDING MODULE

The group of useful models relates to building structures using plug-in formwork modules to create wall structures, foundations, and in particular to a system for creating structures by filling concrete with fixed formwork, as well as to module elements. Thus, the design as a whole (the building module) and its parts (wall panel and transverse connector) are claimed.

Known construction site with jumpers RF Patent 2143036, MKI E04 2/86, publ. 12/20/1999, the building site contains two panels made of foamed plastic material. The panels are mutually spaced parallel to their surfaces facing each other. At least two transverse connectors extend between the panels. Each transverse connector has a pair of elongated end plates, partially molded into the body of the panels, so that thin narrow strips extend onto the outer surface of the panels. The connector incorporates a transverse narrow strip connecting the end plates, as well as braces extending from the middle of the transverse strip. On the braces are made nests for mounting longitudinal reinforcement.

The main disadvantage of the described construction is that the rigid fixing of wall panels at a predetermined distance from each other is carried out during their formation, which complicates the manufacturing technology and increases transport costs when delivering modules to the object. The second disadvantage is the complexity of the design of the transverse connector.

Non-removable formwork, described in the Modular wall design, Patent of the Russian Federation 2081263, MKI E04B 2/00, publ. 1997. The building module incorporates two wall panels made of polystyrene and located opposite each other on some

   / E04B 2/84

distance from each other. The distance between the walls is fixed by transverse connectors. The connectors are equipped with shanks having a T-shaped plan. Shanks are interconnected by a spacer. The spacer has a complex structure comprising two triangular elements oriented in a vertical plane. Triangular elements converge with sharp vertices to the central element, which is the holder of the vertical bar of the reinforcement and made in the form of a sleeve. The spacer is equipped with vertical protrusions (pins) that allow you to distribute the longitudinal reinforcement on the upper edge of the triangular element, preventing it from rolling to the center.

To fix the shanks of the connectors in the walls (on the surfaces facing inward), corresponding T-shaped vertical grooves are made, extending from the top surface of the panel and ending just below the middle (height) of the panel, forming a stop for fixing the position of the shanks of the connector. On the upper faces of the panels there are longitudinal protrusions, and on the lower faces there are reciprocal grooves forming a pair for connecting the wall panels in height.

The main disadvantage of this module is the low reliability of the design of the connector, since under the influence of the gravity of the reinforcement the support pins break off, which leads to an uneven distribution of the reinforcement. In addition, the design is not technologically advanced, since T-grooves are non-through and can only be performed by milling, i.e. in the factory, and not directly at the construction site. In this case, in the case of different heights of the T-grooves, distortions occur during installation of the connectors.

As a prototype of the second object, the wall panel, the wall panel selected in the cited source, RF Patent 2081263, MKI E04B 2/00, publ. 1997

As a prototype of the third object - the transverse connector, the connector is selected, also presented in the above source Patent RF 2081263, MKI E04B 2/00, publ. 1997

the basis of the group of utility models is the task of expanding the arsenal of construction tools and creating a building module and its constituent elements of simple design, reliable in operation, technologically advanced in manufacturing and installation, including at the construction site.

The problem is solved by changing the design of the building module, and its components.

The building module is a fragment of fixed formwork and includes at least two wall panels made of foamed plastic material. Wall panels are located opposite at some distance from each other and are interconnected by a transverse connector. On the inwardly facing surface of each wall panel, vertically oriented T-grooves are made. The transverse connector has a spacer equipped with means for fixing longitudinal reinforcement. At least two shanks are attached to the spacer, oriented in a plane perpendicular to the spacer plane and installed in opposed T-slots. New is that the T-grooves are made through from the top to the bottom surface of the wall panel, and the spacer is made in the form of a frame structure consisting of vertical end plates connected by horizontal jumpers.

At the same time, the means of fixing the longitudinal reinforcement available on the spacer are recesses made on horizontal jumpers or made in the form of arched brackets, which the frame structure is equipped with, while the brackets are made so that the longitudinal reinforcement can be covered from above or from below. In the vertical end plates, windows can be made. The frame structure can be equipped with inclined jumpers designed to give rigidity to the structure.

In more detail, the utility model (building module and its parts: wall panel and transverse connector) is illustrated by the following implementation examples and Figures of the drawings, which show:

FIG. 1- Building module in the assembly process.

The building module has two 1.2 steiye blocks made of foamed plastic material, for example, from a standard sheet of expanded polystyrene with smooth or ribbed surfaces. Wall panels 1.2 in the block are located opposite (opposite to each other), at some distance from each other. Such a mutual arrangement of the panels is fixed by means of transverse connectors 3 made in injection molding machines from a polymeric material, for example, from polypropylene.

The transverse connectors may have a very simple shape, such as that shown in FIG. 2. The transverse connector has a spacer in the form of a flat rectangular frame consisting of vertical plates 4 connected by horizontal jumpers 5. At least two shanks 6 are attached to the vertical plates 4, which are plates oriented in a vertical plane perpendicular to the plane of the frame. Preferably, four shanks are made on each connector — two on each vertical plate. On the ribs of the horizontal jumpers 5 are recesses 7, which provide for the positioning of longitudinal reinforcement.

A more complex design of the transverse connector is shown in Fig.Z. It also contains a spacer in the form of the above-described frame structure containing vertical plates 4 and horizontal jumpers 5. Shanks 6 are adjacent to the spacer - two on one side. The frame structure may be provided with additional vertical plates 8, one from each end, located closer to the vertical axis of the connector. Thus, between the vertical plates 4 and 8, a vertically oriented window 9 is formed on each side. The presence of windows, on the one hand, reduces the material consumption of the connector, on the other hand, improves the adhesion of the structure to concrete.

As a means of fixing the longitudinal reinforcement, arcuate brackets 10 can be used with which the frame structure is provided. Such brackets can be, for example, four - two for each horizontal jumper. Each bracket with its base is connected from the outside to the corner of the frame. The free (loose) ends of the brackets are oriented towards

vertical axis of the connector. This design allows you to distribute part of the longitudinal reinforcement on the upper horizontal bridge, while the upper arcuate brackets cover the reinforcement from above. The second part of the longitudinal reinforcement is distributed on the lower arcuate brackets, which support it, covering the bottom.

The connector may be further provided with inclined jumpers 11 extending, for example, as shown in FIG. 3 from the middle of the upper horizontal jumper to the edges of the lower horizontal jumper. Such inclined elements serve as additional stiffening ribs.

The presented examples of the implementation of the connectors do not exhaust all possible combinations of the above-mentioned additional elements with which the frame structure of the spacer can be equipped.

The height of the connector is equal to or a multiple of the height of the wall panel.

On the wall panels, on the surfaces facing the inside of the module, vertically oriented grooves 12 are made having a T-shape in cross section. The grooves are made through - from the top to the bottom surface (face). Such grooves can easily be performed by burning hot wire in two stages: first, a transverse groove to a depth corresponding to the width of the vertical plate, and then a transverse groove to a width corresponding to the width of the plate 6. Such a groove can be performed directly on the construction site if necessary.

A longitudinal groove 13 is made on the lower face of the wall panel, and a longitudinal ridge 14 is formed on the upper face, forming a pair of joints between the upper and lower naneli. At the end surfaces, grooves and ridges are respectively made for connecting adjacent panels in the row.

The modules are assembled in a single unit, preferably in a production environment. Through one of the surfaces of a standard (or specially cut to size) wall panel made of foamed plastic material, for example, polystyrene, through T-grooves are made as described above. A second similar panel is mounted opposite and parallel to the first at a given distance, while surfaces with T-shaped grooves are facing inward.

shanks of transverse connectors are inserted into opposite T-grooves from above to full depth. In one pair of panels, 4-6 transverse connectors are inserted in parallel, which fix the parallelism of the panels and the gap between them. Window and door blocks can be mounted in separate formed wall blocks.

At the construction site, the modules are installed according to the design and place the elements of longitudinal reinforcement, laying it in the recesses on horizontal lintels or using arcuate brackets. The cavity of the formed “tier of wall formwork is filled with a filler, for example, concrete, and maintained until the required strength is set.

Overlying wall blocks are fixed to the underlying ones by connecting longitudinal grooves and longitudinal ridges on the upper and lower faces of the wall panels.

Wall panels, made up of height, made of foamed plastic material (expanded polystyrene) during operation play not only the role of fixed formwork, but also the role of insulation. The reinforced concrete wall formed in the cavity of the formwork performs the function of the supporting structure.

Thus, as can be seen from the above implementation examples, the claimed utility model has a simplified design and is convenient for installation and transportation.

Claims (11)

1. A building module, which is a fragment of a fixed formwork and comprising at least two wall panels made of foamed plastic material, wall panels are located opposite at some distance from each other and are interconnected by a transverse connector, on the inwardly facing surface of each wall panel vertically oriented T-grooves are made, the transverse connector has a spacer equipped with means for fixing longitudinal reinforcement, at least two shanks oriented in a plane perpendicular to the strut plane and installed in opposed T-grooves, characterized in that the T-grooves are made through from the top to the bottom surface of the wall panel, and the spacer is made in the form of a frame structure consisting of end vertical plates connected by horizontal jumpers. 2. The building module according to claim 1, characterized in that the means for fixing the longitudinal reinforcement available on the spacer are recesses made on horizontal lintels. 3. The building module according to claim 1, characterized in that the means for fixing the longitudinal reinforcement available on the spacer are arcuate brackets, which the frame structure is equipped with, while the brackets are made so that the longitudinal reinforcement can be covered from above or below. 4. The building module according to any one of claims 1 to 3, characterized in that the windows are made in the vertical end plates. 5. The building module according to any one of claims 1 to 4, characterized in that the frame structure is equipped with inclined jumpers designed to impart structural rigidity. 6. The wall panel of the building module, made of foam plastic material, on the surface of which vertically oriented T-shaped grooves are made, characterized in that the T-shaped grooves are made through from the upper to the lower surface of the wall panel. 7. The transverse connector of the building module, comprising a spacer equipped with means for fixing longitudinal reinforcement, at least two shanks oriented in a plane perpendicular to the spacer plane are attached to the spacer, characterized in that the spacer is made in the form of a frame structure consisting of end vertical plates connected by horizontal jumpers. 8. The transverse connector according to claim 7, characterized in that the means of fixing the longitudinal reinforcement available on the spacer are recesses made on horizontal jumpers. 9. The transverse connector of claim 8, characterized in that the means for fixing the longitudinal reinforcement available on the spacer are arched staples, which are equipped with a frame structure, while the brackets are made so that the longitudinal reinforcement can be covered from above or below. 10. The transverse connector according to any one of claims 7 to 9, characterized in that the windows are made in the vertical end plates. 11. The transverse connector according to any one of paragraphs.7-10, characterized in that the frame structure is equipped with inclined jumpers designed to impart structural rigidity.