RU2256754C1 - Method for separate cast-in-place building structure erection - Google Patents

Abstract

FIELD: construction, particularly for erecting frame or frameless cast-in-place structures, particularly to construct low-story buildings and buildings in the case of limited capacity of building equipment usage.

SUBSTANCE: method involves forming cavity by fixing retained form members with the use of knock-down form so that retained form members are arranged on inner surfaces of knock-down form panels; strutting off opposite retained form members by stay rods having stops; connecting opposite knock-down form panels with each other with the use of fastening members which pass through members of retained and knock-down forms; pouring concrete mix in layers; grouting stay rods in wall and demounting knock-down form after concrete layer hardening. To perform above method at least 4 rows of orifices are formed in knock-down form panels, retained form panels comprise at least 2 rows of orifices formed so that the orifices are located in apexes of rectangles identical for forms of both types and for any two pairs of the nearest orifices of adjacent rows. Horizontal row of knock-down form panels is installed on lower hardened wall layer or on a base and retained form is installed along with air-tightly connecting adjacent members thereof. Then retained form orifices are coaxially aligned with knock-down form ones. Stay rods formed of heat-insulating material and having stop washers on stay rod ends and threaded orifices are installed in the cavities. The threaded orifices are coaxially aligned with knock-down form ones. Threaded sections of fastening members are inserted in end threaded orifices of stay bars through pressing washers and orifices of the forms. Guiding sections are simultaneously seated in knock-down form panel orifices. Pressing washers are located from outer surfaces of knock-down form panels. Both forms are secured by screwing in fastening members and thereby pressing knock-down form panels to retained form members over the full surface thereof along with pressing retained form members to limiting washers. After being demounted knock-down form is moved upwards and new row of form panels is mounted by connecting lower edges thereof to wall with the use of at least two rows of grouted stay rods and fastening members. After that cavities inside upper part of knock-down form are formed once again for pouring next concrete mix portion.

EFFECT: possibility to utilize only friction force appeared due to pressing retained form members to stay rods over their surface by knock-down form panels for retained form fastening during building structure erection; possibility to regulate above force and to substitute some members for simple and light-weight ones (knock-down form), elimination of other members (post), prevention of cold bridges appearance, optimization of building process due to structure member reuse.

12 cl, 17 dwg

Description

The invention relates to the field of construction and can be used in the construction of frame and frameless monolithic structures. It is most appropriate to apply in low-rise, individual construction, as well as where the possibilities of using construction equipment are limited.

Modern walls should have good heat and sound insulation (TZI), high load-bearing capacity, quick-build and a number of other properties at a low cost. The reduction of their final cost is achieved mainly by the use of new materials, their compositions and rational construction methods.

An example of optimization of the construction process is the method of concreting monolithic walls of buildings [1], where a rubberized tape with transverse stiffeners is used as the formwork, which, on the one hand, is an easy and cheap construction and does not require heavy construction equipment, and on the other, a tie The system contains reusable items. But the use of such lightweight formwork in a multiple process with high loads arising from the fact that it is loaded as a cantilever fastened with only one row of screeds, and especially with loads arising during dismantling after hardening of concrete, causes increased wear, loss of functional properties of the formwork and, accordingly, quality of the wall.

Another example of optimization is the method of erecting monolithic walls of buildings [2], in which special anchors are placed in the cavity for pouring concrete, which are then monolithic and then used to fasten the cladding, which excludes the operation of fixing the anchors at the finishing stage. However, this method is applicable only in systems with fixed formwork and requires certain properties from the latter: it must hold anchors, i.e. be strong, and to facilitate the installation of anchors be soft; in addition, the work of placing anchors directly on the construction site during the installation of the wall requires labor and time.

Currently, the use of multilayer, i.e. Composite walls are ubiquitous. The most widespread are systems of monolithic walls with fixed formwork, which after hardening of concrete remains as a constant TZI, which optimizes the construction process, since a separate operation for the installation of TZI is excluded.

Fixed formwork using plates made of materials with TZI properties is known [3], but they require the TZI of the material also the properties inherent to the formwork, namely, a sufficiently high bending and tensile strength, which determines the use of special TZI materials (extrusion or hardened polystyrene foam, cement-bonded particle boards, etc.), for the manufacture of which high-tech and expensive equipment is needed, and, in addition, this limits the use of a wide range of other TZI materials.

Designs are also known [4], where fixed formwork is reinforced with a rigid element at the manufacturing stage, or an additional layer of TZI material is glued onto the fixed formwork. However, this solves the indicated problem only partially and at the same time complicates and increases the cost of the fixed formwork itself.

The system [5] is very rational, where the usual standard formwork is used, and the plates made of TZI material have grooves on the side faces and are fixed with the help of plates, which are installed into the spacers between the formwork screeds and inserted into these grooves during installation. The plates hold the TZI plate subsequently on the wall surface together with the adhesion forces, and are also used in the future for fastening the finishing materials. Similarly, in the method of erecting monolithic insulated walls [6], together with standard formwork, a T-shaped bracket is used, which remains in concrete after pouring the body of the wall and holds the TZI plate subsequently on the wall surface together with adhesion forces, and is then used to fasten the finishing materials. The indicated systems, however, have drawbacks, namely: only plates with a certain elasticity and thickness should be used as the TZI of the material, since this determines their fixation in the design, which makes it impossible to use roll and film, as well as amorphous paste and gel or bulk TZI materials; the protruding parts of the screeds in the standard formwork design after breaking off the latter break off, which requires additional labor costs, and can also damage individual sections of the TZI of the material; these systems also use standard panels of stationary formwork, which are good for continuous and multi-story construction, but are expensive for rental in small-scale construction.

Closest to the proposed one is a method of erecting building structures [7] (prototype), which includes fixing fixed panels of formwork, as well as laying concrete mix in the internal cavity of the formwork, while fixing is carried out using longitudinal and transverse elements made in the form of interconnected forming metal grids, which are placed on the outer surfaces of the formwork panels, connecting opposite grids with spacer elements, and pre-assemble in the end zones of the structure additional longitudinal elements connected by spacer elements, on which the formwork panels are rigidly fixed, in the middle part of the structure, additional spacer rods with two stops at each end are mounted to be placed between each two stoppers of the fixed formwork panels, and opposite metal nets are connected by spacer elements by passing them through the panels formwork and fixing their ends with the possibility of interaction with mesh elements, while using mesh, the size of the transverse electric cops which exceeds the dimensions of formwork panel, and laying of concrete produced in layers, first into the cavity of formwork formed by one row of boards and then into the cavity formed by each subsequent series.

The specified method is also not free from disadvantages, namely:

the formwork is loaded with large vertical loads arising from the weight of the formwork itself and the metal nets hung on it, which makes the formwork heavier and more expensive and does not allow the use of effective TZI materials;

metal grids and additional longitudinal elements (racks) determine the large metal consumption of the structure, and the couplers connecting them form “cold bridges”.

The task of the invention is to unload, i.e. to facilitate and reduce the cost of non-removable formwork, making it possible to use formwork made of materials with increased TZI properties, reduce material consumption and improve thermal insulation in the erected building structure, simplify the construction process.

The technical results of the invention are: the use of only friction forces for fastening the elements of the fixed formwork for the period of construction of the building structure, arising from the pressing of the panels of the removable formwork to the spacer rods immediately over their entire surface, and with the possibility of regulating the generated force; replacing some applied structures (nets) with simpler or lighter ones (removable formwork) and excluding others (racks), eliminating cold bridges, optimizing the construction process by reusing structural elements,

This is achieved by the fact that during the construction of building structures they form a cavity by fixing the elements of the fixed formwork using removable formwork, placing the elements of the fixed formwork on the inner surfaces of the panels of the removable formwork, burst the opposite elements of the fixed formwork with spacer rods with limiters, connect the opposite panels of the removable formwork passing them through the elements of both formwork, lay the concrete mixture in layers, monopolize the spacer rods in the wall and after the concrete layer has hardened, the removable formwork is dismantled, while at least 4 rows are preformed in the removable formwork panels, and at least 2 rows of through holes in the fixed formwork elements, having their axes at the vertices of the rectangles identical for both formwork and for any two pairs of nearest openings from adjacent rows, install a horizontal row of panels of removable formwork on the underlying hardened wall layer or base, then install a fixed formwork, hermetically connecting its adjacent elements entom, and, locating its holes coaxially with the holes of the removable formwork, install spacer rods made of heat-insulating material in the cavity space with thrust washers fixed at their ends and with threaded holes made on the side of the ends, also arranging these holes coaxially with the holes of the removable formwork, threaded sections of fasteners are inserted into the end threaded holes of the spacer rods through the clamping washers and the holes in the formwork, while their mounting of the avalanching sections into the openings of the panels of removable formwork, while holding the clamping washers on the outer sides of the panels of removable formwork, fix both formwork simultaneously by screwing the fastening elements and thereby pressing the panels of the removable formwork to the elements of the fixed formwork over their entire surface, while simultaneously pressing the elements of the fixed formwork to restrictive washers, after dismantling the removable formwork, it is moved up and a new row of panels is mounted, fixing their lower part on the wall with the help of at least two rows of monolithic p bearing rods and fasteners, and then, using a new group of fixed formwork elements, again create cavities inside the upper part of the removable formwork for laying the next volume of concrete mix.

Using spacer rods with ends cantilever beyond the restrictive washers and having a length not exceeding the thickness of the fixed formwork element, the opposite elements of the fixed formwork are first combined into blocks by inserting the ends of the spacer rods in their holes, and then the fixed formwork is installed in blocks.

When performing expansion rods with through holes, elongated rods are used as fasteners, passed through these holes and both pairs of formwork elements and having at least one threaded section with a nut screwed onto it to fix the formwork, and the holes in the rods are sealed after dismantling the removable formwork.

Using spacer rods having ends with holes and an external thread, cantilever protruding beyond the limit washers, and with a length exceeding the thickness of the fixed formwork element, the opposite elements of the fixed formwork are combined into blocks by inserting the ends of the spacer rods into their holes directly during installation on the underlying layer, then alternately opposing panels of removable formwork are installed, passing the ends of all the necessary spacer rods into their holes at the same time, including the lower part - omonol They are fixed in the wall, and the formwork is fixed by screwing nuts with washers onto the external thread of the cantilever ends of the spacer rods.

Making holes in the ends of the spacer rods smooth, use self-tapping screws as fasteners.

Using spacer rods having cantilever ends on only one side, mount the panels of the removable formwork, first place the elements of fixed formwork on one side of the wall, install the spacer rods, then, on the other side of the wall, first install the elements of the permanent formwork, and then the panels of the removable formwork and fix the formwork with fasteners.

Using thin film as one non-removable formwork on one or both sides of the wall, it is glued to the panels of the removable formwork, positioning its holes coaxially with the holes of the removable formwork, using a low-adhesion gel, for example, solid oil or petroleum jelly, after which alternately opposite panels of the removable formwork are installed, and after dismantling the removable formwork, additional TZI plates or mats are hung on the ends of the spacer rods protruding from the wall, which can subsequently facilitate the repair of insulation.

When using detachable spacer rods from the parts of the same name and the element of the permanent formwork, a semi-block is assembled, install it in the upper part of the shield of the removable formwork, then using other parts of the same name of the detachable spacer rods, the second half block is assembled, install it on the top of the other shield of the removable formwork why both panels of the removable formwork are simultaneously mounted on the underlying layer of the wall, installing them in a V-shape from its two sides, and gradually bringing their upper parts together, they are first passed into their holes the ends of the spacer rods protruding from the wall, and then alternately connect the detachable spacer rods, after which the formwork is fixed.

To create large-volume cavities, two or more horizontal rows of removable formwork are installed at the same time, fastening the boards adjacent horizontally and vertically with an additional board installed overlapping at the junction, using elongated fasteners to fasten the main and additional boards with an expansion rod.

Using the methods of fastening formwork described in this invention when erecting a building structure, spacer rods that are monolithic in the wall are used to fasten scaffolding and auxiliary racks, and after erecting a building structure, they are used to fasten linings or battens, which simultaneously additionally fix fixed formwork.

The lining can be fixed with the formation of a gap between it and the fixed formwork, and an additional layer of amorphous, loose, pasto- or foam-like, heat-, soundproofing, moisture- or fire-retardant materials is placed in the formed cavity. If a thin-layer film is used as a fixed formwork, the specified additional layer of insulation becomes the main one.

The drawings show:

Figure 1-4 - mounting formwork (cuts).

Figure 5-8 - fastening formwork (sections).

Figures 9-12 are installation diagrams of formwork (sections).

Fig. 13 is a diagram of a mounting of adjacent boards of a removable formwork.

Fig - installation diagram of the shuttering formwork (section).

Fig.17-17 - possible options for fastening the cladding (cuts).

For an illustrative example, we will use: as a shield for removable formwork - a sheet of plywood 1 with five rows of holes 2 drilled in it (Fig. 10) or sheet 3 with four rows - for laying the lower concrete layer (Fig. 9), as a non-removable element formwork - a sheet of expanded polystyrene 4 with three rows of holes 5 drilled in it, with a quarter 6 selected along the perimeter, and also an expansion rod 7 with cantilever ends 8, shown in FIG. 2. Accordingly, the formwork fastening scheme and fasteners 9 according to FIG. 6 are used. To ensure the mobility of the elements of the fixed formwork when installing them on the inner surface of the removable formwork, the diameters of the holes in the fixed formwork 5 should be larger than those in the removable formwork 2. The sheets of polystyrene foam on one side of the wall can have a different thickness than on the other side.

A. The construction of the wall.

On the base plate along the perimeter of the wall, a horizontal platform is prepared. Blocks 10 are assembled from the elements of the fixed formwork 4 using the spacer rods 7, as shown in Fig. 9. For the frame structure, a reinforcing mesh is mounted (not shown in the example).

By installing a horizontal row of panels of removable formwork 3, create a frame of one layer of the wall around its perimeter, at the same time blocks of fixed formwork 10 are mounted inside this frame using fasteners 9 (Fig. 9), forming cavities 11 for laying concrete mix. In the example, inside one layer of removable formwork 3, two layers of fixed formwork are mounted.

Shields of removable formwork 3 are connected end-to-end with an additional shield that overlaps the overlap joint. In this case, the openings of the additional shield and the fastened boards are coaxial and located at the vertices of the rectangle, so that this arrangement of holes and, accordingly, spacer rods extends to the entire surface of the wall without distorting its size. In the corners of the building, as well as at the junction of walls and ceilings, two adjacent panels of the removable formwork are connected by hinges 12, and the sheets of the fixed formwork are molded L-shaped during manufacture or glued on the construction site from flat elements. Some panels of the installed horizontal row of removable formwork are fixed using loops installed under the washers 13 of the fasteners and connected with embedded parts in the base of the wall (not shown in the example).

Adjacent elements of the fixed formwork 4 are connected by combining quarters 6, while the thrust washers 14 of the spacer rods 7, when screwing the fastening elements 9 passing through both formwork into the threaded hole 15 (see Fig. 6), press the sheets of the fixed formwork 4 to the removable 3, in this case, the fixed formwork is uniformly loaded and only in compression, and in the direction of the smallest thickness, and is held in place by friction forces. This also ensures the sealing of the interdeck space, which is facilitated by the placement of holes around the perimeter of the sheets of fixed formwork at the joints through the selected quarter. When using material with a low density or soft material along the horizontal and vertical axis of the holes on the inside, rigid reinforcing gaskets or assemblies of such gaskets can be installed (not shown in the example).

In the prepared cavity 11 lay the concrete mixture. When hardening concrete, fixed formwork 4 seizes with it due to natural adhesion. Spacer rods 16 are monolithic in the wall. After hardening the concrete, the lower layer of the wall 17 is ready. Fixed formwork 4 remains on the laid concrete layer (Fig. 9).

Increase (blocks 10) the next layer of fixed formwork and lay the second layer of concrete mixture (Fig 9). After hardening, the panels of the removable formwork 3 are alternately dismantled, moved one or two steps up and mounted in a new position (Fig. 10). At the same time, the lower part of the shields is fixed on the spacer rods 16 embedded in the wall, and the upper part is fastened together by the spacer rods 7 together with the fixed formwork 4, which allows the cavity 11 to be formed for the next concrete layer (Fig. 10). In this case, the removable formwork 1 is held on the wall due to the friction forces arising from the forces of attraction to the monolithic wall.

Further, the process continues many times until the completion of the wall.

After laying concrete to a height of 80-100 cm (second layer) instead of panels 3, panels of removable formwork with five rows of holes 1 are used (Fig. 10). The remaining spacer rods 16 remaining in the wall are subsequently used for fastening the inner and outer linings 18 (directly or using a battens), FIGS. 15-17. The same rods can be used to hold upright the scaffolds and auxiliary racks resting on the base and serving to facilitate the installation of removable formwork (not shown).

For the erection of a curtain wall, as a fixed formwork, you can use thin-layer insulating material, for example polystyrene foam 19, or rolled polyethylene foam or hardboard, gluing sheets at the joints with adhesive tape or furniture adhesive tape, and use reduced size spacer rods to fasten the formwork (figure 5) without cantilevered protrusions (figure 1).

B. The construction of the floor.

Due to the strict regularity of the location of the holes from the panels of the removable formwork 1, it is possible to assemble a flat horizontal surface of large size, connecting them end to end, and at the joints of four adjacent sheets of overlap with additional shields (Fig. 13). Such a surface, according to the size of the overlap, is assembled using temporary ties and mounted on vertical posts 20 (Fig. 14). Moreover, in places where walls and floors adjoin, articulated panels of removable formwork 12 are used.

The sheets of the fixed formwork 4 are laid exactly according to the size of the overlap and, using shortened spacer rods 21, are fastened to the panels of the removable formwork 1 resting on the vertical posts 20. As a result, a closed sealed cavity 22 is formed, which can be filled with concrete.

But pre-assembled ceiling reinforcement, fastened to embedded parts in the wall (not shown in the drawing).

After pouring and hardening of concrete, the ceiling is ready and the removable formwork 1 can be removed. The shortened spacer rods 21 remaining in the flooring body can be used for fastening the ceiling claddings.

Some other designs and patterns of installation and fastening of formwork and cladding are shown in the drawings. The spacer rod 23 with threaded holes 15 without cantilever ends is shown in figure 1. Spacer rod 7 with cantilever ends 8 is shown in figure 2. Figure 3 shows the spacer rod 24 with a through hole 25, and having a cantilever end 8 only on one side (asymmetric), and its fastening element 26 in the form of an elongated rod. Figure 4 shows the spacer rod 27 with elongated cantilever ends 28 and an external thread 29 at their ends.

FIG. 5 illustrates the formwork attachment scheme with a cantilever spacer rod 23, and FIG. 6 illustrates a formwork rod 7 having cantilever ends 8. FIG. 7 illustrates the formwork fastening structure with a fastener 26 in the form of an elongated rod using an asymmetric spacer rod 24 with a through hole 25 In Fig. 8 formwork is fastened with nuts 30 along the external thread 29 of the spacer rod 27 with elongated cantilever ends 28.

Fig.9 shows a section of a wall with a laid bottom layer of concrete 17 and the installation diagram of the next block 10 of fixed formwork. In figure 10, two layers of concrete are laid in the wall, the shorter panels of the removable formwork 3 are replaced by the usual 1 and moved one step up compared to figure 9. 11 and 12 explain the installation of formwork using a spacer rod 27 with elongated cantilever ends 28. In this figure 11, the opposite elements of fixed formwork 4 are combined into blocks, inserting the ends 28 of the spacer rods 27 into their holes 5, directly during their installation on the underlying layer, then alternately opposite opposite panels of the removable formwork 1 are installed, passing the ends 28 simultaneously into their holes 2 of all the necessary spacer rods 27, including monolithic ones in the wall 16. FIG. 12 shows the assembly diagram of the opal side using a detachable spacer rod 31. In the final step the compound due to the large length of the cantilevered portion ends ganging rods have a mobility that facilitates the connection.

On Fig shows the fastening of four adjacent blocks of removable formwork to create an enlarged cavity for concrete mix or for the floor surface. When installing the bottom row, two adjacent horizontal panels of removable formwork are also fastened together.

In Fig.15 shows the fastening of the cladding 18 without using the crate by directly adjoining to the TZI the wall layer formed by the fixed formwork 4. Fig.16 shows how to fix the cladding with a gap and form a cavity 32 for backfilling or filling it with an additional insulation layer. The size of the cavity 32 is determined by the sleeve 33, and the lining is fastened by the fastening element 9 through the disk washer 34. In FIG. 17, the cavity 35 is larger because the film 36 is used as the initial insulation, and the lining fastening is simpler, since the spacer rods 27 are used with elongated cantilevered ends 28. In this case, solid-state additional fire-resistant or insulating material may be used. They fill the cavity 35, hanging it with sheets with corresponding holes on the ends 28 of the spacer rods protruding from the wall and fixing it on the wall surface with the help of fasteners 9 and cladding 18.

Sources of information

1. USSR author's certificate No. 1680907 of 1991.09.30. The method of concreting monolithic walls of buildings.

2. RF patent No. 2119022 from 1998.09.20. The method of construction of monolithic walls of buildings.

3. Application No. 20011114936 dated 05.27.2003. Fixed formwork and method of its installation. Abstracts of Russian Patent Documents 1994-2003

4. US patent No. 5735093 from 1998.04.07. Concrete formwork with backing plates.

5. US patent No. 6349520 from 2002.02.26. Insulated concrete wall system.

6. US patent No. 6625947 from 2003.09.30. Insulated concrete wall system and method of making same.

7. RF patent No. 2153561 from 2000.07.20. The method of construction of building structures.

Claims (12)

1. The method of construction of insulated building structures, which consists in the fact that they form a cavity by fixing the elements of the fixed formwork using removable formwork, placing the elements of the fixed formwork on the inner surfaces of the panels of the removable formwork, burst the opposite elements of the fixed formwork with spacer rods with limiters, connect the opposite panels of the removable formwork formwork with fasteners by passing them through the elements of both formwork, lay the concrete mixture layer by layer, unify After the hardening of the concrete layer, the rods in the wall dismantle the removable formwork, characterized in that at least 4 rows are preliminarily performed in the panels of the removable formwork and at least 2 rows of through holes in the elements of the fixed formwork, having their axes in the vertices of the rectangles, the same for both formwork and for any two pairs of the nearest openings from adjacent rows, install a horizontal row of panels of removable formwork on the underlying hardened layer of the wall or base, then install a fixed formwork, g Hermetically connecting its adjacent elements and arranging its holes coaxially with the holes of the removable formwork, install expansion rods made of heat-insulating material in the cavities with thrust washers fixed at their ends and with threaded holes made on the side of the ends, also arranging these holes coaxially with the holes of the removable formwork, threaded sections of fasteners are inserted into the end threaded holes of the spacer rods through the clamping washers and the holes in the formwork by fitting the guide sections into the openings of the panels of the removable formwork, while holding the clamping washers on the outer sides of the panels of the removable formwork, fix both formwork simultaneously by screwing the fastening elements and thereby pressing the panels of the removable formwork to the elements of the fixed formwork over their entire surface, while simultaneously pressing the elements of the fixed formwork formwork to the restrictive washers, after dismantling the removable formwork, it is moved up and a new row of panels is mounted, fixing their lower part on the wall with at least two rows in monolithic spacer rods and fasteners, and then, using a new group of fixed formwork elements, cavities are again created inside the upper part of the removable formwork to lay the next volume of concrete mix. 2. The method according to claim 1, characterized in that when creating a cavity from different sides, respectively, use fixed formwork of different thicknesses, including the use of a thin layer film or a multilayer fixed formwork. 3. The method according to claim 2, characterized in that when creating the cavity, the removable formwork is installed in two or more horizontal rows, connecting every three or four adjacent vertically and horizontally of the shield of the removable formwork with an additional shield installed overlapping at the junction, and for fastening shields with a spacer rod using fasteners elongated by the thickness of the shield. 4. The method according to claim 3, characterized in that the end holes in the spacer rods are smooth, and self-tapping screws are used as fasteners. 5. The method according to claim 4, characterized in that fasteners in the form of elongated rods having at least one threaded section with a nut screwed onto it to fasten the formwork are passed through opposite formwork elements and spacer rods with through holes; and after dismantling the removable formwork, the through holes in the middle of the spacer rods are sealed with heat and sound insulation (TZI) material. 6. The method according to claim 5, characterized in that when erecting a building structure, the expansion rods monolithic in the wall are used for fastening scaffolding and auxiliary racks, and after the erection of a building structure, for attaching lining, which simultaneously additionally fix the fixed formwork. 7. The method according to claim 6, characterized in that the lining is fixed, forming a gap between it and the fixed formwork, and an additional layer of amorphous, loose, pasty or foam-like, heat-, soundproofing, moisture- or fire-retardant materials is placed in the formed cavity. 8. The method according to claim 7, characterized in that before installation, the opposite elements of the fixed formwork are combined into blocks by inserting the ends of the spacer rods with threaded holes into their openings, cantilever beyond the restrictive washers and having a length not exceeding the thickness of the fixed formwork element, and then install fixed formwork blocks. 9. The method according to claim 7, characterized in that the elements of the fixed formwork are combined into blocks directly during their installation on the underlying layer, inserting the ends of the spacer rods with external threads having a length exceeding the thickness of the element of the fixed formwork into their holes, alternately opposite shields of removable formwork, passing the ends of all the necessary spacer rods into their holes at the same time, including in the lower part - monolithic in the wall, and the formwork is fixed by screwing nuts with washers onto the external thread to nsolnyh ends of the spacer bars. 10. The method according to claim 9, characterized in that they use detachable spacer rods, from which parts of the same name and element of non-removable formwork are assembled half-block, install it in the upper part of the shield of removable formwork, then, using other parts of the same name of detachable spacer rods, collect the second half-block , install it in the upper part of the other panel of the removable formwork, after which both panels of the removable formwork are simultaneously mounted on the underlying layer of the wall, installing them V-shaped from its two sides and gradually bringing together their upper parts, first, the ends of the spacer rods protruding from the wall are passed into their opening, and then the detachable spacer rods are connected alternately, after which the formwork is fixed. 11. The method according to claim 7, characterized in that, using spacer rods having cantilever ends only on one side, mount the panels of the removable formwork first on one side of the wall, place elements of the fixed formwork on them, install the spacer rods, then on the other side the walls first install the elements of the fixed formwork, and then the panels of the removable formwork and fix the formwork with fasteners. 12. The method according to p. 8, or 10, or 11, characterized in that as a non-removable formwork, a thin-layer film is used, which is installed by sticking on the panels of the removable formwork, positioning its holes coaxially with the holes of the removable formwork, using a low adhesion gel, for example, solidol or petroleum jelly, after which alternately opposite panels of removable formwork are installed, and after dismantling of the removable formwork, additional TZI plates or mats are hung on the ends of the spacer rods protruding from the wall.

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