RU2755174C1 - Ribbed dome made of glued wooden arch trusses - Google Patents

Abstract

FIELD: construction industry.

SUBSTANCE: invention relates to the field of construction, in particular to a ribbed dome made of glued trusses. The frame of the ribbed dome includes the lower support element of base 1, meridional arched ribs 2 and upper support element 3. For the manufacture of the meridional ribs and the lower support element of the base, glued wooden arched trusses containing two curved belts fastened together by a connecting grid and having cantilever outlets at both ends were used. Each meridional edge is a glued-wood arch truss, and the lower support element of the base is made in the form of a closed detachable ring of glued-wood arch trusses. The upper support element is made in the form of a frame-ring system. The junctions of the meridional arched ribs with the lower support element of the base and the upper support element are made by means of cantilever releases of the rib belts using grooved and bolted connections.

EFFECT: increase in the spatial rigidity and stability of the dome.

5 cl, 11 dwg

Description

The invention relates to the field of industrial, civil and agricultural construction, in particular to architecture and construction of buildings and structures for various purposes.

The dome, as a separate form-building structural system, has found wide application as a traditional type of housing among many indigenous peoples living in various climatic conditions. Also, domed structures are actively used in modern architectural and construction projects of buildings and structures for various purposes, which makes it possible to significantly expand space-planning solutions, improve ergonomic characteristics, and reduce operating costs. Including ample opportunities for high-quality provision of standardized values and indicators in the field of architectural and construction acoustics, lighting engineering, construction heat engineering and aerodynamics.

From technical literature by the author Lipnitsky M.E. in the book Domes (calculation and design). - L .: Publishing house of literature on construction, 1973 .-- 128 p. [1] the following types of domes are identified: shell-domes, ribbed domes, rib-ring, rib-ring with lattice ties and mesh, as well as various options for their modification.

From the scientific and technical literature [1], a ribbed dome is known, consisting of separate flat ribs installed in the radial direction. Ribbed domes are a spacer system. At the top of the dome, radial ribs adjoin the upper ring. In this case, the configuration of the lower support ring in the plan can be made curved along a given radius, or in the form of a polyhedron with rigid or hinged coupling in the corners. Special flooring is laid between the ribs, or a membrane or panel covering is created.

Known dome-shaped structure with a wooden arch according to CN patent No. 202809943, E04B 7/08, publ. 03/20/2013 [2], in which the lower arched belts and ribs are made of wooden elements connected to each other according to the tongue-and-groove system.

The disadvantage of this design is a significant number of joints of wooden elements, which requires high physical and mechanical qualities of the wood used, qualified installation of the structure and high accuracy in the geometry of each part.

Known dome according to the RF patent for invention RU No. 2627800, E04B 1/32, publ. 08/11/2017 [3], consisting of composite meridional arched ribs, evenly spaced along the perimeter of the dome, the upper ends of which are connected to the central support element, and the lower ends - to the support element of the base. The meridional arched ribs are made of overlapping ends at an angle to each other of elements fastened with dowels. In each of the nodes of interface of the rib elements, it is also provided for the fastening of horizontal girders, put on the free ends of the dowels.

The disadvantage of this solution is that the meridional arched ribs are a composite structure, the elements of which are connected by pins. The presence of horizontal girders in nodal connections is a vulnerability, as their geometric displacement can lead to progressive collapse. At the same time, a large number of nodal joints and the metal fasteners required for them leads to a decrease in the thermal engineering uniformity of the structure.

The closest analogue to the proposed design of the dome, adopted as a prototype, is considered a dome, according to the RF patent for a useful model RU 193237, E04B 1/32, publ. 21.10.2019 [4], containing compound meridional arched ribs, evenly spaced along the perimeter of the dome. The meridional arched ribs are fixed from above to the central element (in the terminology of the description of the present invention - the upper supporting element), and from below to the supporting element of the base (in the terminology of the present patent - the lower supporting element of the base). All elements of the dome frame are made of wood, the upper support element is disk-shaped. As in the above-described patent [3], the elements of the arched ribs are interconnected with an overlap along the cut ends and fastened in the transverse direction with dowels, and also connected to horizontal girders put on the free ends of the dowels. The difference between the prototype and the design described in the patent [3] is the use of fasteners in the nodes according to the thorn-groove principle, formed by milled ends of elements with offset edges.

The design of the prototype has a number of disadvantages, mainly due to the fact that, similar to the dome from the patent [3], this solution includes a large number of structural elements and their connections made with the use of metal products. The totality of the structural system does not provide sufficient rigidity and stability of the nodal joints in the event of linear deformations due to the pliability of the elements. The exclusion of one of the structural elements from the operation of the dome structure in the longitudinal or transverse directions can lead to an emergency situation, as a result of which a progressive collapse may occur. Also, the above characteristics of the prototype generally reduce the thermal engineering uniformity of the structure. On the other hand, the design of the prototype does not provide for the possibility of adaptive design of every part, including sawing and cutting sawn timber, which leads to increased costs and waste in the production of structural elements.

In addition, the upper support element made in the form of a disk excludes the possibility of installing a translucent structure (for example, a skylight) from above in the center of the dome, which could serve for effective insolation and aeration of the room. In addition, the connection of such a support element with the meridional ribs is rather vulnerable. The disc is secured into evenly spaced slots in the upper part of the meridional ribs. In the process of preliminary compression of the disk contour in the places of its conjugation with the grooves, local crushing sites are formed, as a result of which there is an increased deformability of these nodal joints. The operation of this type of joints in timber structures can cause material destruction.

The technical result to be achieved by the present invention is to create a thermally homogeneous structure of the ribbed dome frame, which has increased spatial rigidity and resistance to deformation. Below, including when describing particular cases of implementation of the proposed invention, other types of the achieved technical result will be named.

The proposed structure of the ribbed dome frame, like the one mentioned above, which is closest to it [4], includes meridional arched ribs, a lower support element of the base made of wooden elements, and an upper support element. Each of the meridional arched ribs in its upper part is connected to the upper support element, and in the lower part - to the lower support element of the base, while in the aggregate the meridional arched ribs are evenly distributed along the contour of the upper and lower support elements.

To achieve the specified technical result in the proposed frame of the ribbed dome, in contrast to the prototype, as structural elements for the manufacture of meridional arched ribs and the lower support element of the base, glue-wood arched trusses are used, each of which contains two curved belts, fastened together by a connecting lattice, and each of the belts has console editions at both ends.

A glued wooden arched truss, which is a glued wooden belt connected by a triangular lattice formed by uprights and braces, is known from the RF patent for a useful model RU No. 197887, E04C 3/12, publ. 06/04/2020 [5]. However, in the proposed structure of the dome frame, modifications of the glued wooden arched truss are used according to the patent [5], which make it possible to implement reliable nodal connections of the dome frame elements and to optimize the material consumption of the structure. Unlike the technical solution according to the patent [5], glue-wood arched trusses used as structural elements of the proposed dome frame contain cantilever outlets at the ends of the belts. In addition, the glued-wood arched trusses, from which the lower supporting element of the base is made, have a different type of connecting lattice, simplified in comparison with the technical solution according to the patent [5]. The use of glue-wood arched trusses, along with the noted features of their manufacture, contribute to the achievement of the above technical result due to the nature of their static work and the functional interaction of such trusses with the supporting elements that make up the proposed frame of the dome, in combination with constructive solutions for the implementation of these elements, which is in more detail explained further.

Each meridional arched rib is a glued-wood arched truss with a polygonal connecting lattice including struts orthogonal to the truss chords and braces located between the struts, and any two adjacent braces are connected to the same end of the struts located between them.

The lower supporting element of the base is made in the form of a closed split ring and is a set of glued-wood arched trusses, the connecting lattice of each of which consists of racks orthogonal with respect to the upper and lower chords. The closed contour of the lower supporting element of the base is formed by fixing the cantilever outlets of the glue-wood arched trusses in a half-tree between themselves.

In addition, to achieve the technical result, the upper support element is made in the form of a frame-ring system, which is two identical rings (upper and lower) located horizontally one above the other with vertical surfaces connected to each other by vertical posts, evenly distributed along the contours rings.

The achievement of the technical result is also ensured by the fact that the junctions of the meridional arched ribs with the lower supporting element of the base and the upper supporting element are made by means of cantilever outlets of the rib belts: at one end of the meridional arched rib, the cantilever outlets of the belts are fixed to the outer and inner surfaces of the lower supporting element of the base, and at the other end, to the outer vertical surfaces of the upper and lower rings of the upper support member.

Glue-wood arched trusses are flat structural elements. Moreover, the scope of their application is limited by the nature of the static work of the structure, which depends on the presence or absence of hinges. By the nature of the work, glue-wood arched trusses can be divided into the following types: hingeless, double-hinged, three-hinged. In the case of their use as ribbed structures of the dome, the spatial nature of the operation of such elements arises. In the proposed dome design, a spatial system is created in which each pair of cross ribs can be considered as a three- or two-articulated arch that transfers the spacer to the lower support ring and the upper connecting element. Thus, the proposed ribbed dome made of glue-wood arched trusses ensures the work of the meridional arched ribs for the perception of axisymmetric loads.

Manufacturing of meridional arched ribs from glue-wood arched trusses provides increased, in comparison with the prototype, rigidity and stability of the dome frame to deformations from external influences (for example, wind and precipitation) due to the absence of redundant attachment points in their design, as well as horizontal girders. The exclusion of one meridional arched rib from the structure of the dome frame will not cause progressive collapse, since the proposed structure is protected by rational means at the development and design stage, which is realized due to an increase in the degree of static indeterminacy of the structure, which is ensured by increasing the continuity of the structure and reducing the number of hinged joints. Spatial rigidity and stability of the ribbed dome are additionally achieved due to the fact that the outer and inner surfaces of the meridional arched rib are strengthened by covering panels.

The free space between the elements of the connecting lattice of the glue-wood arched trusses makes it possible to effectively use it for placing heat-insulating materials and routing engineering communications. Thus, the proposed solution makes it possible to increase the heat-shielding qualities of the enclosing structure, reduce operating costs, achieve a compactness of the internal volume of a building or structure, and create an ergonomic interior design.

In domes of this type, the lower support element of the base perceives tension from the maximum spacing of the meridional arched ribs, evenly distributed along its looped contour, due to which resistance to linear deformations of the structure as a whole is achieved. The stability of the most closed contour of the lower supporting element of the base is achieved by connecting the cantilever outlets of the chords of glue-wood arched trusses to each other in a half-tree. This type of connection is easy to manufacture and allows you to reliably unite structural elements into a single whole.

To reduce material consumption, braces are excluded from the structure of the connecting lattice of glue-wood arched trusses forming the lower supporting element of the base, since they do not participate in the static operation of the lower supporting element.

In order to ensure free radial and angular displacements of the lower supporting element of the base, the proposed structure can also be attached to the underlying structures, for example, using embedded parts and fastening materials provided at the joints of these structures.

The use of glue-wood arched trusses as structural elements of a ribbed dome makes it possible to achieve unification of individual parts for design, construction and assembly. For example, for the manufacture of meridional arched ribs and the lower support element of the base, it is optimal to use glued-wood arched trusses with the same cross-section of the chords.

The proposed constructive solution of the upper support element in the form of a frame-ring system allows for various options for connections with meridional arched ribs, providing spatial rigidity in the attachment points, which increases the overall stability of the dome under the perception of snow and wind influences. For example, various types of bolted connections are possible. In this case, the selection of the geometric parameters of the bolts is determined by calculation.

In addition, the use of an upper supporting element of this type makes it possible to provide for the installation of a translucent structure (for example, a skylight) in the volume of the frame-ring system, which makes it possible to increase the intensity and duration of insolation in the room and to increase the efficiency of natural air exchange.

To connect the meridional arched ribs with the outer side surfaces of the rings of the upper support element, it is necessary to provide that the distance between the rings of the frame-ring system is less than or equal to the distance between the belts of the meridional ribs, while the specific choice of the distance between the rings and the height of the cross-section of the rings depends on the nature of the perceived loads and external influences of the environment.

The combination of these distinctive features of the proposed structure of the ribbed dome frame, when all the elements work together, leads to a reduction in the number of interface nodes in the structure and, accordingly, the number of fasteners used, thereby increasing the thermal engineering uniformity of the structure while reducing material consumption. With a small number of interfaces and unification of structural elements, the assembly assembly of the structure is also simplified, which avoids the costs associated with the purchase of specialized equipment and the involvement of highly qualified specialists. Together with a decrease in material consumption, this reduces the cost of the process of erecting dome structures and makes it less laborious.

It is recommended to fasten the meridional arched ribs to the lower supporting element of the base using groove joints. For this, grooves coaxial to each other are made on the outer and inner surfaces of the lower support element of the base, the number of pairs of which is equal to the number of ribs. Pairs of grooves are evenly distributed along the contour of the bottom support element of the base. Each pair of grooves is fixed with cantilever outlets of the meridional arched rib belts, while the fixation can be reinforced with adhesive joints and glass composite rods. The grooves located on the outer surface of the lower supporting element of the base are connected to the cantilever outlets of the upper chords of the meridional arched ribs, and the grooves located on the inner surface of the lower supporting element of the base are connected to the cantilever outlets of the lower chords of the meridional arched ribs. Each groove is made in such a way that one of its edges is mated with the curved surface of the cantilever outlet in such a way that the adjacent surfaces have a common angle of inclination.

The presence of evenly spaced groove joints of the meridional arched ribs with the lower supporting element of the base provides the necessary rigidity of the dome structure and redistributes the resulting loads on the foundation and the subgrade. Also, the use of glued-wood groove joints allows to increase the thermal engineering uniformity of the structure.

The optimal ratio between material consumption and structural stability is also achieved when choosing the number of orthogonal posts of the connecting lattice of glued-wood arched trusses, forming the lower support element of the base, equal to 2n, where n is the number of meridional arched ribs.

The frame-ring system of the upper support element can be made of metal, wood or composite materials. The metal version of the frame-ring system has advantages in speed and economy when erecting a dome structure, and also has higher strength characteristics during operation. When a frame-ring system is made of metal, the rings of the upper support element can be closed bent profiles, to the outer side surface of which fittings with flat side faces, which are evenly distributed along the contour of the rings, are rigidly fixed (for example, by welding). The shaped products are located relative to each other on the upper and lower rings in such a way that they form pairs with a common vertical axis of symmetry. The number of such pairs of fittings coincides with the number of meridional arched ribs. Fastening of cantilever outlets of belts of meridional arched ribs to paired fittings can be carried out using bolted connections or using metal toothed plates. In the case of using a bolted connection, through holes are provided in the lateral faces of fittings and console outlets of chords.

The use of wood or composite materials for the manufacture of the upper support element provides a higher thermal engineering uniformity of the structure. For example, the frame-ring system can be made of solid wood or bent glued lamellas. In this case, the connection of the cantilever outlets of the belts of the meridional arched ribs with the frame-ring system can be grooved. To implement such a connection, paired grooves must be provided in the outer vertical surfaces of the upper and lower rings, evenly distributed along the contour of the upper support element. Accordingly, the number of pairs of such grooves should be equal to the number of meridional arched ribs of the dome.

In addition to the above recommended characteristics, in most cases, in order to achieve the technical result, as well as ergonomic indicators during the design and assembly of the dome frame, it is necessary to adhere to the following geometric criterion: the value of the dihedral angle between the tangent plane to the outer surface of the meridian rib at the point of conjugation with the lower support ring and the horizontal plane should be between 80 ° and 90 °.

In the graphical part, the essence and variability of the manufacture of the dome frame according to the invention is illustrated by drawings and photographs shown in Figs. 1-11.

Figure 1. General view of the structure of the frame of the dome. Isometric view.

Figure 2. The layout of the structure of the frame of the dome in the plan.

Figure 3. Section 1-1.

Figure 4. Node A. Option 1.

Figure 5. Node A. Option 2.

Figure 6. Upper support element made in the form of a frame-ring system of bent metal profiles.

Figure 7. Node B. Conjugation of the meridional arched ribs with the upper support element (in the metal version).

Figure 8. Node of conjugation in the structure of the lower support element of the base. Photography in building conditions.

Figure 9. Node of conjugation of meridional arched ribs with the lower supporting element of the base. Photography in building conditions.

Figure 10. Element-wise installation of the supporting structures of the dome frame (with the upper support element made of bent metal profiles). Photography in building conditions.

Figure 11. The final stage of installation of the supporting frame of the dome (with the upper support element made of bent metal profiles). Photography in building conditions.

File of a three-dimensional model of the invention in electronic form. File name: Ribbed dome made of glue-wood arched trusses.stl. The presented 3D model of the dome frame includes an assembly of glue-wood arched trusses and other structural parts and elements.

Presented in figures 1, 2, the frame of the ribbed dome includes a lower support element of the base 1 formed from glue-wood arched trusses 1.1, meridian arched ribs 2 and an upper support element 3 (a metal version is shown).

Figure 3 illustrates a longitudinal section 1-1 of the frame of the dome, which shows a frontal projection of the dihedral angle between the tangent plane to the outer surface of the meridional arched rib 2 at the point of conjugation with the lower support element of the base 1 and the horizontal plane. The drawing indicates the range of angle values from 80 ° to 90 °, which is optimal for most cases.

In figures 4, 5, in two versions, node A is shown, showing the types of connection of glued-wood arched trusses 1.1 to each other to form a closed contour of the lower supporting element of the base 1. The belts of each of the trusses 1.1, having cantilever outlets 1.4, are fastened together by radially arranged posts 1.2 ... In the console outlets of chords 1.4, through holes 1.5 are provided, allowing, using fasteners, for example, screws 1.6 and nuts 1.7, to make a half-wood connection 1.8 to form a closed loop of the lower support element of the base 1. On the outer and inner surfaces of the lower support element of the base 1 there are paired grooves 1.3 (see Fig. 5) for fixing the cantilever outlets of the belts 2.1 of the meridional arched ribs 2 (see Fig. 4).

Figures 6, 7 show an embodiment of the frame-ring system of the upper support element 3 made of bent metal profiles. The upper 3.1 and lower 3.2 rings are connected by posts 3.3. Paired fittings are welded to the vertical surfaces 3.5 of the upper 3.1 and lower 3.2 rings 3.4. Through holes 3.6 are provided in the lateral faces of fittings 3.4 and cantilever outlets of the belts of the meridional arched ribs 2, which make it possible to connect the meridional arched ribs 2 with the upper support element 3 by means of tightening bolts 3.7.

The assembly of the ribbed dome frame, some of the steps of which are illustrated in FIG. 8-11 is performed in the following technological sequence and in compliance with the following conditions:

• a plot of land is being prepared on which one of the types of foundation is being installed: for example, strip, pile or solid;

• in the case of using a pile-type foundation, its heads are fastened with a grillage, on the horizontal surface of which the base of the floor is laid in the form of separate sectors, forming a polygon in the plan supported by a central grillage;

• the grillage can be a split ring consisting of metal arcs connected to each other using equal angles welded to the heels of the arcs from the inside; the joining of the arcs included in the split ring is performed using a system of paired corners connected with fasteners (for example, two mirrored screws) through pre-prepared holes;

• to the bottom edge of the grillage, made in the form of a split ring, from the inner side of each arc with an intermittent seam at an equal distance from each other, metal products are welded, which include horizontal metal plates with a mounting loop; each horizontal plate has a hole for attachment to the supporting structure (for example, foundation, wall, column) using anchor bolts;

• further along the perimeter of the base of the floor, forming a polygon shape in the plan, glue-wood arched trusses 1.1 are laid, which are fastened together by fixing the console outlets of the chords 1.4 in the half-wood 1.8 to form the lower supporting element of the base 1;

• the meridional arched ribs 2 are attached to the outer and inner surfaces of the lower supporting element of the base 1 by connecting the grooves 1.3 with the console outlets of the chords 1.4 located at one end of the ribs;

• grooves 1.3 are made tetrahedral in such a way that the lower face is horizontal, the two lateral faces are orthogonal to the lower one, and the adjacent face, conjugated with the curved surfaces of the belts of the meridional arched rib, is inclined and coincides in the angle of inclination with the adjoining surface;

• cantilever outlets of chords 1.4, located at the other end of the meridional arched ribs 2, are attached to the lateral faces of paired fittings 3.4 of the upper support element 3 through pre-made holes 3.6 using tie bolts 3.7.

To check the correctness of the installation of the structure, the criterion can be the value of the angle of inclination of each of the meridional arched ribs 2 to the horizontal plane of the lower supporting element of the base 1, which should lie in the range of values from 80 ° to 90 °.

All glue-wood arched trusses used in the structure of the ribbed dome frame are ready-made assembly units and are manufactured in off-site conditions, which simplifies the installation of the dome structure. The assembly of individual structural elements included in the frame of a ribbed dome with an internal volume of up to 90 m ³ can be carried out in a room with an area of up to 100 m ² by two or three people.

In addition to glued timber, it is planned to manufacture arched trusses for the lower supporting element of the base and meridian arched ribs from various composite materials. The conditions for their use are relatively low density, strength, a high degree of thermal engineering homogeneity and a low thermal conductivity coefficient (0.14 ... 0.35 W / (m⋅ ° C)), which provide high heat-shielding characteristics.

The frame of the ribbed dome made of glue-wood arched trusses can be used in the construction of low-rise residential buildings, as well as for solving various problems in the field of industrial, civil and agricultural construction, architecture, interior and environmental design. Such a dome frame can, for example, be used for the construction of theaters and concert halls, greenhouses, laboratory houses, hangars for storing fertilizers and elevators, as well as exhibition pavilions, baths and spa complexes.

The proposed invention provides ample opportunities for the use of dome structures in areas with different climatic and weather conditions. For example, in areas with harsh climatic conditions, the proposed structure of the dome frame allows achieving high specific characteristics of heat energy consumption for heating and energy savings during the operation of buildings and structures; in areas with hot climates - to increase the thermal stability of the enclosing structures and to create the optimal parameters of the microclimate of the internal premises. In climatic regions characterized by difficult weather conditions, for example, strong winds or precipitation, this design allows you to provide the required indicators for the reliability and stability of the structure in question. The widespread use of a ribbed dome in mass low-rise construction will reduce production costs at the stage of manufacturing individual structural parts, reduce the number of standard sizes of elements and simplify the installation technology.

Bibliography

1. Lipnitskiy M.E. Domes (calculation and design). - L .: Publishing house of literature on construction, 1973 .-- 128 p.

2. Patent No. 202809943, People's Republic of China (CN), IPC E04B 7/08 (2006.01). Appl. 08/22/2012: publ. 03/20/2013.

3. Patent No. 2627800, Russian Federation (RU), IPC Е04В 1/32 (2006.01). Dome / Tarasov V.M; applicant and patentee Tarasov V.M. - No. 2016125035: Appl. 06/22/2016: publ. 11.08.2017, bul. 23.

4. Patent for running meter No. 193237, Russian Federation (RU), IPC Е04В 1/32 (2006.01). Dome / Zhuravlev I.A., Zolotsev I.V .; applicant and patentee Zhuravlev I.A., Zolottsev I.V. - No. 2019112279: Appl. 04/23/2019: publ. 2019, bul. thirty.

5. Patent for running meter No. 197887, Russian Federation (RU), IPC E04C 3/12 (2006.01). Glued wooden arched truss / Novozhilov V.V., Kuznetsov A.V., Voloshina P.V; applicant and patentee Novozhilov V.V., Kuznetsov A.V., Voloshin P.V - No.2020107195: Appl. 02/17/2020: publ. 06/04/2020, bul. 16.

Claims (5)

1. The frame of the dome, containing the meridional arched ribs and the lower support element of the base, made of wood, as well as the upper support element, with each of the meridional arched ribs connected in the upper part with the upper support element, and in the lower part with the lower support element bases, and the lower and upper supporting elements have a closed contour, and the meridional arched ribs are collectively evenly distributed along the contour of the upper and lower supporting elements, characterized in that glue-wood arched trusses are used as structural elements for the manufacture of meridian arched ribs and the lower supporting element of the base , each of which contains two curved belts, fastened together by a connecting lattice, and each of the belts has cantilever outlets at both ends, while each of the meridional arched edges is made in the form of a glued-wood arched truss with a polygonal connecting lattice, including racks, about rtogonal to the truss belts, and the braces located between the struts, and any two adjacent braces are connected to the same end of the rack located between them, and the lower supporting element of the base is made in the form of a closed split ring, which is a set of glued-wood arched trusses, each of which includes a connecting lattice, consisting of racks orthogonal with respect to the upper and lower chords, and the closed contour of the lower supporting element of the base is formed by fixing the cantilever outlets of glue-wood arched trusses in a half-tree; in addition, the upper supporting element is made in the form of a frame-ring system, which includes two identical rings located horizontally one above the other with vertical surfaces - upper and lower, connected to each other by vertical posts, evenly distributed along the contours of the rings; in addition, the junctions of each of the meridional arched ribs with the lower supporting element of the base and the upper supporting element are made by means of cantilever outlets of the belts of the meridional arched rib, while the cantilever outlets of the belts at one end of the meridional arched rib are fixed to the outer and inner surfaces of the lower supporting element of the base, and at the other end to the outer side surfaces of the upper and lower rings of the upper support member. 2. The frame of the dome according to claim 1, characterized in that each meridional arched rib is connected to the lower supporting element of the base by means of a pair of coaxial grooves provided on the outer and inner surfaces of the lower supporting element of the base, wherein each groove is made in such a way, that one of its faces is conjugated with the adjacent curved surface of the cantilever outlet of the belt of the meridian arched rib, and the pairs of such grooves are evenly distributed along the contour of the lower supporting element of the base. 3. The frame of the dome according to claim 1 or 2, characterized in that fittings with flat side faces are installed on the outer side surfaces of the upper and lower rings of the upper support element, which are evenly distributed along the contour of the upper support element and are located relative to each other on the upper and the lower rings of the upper supporting element in the form of pairs with a common vertical axis of symmetry, while the number of pairs of shaped products coincides with the number of meridional arched ribs, moreover, for attaching the meridional arched ribs to the upper supporting element in the lateral faces of shaped products and cantilever outlets of the belts of meridional arched ribs through holes. 4. The frame of the dome according to claim 1 or 2, characterized in that the number of orthogonal posts of the connecting lattice of the glued-wood arched trusses forming the lower supporting element of the base is equal to 2n, where n is the number of meridional arched ribs. 5. The frame of the dome according to claim 4, characterized in that fittings with flat side faces are installed on the outer side surfaces of the upper and lower rings of the upper support element, which are evenly distributed along the contour of the upper support element and are located relative to each other on the upper and lower rings the upper supporting element in the form of pairs with a common vertical axis of symmetry, while the number of pairs of shaped products coincides with the number of meridional arched ribs, and through holes are provided for attaching the meridional arched ribs to the upper supporting element in the lateral faces of shaped products and cantilever outlets of the belts of meridional arched ribs ...

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