RU134959U1 - FITTING FOR MOUNTING OF SUPPORT ROD ELEMENTS AND FRAMES IN CARRYING FRAMEWORK CONSTRUCTIONS - Google Patents

Abstract

1. A device for mounting supporting rod elements and frames in load-bearing frame structures, characterized in that it is made in the form of a removable universal support unit, which consists of a removable seat and a removable shoe, while the shoe is rigidly fixed to the supporting end of the rod element for installation time installed in the saddle, which is rigidly fixed to the support during installation; wherein the shoe contains two vertical side walls parallel to each other and one front wall perpendicular to the side, these walls form a segment of a U-shaped profile, and at least one of these walls has at least one hole for the fastener in its upper part as well as two cylindrical clamps that are mounted externally on the same axis on two side walls of the shoe at the lower edge of the front wall of the shoe; wherein the saddle contains a supporting U-shaped plate, and in the specified plate there is at least one hole for the mounting element, as well as two vertical parallel side guide walls with locking lower and upper protrusions and with, as shown in figb guides, preferably inclined slots for cylindrical shoe fixers; moreover, the saddle, depending on the final location of the rod element relative to the edges of the abutment surface and the lifting direction, is preferably provided with one front corner, or one side corner, or two side corners, or one front corner and one side corner or one front corner and two side corners , and each corner contains

Description

The technical field to which the utility model belongs.

The utility model relates to the field of construction, to devices for mounting supporting rod elements and frames in supporting frame structures, and can be used, for example, in the construction of frame buildings and structures, frame superstructures to buildings and structures, warehouse hangars, in particular hangars, equipped with lifting equipment.

The objective of the proposed technical solution is the development of a sufficiently light and durable device for the installation of supporting rod elements (OSE) and frames in the supporting frame structures, which, while maintaining the existing level of technology:

- the possibility of safe installation and dismantling of the OSE and frames with a minimum number of personnel and equipment, up to the possibility of mounting and dismantling the OSE and frames by one installer without the use of crane equipment, for example, using a conventional winch;

- the possibility of choosing the optimal ratio of the accuracy of mounting the OSE and frames, the speed of installation and dismantling, as well as the number of installers and the cost of installation and dismantling for work without the use of crane equipment;

- the possibility of saving money, materials and installation time of OSE and frames through the use of local lumber;

provides achievement of new opportunities:

1. saving money and materials during the installation of OSE and frames due to the repeated use of the device;

2. the possibility of using devices with different dimensions of the OSE sections and frames;

3. simplification of installation on any desired section of the supporting surface, including, for example, mounting the OSE and frames close to the edges of the timber base;

4. reducing the cost of funds, materials and time for thermal insulation by eliminating cold bridges.

The level of technology.

From the existing level of technology, the authors know only one device that is successfully used for the safe installation and dismantling of prefabricated transverse frame elements, for example, frames in supporting frame structures with a minimum of personnel and equipment, up to the possibility of mounting and dismounting by one installer without the use of crane equipment, for example, using a conventional winch.

Known PM FRAME DESIGN (OPTIONS) which describes:

OPTION 1. FRAME STRUCTURE, characterized in that it consists of several prefabricated transverse frame elements (PEC), each of which is installed in a vertical plane on the foundation or foundation posts, piles or lower or upper strapping or on another fixed support, fixed on the support , is connected by longitudinal rectilinear rod elements with the nearest PEC, and consists of supporting nodes and either one bearing rod curvilinear element, both ends of the rod element being supporting and each the second of them is connected to one support node, or from at least two bearing rod elements, the adjacent ends of the bearing rod elements being rigidly interconnected by any known method, the two extreme bearing rod elements being support and each supporting extreme bearing rod element connected to one reference node; wherein each of the support nodes consists of a saddle and a shoe, each shoe being rigidly fixed to the supporting end of the supporting rod element, mounted and rigidly fixed in the saddle, which is rigidly fixed to the support; each shoe contains a bottom and four walls forming a segment of a rectangular pipe with a bottom located at the bottom of the pipe perpendicular to the walls, two cylindrical clamps that are installed externally on two side opposite walls of the shoe on one axis close to the bottom of the shoe and to the front wall of the shoe ; each saddle contains a bottom with holes for fasteners and / or pre-installed fasteners for fastening to a support, a rear wall, a support bar, two side walls with fixing ears and made as shown in the drawing (figa of the specified patent) or (figb specified patent), guide slots for the cylindrical clamps of the shoe; there are at least one hole in the rear wall of the shoe and in the rear wall of the saddle and / or at least one hole in each side wall of the shoe and in each side wall of the saddle, and the holes are made so that after installation of the PEC in a vertical plane on the support, in each support node, the fastening element, passing through the coaxial holes, fastens simultaneously the supporting end of the rod element, shoe and saddle. (19) RU (11) 119766 (13) U1 (51) IPC [E04B 1/24 (2006.01)] Posted: 08.27.2012

OPTION 2: FRAME STRUCTURE, characterized in that it consists of a frame structure, characterized in that it consists of several prefabricated transverse frame elements (PEC). each of which is mounted in a vertical plane on the foundation or foundation pillars, piles or lower or upper strapping or on another fixed support, fixed on the support, connected by longitudinal rectilinear rod elements to the nearest PEC, and consists of supporting nodes and of at least one corner connector and from at least two supporting rod elements, moreover, the pairs of adjacent ends of the bearing rod elements are rigidly interconnected by means of corner connectors, and the two extreme bearing st rzhnevyh and support element are each support rod extreme bearing element is connected with one support node; in this case, geometrically each angular connector that provides a pair of adjacent ends of the rod elements to each other consists of two receiving elbows connected at an angle of 5 to 175 (relative to each other, and the elbow of each angular connector is made of pipe or assembled from plates and has a rectangular or a circular cross-section; in this case, each of the support nodes consists of a saddle and a shoe, while each shoe is rigidly fixed to the supporting end of the supporting rod element, mounted and rigidly fixed in the saddle, the cat The frame is rigidly fixed to the support; each shoe contains a bottom and four walls forming a segment of a rectangular pipe with a bottom located perpendicular to the walls at the bottom of the pipe, two cylindrical clamps that are installed externally on two opposite side walls of the shoe on one axis close to the bottom shoe and to the front wall of the shoe; each seat contains a bottom with holes for fasteners and / or pre-installed fasteners for mounting to a support, a rear wall, a support bar, two sides walls with fixing ears and with guide slots for cylindrical shoe fixers, as shown in the drawing (Fig. 1a) or (Fig. 16); there are at least one hole in the rear wall of the shoe and in the rear wall of the saddle and / or at least one hole in each side wall of the shoe and in each side wall of the saddle, and the holes are made so that after installation of the PEC in a vertical plane on the support, in each support node, the fastening element, passing through the coaxial holes, fastens simultaneously the supporting end of the rod element, shoe and saddle. (19) RU (11) 119766 (13) U1 (51) IPC [E04B 1/24 (2006.01)] Posted: 08.27.2012

Thus, the existing PM FRAME DESIGN (OPTIONS) is characterized, inter alia, by the fact that both options include support nodes. Each of these nodes consists of a saddle and a shoe, while each shoe is rigidly fixed to the supporting end of the supporting rod element, mounted and rigidly fixed in the saddle, which is rigidly fixed to the support; each shoe contains a bottom and four walls forming a segment of a rectangular pipe with a bottom located at the bottom end of the pipe perpendicular to the walls, two cylindrical clamps that are installed externally on two side opposite walls of the shoe on one axis close to the bottom of the shoe and to the front wall of the shoe ; each saddle contains a bottom with holes for fasteners and / or pre-installed fasteners for fastening to a support, a rear wall, a support bar, two side walls with fixing ears and made as shown in the drawing (figa of the specified patent) or drawing (figb specified patent), the guide slots for the cylindrical clamps of the shoe; at the same time, there are at least one hole in the rear wall of the shoe and in the rear wall of the saddle and / or at least one hole in each side wall of the shoe and in each side wall of the saddle, and the holes are made so that after installing the OSE and / or frames in a vertical plane on the support, in each support node, the fastening element, passing through the coaxial holes, fastens simultaneously the supporting end of the rod element, shoe and saddle.

The use of support nodes of this design really provides:

- the possibility of safe installation and dismantling of the OSE and frames with a minimum number of personnel and equipment, up to the possibility of mounting and dismantling the OSE and frames by one installer without the use of crane equipment, for example, using a conventional winch;

- the possibility of choosing the optimal ratio of the accuracy of mounting the OSE and frames, the speed of installation and dismantling, as well as the number of installers and the cost of installation and dismantling for work without the use of crane equipment;

- the possibility of saving money, materials and installation time of OSE and frames through the use of local lumber;

However, from the point of view of the technical problem posed, a significant drawback of the known utility model is that the support nodes in the form of saddles and shoes, used as part of this known design, do not allow to provide:

1. saving money and materials during the installation of OSE and frames due to the repeated use of the OS of known design, due to the fact that saddles and shoes of known design are not removable.

2. the possibility of using saddles and shoes of known design with different dimensions of the cross-section of the OSE and frames;

3. simplification of installation on any desired portion of the supporting surface, including, for example, mounting the OSE and frames close to the edges of the beam base, due to the lack of the possibility of fitting the known structure to the seat location;

4. reducing the cost of funds, materials and time for thermal insulation by eliminating cold bridges due to the fact that saddles and shoes of known design are not removable.

So, for example, for the installation of a hangar structure consisting of 10 prefabricated wooden frames assembled from a timber with a section of 200 × 200 on a timber base of the same section, 10 * 2 = 20 support nodes (OS) of a known design are required. Each of the well-known DTs in the assembly weighs about 8 kg, consists of a saddle and a shoe, and requires time, requires material costs, the cost of manufacturing DT, and the cost of delivering all DT to the facility. In addition, the well-known DTs are not intended for repeated reuse without dismantling the entire hangar, since these DTs are not removable. At the same time, mounting the frames close to the edge of the base, for example, to the edge of the beam base, is either impossible, since this does not allow the construction of the known saddle, or requires special solutions and additional parts and, accordingly, the time and money spent on their manufacture and delivery to the object slows down construction.

Thus, these 20 (twenty) known op-amps are non-removable and

1. in aggregate, they have a mass an order of magnitude greater than the solutions proposed for protection,

2. In total, for the facility as a whole, they cost an order of magnitude more than the solution proposed for protection,

3. collectively for the facility as a whole require additional shipping costs

4. being non-removable, these support nodes, in the most common case made of metal, inevitably form unremovable cold bridges, requiring additional technical solutions and the expense of funds and time for their thermal insulation

Moreover, the number of OS made in the form of saddles and shoes of known design cannot be reduced, since after installation it is not possible to reuse known fixed seats and shoes without dismantling the erected supporting frame. In cases of regular construction of various frame structures consisting of OSE and / or frames, as a result of the application of the device proposed for protection, the cost of the solution in the form of a removable universal OS will be much lower. This is because the cost of the claimed device, usually used in the amount of 2 pieces for the entire object, consisting of several OSE and / or frames, is divided by a value close to half the number of all OSE of all frames of all constructed objects. We also note that the bridge of cold after dismantling the inventive device disappears.

Thus, in the current level of technology, the authors have not found other designs that can fully solve the problem of the proposed technical solution.

Disclosure of a utility model.

The objective of the proposed technical solution is to develop a sufficiently light and durable device for mounting the OSE and frames in the supporting frame structures, which, while maintaining the existing level of technology:

- the possibility of safe installation and dismantling of the OSE and frames with a minimum number of personnel and equipment, up to the possibility of mounting and dismantling the OSE and frames by one installer without the use of crane equipment, for example, using a conventional winch;

- the possibility of choosing the optimal ratio of the accuracy of mounting the OSE and frames, the speed of installation and dismantling, as well as the number of installers and the cost of installation and dismantling for work without the use of crane equipment;

- the possibility of saving money, materials and installation time of OSE and frames through the use of local lumber;

provides achievement of new opportunities:

1. saving money and materials during the installation of OSE and frames due to the repeated use of the device;

2. the possibility of using devices with different dimensions of the OSE sections and frames;

3. simplification of installation on any desired section of the supporting surface, including, for example, mounting the OSE and frames close to the edges of the timber base;

4. reducing the cost of funds, materials and time for thermal insulation by eliminating cold bridges.

The technical result is that the implementation of the claimed utility model ensures the implementation of a sufficiently lightweight and durable device for mounting the OSE and frames in the supporting frame structures, which, while maintaining the existing level of technology:

- the possibility of safe installation and dismantling of the OSE and frames with a minimum number of personnel and equipment, up to the possibility of mounting and dismantling the OSE and frames by one installer without the use of crane equipment, for example, using a conventional winch;

- the possibility of choosing the optimal ratio of the accuracy of mounting the OSE and frames, the speed of installation and dismantling, as well as the number of installers and the cost of installation and dismantling for work without the use of crane equipment;

- the possibility of saving money, materials and installation time of OSE and frames through the use of local lumber;

provides achievement of new opportunities:

1. saving money and materials during the installation of OSE and frames due to the repeated use of the device;

2. the possibility of using devices with different dimensions of the OSE sections and frames;

3. simplification of installation on any desired section of the supporting surface, including, for example, mounting the OSE and frames close to the edges of the timber base;

4. reducing the cost of funds, materials and time for thermal insulation by eliminating cold bridges.

This technical result is very relevant, since non-removable supporting saddles and shoes pass from the category of consumable materials and structural components to the category of reusable removable devices, and therefore become a simple, practical, widely used and economical device for installation. The result is especially relevant for the installation of powerful load-bearing frame structures in the case of the impossibility of using crane equipment, in the conditions of a lack of manpower, in the impossibility of transferring large bearing frames with an abundance of powerful and heavy OSE and / or frames of many-kilogram batches of non-removable support nodes to the area of the proposed construction, as well as in regions with climatic and other natural conditions that further complicate the installation and operation of known load-bearing frame structures.

The receipt of this technical result is ensured by the following implementation of the design of the device. The protected utility model is a DEVICE FOR THE INSTALLATION OF SUPPORT ROD ELEMENTS AND FRAMES IN CARRYING FRAMEWORK DESIGNS in the form of a universal removable support unit. The specified node is used for sequential installation of the OSE and frames in the supporting frame structures. It can be used as one universal removable op-amp, for example, for lifting individual racks, or several universal removable op-amps at the same time, for example, for lifting pre-assembled in a horizontal position frames. After lifting with the help of the protected devices of the separate support rod or the whole frame to the vertical position and carrying out the final fixing of the support rod or the whole frame, for example, by means of slopes, the protected devices are dismantled and ready for further repeated use.

In the main embodiment, the protected device is made in the form of a removable universal support unit, which consists of a removable saddle and a removable shoe, while the shoe is rigidly fixed to the supporting end of the rod element for the time of installation, installed in the saddle, which is rigidly fixed to the support during installation; wherein the shoe contains two vertical side walls parallel to each other and one front wall perpendicular to the side, these walls form a segment of a U-shaped profile, and at least one of these walls has at least one hole for the fastener in its upper part as well as two cylindrical clamps that are mounted externally on the same axis on two side walls of the shoe at the lower edge of the front wall of the shoe;

while the saddle contains

supporting U-shaped plate, and in the specified plate there is at least one hole for the mounting element,

as well as two vertical parallel lateral guide walls with locking lower and upper protrusions and made, as shown in Fig.2b, guides, preferably inclined, slots for the cylindrical clamps of the shoe;

moreover, the saddle, depending on the final location of the rod element relative to the edges of the abutment surface and the lifting direction, is preferably provided with one front corner or one side corner or two side corners or one front corner and one side corner or one front corner and two side corners, each the corner contains holes in each of its shelves, and the holes in the horizontal shelves are aligned with the corresponding holes in the supporting U-shaped plate of the saddle.

Now consider additional options for the execution of PM. Such an embodiment is possible in which, for the convenience of installing fasteners, the axis of the holes in the vertical shelves is made intersecting with the axis of the holes in the supporting U-shaped plate of the saddle. The mismatch of the axes of the holes in the vertical shelves with the axes of the holes in the seat plate reduces the likelihood of contact, and hence the breakdown of fasteners, such as screws.

A variant is possible in which a thread is cut inside the hole or holes in the upper part of the shoe for fixing the core element in the shoe with tightening bolts. For more rigid fixation of the core element in the shoe, an embodiment of the design is possible in which the shoe is provided with an external patch bracket that is superimposed externally on the core element from the side parallel to the front wall of the shoe, and the front wall of the shoe is bonded to the core element and with said strip at least at least one, preferably through, fastening element. For even more rigid fixation of the core element in the shoe, an embodiment of the design is possible in which the shoe is provided with an external patch bracket that is applied externally to the side walls of the shoe and the core element in such a way that coverage of the core element from 4 sides is achieved, with an external patch the mounting bracket is made of a segment of a U-shaped profile with slit-like slots and / or holes for fasteners made in the side walls of the bracket, and the slots in the bracket are aligned yuschim slot-shaped slits and / or holes, wherein said bracket is formed so as to completely eliminate its contact with the seat during mounting. Moreover, the use of any or several of the three abovementioned versions at once, using the appropriate fasteners of the required length, which ensures tightening and fixing the OSE and / or frames in the shoe (s), makes it easier to fit the shoe under the OSE and / or frames of both rectangular and circular cross-section, as well as fitting shoes under the OSE and / or frames of different sections and different dimensions, for example, fitting under the OSE from round logs of different sections and diameters.

An embodiment of the device is possible, in which the diameters of the holes in the walls of the saddle are increased by at least 1 mm compared to the diameter of the fastener.

This option facilitates the dismantling and installation using fasteners made of materials whose temperature coefficient of expansion differs from the temperature coefficient of expansion of the protected op-amp, thus eliminating jamming of the fasteners in the op-amp.

An embodiment of the device is also possible, in which, to guarantee achievement of the working gap, the distance between the inner planes of the side walls of the saddle exceeds the distance between the outer planes of the side walls of the shoe by at least 1 mm. In the two above-mentioned versions, the necessary working gaps through facilitating the mating between the saddle and the shoe and the increased diameter of the holes for the fasteners significantly simplify installation in conditions where the process of pairing the shoe and the saddle, as well as the process of installing the OSE fasteners through the holes in the shoe, is difficult, for example during installation in severe climatic conditions, as well as during installation in low light conditions.

For installation in conditions where the OSE mass exceeds 100 kg, it is preferable to use such an embodiment of the PM in which the diameter of the cylindrical clamps is not less than twice the wall thickness of the shoe and not less than 10 mm.

The inventive PM is preferably made of metal or high-strength plastic or composite materials. Embodiments are also possible in which the shoes, seats and corners are made, in particular, of galvanized steel, from steel with a paint or powder coating, from stainless steel, from cast iron, from aluminum or from alloys containing aluminum.

One of the preferred applications for PM is the installation of separate wooden OSE. Another preferred application of PM is the installation of wooden whole, pre-assembled, for example, from two OSE and one transverse core element, frames on a wooden base.

Consider, as an example, the use of a protected device when installing prefabricated wooden frames on a base of timber. First, saddles are mounted on the support using fasteners, so that their U-shaped supporting surfaces lie in one horizontal plane. In this case, each saddle is attached to the support either directly through the mounting holes in the U-shaped plate or through the corner / corners, which are mounted directly on the support using one of the methods described below for installing the saddle on the supporting surface.

Moreover, the saddle, depending on the site of the OSE, is preferably equipped with one front corner or one side corner or two side corners or one front corner and one side corner or one front corner and two side corners, each corner containing holes in each of its shelves moreover, the holes in the horizontal shelves are aligned with the corresponding holes in the support U-shaped plate. When mounting frames, shoes are fixed at the lower ends of the OSE frame using fasteners on a support or on any horizontal surface, for example, on the ground.

Then, from a horizontal position, the entire frame is mounted in a vertical plane by turning around the cylindrical clips of the shoes in the respective saddles, using, for example, a conventional hand winch, preferably with a falling boom. To raise the entire frame to the vertical plane, the winch cable is attached to the upper part of the entire frame at least at two points selected in such a way as to avoid possible skewing of the frame. A falling arrow is mounted in a vertical plane, so that the cable from the winch passes through the top of the falling arrow. Then the winch gently lifts the whole frame in a vertical plane. Moreover, the design of saddles with locking side walls and guides, preferably inclined, slots and paired saddles of shoes with cylindrical clamps, makes it possible and safe to lift the forces of one installer OSE and / or frames through rotation about an axis passing through the clamps of the shoes. After installing the frame in a vertical plane , each OSE frame is fixed in a vertical position, for example by mowing, and all removable op-amps are dismantled. Removal of each removable op-amp is to remove fasteners from the saddle a, shoe, corners and removing all OS from all OSE installed frame. After that, using the same set of removable op-amps, the next frame is mounted and so on until the complete installation of the supporting frame. For sequential installation of additional individual supports sequentially used a single removable op-amp.

The claimed design makes it possible before lifting the frames to fix the shoes in the saddles without additional fasteners; and also makes it possible to safely raise and lower each frame by one installer using a winch through rotation about an axis passing through the shoe latches perpendicular to the plane of rotation of the OSE frames. The inventive design eliminates the possibility of accidental exit of the shoes from the seats and the possibility of any individual OSE or the entire frame falling when lifting and installing each individual OSE or frame in a vertical plane with subsequent fixing by fixing elements. The inventive design excludes the possibility of accidentally leaving the shoes from the seats and the possibility of any individual falling OSE or the entire frame when lowering each individual OSE or the entire frame to a horizontal plane when dismantling or reinstalling the supporting structure .

The technical result provided by the given set of features in the claimed PM is the creation of a sufficiently light and durable device for mounting the OSE and frames in the supporting frame structures, which, while maintaining the existing level of technology:

- the possibility of safe installation and dismantling of the OSE and frames with a minimum number of personnel and equipment, up to the possibility of mounting and dismantling the OSE and frames by one installer without the use of crane equipment, for example, using a conventional winch;

- the possibility of choosing the optimal ratio of the accuracy of mounting the OSE and frames, the speed of installation and dismantling, as well as the number of installers and the cost of installation and dismantling for work without the use of crane equipment;

- the possibility of saving money, materials and installation time of OSE and frames through the use of local lumber;

provides achievement of new opportunities:

1. saving money and materials during the installation of OSE and frames due to the repeated use of the device;

2. the possibility of using devices with different dimensions of the OSE sections and frames;

3. simplification of installation on any desired section of the supporting surface, including, for example, mounting the OSE and frames close to the edges of the timber base;

4. reducing the cost of funds, materials and time for thermal insulation by eliminating cold bridges.

A brief description of the drawings.

The essence of the utility model is illustrated by the following drawings, which do not cover and, moreover, do not limit the entire scope of the claims of this technical solution, but are only illustrative materials of a particular case of execution:

figa Shoe with cylindrical retainers and holes for fasteners, view 1.

figb Shoe with cylindrical retainers and holes for fasteners, view 2.

figa Saddle with guides, preferably inclined, slots for the cylindrical clamps of the shoe, fixing the upper and lower protrusions and holes for fasteners, view 1.

figb Saddle with guides, preferably inclined, slots for the cylindrical clamps of the shoe, fixing the upper and lower protrusions and holes for fasteners, view 2.

figa Shoe assembly with an external patch mounting bracket.

figb Shoe assembly with an external invoice mounting bracket fixed to the OSE.

Fig.3v Shoe assembly with an external overhead mounting bracket and with slit-like slots for fasteners mounted on the OSE (side fasteners not shown).

Fig. 3 g. The shoe assembly with an external overhead mounting bracket and with holes for fasteners is mounted on the OSE (side fasteners are not shown).

figa Mounting saddles on a plane

figb, 4c, 4g, 4d, 4e Various, depending on the installation location of the OSE and / or frames, methods of fastening the saddle to the base (beam) using angles and fasteners.

figa Prepared for installation of the OSE with a shoe mounted on the supporting end of the OSE using fasteners, and a saddle mounted on the support bar using angles and fasteners.

figb Start installation of the shoe in the saddle. Shoe latches are inserted into the corresponding inclined guide slots of the saddle.

figv Start lifting OSE in a vertical plane. Shoe latches slip until the front wall of the shoe and the U-shaped base plate of the saddle come in contact with the fasteners.

5 g Rise OSE in a vertical plane. The intermediate position of the OSE with the shoe in the saddle, the shoe latches are in the inclined guide slots of the saddle in the lower positions.

figd Completion of the ascent. OSE is installed in a vertical plane.

5e. Installed in the vertical plane of the OSE is fixed with a jib.

5g. The start of dismantling the shoe and saddle. The fasteners securing the shoe to the OSE and the saddle to the support beam are removed. figs. Shoe and saddle are completely dismantled.

Implementation of a utility model.

THE DEVICE FOR INSTALLATION OF SUPPORT ROD ELEMENTS AND FRAMES IN THE BEARING FRAMEWORK STRUCTURES is performed in the form of a removable universal support unit, which consists of a removable saddle and a removable shoe, while the shoe is rigidly fixed to the supporting end of the rod element for the installation time the mounting is rigidly fixed to the support; wherein the shoe (figa, figb) contains two vertical side walls parallel to each other (2) and one front wall perpendicular to the side wall (1), these walls form a segment of a U-shaped profile, at least in one of these walls in its upper part there is at least one hole (4) for the fastener, as well as two cylindrical clamps (3), which are mounted externally on the same axis on two side walls of the shoe at the lower edge of the front wall of the shoe; wherein the saddle (figa, fig.2b) contains a support U-shaped plate (5), and in the specified plate there is at least one hole (8) for the mounting element, as well as two vertical parallel lateral guide walls ( 10) with fixing lower (6) and upper (7) protrusions and with guides, preferably inclined, cuts (9) for cylindrical clamps (3) of the shoe, made as shown in figa and fig.2b; moreover, the seat, depending on the installation location of the supporting rod element, is preferably provided (figa, figb) with one front corner or one side corner or two side corners or one front corner and one side corner or one front corner and two side corners and each corner contains holes in each of its shelves, and the holes (12) in the horizontal shelves (14) correspond to the holes (8) in the support U-shaped plate of the saddle. The axis of the holes (13) in the vertical shelves (11) is preferably intersected with the axes of the holes (8) in the support U-shaped plate of the saddle.

The implementation of the removable universal support node begins with the fact that with the help of fasteners at the end of the OSE, the shoe is fixed. If necessary, more rigid fixation of the shoe on the OSE can be used external patch bracket (figv, 3 g), imposed externally on the rod element from the side parallel to the front wall of the shoe, and the front wall of the shoe is bonded to the rod element and with the specified strip, at least one, preferably through, fastening element. If necessary, even more rigid fixation of the shoe on the OSE can be used external patch mounting bracket (fig.3d, 3e), superimposed externally on the side walls of the shoe and the rod element so that coverage of the rod element is achieved from 4 sides, and the external invoice the mounting bracket is made of a segment of a U-shaped profile with slit-like slots (Fig.3d) and / or holes (Fig.3e) for fasteners made in the side walls of the bracket, and the slots and / or holes in the bracket are aligned with the corresponding opening tiyam in the walls of the shoe. Preferably, the specified bracket was made in such a way as to ensure the complete exclusion of its contact with the seat during installation.

Then, a saddle is mounted on the supporting surface using fasteners, for example, as shown in FIGS. 4a, 4b, 4c, 4e, 4e. A shoe is attached to the lower end of the support rod by fasteners, as shown in FIG. 5a. Consider the methods and procedures for assembling and installing the inventive device. The mounting methods of the saddle on the supporting surface may differ depending on the final location of the supporting rod element relative to the edges of the supporting surface and the lifting direction:

1. When mounting away from the edges of the supporting bearing plane for any direction of lifting of the supporting rod element, the saddle is mounted without angles, for example, as shown in figa.

2. When mounting at two parallel edges of the supporting bearing plane when lifting the supporting rod element in a plane parallel to the specified edges, the saddle is installed with two side corners, for example, as shown in figb.

3. When mounting at three edges of the supporting bearing plane, for example, in the end of the beam, when lifting the supporting rod element in a plane perpendicular to the end edge, the saddle is installed with one front corner and two side corners, for example, as shown in figv.

4. When mounting at one edge of the supporting bearing plane when lifting the supporting rod element in a plane perpendicular to the specified edge, the saddle is installed with one front corner, for example, as shown in Fig.4 g.

5. When mounting at two perpendicular edges of the supporting bearing plane (in the corner) when lifting the supporting rod element in a plane perpendicular to the selected one, the saddle is installed with one front corner at the selected edge and one side corner, for example, as shown in FIG. 4d

6. When mounting at one edge of the supporting bearing plane when lifting the supporting rod element in a plane parallel to the specified edge, the saddle is installed with one side angle, for example, as shown in fig.4e.

7. In special cases, for example, when mounting the saddle at an angle to the edges of the supporting surface, one of the above methods of mounting the saddle can be selected locally, while mounting each or some of the desired angles using only one mounting hole is permissible.

The installation of the shoe on the end of the OSE is carried out in a known manner by tightening and fixing the OSE in the shoe using conventional fasteners. Depending on the size of the section and the shape of the OSE, sealing inserts and / or external patch strips or staples with slots and / or holes for fasteners can be additionally used.

Next, we consider the installation of supporting rod elements in a specific example of a frame structure consisting of several identical frames. Let each of the frames is formed of 3 rod wooden rectilinear elements of rectangular cross section, with two of these rod elements being support. Let two protected devices in the form of universal removable support nodes, each of which consists of a shoe and a saddle, be installed at the ends of the indicated OSE. The installation of the frames begins with the fact that two steel saddles (Fig. 2a) are rigidly fixed to the support using various methods of installing the saddles (Fig. 4a, 4b, 4c, 4g, 4e, 4e) depending on the final position of the frame OSE relative to the edges supporting surface and lifting directions (listed above). After assembling the frame near the already installed saddles, a pair of steel shoes are put on and rigidly fastened to the lower ends of the supporting rods of the frame (Fig. 5a) using known methods for installing the shoe depending on the cross-sectional size and the shape of the OSE of the installed frame.

Installation of construction begins with the installation of the first frame. On figa shows the lower part of the frame - shoe assembly with OS. made of rectangular timber, lying near the saddle mounted and fixed on the support. The assembled first frame with two OSEs is placed with the shoes in the corresponding saddles in the position shown in Fig.5b, while the cylindrical clamps (3) of the shoes (Fig.1a) are placed in the fixing slots (9) of the seats (Fig.2a).

The lower locking protrusions of the seats (6) do not allow the shoes to move along the axis of the cylindrical retainers (3) relative to the seats. Thus, all the shoes of the OSE of the first frame are fixed in the initial position in the corresponding saddles of this frame and the frame is ready for safe lifting for installation in a vertical plane. Further, from a horizontal position, the first frame is installed in a vertical plane by turning around the cylindrical clamps of the shoes in the respective saddles, using, for example, a winch or winch and a tipping rack. Figs 5c, 5g, 5e show the rotation of a fragment of one OSE frame with a clockwise lift direction. On figv shows the beginning of the rise of the OSE fragment. The shoes of both OSE frames are in the saddles. As the winch cable is tensioned, the cylindrical lock of each shoe (3) moves along its fixing slot (9), passing through it until it stops. The rise of both OSEs and, thus, of the entire frame to the vertical plane begins. At the end of the lifting frame (fig.5d) OSE frames with their end parts stand on the bearing surface. The tension of the winch cable does not allow the frame to tip over against the lifting direction, and the upper locking tabs (7) of the seats and the clamps (3) of the shoes do not allow the frame to tip over in the direction of lifting.

The supporting rods of the frame in an upright position are fixed on the supporting surface in any known manner, for example by means of slopes (Fig. 5e), thereby eliminating the possibility of the frame falling. Thus, during installation, the following are saved:

- the possibility of safe installation and dismantling of the OSE and / or frames with a minimum number of personnel and equipment up to the possibility of mounting and dismantling the OSE and / or frames by one installer without the use of crane equipment, for example, using a conventional winch;

- the possibility of choosing the optimal ratio of the accuracy of installation of the OSE and / or frames, the speed of installation and dismantling, as well as the number of installers and the cost of installation and dismantling for work without the use of crane equipment;

- the possibility of saving money, materials and installation time of OSE and / or frames through the use of local lumber

After that, the fasteners (Fig. 5g) connecting the shoes with the OSE and the fasteners (Fig. 5g) connecting the saddles and corners with the supporting surface are removed. The installation of the first frame on this is completed. Each device in the form of a universal removable op-amp, consisting of a shoe and a saddle, is completely dismantled (Fig.5z) and all devices are transferred to the mounting area of the OSE of the next frame. Thus, the use of a protected device during installation ensures the achievement of new features:

1. saving money and materials during the installation of OSE and frames due to the repeated use of the device;

2. the possibility of using devices with different dimensions of the OSE sections and frames;

3. simplification of installation on any desired section of the supporting surface, including, for example, mounting the OSE and frames close to the edges of the timber base;

4. reducing the cost of funds, materials and time for thermal insulation by eliminating cold bridges.

We have shown how the set technical task is solved with the help of the protected device.

Claims (15)

1. A device for mounting supporting rod elements and frames in load-bearing frame structures, characterized in that it is made in the form of a removable universal support unit, which consists of a removable seat and a removable shoe, while the shoe is rigidly fixed to the supporting end of the rod element for installation time installed in the saddle, which is rigidly fixed to the support during installation; wherein the shoe contains two vertical side walls parallel to each other and one front wall perpendicular to the side, these walls form a segment of a U-shaped profile, and at least one of these walls has at least one hole for the fastener in its upper part as well as two cylindrical clamps that are mounted externally on the same axis on two side walls of the shoe at the lower edge of the front wall of the shoe; wherein the saddle contains a supporting U-shaped plate, and in the specified plate there is at least one hole for the mounting element, as well as two vertical parallel side guide walls with locking lower and upper protrusions and with, as shown in figb guides, preferably inclined slots for cylindrical shoe fixers; moreover, the saddle, depending on the final location of the rod element relative to the edges of the abutment surface and the lifting direction, is preferably provided with one front corner, or one side corner, or two side corners, or one front corner and one side corner, or one front corner and two side corners moreover, each corner contains holes in each of its shelves, and holes in the horizontal shelves of the corners of the pine with corresponding holes in the supporting U-shaped plate of the saddle. 2. The design according to claim 1, characterized in that the axis of the holes in the vertical shelves of the corners of the saddle are made intersecting with the axis of the holes in the supporting U-shaped plate of the saddle. 3. The construction according to claim 1, characterized in that a thread is cut inside the hole or holes in the upper part of the shoe for fixing the core element in the shoe with tightening bolts. 4. The construction according to claim 1, characterized in that the shoe is provided with an external patch mounting plate, which is superimposed externally on the core element from a side parallel to the front wall of the shoe, wherein the front wall of the shoe is bonded to the core element and to said strip at least one preferably a through fastener. 5. The construction according to claim 1, characterized in that the shoe is provided with an external patch bracket that is superimposed externally on the side walls of the shoe and the rod element in such a way that coverage of the rod element from 4 sides is achieved, and the outer patch bracket is made of cut P- shaped profile with slit-like slots and / or holes for fasteners made in the side walls of the bracket, and the slots and / or holes in the bracket are aligned with the corresponding holes in the walls of the shoe, and the specified bracket in polyene so as to allow the complete elimination of its contact with the seat during mounting. 6. The construction according to claim 1, characterized in that the diameters of the holes in the walls of the saddle are increased by at least 1 mm compared to the diameter of the fastener. 7. The construction according to claim 1, characterized in that the distance between the inner planes of the side walls of the saddle exceeds the distance between the outer planes of the side walls of the shoe by at least 1 mm. 8. The design according to claim 1, characterized in that the diameter of the cylindrical clamps is not less than twice the wall thickness of the shoe and not less than 10 mm 9. The construction according to claim 1, characterized in that the shoes and saddles are made of galvanized steel. 10. The construction according to claim 1, characterized in that the shoes and saddles are made of high strength plastic or composite materials. 11. The design according to claim 1, characterized in that the shoes and saddles are made of steel with a paint or powder coating. 12. The design according to claim 1, characterized in that the shoes and saddles are made of stainless steel. 13. The design according to claim 1, characterized in that the shoes and saddles are made of cast iron. 14. The construction according to claim 1, characterized in that the shoes and saddles are made of aluminum. 15. The design according to claim 1, characterized in that the shoes and saddles are made of alloys containing aluminum.

Images