RU76054U1 - TENT COVERED PAVILION - Google Patents

Abstract

The proposed technical solution relates to the field of ground-based construction, in particular, to building structures, and can be used for the erection of pre-mounted and quick-mounted frame tent covers in the form of areas and platforms, pavilions, hangars, tents, summer cafes that are sheltered from the sun and atmospheric precipitation. The purpose of creating a utility model is to create a structure using smaller arched arches that form the frame, with increased frame rigidity and increased strength of fastening the arcuate arches of the pavilion frame to its base, i.e. improving operational performance. The pavilion contains an awning covering over the frame and a base with thrust bearings, in which the frame contains arched arches connected by screeds and fixed with their lower ends to the thrust bearings of the base, and the tent covering along the perimeter is fixed to the arched arches or partially covers them from above and contains along the perimeter an edging belt integrated in the awning, connected at the corners of the awning roof with the lower ends of the arched arches or thrusts of the base, and at least one arched arch made in it on the composite, the lower ends of the arched arches are rigidly fixed to the thrust bearings of the base, and the couplers connecting the arched arches into a single frame are made in the form of straight lines. Drawings - 9 FIG. The formula of the utility model: 1 n.p .; 20 s.p.

Description

The proposed technical solution relates to the field of ground-based construction, in particular, to building structures, and can be used for the erection of pre-mounted and quick-mounted frame tent covers in the form of areas and platforms, pavilions, hangars, tents, summer cafes that are sheltered from the sun and atmospheric precipitation.

A tent is known comprising a tent frame with racks, the racks are interconnected in the upper parts by the side beams and the rafters and in the lower parts by the lower side beams or the racks are interconnected only in the upper parts of the racks by the upper side beams and the rafters, in which the ends of the rafter beams can be inserted directly into the cavity of the upper ends of the uprights with the formation of an annular gap between the inner wall of the uprights and the outer side surface of the ends of the of reinforced beams, the ends of the side strand beams are flattened so that they can be inserted into the aforementioned annular gap with the possibility of free longitudinal and transverse movement along the above annular gap, and the symmetry axes of the cross section of the flattened ends for each of the side strand beams are rotated in the opposite direction at an angle β on one side of the plane passing through the longitudinal axis of the uprights, into which the ends of each of the beams of the side strapping are inserted (RF patent for utility model No. 32162, MKN (7) E04H 15/00, publ. 09/10/2003, bull. No. 25).

In this device, the awning tension on the frame is difficult. A prefabricated awning must exactly match the dimensions of the frame with a tolerance on the awning tension. For normal rainwater flow for a known design, rafters are needed that provide the necessary slope of the tent roof. At the same time, water during rain flows down the entire perimeter of the tent roof and drips from all sides of the pavilion or tent, which reduces the convenience of using the tent roof of the famous pavilion.

Also known is a pavilion containing a tent roof on top of the frame, in which the frame contains arches connected to each other inside the pavilion by arc removable screeds in the form of curved pipes or curved arched trusses, and the arc screeds are fixed to the sides of the arches or to the ends of the lintels, and the tent by the perimeter is fixed to the arches or partially covers them from above and contains along the perimeter an edge belt or edging integrated in the tent, connected at the corners of the tent roof through the tension elements to the lower ends of the arches or Pyatnikov arches (RF patent №2280138,

IPC (7) Е04Н 15/00, publ. 07/20/2006, bull. No. 20). This technical solution is the closest in technical essence to the proposed technical solution and it is taken as a prototype. Compared with the previous one, in this technical solution the rainwater drain from the tent roof (as in the text of the description of the invention) is improved, the performance of the pavilion and the resistance to wind loads are increased.

A small remark - in the description of the invention provides a detailed description of the specific node mounting the thrust bearing to the tubular arches of the frame (Fig.9), and in the claims this important node is missing.

However, this technical solution has some disadvantages. Firstly, this applies to the use of arched arches, depending on the specific circumstances, sometimes quite significant sizes. The design of the arch (pos. 2) in detail is not disclosed in the description of the invention, however, it can be clearly seen from the graphic materials (Fig. 2, Fig. 7 (photo)) that they (arches) are of a triangular section, with internal connections. It is quite obvious that such arches, especially of a large size (and, accordingly, weight), are difficult to manufacture, they are difficult to transport, install (mount at the place of assembly and installation of the finished pavilion) in comparison with smaller arches. Secondly, in this technical solution, ties are used (pos. 5), which are defined in one place of the description as "... curved inner ties ...", in the other - "... in the form of removable arcs ..." , a rather complex structure, which, like arched arches, is also difficult to manufacture. In addition, from the point of view of the structural strength of the pavilion frame, if we consider them (ties) as a connection, it is known that this type of connection, namely in the form of an arc, does not work best for compression-tension. When applying compression-tension loads to the ends of the arc-shaped screed, it (the screed in the form of an arc) will work better as an elastic, deformable unit under the applied load. In case of increased, compared with normal operating conditions, the load on the tent roof of the pavilion (dust, dirt, liquid and / or solid precipitation followed by icing, wind pressure, etc.), it (load) is transferred to the underlying tent roof pavilion arched arches, which in this case will work mainly on compression, and connecting arches screeds, respectively, mainly on tension. It is known that when certain structural elements of the pavilion frame perform the function of elastic (i.e., deformable under variable load) elements, the rigidity of the entire structure as a whole (in our case, the pavilion frame) decreases due to the use of such elastic elements. Thirdly, the description of the invention states: "The lintels of the arches 2 and screeds 5 of the sides of the arches 2 form a power circuit inside the pavilion with the axes of the pipes of the lintels 4 and screeds 5 that lie in the same plane." In the claims

it is mentioned that "... the arc ties are fixed to the sides of the arches or to the ends of the lintels ...", although this point is not disclosed in the description of the invention, and you have to think about how (from a structural rather than functional point of view) ) put into practice this node of the pavilion frame construction, taking into account the arched shape of both arches and screeds. Fourth, a lot of questions are raised by the chosen option of fixing the arches of the frame to the base (foundation) of the pavilion. On the one hand, the use of the attachment point of the arches to the base in the form of two coaxial pipes installed one into the other accelerates the installation of the frame (the time it takes to install the frame on the base), but, on the other hand, this type of installation (frame on the base) does not have the required rigidity the design of the pavilion as a whole, especially with changing loads on the tent roof, which can lead to undesirable consequences during the operation of the pavilion. This is because when installing one pipe in another, inevitable backlash between them (gaps between the mating surfaces) is assumed, otherwise (in the absence of gaps) it is impossible to insert one pipe into another. The inner diameter of the outer pipe installed on the base of the pavilion should be larger than the outer diameter of the inner pipe, which is the end of the arcuate arch. With a constant load on the tent roof of the pavilion and, accordingly, on the arches of the frame and further on to the base of the pavilion, all the elements of the mount (see Fig. 9) are in a static state and do not move relative to each other. However, it is obvious that in the case when the load on the tent roof of the pavilion changes, depending on the wind pressure, precipitating dust, dirt, liquid and / or solid atmospheric precipitation, which, moreover, can ice up, the load transferred to the arched arches, and further, on the base of the pavilion, it will also change, and within a fairly wide range. That is, the load from the tent roof of the pavilion is transferred to the frame supporting the tent roof, consisting of arched arches, which, in turn, transfers the total load (the weight of the tent roof, the weight of precipitation, dust, dirt and the weight of the pavilion frame itself (arches, lintels, screeds , doors, windows, false ceiling plus wind pressure, etc.)) to the base of the pavilion through the above-mentioned attachment points of the arches to the base. The presence of backlashes in the described embodiment of the attachment to the base (one pipe is inserted into the other) leads to inevitable fluctuations of the roof and arches of the pavilion frame relative to its base, which leads, in addition to the inevitable creak and rattle, which, although unpleasant for the hearing, can be experienced, mechanical loosening of the mount and, as a consequence, to a deterioration in its mechanical strength. For clarity, you can draw an analogy with prefabricated stalls in markets that use a similar method of joining frame components

tents, i.e. smaller diameter tubes are inserted into larger diameter tubes. The inevitable consequences of this type of connection are the gradual weakening of the mounting location due to an increase in backlash at the pipe joints, an increase in the amplitude of oscillations of the components of the mounting unit relative to each other, and, as a result, the swing of the pavilion frame under the influence of external disturbing factors (wind pressure, atmospheric precipitation, etc.). A properly designed device should not have such squishy joints. On the whole, indeed, the use of this method of installing and attaching the ends of the pipe arches in coaxial holes in the cups-thrusters, from which the locking buttons protrude, accelerate the installation time of the pavilion frame on its base, however, this “cheap” time saving entails “ruble »Losses during the operation of the pavilion.

The basis for the creation of the proposed technical solution is the task of creating a pavilion design that is free from the above disadvantages of the prototype using components, namely arc-shaped arches of smaller (compared to the prototype) dimensions, with increased rigidity of the frame and increased strength of fastening of the arc-shaped arches of the pavilion frame to its foundation, i.e. improving performance.

The goals are achieved due to the fact that in the pavilion containing an awning covering over the frame and a base with thrusts, in which the frame contains arched arches connected by screeds and fixed with their lower ends to the thrust bearings of the base, and the awning covering around the perimeter is fixed to the arched arches or partially covers them from above and contains along the perimeter an edge strap integrated in the tent, connected at the corners of the tent roof with the lower ends of the arched arches or the base bearings of the base, at least one arcuate arch made integral, the lower ends of arcuate arches rigidly secured to the thrust bearing base and ties connecting the arcuate arches in a single frame, are designed as straight line segments. In addition, the frame contains at least two arched arches; all arched arches forming the frame are located in vertical planes; at least one arcuate arch is located in a plane other than vertical; each composite arcuate arch consists of at least two parts, for example, two semi-arches, rigidly fastened together, in particular, by means of a bolted connection; each part of the arc-forming arch is made of a triangular section, with pipes to the vertices of the triangle and struts as sides of the triangle; each part of the arcuate arch is made of triangular section, with pipes at the vertices of the triangle, with stiffeners, for example, in the form of plates forming inside the outer contour of the arcuate arches in the form of a triangle formed by pipes and

spacers, the inner triangle, and the vertices of the inner triangle formed by stiffeners lie on the midpoints of the sides of the outer triangle formed by the spacers; each arcuate arch, including the composite as a whole, or its individual sections are described by an equation of at least second degree, for example, a conical section, in particular a circle, ellipse, hyperbola or parabola; all arched arches forming the frame of the pavilion have the same dimensions, in particular, the height above the base of the pavilion; the arched arches forming the frame of the pavilion have different sizes, in particular, the heights above the base of the pavilion; the base bearings for all arched arches forming the pavilion frame are located at the same distance above the pavilion base, in one horizontal plane; the base bearings for the arched arches forming the pavilion frame are located at different distances above the pavilion base, in different horizontal planes; screeds connecting arched arches into a single frame are located at the same height above the base of the pavilion, in one horizontal plane; screeds connecting the arched arches into a single frame are located at different heights above the base of the pavilion, in several horizontal planes; part of the couplers connects adjacent arched arches into a single frame; part of the couplers connects to the adjacent arched arches into a single frame; the thrust bearings of the base are made with brackets for rigid fixing on them, for example, using bolted joints, the lower ends of the arched arches; the tent roof is attached to the arcuate arches or thrusts of the base through tensioning elements, for example, turnbuckles; the tent roof is attached to the arcuate arches or thrusts of the base at all points (for) fastening at the same distance above the level of the base of the pavilion, in one horizontal plane; the awning roof is attached to the arched arches or thrusts of the base at various heights above the level of the base of the pavilion, in various horizontal planes; the tent roof is pressed from above to the pavilion frame with tension cables attached to the pivot bearings of the pavilion base.

The claimed technical solution is illustrated by drawings, which depict:

figure 1 - General view of the pavilion with awning;

figure 2, 3 - frame pavilion with 4 arches;

figure 4 - frame pavilion with 2 arches;

figure 5 - frame pavilion with arches of different sizes;

figure 6 - node connecting two sections of arches;

Fig.7 is a cross section of the arch;

on Fig - thrust base with brackets for (for) fastening the lower ends of the arches and tension cables of the tent covering;

Fig.9 - the site of attachment of the awning cover to the pads of the pavilion base.

The list of symbols in the drawings:

1 - arcuate arch; 2 - tent covering; 3 - screed; 4 - a tension cable; 5 - base thrust; 6 - awning stretch; 7 - a flange; 8 - pipe; 9 - brace of an arched arch; 10 - plate (stiffener); 11 - overlay; 12 - stiffener end of the arcuate arch; 13 - bracket (for) securing the end of the arcuate arch; 14 - bolted connection; 15 - bracket (for) mounting the tension cable of the tent covering; 16 - lower end of the arcuate arch; 17 - anchor bracket; 18 - lanyard; 19 - threaded rod; 20 - double plate; 21 - tent tension cable; 22 - an edge belt; 23 - connecting plate.

The pavilion consists of a frame formed by arched arches (1), over which a tent covering (2) is stretched. The number of arched arches (1) can vary within wide limits, starting from two, depending on customer requirements, climatic conditions, the purpose of the pavilion, etc. Arcuate arches (1) are connected into a single frame using screeds (3) located, as a rule, horizontally. Couplers (3) can be located both in one horizontal plane (Fig. 1, 2), and in several horizontal planes (Fig. 5). Ties (3) can connect both adjacent arcuate arches (1) (see FIGS. 1, 2, 5), as well as adjacent ones (see FIG. 5). In some cases, with large sizes of tent cover (2), expected precipitation of high intensity and / or strong wind pressure, tension cables (4) are pulled over the tent cover (2). Arcuate arches (1) and awning cover tension cables (2) are fixed on the thrust bearings (5) of the base, fixed on the foundation of the pavilion. In some cases, depending on the specific operating conditions, the proper arched arches (1) are connected by tent extensions (6), on which the tent covering (2) is applied from above. Part of the arched arches (1), especially if they are of considerable size, can be made compound, containing several sections that are separately manufactured and transported to the site of the pavilion construction, which are connected into a single structure and installed as part of the pavilion frame. One of the possible options for connecting the components into a single structure of an arched arch (1) is presented in figure 3. Each section of the arcuate arch (1) at the junction of the sections ends with a flange (7) with an opening for fastening bolts (not shown in Fig. 3). At the assembly site, using bolted connections, the flanges (7) of adjacent sections of the arched arches (1) are connected into a single whole. Each arcuate arch (1), or its component in the implemented version of the claimed technical solution is a section in the form of a triangle, in

the tops of which are pipes (8), preferably of circular cross section, interconnected by braces (9) made, for example, of a bar. Inside this outer triangle there is an inner triangle made of plates (10) that act as stiffeners, with the vertices of the inner triangle lying on the midpoints of the sides of the outer triangle (see Fig. 4). If this section of the arcuate arch (1) is connected to another arcuate arch (1), an overlay (11) is installed at the junction, for example, by welding, to which it is attached by known methods, for example, also by welding, a horizontal screed (3) connected at the other end to another arcuate arch (1) (adjacent or adjacent). Arcuate arches (1) in the implemented embodiment are made as follows. Pipes (8), forming the outer contour of the arcuate arches (1) in the form of a triangle, at the installation sites are reinforced with stiffeners (12) and end with lower ends (16), which are bolted to the brackets (13) attached , for example, bases welded to the thrust bearings (5) installed on the foundation (not shown) of the pavilion. Attachment points of the tent cover (2) are attached to the thrust bearings (5) of the base (see Fig. 7). Awning cover (2) along the perimeter of the web is equipped with an edge strap (22) and along the edges with double plates (20), which are connected through threaded brackets (17) to threaded rods (19), which through lanyards (18) and anchor brackets (17 ), are connected to the connecting plate (23), which, in turn, through the anchor bracket (17), the lanyard (18), the tension cable (21) and the anchor bracket (17) are connected to the thrust bearings (5) of the base. With the help of lanyards (18), the tent cover (2) is smoothly tensioned after it is thrown onto the pavilion frame.

The frame assembled at the installation site of the pavilion consists of the required number of arched arches (1) of the desired configuration and size, depending on the customer's requirements (see figures 1, 2, 3, 4, 5). The awning panel (2) is poured over the frame along the arcuate arches (1) so that the edges of the tent cover (2) through the tension nodes (see Fig. 9) hang from the outside of the arcuate arches (1). Then, with the help of tension elements in the form of lanyards (18), the tent cover (2) is finally pulled, after which the pavilion is ready for operation. In the tent covering (2), the necessary slopes and gutters are automatically formed in all directions from the tops of the arched arches (1) to the center of the pavilion and further to the places of fastening of the tent covering (2) to the thrust bearings (5) of the base, where special measures can be taken to protect the actual glides (5) of the base from the effects of precipitation flowing down onto the tent cover (2). If necessary, walls, doors, windows, etc .; are mounted (installed) in the frame of the pavilion; depending on the purpose of the pavilion.

The proposed technical solution allows you to create a wide range of pavilions for various purposes for various climatic conditions, using the above-described relationship of its constituent parts. Using the proposed technical solution simplifies the process of manufacturing and transportation of arched arches that form the frame of the pavilion. The use of screeds connecting arcuate arches into a single frame in the form of rectangular segments increases the rigidity of the frame structure and, accordingly, the pavilion as a whole. Rigid fastening of the arched arches to the base of the pavilion ensures the structural strength of the assembled pavilion and eliminates the inevitable increase in the gaps in the attachment points characteristic of the prototype structure. On the whole, the reliability and durability of the pavilion design, i.e. its operational characteristics are increased.

The described implementation option of the proposed solution, made in accordance with the present description, provides the possibility of its implementation and the achievement of the above technical results. It goes without saying that they do not exhaust all the possibilities of implementing the proposed technical solution, characterized by a combination of features given in the utility model formula, both in independent and dependent clauses.

A comparative analysis of the proposed technical solution with known (from patent, scientific, technical, advertising and other sources of information) allows us to conclude that objects of technology with such a combination of the claimed features are not known from the prior art. The novelty of the proposed technical solution lies in the specific design of the pavilion as a whole and its components, which relates to the forms of execution of the components, in particular, their geometric shapes, sizes, relationships. The determination from the list of identified analogues of the prototype as the closest analogue in terms of the totality of features made it possible to establish the set of distinguishing features that are essential to the applicant's technical result, as set forth in the utility model formula. Based on the foregoing, we can conclude that the proposed technical solution meets the requirements of the condition (criterion) of patentability “novelty”.

The claimed technical solution relates to the field of ground construction and can be used in the development and production of pavilions with awning covering a wide range and purpose. The results of calculations, simulations, laboratory and field tests showed the high efficiency of this technical solution, which consists in the fact that kits for assembling and installing pavilions (frames with

tent coating), which eliminates their fitting during installation, dramatically increases the speed of installation of the frame of the arched arches with an increase in their overall dimensions. The proposed design provides a wide variety of options for the design and construction of pavilions with awning. Based on the foregoing, we can conclude that the proposed technical solution meets the requirement of the condition (criterion) of patentability "industrial applicability".

Claims (21)

1. A pavilion containing an awning cover (2) on top of the frame and a base with thrust bearings (5), in which the frame contains arched arches (1) interconnected by ties (3) and fixed with their lower ends (16) to the thrust bearings (5) bases, and the awning cover (2) around the perimeter is fixed to the arched arches (1) or partially covers them from above and contains along the perimeter an edge belt (22) integrated in the tent, connected at the corners of the tent roof with the lower ends (6) of the arched arches (1 ) or thrust bearings (5) of the base, characterized in that in m at least one arch-shaped arch (1) is made composite, the lower ends (16) of the arched arches (1) are rigidly fixed to the thrust bearings (5) of the base, and the ties (3) connecting the arched arches (1) into a single frame are made in the form line segments. 2. The pavilion according to claim 1, characterized in that in it the frame contains at least two arched arches (1). 3. The pavilion according to claim 1, characterized in that in it all the arched arches (1) forming the frame are located in vertical planes. 4. The pavilion according to claim 1, characterized in that in it at least one arcuate arch is located in a plane other than vertical. 5. The pavilion according to claim 1, characterized in that in it each composite arcuate arch (1) consists of at least two parts, for example two semi-arches, rigidly fastened to each other, in particular by means of a bolted connection. 6. The pavilion according to claim 1, characterized in that in it each part of the arc-forming arch (1) is made of a triangular section with pipes (8) at the vertices of the triangle and struts (9) as sides of the triangle. 7. The pavilion according to claim 1, characterized in that in it each part of the arcuate arch (1) is made of a triangular section with pipes (8) at the vertices of the triangle, with stiffeners (10), for example, in the form of plates forming inside the external contour arcuate arches (1) in the form of a triangle formed by pipes (8) and struts (9), the inner triangle, and the vertices of the inner triangle formed by stiffeners (10) lie on the midpoints of the sides of the outer triangle formed by struts (9). 8. The pavilion according to claim 1, characterized in that in it each arcuate arch (1), including the composite as a whole, or its individual sections are described by an equation of at least second degree, for example, a conical section, in particular a circle, an ellipse, hyperbola or parabola. 9. The pavilion according to claim 1, characterized in that in it all the arched arches (1) forming the pavilion frame have the same dimensions, in particular the height above the base of the pavilion. 10. The pavilion according to claim 1, characterized in that it has arched arches (1) forming the frame of the pavilion, have different sizes, in particular the height above the base of the pavilion. 11. The pavilion according to claim 1, characterized in that in it the thrust bearings (5) of the base for all arcuate arches (1) forming the pavilion frame are located at the same distance above the pavilion base in one horizontal plane. 12. The pavilion according to claim 1, characterized in that therein, the thrust bearings (5) of the base for the arched arches (1) forming the pavilion frame, are located at different distances above the pavilion base in different horizontal planes. 13. The pavilion according to claim 1, characterized in that there are couplers (3) connecting arched arches (1) into a single frame, located at the same height above the base of the pavilion in one horizontal plane. 14. The pavilion according to claim 1, characterized in that there are couplers (3) connecting arched arches (1) into a single frame, located at different heights above the base of the pavilion in several horizontal planes. 15. The pavilion according to claim 1, characterized in that in it part of the couplers (3) connects the adjacent arched arches (1) into a single frame. 16. The pavilion according to claim 1, characterized in that in it part of the couplers (3) connects the adjacent arched arches (1) into a single frame. 17. The pavilion according to claim 1, characterized in that in it the thrust bearings (5) of the base are made with brackets (13) for rigidly fastening to them, for example, using bolted connections (14) of the lower ends (16) of the arched arches (1) . 18. The pavilion according to claim 1, characterized in that in it the tent roof (2) is attached to the arcuate arches (1) or the thrust bearings (5) of the base through tensioning elements, for example, turnbuckles (18). 19. The pavilion according to claim 1, characterized in that in it the tent roof (2) is attached to the arched arches (1) or the thrust bearings (5) of the base at all points (for) fastening at the same distance above the level of the base of the pavilion in one horizontal plane . 20. The pavilion according to claim 1, characterized in that in it the tent roof (2) is attached to the arched arches (1) or the foot (5) of the base at various heights above the base level of the pavilion in various horizontal planes. 21. The pavilion according to claim 1, characterized in that the tent roof (2) in it is pressed from above to the pavilion frame with tension cables (21) attached to the pivot bearings (5) of the pavilion base.