RU2769001C1 - Method for assembling composite and multilayer thermal columns and floor thermal beams - Google Patents

Abstract

FIELD: construction.SUBSTANCE: invention relates to a method for assembling composite metal thermal beams and thermal columns. The method for assembling composite and multilayer thermal columns and thermal beams is performed from a set of profile elements made by the method for profiling cold-rolled metals. Profile elements are connected to form structural layers. Each subsequent structural layer covers the previous one with the formation of thermal cavities.EFFECT: simplification of the assembly of the structure.6 cl, 11 dwg

Description

The invention relates to the field of industrial and civil engineering, namely to building metal structures, including long-length load-bearing metal elements used in the construction of metal structures: industrial buildings, shopping centers, sports facilities, hangars. The basis for the mentioned metal structures are columns and floor beams.

The GPS profile (bent rack profile) is known (see, for example, https://www.vseangari.ru/index.php/profil-lstk/gps-s-profil). The profile is a C-shaped LSTK profile, with two stiffeners, used for the manufacture of columns, racks, floor beams.

The GPS-sigma profile is also known (see, for example, http://pro-lstk.ru/prodazha-profilei-lstk.html), which is used for the manufacture of racks, columns, frames and beams.

A compressed-bent LSTK I-beam is also known (see, for example, https://stroj.su/raschety-metallicheskih-konstrukcij/raschet-lstk-konstrukcii/kolonna-lstk-proverka-ustojchivosti.html), which is made of two Sigma -profiles and is used for the manufacture of columns.

It is also known to use a C-shaped profile (see, for example, https://lstkclub.ru/uzli-kreplenie-lstk/), for the manufacture of beams, racks and trusses, when thin-walled profiles are connected through a connecting plate, which is a steel sheet 8 mm thick as reinforcement.

It is also known to manufacture columns (see, for example, https://xn-24-6kcao3dxa.xn--p1ai/info/527-Proizvodstvo-metallokonstruktsii-kolonny). Profiles of columns in cross section are made rectangular or square, as well as round, made of pipes, or I-beams. Columns are made of constant and variable section (stepped columns). They are made by automatic welding. The starting material in production is metal sheets, which are first stretched and rolled into the desired shape (usually in the form of an I-beam or rectangular profile). To perform such an operation, a special welding mill is required. Rolled metal structures of columns of circular cross section are made using the methods of seamless hot rolling from metal billets. First, the metal blanks are subjected to heating, then they are stitched. For the manufacture of rolling metal structures of columns, a special mill is used, on which billets are rolled.

Typical cross-sectional shapes of thin-walled bent profiles are also known (see, for example, https://meqanorm.rU/Data2/1/4293748/4293748507.htm), including the shapes of composite sections from these profiles used in the manufacture of columns, racks and beams.

It is also known to use a C-shaped profile (see, for example, http://www.polimetall-spb.ru/tehlstk/floor.shtmt) as floor beams. In buildings with interfloor spans over 6 meters, it is possible to integrate ferrous metal floor beams.

It is also known to overlap from LSTK (see, for example, https://lstkclub.ru/perekritie-lstk/), for the manufacture of which light steel thin-walled galvanized C- and Z-shaped profiles are used.

The subject of this technical solution is a method for assembling composite and multilayer thermal columns and floor thermal beams from a set of profile elements made by profiling cold-rolled metals, consisting of a figured profile, P-profile and Sigma-profile.

The technical result of the claimed invention is to achieve ease of assembly of composite and multilayer thermal columns and thermal beams of ceilings from structural layers without the use of crane equipment, in the ease of forming a variable section of products, which gives more than 50% metal savings, in giving products high thermal insulation properties by providing many thermal cavities in the internal structure of products, in the exclusion of welding during assembly of products, in increasing the durability of products without damaging metal coatings, in simplifying production by manufacturing a set of profile elements on the same type of profiling lines with adjustable width.

The specified technical result is achieved by the fact that a method is proposed for assembling composite and multilayer thermal columns and thermal beams of floors from a set of profile elements made by the method of profiling cold-rolled metals, including those with coatings, including a figured profile with stiffeners, containing shelves, legs, heels and racks, U-profile containing a shelf and legs, SIGMA-profile with stiffeners, containing a saddle, shelves and legs and a reinforcing element made of two truncated curly profiles with shelves and legs, which is implemented by connecting the elements of the set with the same name to form structural layers , while each subsequent structural layer covers the previous one with the formation of thermal cavities, and the adjacent structural layers are made of opposite elements of the set, in addition, the inner structural layer is formed from any profile of the set for the entire length of the composite and multilayer thermal column or floor thermal beam, and the lengths and k the number of subsequent structural layers is formed as necessary, in addition, a structural layer of two curly profiles can be made by connecting profile shelves or profile heels, and a structural layer of two U-profiles can be made with an overlap of the legs of the profiles, in addition, a constructive a layer of two SIGMA profiles can be superimposed closely on the previous structural layer, and for additional reinforcement of the structural layer made of two figured profiles with the connection of the heels of the profiles, a reinforcing element can be installed in the inner cavity of this layer.

With the claimed method, the profile elements of the set are made on the same type of profiling lines with adjustable width from a strip of different widths, ensuring consistency and accuracy of geometric dimensions. At the same time, the profiles of the elements of the set are designed in such a way that during the assembly of the structural layers, numerous thermal cavities are formed, which provide thermal insulation of the structures during the subsequent operation of the composite and multilayer thermal columns and thermal beams of the floors. It is important that with this assembly method it becomes possible to produce columns of variable thickness depending on the number of storeys of the structure, and additional structural layers can be added to strengthen the columns and floor beams.

In FIG. 1 shows a cross section of the shaped profile of the set; in fig. 2 - cross section of the P-profile; In FIG. 3 - cross section of the SIGMA profile; in fig. 4 - cross section of the reinforcing element; in fig. 5 - cross-section of a structural layer from a figured profile with a connection of profile shelves; in fig. 6 - cross-section of the structural layer of the figured profile with the connection of the heels of the profiles; in fig. 7 - cross-section of a structural layer of a figured profile with a connection of the heels of the profiles, reinforced with a reinforcing element; in fig. 8 - cross section of two structural layers made of a figured profile and a U-profile; in fig. 9 - cross section of three structural layers made of a figured profile, a P-profile and a SIGMA-profile; in fig. 10 is a diagram of the execution of a composite and multilayer thermocolumn for a three-story building; in fig. 11 is a diagram of the execution of a composite and multilayer thermal beam of the floor, based on three columns.

The set of profile elements used in the assembly of composite and multilayer thermal columns 1 and floor thermal beams 2 includes a figured profile 3 with stiffeners 4, containing shelves 5, legs 6, heels 7 and racks 8, P-profile 9, containing a shelf 10 and legs 11, SIGMA-profile 12 with stiffeners 13, containing a saddle 14, shelves 15 and legs 16 and a reinforcing element 17, made of two truncated figured profiles 3 with shelves 18 and legs 19. The assembly method is implemented by connecting the same elements of the set with the formation of structural layers, while each subsequent structural layer covers the previous one with the formation of thermal cavities 20, and the adjacent structural layers are made of opposite elements of the set, in addition, the inner structural layer 21 is formed from any profile of the set for the entire length of the composite and multilayer thermocolumn 1 or floor thermal beam 2, and the length and number of subsequent structural layers are formed as necessary, in addition to At the same time, the structural layer 21 of two curly profiles 3 can be made by connecting the shelves 5 of the profiles or by connecting the heels of the 7 profiles, and the structural layer 22 of two P-profiles 9 can be made with an overlap of the legs 11 of the profiles, in addition, the structural layer 23 of the two SIGMA profiles 12 can be superimposed closely on the previous structural layer, and for additional reinforcement of the structural layer 21, made of two figured profiles 3 with the connection of the heels 7 of the profiles, a reinforcing element 17 can be installed in the inner cavity 24 of this layer.

When assembling composite and multilayer thermal columns 1 and floor thermal beams 2, self-tapping screws 25 are used in accordance with the set of rules SP 260.1325800.2016 “Thin-walled steel structures from cold-formed galvanized profiles and corrugated sheets”.

The claimed method of assembling composite and multilayer thermal columns 1 and floor thermal beams 2 involves the use of profile elements from a set made by profiling cold-rolled metals and consisting of a figured profile 3, P-profile 9, Sigma-profile 12 and reinforcing element 17.

In FIG. 1 shows a section of a figured profile 3 with stiffeners 4, two shelves 5, two legs 6, two heels 7 and two posts 8, from which the structural layer 21 is made.

In FIG. 2 shows a section of a U-profile 9 with a shelf 10 and two legs 11, from which the structural layer 22 is made.

In FIG. 3 shows a section of a SIGMA profile 12 with stiffeners 13, a saddle 14, two shelves 15 and two legs 16, from which the structural layer 23 is made. The molding depth of the saddle 14 is half the height of the leg 16.

In FIG. 4 shows a section of a reinforcing element 17 made of two truncated curly profiles 3 with shelves 18 and legs 19, connected by shelves 18 and fastened with self-tapping screws 25. The reinforcing element 17 can be installed in the inner cavity 24 of any structural layer to increase its rigidity.

In FIG. 5 shows a cross section of the structural layer 21, made of two figured profiles 3 with the connection of the shelves 5 of the profiles and fastened with self-tapping screws 25.

In FIG. 6 shows a cross-section of the structural layer 21, made of two shaped profiles 3 with the connection of the heels 7 of the profiles and fastened with self-tapping screws 25. With this fastening of the shaped profiles 3, an internal cavity 24 is formed, in which it is possible to place a reinforcing element 17 to increase the rigidity of the structural layer.

In FIG. 7 shows a cross-section of the structural layer 21 of two figured profiles 3 with the connection of the heels 7 of the profiles, reinforced by a reinforcing element 17 placed in the inner cavity 24 of the structural layer 21, all elements of which are fastened with self-tapping screws 25.

The structural layer 21 with or without a reinforcing element 17 contains up to three thermal cavities 20 and can be used to form a thermocolumn 1 or a floor beam 2.

In FIG. 8 shows a cross section of two structural layers connected as follows: on the structural layer 21, made of a figured profile 3, a structural layer 22, made of a U-profile 9, is superimposed, with an overlap of the legs of the profile. Both structural layers are fastened with self-tapping screws 25. This design as a whole contains five thermal cavities 20, which gives the thermal column 1 or the thermal beam of the floor 2, made of these two structural layers, high thermal insulation properties.

In FIG. 9 shows a cross-section of three structural layers connected as follows: on the inner structural layer 21, made of a figured profile 3, a structural layer 22, made of a P-profile 9, is superimposed, on which the outer structural layer 23, made of a SIGMA profile, is closely superimposed 12. All three structural layers are fastened with self-tapping screws 25. This design as a whole contains nine thermal cavities 20, which gives the thermal column 1 or the thermal beam of the ceiling 2, made of these three structural layers, even higher heat-insulating properties.

In FIG. 10 shows an example of a composite and multilayer thermocolumn 1 with a variable cross section for a three-story building. In the space of the first floor 26, the thermal column 1 consists of three structural layers, in the space of the second floor 27 - of two structural layers, in the space of the third floor 28 - of one structural layer. The inner structural layer 21 is made of a figured profile 3 and permeates all floors of the building. At the level of the first 26 and second 27 floors, the inner structural layer 21 is covered by the second structural layer 22 of the P-profile 9. On the first floor 26, both previous structural layers are covered by the third structural layer 23 of the SIGMA profile 12. Composite and multilayer thermocolumn 1 with a variable section installed on the foundation 29. The proposed method of assembling a composite and multilayer thermal column excludes the use of welding, excludes cross-linking of parts of the column with different sections, and ensures ease of assembly without the use of crane equipment.

In FIG. 11 shows an example of the execution of a composite and multilayer thermal beam of the floor 2, based on three columns 30. The thermal beam of the floor 2 is made with a variable section. The first structural layer 21 of the shaped profile 3 is made along its entire length. The second structural layer 22 of the U-profile is made partially: at the ends of the thermal beam 2 and in its middle part in the region of support on the middle column 30.

It should be noted that the options for combining structural layers in the manufacture of thermal columns 1 and thermal beams of floors 2 from the proposed set of profile elements can be very different, for example:

- figured profile 3, P-profile 9, SIGMA-profile 12;

- curly profile 3, P-profile 9;

- figured profile 3, SIGMA profile 12;

- P-profile 9, SIGMA-profile 12;

- SIGMA-profile 12, P-profile 9;

- figured profile 3, P-profile 9, SIGMA-profile 12, P-profile 9.

Thermocolumn 1 or thermal beam floor 2 can be made of one structural layer with any profile. If there is an internal cavity 24 in the structural layer, it is possible to use a reinforcing element 17. Any variant of assembling a thermocolumn 1 or a floor beam 2 can be completed with an external structural layer of P-profile 9 or SIGMA-profile 12.

Claims (6)

1. A method for assembling composite and multilayer thermal columns and floor thermal beams from a set of profile elements made by profiling cold-rolled metals, including those with coatings, including a figured profile with stiffeners, containing shelves, legs, heels and racks, U-profile, containing a shelf and legs, SIGMA-profile with stiffeners, containing a saddle, shelves and legs and a reinforcing element made of two truncated curly profiles with shelves and legs, characterized in that the assembly is carried out by connecting the elements of the same name with the formation of structural layers, with In this case, each subsequent structural layer covers the previous one with the formation of thermal cavities, and the adjacent structural layers are made of opposite elements of the set, in addition, the inner structural layer is formed from any profile of the set for the entire length of the composite and multilayer thermal column or floor thermal beam, and the lengths and number of subsequent constructive x layers are formed as needed. 2. A method for assembling composite and multilayer thermal columns and floor thermal beams according to claim 1, characterized in that the structural layer of two figured profiles is made by connecting the profile shelves. 3. The method of assembling composite and multilayer thermal columns and thermal beams of floors according to claim 1, characterized in that the structural layer of two figured profiles is made by connecting the heels of the profiles. 4. The method of assembling composite and multilayer thermal columns and floor thermal beams according to claim 1, characterized in that the structural layer of two U-profiles is made with an overlap of the legs of the profiles. 5. The method of assembling composite and multilayer thermal columns and floor thermal beams according to claim 1, characterized in that the structural layer of two SIGMA profiles is applied closely to the previous structural layer. 6. The method of assembling composite and multilayer thermal columns and floor thermal beams according to claim 3, characterized in that a reinforcing element is installed in the internal cavity of the structural layer, made of two figured profiles with the connection of the heels of the profiles, to further strengthen the structural layer.

Images