RU2183712C2 - Frames and built-up frameworks - Google Patents

Abstract

FIELD: civil engineering. SUBSTANCE: the frame has a supporting strut, the first connecting supporting member fastened in the middle point of the supporting strut, the second connecting supporting member or members fastened in the upper or lower point or in both of them of the supporting strut, one or several transverse members connected to the lateral part of the supporting strut rigidly, detachably or for turning, and a coupler fastened on the remote end of transverse member, whose vertical position corresponds to the vertical position of the first or second connecting supporting member. EFFECT: enhanced field of application, excellent mounting characteristics, simplified assembly and disassembly. 6 cl, 32 dwg

Description

 The invention relates to structures similar to prefabricated scaffolding, supports and supporting trusses, as well as to the frames from which such structures are mounted.

 When performing construction or installation works, prefabricated scaffolding for accommodating workers is usually installed on the outside of the structure.

 Similarly, when performing installation work, building construction or building bridges, supports or support trusses are used to create support for heavy loads, for example, for interfloor ceilings and bridge trusses.

 Prefabricated scaffolds, supports and supporting trusses have frames in the frame in which the supporting posts are longitudinal and transverse. For example, the well-known frame product PAL SUPPORT is used exclusively for the construction of supports. The PAL SUPPORT product is a frame, when viewed from the front, having the shape of a triangle and containing a support post, a V-shaped transverse element connected transversely to the support post, and a connecting element fixed to the distal end of the transverse element and having an opening.

 Since the frames for the above-mentioned supports, prefabricated scaffolds and support trusses are designed to fulfill certain specific goals, they cannot be used in any structures, that is, they are not universal and therefore not economical.

 In addition, in most cases, known frames are not finished products, since other components of various designs are used for their assembly, which entails an increase in the total number of components. In addition, the assembly of the individual components is very laborious. In such circumstances, there is a need to create a frame that even unskilled workers could assemble and that would be distinguished by improved performance and cost-effectiveness.

 The aforementioned PAL SUPPORT product has the advantage of being able to perform assembly in both longitudinal and transverse directions with equal success. However, if after coupling the connecting element of one support post to another support post, it becomes necessary to remove or replace a part during operation or after completion of assembly, then the vertical support posts must also be removed, which is associated with the implementation of time-consuming and dangerous work.

 Therefore, the aim of the present invention is to provide a frame characterized by versatility, improved mounting characteristics, ease of assembly, disassembly and transportation, and the absence of special storage requirements, as well as creating a structure similar to prefabricated scaffolding, supports or support trusses in which the said frame is used, without compromising its design characteristics, and which is both more economical and safe.

 To accomplish the aforementioned goal in accordance with the present invention, the frame includes a support post, a first connecting support member attached at a mid or substantially midpoint of a support post, a second connecting support member attached at an upper or lower point of the support post or simultaneously at the top and the lower points of the support post, one or more transverse elements, each of which is connected transversely to the support post detachably or rotatably, and a connector mounted on tdalennom end cross member, and whose vertical position corresponds to the vertical position of the first or second connector support member.

 Further, in order to achieve the stated goal, the prefabricated scaffolding according to the present invention is constructed from a plurality of named frames assembled in the longitudinal and transverse directions.

 Similarly, a support according to the present invention consists of a plurality of said frames assembled in the longitudinal and transverse directions.

 Similarly, the support truss of the present invention consists of a plurality of said frames assembled in the longitudinal and transverse directions.

The invention will now be explained using the drawings, in which:
FIG. 1 is a front view of a frame according to an embodiment of the present invention;
FIG. 2 is a front view of a frame according to another embodiment of the present invention;
FIG. 3 is a front view of a frame according to another embodiment of the present invention;
FIG. 4 is a front view of a frame according to another embodiment of the present invention;
FIG. 5 is a front view of a frame according to another embodiment of the present invention;
FIG. 6 is a front view of a frame in accordance with yet another embodiment of the present invention;
FIG. 7 is a front view of a frame according to another embodiment of the present invention;
FIG. 8 is a front view of a frame according to another embodiment of the present invention;
FIG. 9 is a front view of a frame according to another embodiment of the present invention;
10 is a front view of a frame according to another embodiment of the present invention;
11 is a front view of a frame corresponding to another embodiment of the present invention;
12 is a front view of a frame according to another embodiment of the present invention;
13 is a front view of a frame according to another embodiment of the present invention;
Fig. 14 is a front view of a frame according to another embodiment of the present invention;
15 is a front view of a frame according to another embodiment of the present invention;
FIG. 16 is a front view of a frame in accordance with yet another embodiment of the present invention; FIG.
17 is a front view of a frame in accordance with yet another embodiment of the present invention;
Fig. 18 is a front view of a frame according to another embodiment of the present invention;
Fig. 19 is a front view of a frame according to another embodiment of the present invention;
FIG. 20 is a front view of a frame in accordance with yet another embodiment of the present invention; FIG.
21 is a front view of a frame according to another embodiment of the present invention;
FIG. 22 is a front view of a frame in accordance with yet another embodiment of the present invention; FIG.
23 is a front view of a frame according to another embodiment of the present invention;
24 is a front view of a frame according to another embodiment of the present invention;
25 is a front view of a frame according to another embodiment of the present invention;
FIG. 26 is a front view of a frame in accordance with yet another embodiment of the present invention; FIG.
FIG. 27 is a front view of a frame according to another embodiment of the present invention; FIG.
FIG. 28 is a front view of a frame in accordance with yet another embodiment of the present invention; FIG.
FIG. 29 is a front view of a frame according to another embodiment of the present invention; FIG.
FIG. 30 is a front view of a frame according to another embodiment of the present invention; FIG.
FIG. 31 is a front view of a frame according to another embodiment of the present invention; FIG.
32 is a front view of a frame according to another embodiment of the present invention;
Fig. 33 is a front view of a frame according to another embodiment of the present invention;
Fig. 34 is a front view of a frame according to another embodiment of the present invention;
Fig. 35 is a front view of a frame in accordance with yet another embodiment of the present invention;
Fig. 36 is a front view of a frame according to another embodiment of the present invention;
FIG. 37 is a front view of a frame in accordance with yet another embodiment of the present invention;
FIG. 38 is a front view of a frame according to another embodiment of the present invention;
FIG. 39 is a perspective view of a frame in accordance with yet another embodiment of the present invention;
FIG. 40 is a perspective view of a frame in accordance with yet another embodiment of the present invention;
FIG. 41 is a perspective view of a frame in accordance with yet another embodiment of the present invention;
FIG. 42 is a front view of the support legs for a frame in accordance with yet another embodiment of the present invention;
FIG. 43 (A) and (B) are front views of the support legs for a frame in accordance with yet another embodiment of the present invention;
FIG. 45 is a front view of the support struts for the frame corresponding to another embodiment;
FIG. 46 is a front view of the support struts for a frame in accordance with yet another embodiment;
FIG. 47 is a perspective view of an exploded frame in accordance with yet another embodiment of the present invention;
FIG. 48 is a perspective view of an exploded frame in accordance with yet another embodiment of the present invention;
Fig. 49 is a front view of a frame according to another embodiment;
Fig. 50 is a front view of a frame according to another embodiment;
Fig. 51 is a perspective view of the frame support posts according to another embodiment of the present invention;
Fig. 52 is a perspective view of a frame in accordance with yet another embodiment of the present invention;
FIG. 53 is an enlarged front view of the upper end part of the support rack;
FIG. 54 (A) and (B), respectively, a top view and a front view of a vertical section of the girth serving as a connecting support element;
FIG. 55 (A) and (B), respectively, a top view and a front view of a vertical section of a girth of another embodiment;
FIG. 56 (A) and (B), respectively, a top view and a front view of a vertical section of the girth of another embodiment;
Fig. 57 is a perspective view of the girth of yet another embodiment;
FIG. 58 is an enlarged front view of the girth after it is mounted on a support stand;
Fig. 59 is an enlarged plan view of a collar serving as a connector;
FIG. 60 is a partial enlarged perspective view of a prefabricated scaffold mounted from frames in accordance with another embodiment of the present invention;
FIG. 61 is a perspective view of disassembled prefabricated scaffolding shown in Fig. 60;
FIG. 62 is a perspective diagram illustrating the arrangement of frames in prefabricated scaffolds mounted from frames in accordance with yet another embodiment of the present invention;
Fig. 63 (A), (B) and (C) respectively are a top view, a front view and a side view of precast scaffolding mounted from frames in accordance with another embodiment of the present invention;
FIG. 64 is a perspective view of a prefabricated scaffold mounted from frames in accordance with another embodiment of the present invention;
FIG. 65 is a perspective view of a prefabricated scaffold mounted from frames in accordance with another embodiment of the present invention;
FIG. 66 is a front view of a support mounted from frames in accordance with another embodiment of the present invention;
Fig. 67 (A) and (B) are respectively a front view and a side view of a support mounted in accordance with yet another embodiment of the present invention;
FIG. 68 (A) and (B) respectively are a front view and a side view of a support according to another embodiment of the present invention;
Fig. 69 (A) and (B) is a perspective view of prefabricated scaffolding mounted from frames in accordance with another embodiment of the present invention;
FIG. 70 (A) and (B) respectively are a front view and a side view of a support truss mounted from frames in accordance with another embodiment of the present invention;
FIG. 71 (A) and (B) respectively are a front view and a side view of a support truss in accordance with yet another embodiment of the present invention;
FIG. 72 is a front view of a support truss in accordance with yet another embodiment of the present invention;
FIG. 73 is a partial enlarged perspective view of the supporting truss depicted in Fig.70;
Fig. 74 (A) and (B) are perspective views of balustrades, each of which is attached to the end part of prefabricated scaffolding;
FIG. 75 (A) and (B) are front views of reinforcing support posts, each of which is mounted vertically in the end part of the prefabricated scaffolding;
FIG. 76 is a perspective view of yet another embodiment of a connector used in the practice of the present invention;
FIG. 77 is a perspective view of an embodiment of a horizontal element serving as a transverse element in the practice of the present invention;
Fig. 78 is a perspective view of another embodiment of a horizontal element;
FIG. 79 is a perspective view of an embodiment of a reinforcing frame included between frames;
Fig. 80 is a perspective view of another embodiment of an amplification frame;
Fig - perspective view of another variant of the reinforcing frame;
Fig - perspective view of another variant of the reinforcing frame;
Fig - front view of another variant of the reinforcing frame.

 Embodiments of the present invention are described below with reference to the attached drawings.

 In FIG. 1 to 58 show frames and reinforcing support legs implementing the present invention.

 On Fig-65 shows prefabricated scaffolding mounted from any of these frames in accordance with the variants of implementation of the present invention.

 In FIG. 66 to 69 show supports mounted from any of the named frames in accordance with embodiments of the present invention.

 In FIG. 70 to 73 show support trusses mounted from any of the named frames in accordance with embodiments of the present invention.

 On Fig-82 shows the support racks, balustrades and reinforcing frames used in the installation of prefabricated scaffolding, supports and support trusses.

 To facilitate understanding of the use of frames corresponding to the present invention, a description of the prefabricated scaffolding shown in Figs. 60 to 62 is first provided.

 The prefabricated scaffolds shown in FIGS. 60, 61 and 62 and indicated by common position A, use the frame shown in FIG. 41. This frame contains two support posts 1, 1 and a horizontal element 4 or 4b attached detachably or pivotally to one support post 1.

 Below is a more detailed description.

 As shown in Figs. 60 and 61, in prefabricated scaffolds A, a plurality of frames 3 are mounted vertically in the transverse direction in two rows, front and rear, each of the frames 3 comprising two parallel vertical support legs 1, 1, a balustrade 2 ', fixed laterally on the support posts 1, 1, and a horizontal element 4 as a transverse element attached to one support post. Opposite - front and rear - support pillars 1, 1 are detachably connected using a horizontal element 4, as a transverse element attached to one support pillar 1, and adjacent in the transverse direction of the support pillars are connected using two horizontal balustrades 2a, serving as transverse elements and attached detachable to the right support post 1, as shown in Fig. 60. Further, one or several boards 5 of the scaffold flooring are laid end-to-end in the transverse direction between the front and rear frames 3, 3, and both end parts of each floor board are detachably linked through their coupling sections 6 with horizontal elements 4 corresponding to the named end parts. On the outer surface of each support post 1 there are fixed girths 7 with holes serving as the first and second connecting support elements at the upper, middle and lower points.

 The balustrade 2 'consists of two horizontal elements, which are the upper horizontal element attached detachably to the upper girths 7, 7, and the lower horizontal element attached detachably to the adjacent support posts 1, 1; however, a case is allowed where the balustrade 2 ′ may consist of one upper or lower horizontal element.

 Similarly, the horizontal elements 4 attached to the front and rear support legs 1, 1 are detachably connected at their ends with the upper, middle and lower girths 7; however, it is allowed to use one horizontal element or two - upper and lower - horizontal elements, as illustrated in the drawings.

 Although the balustrades 2a are connected to the supporting posts 1, 1 by means of the girths 7 serving as the connecting supporting elements, other connecting supporting elements, such as, for example, fingers, are allowed.

 The floorboards 5 are stacked with splicing in the transverse direction and tight fit in the front to back direction; however, the board may be unique in the front to back direction if its width is sufficient in that direction.

 At both ends of each floorboard, coupling sections 6 of a C- or L-shaped profile are made. Using the coupling sections 6, the floorboards 5 are detachably connected to the middle or lower horizontal elements 4. For the floorboards 5, 5 adjacent in the transverse direction, the right coupling section 6 of the left laying board 6 and the left coupling section 6 of the right laying board 5 are arranged connection to the tongue.

 Frames 3, 3, adjacent in the transverse direction, are connected using a balustrade 2a, which is detachably attached to the upper girths 7, 7. The balustrade 2a consists of two - upper and lower - horizontal elements, right and left vertical support rods attached to the end sections of two horizontal elements, and fork metal parts 12, serving as connectors and fixed at both ends of each horizontal element. Two horizontal elements can be replaced with one horizontal element. Next, one or more skirting boards 8 are stacked vertically and spliced in the transverse direction from both the front and back sides of the floorboards 5. The end parts of each skirting board 8 are detachably connected through the openings of the girths 7 using fingers.

 On each of the two - left and right - ends of the prefabricated scaffolds, skirting boards 9 are stacked vertically in the front to back direction and are attached as described above.

 The following describes a method for installing prefabricated scaffolding A outside of structure B, such as, for example, a building. A large number of frames 3 are mounted vertically in the transverse direction in two rows, front and rear. In this case, the frames 3, adjacent in the transverse direction, are connected to each other by means of a balustrade 2a, which is detachably attached to one support column 1, and the frames 3, 3, opposite in the front to back direction, are connected to each other by horizontal elements 4, attached to one support column 1. Thus, scaffolds in the form of a rectangular parallelepiped are mounted in which floorboards 5 are then laid at an average level to create a flooring.

 There is a choice between the location of the front and rear frames 3, 3 in symmetrical or staggered positions. In the latter case, the rear row of balustrades 2a is opposite to the front frame 3, and the horizontal element is connected to the right support post 1 of the front frame 3 and the left support post of the rear frame 3.

 Support racks can be installed directly on the ground. In another case, the support posts can be installed on the stands and support posts 1 included in each frame 3, can be detachably inserted into the corresponding upper ends of the support rods.

 Support racks can be installed one after the other, however, you can first install on the soil on the supports a lot of support racks 3, pairwise fastened with a horizontal bar. Further, the frame 3 can be expanded up in many tiers. In this case, as shown in FIG. 53, the upper support post 1 is inserted with the sleeve part 1a into the hole at the upper end of the lower support post 1.

 62 is a schematic representation of prefabricated scaffolds according to another embodiment of the present invention. These prefabricated scaffolds, indicated by A, are mounted from the frames shown in FIGS. 3 or 9. More specifically, the frame 3a consists of one support post 1 and a balustrade 2 serving as a transverse member, which is attached transversely to the support post 1. A plurality of such frames 3a installed vertically in the transverse direction in two - front and rear - rows. The front and rear support pillars 1, 1, opposite each other, are detachably connected using horizontal elements 4, as shown in Fig. 60, and the support pillars 1, 1, adjacent in the transverse direction, are connected using the balustrade 2 of the support pillar 1 and metal details 13 serving as a connector. Next, one or more floorboards 5 are stacked to perform splicing in the transverse direction between the front and rear frames 3, 3, and both end sections of each floorboard 5 are detachably coupled to respective horizontal elements 4.

 At the far left end of the prefabricated scaffolding A, a support stand 1A is installed, shown in Fig. 75 or depicted in Fig. 62, the same frame as frame 3 in Fig. 60 is mounted on the ground.

 If one frame 3a, consisting of a single post 1 and a balustrade 2 attached at the upper point of the support post 1, must be connected to another same frame 3a, the end sections of the balustrade 2 are attached detachably to the support post of the frame 3a adjacent to the first frame in the transverse direction. The balustrade 2 consists of one or two parallel horizontal elements, and one end of the balustrade 2 can be connected to the support column in various ways: using the girths 7, fingers, welding, or something similar. At the opposite end of the balustrade 2, a metal part 13 is fixed, which serves as a connector for connecting to the girth 7 on an adjacent support post 1.

 The remaining structural characteristics and the assembly method are similar to those described with reference to Fig. 60.

 Frames implementing the present invention are described below with reference to FIGS. 1-58.

 The frames depicted in figures 1 to 18 belong to one group and are similar in that one or more horizontal elements, which are transverse elements, are located horizontally relative to one support pillar. Each of the frames 3 under consideration has one support post 1, a girth 7, serving as a first connecting support element fixed at a midpoint of a support post 1, a girth 7, serving as a second connecting support element secured at an upper point of a support post 1, a horizontal element that is transverse element and connected to the middle or upper girth 7, and a metal part 13, which serves as a connector and located at the distal end of the horizontal element in accordance with the location of the attached girth 7.

 The frame 3 shown in Fig. 1 consists of a support post 1, girths 7, 7 located at the mid and lower points, respectively, of a support post 1, a horizontal element 2a, attached at its base end to the middle girth 7, and a metal part 13 located at the distal end of the horizontal element 2A, and the metal part 13 is made in the form of a bracket and a wedge. At the upper end of the support column 1 is made of the sleeve part 1A of a smaller diameter. When the support posts are stacked one on top of the other, the sleeve portion 1a of the lower support post 1 is inserted into the lower end of the upper support post 1. The sleeve portion 1a can be formed at the lower end of each support post 1.

 In the frame 3 shown in FIG. 2, the base end of the horizontal element 2, which is a transverse element and which can also serve as a balustrade, is attached to the girth 7, fixed at the upper point of the support post 1. The remaining structural characteristics are similar to those for the frame shown in FIG. .1.

 In the frame shown in Fig. 3, two - upper and lower - horizontal elements 2 are attached respectively to the upper girth 7 and the outer surface of the support post 1, the horizontal plinth 8 is attached to the middle girth 7, two horizontal elements 2, 2 and the plinth 8 are connected together at its distal ends with a vertical support rod, the metal part 13 is attached to the distal end of the upper horizontal element and the pin 8a is fixed to the distal end of the baseboard 8.

 In the frame shown in Fig. 4, the base end of the horizontal element L3, which is a transverse element, is attached to the middle girth 7, the metal part is fixed at the distal end of the horizontal element L3, two - the upper and lower - inclined elements 2b, 2b, which are transverse elements attached to the surfaces of the upper and lower parts of the support column 1 and the distal end of the horizontal element L3.

 In the frame of FIG. 5, a U-shaped transverse member consisting of a horizontal member 2 and an L-shaped member 2e is attached to a support post 1. More specifically, the base ends of the horizontal member 2 and the L-shaped member 2e are connected to the upper girth 7 and the outer surface of the support column 1, the metal part 13 is fixed at the distal end of the horizontal element 2.

 The frame of FIG. 6 is the frame of FIG. 3, which includes reinforcing inclined elements 22, 22 attached X-shaped.

 In the frame of FIG. 7, which is a modification of the frame of FIG. 2, the reinforcing inclined element 19 is attached to the middle girth 7 and the distal end of the horizontal element 2.

 In the frame of FIG. 8, which is a modification of the frame of FIG. 7, the horizontal reinforcing member H12 is attached to the support post 1 and the inclined member 2d.

 In the frame shown in Fig. 9, horizontal elements 2a, 2a, which are transverse elements and serve as balustrades, are attached with their base ends to the upper girth 7 and the average girth 7, respectively, and metal parts 13, 13 are mounted respectively at the distal ends of the horizontal elements 2a 2a.

 In the frame of FIG. 10, which is a modification of the frame of FIG. 9, the horizontal reinforcing element 2f reinforcing the horizontal elements 2a, 2a and the vertical supporting rod 2g are used as additional components.

 In the frame shown in Fig. 11 and indicated by 3A, two - upper and lower - girth 7, 7 and middle girth 7 are fixed on the support post 1, horizontal elements 2a, 2a1, which are transverse elements, are attached with their base ends respectively to the girths 7, the distal ends of the horizontal elements are connected using a vertical support rod, and metal parts 13, 13 corresponding to the girths 7 are fixed to the distant ends of the horizontal elements 2a, 2a1.

 In the frame of FIG. 12, which is a modification of the frame of FIG. 8, the base end of the horizontal member H6 is attached to the middle girth 7 and the diagonal member 2d is attached to the base end of the horizontal member H6 and the distal end of the upper horizontal member 2c.

 In the frame of FIG. 13, which is a modification of the frame of FIG. 12, the tilt member 2d and the vertical support rod 2g are attached to the upper and lower horizontal members 2c, H11, which are connected respectively to the upper and lower girths 7, 7 .

 In the frame shown in FIG. 14, which is a modification of the frame shown in FIG. 9, a cross-shaped reinforcing element H14 is attached as an additional component to the upper and lower horizontal elements 2c, 2c.

 In the frame shown in FIG. 15 and is a modification of the frame shown in FIG. 10, the reinforcing inclined element 2h is attached to the distal end of the lower horizontal element 2a and the lower end of the support column 1.

 In the frame shown in FIG. 16 and representing a modification of the frame shown in FIG. 15, the inclined element 2i is attached to the two horizontal elements 2a, 2a instead of the horizontal element 2f.

 The frame of FIG. 17 is a combination of the frames of FIG. 2 and 4. The horizontal elements 2a, L3 and the inclined elements 2b, 2b are connected as transverse elements to the support column 1.

 In the frame of FIG. 18, which is a modification of the frame of FIG. 14, three - the upper, middle and lower - horizontal elements 2c, H11, H12 are connected to the support column 1 and the cross-shaped reinforcing elements H4 are attached respectively to the horizontal elements 2c and H11 and to the horizontal elements H11 and H12.

 The frame shown in Fig. 19 contains three - upper, middle and lower - horizontal elements L4, L3, L5, a support rod 2g connecting the horizontal elements to each other, and inclined elements 2b.

 The frames depicted in Fig.20 - 23 belong to one group. Each of these frames contains a support column 1 and a V-shaped frame connected to it as a transverse element. The remaining design characteristics are similar to those for the frame shown in figure 1.

 The frame shown in Fig. 20 and indicated by 3B comprises a support post 1, girths 7, 7 located respectively at the upper and middle points of the support post 1, a V-shaped frame, which is a transverse element connected by the base ends to the outer surface of the support post 1 in its upper and lower parts, and a metal part 13, which serves as a connector and mounted on the remote end of the frame 2b to ensure compliance with the girth 7. Frame 3B, when viewed from the front, has the shape of an arbitrary triangle or isosceles flax.

 The frame shown in FIG. 21 is substantially similar to the frame shown in FIG. The V-shaped frame 2b allows adjustment of its length using expansion mechanisms 2b1, for which hinges O and P are provided at the base ends and the distal end, respectively, of the frame 2b.

 In the frame shown in FIG. 22, which is a modification of the frame shown in FIG. 20, the horizontal element 2a is connected to the support column 1 by means of the upper girth 7.

 In the frame shown in Fig. 23 and which is a modification of the frame shown in Fig. 20, a U-shaped transverse element consisting of a horizontal element 2a and a reinforcing frame 2a2 is connected to the upper girth 7 and the outer surface of the support leg 1.

 The frames depicted in Figs. 24 to 29 comprise one group and have in common that each necessarily contains a support post 1 and a V-shaped frame, which is a transverse element and connected to the support post 1, and the support post and the V-shaped frame form right triangle. Other structural characteristics are similar to those for the frame shown in figure 1.

 In the frame shown in Fig. 24 and indicated by 3C, two - upper and lower - V-shaped frames, each of which includes a horizontal element 2K and an inclined element 2L, are connected at their base ends with upper and lower girths 7, 7 and connected to the outer surface of the support column 1.

 The frame shown in FIG. 25 and indicated by 3C is the simplest frame in the form of a right triangle. More specifically, the frame under consideration consists of a support post 1, girths 7, 7 located respectively at the upper and middle points of the support post 1, a V-shaped horizontal element 2c connected at its base ends to the upper girth 7 and the outer surface of the lower part of the support post 1, and a metal part 13, which serves as a connector and mounted on the distal end of the horizontal element 2C to ensure compliance with the upper girth 7.

 In the frame of FIG. 26, which is a modification of the frame of FIG. 25, the horizontal reinforcing element H1 is attached to the middle girth and the inclined element 2c.

 In the frame of FIG. 27, which is a modification of the frame of FIG. 25, the U-shaped reinforcing element HU is connected to the middle girth 7, the outer surface of the upper part of the support column 1 and the inclined element 2C.

 In the frame shown in Fig. 28 and which is a modification of the frame shown in Fig. 25, the horizontal reinforcing element H8 is connected to the middle girth 7 and the inclined element 2c, and the metal part 13 is fixed at the distal end of the horizontal element H8.

 In the frame of FIG. 29, which is a modification of the frame of FIG. 28, the second horizontal element H9 is attached to the support column 1 and the inclined element 2c in parallel with the horizontal element H8.

 In the frame of FIG. 30, which is a modification of the frame of FIG. 25, the reinforcing frame H10 is attached to the distal end of the horizontal element 2c and the lower girth 7, the reinforcing frame H10 in front view having the shape of an inverted letter "L".

 The frames depicted in Figs. 31 to 38 and forming one group, have in common that any of these frames has the outline of a trapezoid or rectangle when viewed from the front.

 In FIG. 31 shows a frame 3A of a simple construction having a trapezoid outline when viewed from the front. Its basic design is similar to that of the frame shown in FIG. 1. The frame shown in Fig. 31 consists of a support post 1, girths 7 located at the mid and upper points of the support post 1, a frame 2A connected at its base ends to the upper girth 7 and the outer surface of the lower part of the support post 1, and metal parts 13, 13 mounted on the remote ends of the frame 2A in compliance with girths 7, 7. Frame 2A is made as a solid cast frame consisting of a horizontal element P, a vertical element Q and an inclined element R. The support column 1 and the frame 2A have trapezoid outline ide front.

 In the frame shown in Fig. 32 and which is a modification of the frame shown in Fig. 31, one horizontal reinforcing element 2A1 is attached to the support column 1 and the vertical element Q.

 Similarly, in the frame shown in FIG. 33 and being a modification of the frame shown in FIG. 31, two horizontal reinforcing elements 2A1, 2A2 are included as additional components.

 In the frame of FIG. 34, which is substantially similar to the frame of FIG. 33, the base end of the lower horizontal element 2A2 is connected to the middle girth 7.

 In the frame shown in Fig. 35 and which is a combination of the frame shown in Fig. 34, the reinforcing element 2A3 is fixed at the upper point of the support post 1 and the midpoint of the frame 2A.

 In the frame shown in Fig. 36, the base ends of the horizontal elements 2a, 2a are connected using a vertical support rod and the metal part is fixed at the midpoint of the vertical support rod to ensure compliance with the average girth 7.

 In the frames depicted in Figs. 37 and 38, a horizontal reinforcing element and one or two inclined elements are further included in the frame depicted in Fig. 36.

 The frames shown in Figs. 39 - 41 and belonging to one group have in common that the horizontal element serving as the transverse element is connected to the girth fixed at the midpoint of the support post 1, and this horizontal element has a direction different from the direction of the upper horizontal item. The remaining structural characteristics are similar to those for the frame shown in figure 1.

 The frame shown in Fig. 39 consists of a support post 1, girths 7, 7, fixed respectively at the middle and upper points of the support post 1, a horizontal element 2, which serves as a transverse element and is attached with its base end to the upper girth 7, of the reinforcing element 2e, attached to the horizontal element 2 at its distant point and the outer surface of the upper part of the support column 1, the second horizontal element 4a, serving as a transverse element and connected to the middle girth 7 in the direction perpendicular to the horizontal the horizontal element 2, and the metal parts 13, 13 fixed respectively at the distant ends of the horizontal elements 2 and 4a.

 The frame depicted in Fig. 40 and the construction of which is described above when describing the prefabricated scaffolding shown in Fig. 69 consists of two support posts 1, 1, a balustrade 2 'attached to the support posts 1, 1, a horizontal element 4 serving as a transverse element and connected to the average girth 7 of one rack 1, and a metal part 15, mounted on the distal end of the horizontal element 4b.

 In the frame shown in Fig. 41 and which is a modification of the frame shown in Fig. 39, the ring coupling 14 is mounted rotatably on the support column 1 in the immediate vicinity of the middle girth 7, the horizontal element 4a is connected to the coupling 14 and the metal part 14a is fixed at the distal end of the horizontal element 4a.

 The support racks of the frames depicted in Figs. 42 - 46 belong to one group and have in common that both support racks 1, 1 are installed vertically and parallel to each other. In these drawings, it is not shown that the cross member is connected to the upper or lower girth 7 of one support post 1. In some cases, each of these support posts can be used separately in the end part of the prefabricated scaffolds without using any transverse member.

 The frame shown in Fig. 42 consists of two parallel support posts 1, 1 and a balustrade 2 'attached to the upper girths 7, 7 of the support posts 1, 1. The transverse element is detachably connected to one of two or both - the upper and lower - girths 7, 7.

 In the frame shown in Fig. 43 (A) and which is a modification of the frame shown in Fig. 42, the second balustrade 2 'is attached to the supporting posts 1, 1. Similarly, in the frame shown in Fig. 43 (B) and is a modification of the frame shown in FIG. 43 (A), the inclined element is attached to the support posts 1, 1. Similarly, in the frame shown in Fig. 44 and which is a modification of the frame shown in Fig. 43 (A), skirting board 8 is attached to the middle girths 7, 7. Similarly, in the frame shown in Fig. 45 and which is a modification of the frame shown in Fig. 44, the corrugated reinforcing element 35 is attached to one balustrade 2 'and the baseboard 8.

 In the frame shown in Fig. 46 and which is a modification of the frame shown in Fig. 42, a cruciform connection 26 is included between the support posts 1, 1.

 The frames shown in FIG. 47 and 48, belong to the same group and have in common that the transverse element is detachably connected to the support column.

 More specifically, the frame depicted in Fig. 47, consists of a support column 1, equipped with two - upper and lower - girths 7, 7 and a composite transverse element X, and the transverse element X consists of two horizontal elements 2, 2, serving as balustrades, one skirting board 8 and one inclined element 23. The base ends of the transverse element X are connected detachably with the girths 7, 7 of the support column 1 using metal parts 13 and 8a, which are mounted respectively at the distal end of one horizontal element 2 and the distant end of the plinth sa 8.

 In the frame shown in Fig. 48, as in the frame shown in Fig. 47, the composite transverse element Y consists of two horizontal elements 2, 2 serving as balustrades, and a V-shaped reinforcing element 24 connected to the horizontal elements 2, 2, the transverse element Y being detachably connected to the girths 7, 7 of the support column 1 by means of metal parts 13 and 25, which are fixed respectively at the distal end of one horizontal element 2 and the distal end of the amplifying element 24.

 The frames shown in Figs. 49 and 50 belong to one group and have in common that the transverse elements are fixed on opposite sides to a support post.

 The frame shown in Fig. 49 consists of a support post 1, girths 7, 7, mounted respectively at the upper and middle points of the support post 1, V-shaped frames 2D, 2D, serving as transverse elements and located opposite to the support post 1, metal part 13, which serves as a connector and mounted on the distal end of one of the V-shaped frames 2D to ensure compliance with the average girth 7, and a metal part 13a, which serves as the third connecting support element and mounted on the distal end of the second V-shaped ama 2D ensuring compliance with the metal part 13.

 The reinforcing horizontal element M, passing through the center of the V-shaped frames 2D, is connected to the average girth 7.

 In the frame shown in Fig. 50, two support posts 1, 1 are connected by two middle horizontal elements Q, a frame 2F serving as a transverse member and including horizontal elements and a vertical member is connected to one support pillar 1, and the other frame 2F of the same type as the first frame is connected to another support column 1. Next, the metal parts 13 are fixed at the distal ends of one frame 2A, the metal parts 13a corresponding to the metal parts 13 and each being a horizontal bar are fixed to the remote at the ends of the second frame 2F.

 On Fig shows another example of a frame, which consists of two support pillars 1, 1, two balustrades 2, 2 attached to two support pillars 1, 1, two girths attached to one support pillar, and metal parts 13, 13 fixed on the surface areas of the other support pillar 1, ensuring compliance with the girths 7, 7.

 In the frame shown in FIG. 52, the V-shaped frame 2b serving as the transverse member is connected to the support post 1, the other V-shaped frame L4 is connected to the support post 1 in a direction perpendicular to the V-shaped frame 2b, and metal parts 13 are fixed respectively at the distal ends of the frames 2b and L4.

 FIG. 53 represents the upper part of the support post 1. At the upper end of the support post 1, a sleeve portion 1a of a smaller diameter is formed for insertion into another support post.

 On Fig-58 presents examples of girths.

 The girth 7 shown in FIG. 54 (A) and (B), is a central disk 7a with an annular hook 7b formed along the outer periphery of the disk 7a. Through the central hole, the girth 7 is set and fixed on the support post 1.

 The girth 7 shown in Figs. 55 (A) and (B) is a disk 7a with eight mounting holes made in a circle in the disk 7a.

 The girth 7 shown in Figs. 56 (A) and (B) is a body 7d with eyes made in the body 7d in four directions spaced 90 degrees apart and with fixing holes 7g in the eyes 7e.

 Girth 7, shown in Fig. 57, has sockets 7f of a U-shaped profile, made on the outer periphery of the support column 1 and spaced in four directions with a step of 90 degrees. The base ends of the sockets 7f are W-welded to the support post 1.

 The girth depicted in FIG. 58 allows rotation held by two upper and lower support rings 123, 123 attached to the outer periphery of the support column 1, whereby the transverse member attached to the girth 7 also allows rotation in any direction.

 FIG. 59 is a further embodiment of a transverse member with a connector. In this embodiment, the clamp K is fixed at the distal end of the horizontal element 2a. The clamp K, which serves as a connector, consists of two clamping parts K1 and K2 and a bolt BT for tightening the clamping parts. Using the clamp K, they connect to another support stand, etc.

 FIG. 63 (A) and (B) represent scaffolding assembled from the same type of frames according to the present invention.

 Referred to as 3C, the frame is shown in FIG. 25, and a plurality of frames 3C are assembled in the vertical and transverse directions. In the vertical direction, the upper and lower support posts 1, 1 are connected to one another, while the frames 3C, 3C, adjacent in the transverse direction, are connected by attaching a metal part 13 at the distal end of the frame element 2C of one support post 1 to the upper girth 7 of the other support racks 1. For example, in the case when the outer wall of the building being erected is curved and the prefabricated scaffold Z must be installed along the outer surface, the installation angle of the metal part 13 on the frame element 2C relative to the circumference 7 etsya. The floorboards 125 are laid along the assembled scaffolding Z. In this case, the frame elements are not only balustrades, but also serve as reinforcing ties in an oblique direction.

 FIG. 64 represents prefabricated scaffolding installed using the frame of FIG. 32. They are essentially similar to the prefabricated scaffolding shown in Fig. 60, which were described above.

 More specifically, the frames 3A shown in FIG. 32 are assembled longitudinally and transversely to install two rows of front and rear frames X, Y, floorboards 5 are laid transversely between the front and rear frames.

 A large number of frames 3A are connected longitudinally, for example, by connecting the support post 1 of the right frame with metal parts 13, 13 of the left frame. On the other hand, frames 3A mounted on one another are connected by inserting the upper end of the lower support post 1 into the lower end of the upper support post 1. This connection is made using the sleeve portion 1a shown in FIG. 53.

 Between the two rows of front and rear frames X, Y, horizontal elements are included for reinforcing the frames, and the end parts of each floorboard 5 are engaged with adjacent horizontal elements to secure the floorboard.

 The above-mentioned horizontal elements and balustrades 50 are attached to the left ends of two rows of front and rear frames X, Y, and the same is done between the right ends of the frames.

 In accordance with the present invention, when installing prefabricated scaffolding around a building under construction, it is first necessary to determine the appropriate width of each floorboard 5, then lay the floorboards of the found width between the frames 3A ', 3A', adjusting the width of each floorboard in the corners of the building being erected, and then install other frames 3A, 3A transversely, matching with frames 3A ', 3A', in the construction of L-shaped scaffolding. As a result of this, the stability of prefabricated scaffolding as an integral structure with transverse loads will increase, since they are given an L-shaped outline.

 In this embodiment, each frame 3A ′, matched in width with each floorboard 5 in each corner, is shorter in transverse dimension than each frame 3A, as shown in this drawing.

 When the frames 3A are installed sequentially in the transverse direction, their total length can be matched with the width of the side facade of the building being erected.

 The following point should be noted in connection with the prefabricated forests described above. Frames X and Y can be easily installed by assembling a large number of frames 3A longitudinally and transversely. In addition, when after completing the installation of frames X and U with the assembly of frames 3A on the lower tier, the same frames 3A still have to be installed one after the other on the installed lower frames, and the workers are already working on the floorboards 5 laid on the lower tier, then there is a need to create railings on floorboards using horizontal elements P and 2A1. In other words, installation work can be performed without the use of a safety rope. Further, after the scaffolding is completed, the inclined elements R work as reinforcing ligaments.

 In FIG. 65 shows prefabricated scaffolds mounted by assembling frames similar to the frame shown in FIG. 40, longitudinally and transversely. They are essentially similar to the forests depicted in FIG. 40. More specifically, the frames X and Y are mounted in two rows, front and rear, and floorboards 5 are laid between the frames X and Y so that they are joined in the transverse direction. Next to the end parts of the frames X and Y are attached a balustrade 50 and a large reinforcing element 51.

 When the X and Y frames are installed in the transverse direction, the right and left support posts 1, 1, mounted side by side, are connected with connectors designed to connect the respective girths 7, 7, and the support posts 1, 1, mounted on top of one another, are connected using the sleeve part 1a as described above.

 Frames X and Y, installed in two rows - front and rear, are connected using horizontal elements 4b, 4b connected to the support posts 1, and the end parts of the floorboards 5 are engaged with horizontal elements 4b, 4b. Additionally, in this case, it is possible to arrange the front and rear rows X and Y by assembling a large number of frames 3 in the vertical and transverse directions. Further, even if the frames 3 are still installed one after the other on the upper tier, the worker can already be on the lower floor 5, of course, with the balustrade 2 'fixed, and work in safety.

 In FIG. 66 depicts a structure assembled in the form of scaffolding or a support of frames 3C, essentially similar to the frame shown in FIG. 19 and selected as an example. More specifically, a large number of supports J are installed on the ground, they are interconnected and reinforced by connecting elements J1. The standard frames N are mounted on the supports J, and the plurality of frames 3C according to the present invention are mounted horizontally and vertically on the frames N. Next, the plurality of upper frames N are mounted on the frames 3C in steps or horizontally, and the upper supports J2 are fixed on the upper frames N so that it was possible to change their height. Each of the supports J2 consists of a bearing part 130, a screw connected to the base of the bearing part 130, a girth 133 connected by a thread to the intermediate part of the screw for rotation, and a nut with a handle 132 connected by a thread to the bottom of the screw. The screw is threaded to the support column by means of a nut with a handle 132. The stepwise installation of the upper frames N is due to the inclination at the outer surface of the building S. The support rods M, which allow elongation and shortening, are used in the frames N located at the top. Each of the support rods M is attached at its ends to the girths of 133 of the supports J2. Since the supports J and J2 are used, the girths 133 are connected to the end parts of the screws 131, in addition, the connecting element J1 or the support rod M is attached to the girths 133, so that it is possible to provide support for local loads. In this case, each of the frames 3C works simultaneously as a balustrade and as a connection.

 FIG. 67 (A) and (B) represent a fixed support, rectangular in plan, mounted by assembling a large number of frames similar to the frame shown in FIG. 17, in the directions from front to back, from right to left and from bottom to top. In the same figures, frames adjacent in the transverse direction are connected together using metal parts of the left frame and the girths 7 on the support post 1 of the right frame, and thus a large number of frames are connected in series in the transverse direction. The support posts 1, 1, adjacent in the vertical direction, are connected by inserting the lower end of the upper support post to the upper end of the lower support post 1.

 The upper end of the support under consideration supports the structure S through supports J, bearing parts 130 and lags 52, as in the case of the support shown in Fig.66.

 FIG. 68 (A) and (B) represent a mobile support of a rectangular shape in plan, mounted by assembling the same frames as those mentioned above, from front to back, right to left, and from bottom to top. Frames 53 and rollers 54 are installed at the bottom of the support, allowing the support to be moved to the desired position. The remaining structural characteristics are similar to those for the support depicted in Fig.67.

 FIG. 69 (A) and (B) represent a support mounted from the above frames. This support consists of four blocks: Z1, Z2, Z3 and Z4. Each block contains a large number of frames assembled vertically, and also the frames are installed on the front, rear, right and left sides, forming a rectangular cross section. Then, the front, rear, right and left individual blocks Z1, Z2, Z3 and Z4 thus assembled are built up and connected together using horizontal elements 55 to create a support, generally representing a rectangular tower. The connection of adjacent frames in the transverse and vertical directions is performed by the same mounting methods as described for the support shown in FIG. 67 and 68. The structure being erected is supported by supports J, logs 52 and support elements 56, as described above.

 70 (A) and (B) represent a single-tier support truss assembled from frames 3B shown in FIG. A large number of such frames 3B are assembled together to create a triangular truss.

 FIG. 71 (A) and (B) represent a two-tier support truss mounted from the above-mentioned frames 3B by assembling in the transverse direction and building up the second tier. Rectangular trusses are made from a large number of such frames.

 FIG. 72 is a support truss in accordance with yet another embodiment of the present invention, which is generally angled and mounted using an additional member 57 at the apex of the corner; for comparison, the support truss depicted in FIG. 70 is straightforward as a whole. Other technical characteristics are similar to those for the support truss depicted in Fig.70.

 FIG. 73 is a three-dimensional diagram of the support truss of FIG. 70. In this drawing, the support frames 3B are shown assembled in a three-dimensional structure. More specifically, the frames T of the supporting truss, each of which is assembled from the frames 3B in the transverse direction, are arranged in two rows, front and rear, and connected to each other using horizontal elements 58 attached to the girths 7. When necessary, the floorboards 5a or the reinforcing bars are fixed with end hooks to the front and rear frames T using the support posts 1. Other technical characteristics are similar to those for the support truss shown in Fig. 70.

 FIG. 74 to 82 represent reinforcing elements used in prefabricated scaffolds, supports, and support trusses in accordance with the present invention.

 More specifically, FIG. 74 (A) shows a balustrade 50 described in connection with the precast scaffolding shown in FIG. 64. The balustrade 50 consists of a horizontal element, a U-shaped reinforcing element and metal parts 13, fixed at the wrong ends of the horizontal element.

 FIG. 74 (B) represents another balustrade 50, consisting of three horizontal elements, two vertical elements, each of which serves to connect the end parts of the horizontal elements with each other, and four metal parts 13 fixed at both ends of the upper and lower horizontal elements. These balustrades are used in the same way as the balustrades 50 shown in Fig. 74 (A).

 FIG. 75 (A) represents an reinforcing or auxiliary support post 1A with girths 7, 7 that are attached at the mid and upper points of the support post 1A. For example, in the prefabricated scaffolds A shown in Fig. 60, if the total length of the frames 3, assembled in the transverse direction, is too large, then the support post 1A is used as reinforcing in the end part of the scaffolds A instead of the frame 3. In Fig. 75 ( C) also shows the reinforcing or auxiliary support rack 1A with several metal parts 13, mounted on the side surface of the support rack 1A. The support rack 1A is installed in a row with the frames and is attached to the frames using metal parts 13.

 FIG. 76 is a connector used during installation. For example, in the prefabricated scaffolding shown in Fig. 65, the connector in question is used to connect the girths 7, 7 of the adjacent - right and left - racks 1, 1 to each other. This connector consists of brackets 59, 59 and wedges 60, 60, which are inserted into the holes in the brackets. Next, the brackets 59, 59 are inserted into the perforated girths 7, 7 and then the wedges 60, 60 are inserted into the combined holes of the brackets 59, 59 and girths 7, 7.

 FIG. 77 and 78 represent horizontal elements or reinforcing elements as transverse elements. The horizontal element shown in FIG. 77, refers to the type of immutable and consists of a pipe 60 and metal parts 13, 13, fixed at both ends of the pipe 60. These metal parts 13, 13 are detachably connected to the girths 7, 7 of the support posts. The horizontal element depicted in Fig. 78 consists of a pipe 60A allowing elongation and shortening, since this pipe consists of an outer pipe and an inner pipe, with metal parts 13, 13 secured to both ends of the pipe 60A.

 FIG. 79 - 82 represent π-shaped auxiliary elements for connecting the support posts, each of the auxiliary elements being attached to adjacent support posts, such as, for example, in the prefabricated scaffolding shown in Fig. 65, or in some support. The auxiliary element shown in FIG. 19, consists of a horizontal pipe 61, metal parts 13, 13 mounted on the pipe 61 on both sides, two support legs 62, 62 extending from the end parts of this pipe, and metal parts fixed on the side surface of the lower ends of the support legs 62, 62. This auxiliary element is installed between the support posts 1, 1 of adjacent frames, and the upper and lower metal parts 13 are attached to the support posts.

 In the auxiliary element shown in Fig. 80, which is essentially similar to the auxiliary element shown in Fig. 79, the upper ends of the support legs 62, 62 are rotatably and detachably connected to the pipe 61. In the auxiliary element shown in Fig. 81 and which is a modification of the auxiliary element shown in Fig. 79, the support legs 62 are made longer, the auxiliary metal parts 13 are fixed at the midpoints of the support legs, and the upper ends of the support legs 62, 62 are detachably connected with the bottom of the pipe 61 using fingers and staples.

 The auxiliary element shown in Fig. 82 and essentially similar to the auxiliary elements shown in Figs. 79 - 81 consists of a truss 63, which is a rigid horizontal element and also serves as a supporting truss, two support legs 62, 62, coming from the bottom of the truss 63 , metal parts 13, 13, fixed at both ends of the truss 63, and metal parts 13, 13, fixed at the middle and lower points of each support leg 62. In the case when the precast scaffold or support has large dimensions and the distance between adjacent support legs 1, 1 large, p the assembled element is attached to adjacent racks using metal parts 13. In this case, under the truss 63, a wide passage is formed for the movement of workers and mechanisms.

 Fig. 83 is another embodiment of a horizontal element or reinforcing element serving as a transverse element, which consists of two or more horizontal or inclined elements 2H, 2H, a metal part 13, rotatably connected to the base ends of horizontal or inclined elements 2H, and metal parts 13, 13, mounted at opposite ends of horizontal or inclined elements. Therefore, the transverse element in question can be connected to the support column 1 not only horizontally, but also obliquely.

 The following objectives are achieved in the implementation of the present invention.

 (1) Since each of the frames defined by the formula includes a support post, first and second connecting support members fixed to the support post, a cross member and a connector fixed to the transverse member, a plurality of such frames can be assembled using these components in the vertical and transverse directions in a single unit or attached to another structure in a very simple way, allowing you to create a variety of combinations. In other words, there is no need to use a variety of frames to create a variety of designs, and, therefore, the claimed frames are positively distinguished by their versatility and simplified assembly technology.

 (2) A transverse member and a connector located at a distant end of the transverse member are fixed to the support post, so there is no need to prepare any connecting member for the support post. Additionally, even after completion of the assembly of the support posts, any of the support posts can be removed for replacement without dismantling the connector. Further, by connecting the transverse element to the corresponding support column directly or selectively with the first or second connecting support element, frames mounted at the same level or at different levels corresponding to the fixing points of each transverse element can be mated.

 (3) Since the first connecting support member is fixed at the midpoint of the support post, it is possible to connect the support post and the reinforcing frame using the named connecting support member and thereby prevent the support post from bending. In addition, since the first and second connecting support elements are fixed at the midpoint and the upper or lower point of the support column, it is possible to collect scaffolds at a height corresponding to the height of the selected first or second connecting support element. In particular, when the scaffold flooring is fixed with the first connecting support element fixed at the midpoint, it is possible to arrange the flooring above the balustrade.

 (4) Further, when constructing scaffolding, a support or a supporting truss with the use of frames having support legs and transverse elements, each transverse element being both a connecting element and reinforcing connection, since the transverse element is fixed on each support column, there is no need to use connections .

Claims (6)

 1. A frame including a support post (1); a first connecting element comprising a girth (7) welded to the middle of the support post (1); a second connecting element comprising a girth (7) welded to the upper part of the support post (1); a transverse element including a frame (2A), mounted on the side of the support column (1); and connectors including metal parts (13) mounted on the outer end of the frame (2A) in a vertical position relative to the girths (7), respectively; said frame (2A) is assembled from a horizontal element (P), the base end of which is connected to the specified upper girth (7), a vertical element (Q), which is simultaneously attached to the end part of the horizontal element (P), and the diagonal element (R), which is simultaneously attached to the lower end of the vertical element (Q) and to the lower part of the support post (1), so that the trapezoidal frame in the frontal projection is formed by the specified support post (1) and the specified frame (2A).  2. The frame according to claim 1, in which the horizontal reinforcing element (2A1) or a plurality of horizontal reinforcing elements (2A1), (2A2) are placed between the support column (1) and the vertical element (Q).  3. The frame according to claim 1, in which one reinforcing horizontal element (2A1) is placed between the support column (1) and the vertical element (Q), and another reinforcing horizontal element (2A2) is placed between the girth (7) welded to the middle of the support racks (1), and a vertical element (Q).  4. The frame according to claim 1, in which the horizontal element (2a) is laid between the girth (7) welded to the middle of the support post (1) and the vertical element (Q), and the diagonal element (2j) is placed between the horizontal element for reinforcement (2a) and the horizontal element (P).  5. A frame including: a support stand (1); the first connecting supporting element, the second connecting supporting element and the third connecting supporting element, each of which includes girths (7) welded to the middle of the supporting column (1), to its upper part and lower part, respectively; a transverse element including a frame (L4), the end of the base of which is fixed on the side of the support post (1) through the upper girth (7) and the lower girth (7); connectors comprising metal parts (13) mounted on the outer end of the frame (L4) in a vertical position relative to the girths (7), respectively; a reinforcing element including a horizontal frame (L3) located between the middle part of the frame (L4) and the average girth (7) of the support column (1); and diagonal elements, including a pair of upper and lower elements (2b), laid between the middle part of the frame (L4) and the upper and lower girths (7).  6. Frame, including: a support rack (1); a first connecting support member including a girth (7) welded to the middle of the support post (1); a second connecting support element, including a girth (7), welded to the upper part of the support column (1); a transverse element including a horizontal element (2k), the base end of which is mounted on the upper girth (7); a transverse element, including a horizontal element (2k), the base end of which is fixed on the average girth (7); connectors comprising metal parts (13) mounted on the outer ends of the horizontal elements (2k), (2k) in a vertical position corresponding to the upper object (7) and the average girth (7), respectively; and elements (2L), which are diagonal elements mounted in a diagonal direction between each of the horizontal elements (2k) and the side of the support post (1).

Images