RU123428U1 - RAPIDLY ASSEMBLY CONSTRUCTIVE STRUCTURE - Google Patents

Abstract

1. A collapsible structure containing a horizontally located supporting metal truss, covered with a ridge and supported at the ends on hollow metal racks, as well as a gable roof made of sheet cellular polycarbonate, at least two sheets of which are fixed on both sides of the truss by means of inclined metal reinforcements cables passed through the holes of the cellular polycarbonate sheets and each fixed with the upper end to the holes of the support truss under the ridge, and the lower end to the ground using a tension anchor, while the reinforcing cables are passed through the holes of the cellular polycarbonate sheets with the possibility of moving the latter along the cables. 2. The structure according to claim 1, characterized in that it is equipped with means for regulating the temperature inside its volume. The structure according to claim 2, characterized in that the temperature control means are made in the form of a longitudinal air duct installed along the truss, a group of pipes laid in the floor and interconnected by collectors connected through hollow struts with a longitudinal air duct. The structure according to claim 3, characterized in that the longitudinal air duct is made in the form of two aluminum corrugated hoses, pipes and headers are made of PVC plastic, and the racks are made of stainless steel. A structure according to any one of claims 3 and 4, characterized in that the longitudinal air duct is made in the form of two aluminum corrugated hoses installed with a slope of 1: 20.6. The structure according to any one of claims 3 and 4, characterized in that the temperature control means are provided with at least one fan installed with the possibility of forced air circulation between the specified duct

Description

The utility model relates to structures designed to create sheltered limited isolated spaces and objects protected from natural climatic factors, for example, greenhouses, shelters, garages, hangars, sports facilities, etc.

Known designs of prefabricated collapsible structures, in particular, greenhouses: RU No. 85298, 93208, 106077, 113633, 2005346, 2021689, 2423821, US No. 2136192, 3461605, 3897622, 4928425, 5519964, 5585418, 6618934, 2009/01 , 2009/0071091, 2011/0183368, GB No. 2262695, 2385612, DE No. 102004004675, 202004000540, FR No. 2540907, 2604860, 2609595, 2738109, 2744159, 2857217, 2902964, CN No. 1922971, 2412368, 2831748 , 201048496, 201443209, 201588319, 201690844, 201718255, 201797808, 201869622, 202035334.

A known greenhouse containing a frame in the form of a series of arcs with a film coating located on them with the formation of the end wall, fastening elements to the frame. The coating is made in the form of panels placed overlapping each other with edges along the frame, and the end wall is equipped with a door frame (SU No. 1782425).

The disadvantage of this greenhouse is the complexity of its assembly, the need for devices to stretch the film over the frame of the greenhouse, the inability to leave the greenhouse for the winter due to cracking of the film from frost, the complexity of the technology of fertilizing the beds inside the already mounted greenhouse.

A known greenhouse containing end walls, frame arcs rigidly bonded to stiffeners, a flexible translucent coating in the form of end sheets fixedly mounted on the frame arches and side sheets, and the frame arcs are rigidly attached to the base and have a profile with one or more longitudinal grooves while two adjacent frame arcs are mounted open grooves towards each other, in which the edges of one sheet or several sheets of translucent coating are laid with the possibility of its sliding along slots. Frame arcs have a profile with two longitudinal grooves open in opposite directions. The edges of two side sheets of translucent coating, lying one above the other, are laid in two open towards each other grooves of two adjacent frame arcs. The length of the rectangular sheet of translucent coating is more than half the length of the frame arc. The side sheets of the translucent coating are overlapped with free edges. The fixing ends of the frame are fixed in the soil with the possibility of extraction or the fixing ends of the frame are permanently fixed in the foundation. A translucent coating can be made of dense plastic sheets or polycarbonate sheets (RU No. 85298).

The disadvantage of this greenhouse is the complexity of its assembly using threaded joints, the need for bending of the coating sheets, the need for manual snow removal, the narrowness of the functional capabilities of the operation. Since polycarbonate has a large coefficient of thermal expansion, with rigid fastening with fasteners (bolts, screws) at large temperature differences, the material experiences heavy loads, up to cutting fasteners. The presence of a large number of fasteners increases the complexity of installation and reduces the strength of the polycarbonate coating and the reliability of the structure.

Also known is a greenhouse, consisting of a solid sheet of honeycomb polycarbonate as a shelter material, characterized in that, as a support frame, inside the parallel plates and through certain partitions between them (i.e., through the honeycombs), yarns are passed at a predetermined interval, the ends of which are fixed at the base of the greenhouse by pulling into the ground. The sides of the greenhouse are fixed by tensioning with each other, a metal or plastic cable, or wire, or a rope, or fishing line, or a hollow plastic tube is used as the threads, and the ends of all the threads on each side of the greenhouse are fixed in a beam that is pressed to the ground tension method. Fasteners in this design are not provided (RU No. 106077, prototype).

The disadvantages of this greenhouse are the complexity of its design due to the need for forced bending of polycarbonate sheets during roof installation, the need for manual snow removal from curved (rounded) polycarbonate sheets, the complexity of disassembling and transporting curved sheets, and the lack of ability to change the position of polycarbonate sheets and, therefore, temperature control.

The technical task of the utility model is to create an effective prefabricated collapsible structure suitable for repeated assembly / disassembly and transportation, and to expand the arsenal of such structures.

The technical result, which provides a solution to the problem, is to simplify the design by eliminating the operations of bending polycarbonate sheets during the manufacture and installation of the roof of the structure, simplifying multiple assembly / disassembling and transportation, while simplifying maintenance by eliminating the need for manual snow removal due to the gable roof providing the possibility of snow sliding under its own weight, as well as in simplifying temperature control by moving sheets of floor carbonate along the ropes.

The drawing of Fig. 1 shows a structural diagram of a quick-assembled collapsible structure using the example of a greenhouse, Fig. 2 is a sectional view of Fig. 1 through air ducts, Fig. 3 is a structural diagram of a quick-built collapsible building using an example of a residential building, garage, hangar in cross section, figure 4 is a view of the floor of the structure of figure 1 with the scheme of laying pipes, figure 5 is a diagram of the installation of racks during the construction of the structure of figure 1, figure 6 is a view 1 of figure 5, Fig.7 is a diagram of the installation of polycarbonate sheets of the greenhouse of Fig.1.

The collapsible structure, in particular, the greenhouse of FIG. 1, contains a horizontally located supporting metal truss 1, covered with a ridge 6 and supported at the ends on hollow metal posts 2, as well as a gable roof made of covering material - sheets 3 of cellular honeycomb polycarbonate. A gable roof is essentially a building structure. At least two sheets 3 are fixed on both sides of the truss 1 by means of inclined metal reinforcing cables 4, passed into the holes of the sheets 3 of honeycomb polycarbonate and each fixed with their upper end to the holes (holes not shown) of the supporting truss 1 under the ridge 6, and the lower end - to the ground using a tension screw anchor 5. In addition, there may be freely overlapped additional sheets of polycarbonate between the sheets 3 fixed by cables 4. In this case, the reinforcing cables 4 are passed into the holes 3 surfers cellular polycarbonate with an opportunity to move past along the ropes 4.

The doorways of the structure can be made in any known manner from standard elements.

The structure is equipped with temperature control means inside its useful disposable volume, i.e. work area 13.

The temperature control means is made in the form of a longitudinal duct 9 installed along the truss 1, a group of pipes 14 laid in the floor and connected by collectors 15 connected through hollow racks 2 with a longitudinal duct 9, and at least one fan (not shown ) installed with the possibility of forced air circulation in the circuit formed by the specified duct 9, posts 2 and pipes 14. In the absence of a fan, duct 9 is installed with a slope of 1:20.

The greenhouse has (may have) an automated control system, for example, the operation of the fan and / or the movement and position of the polycarbonate sheets 3.

The longitudinal duct 9 is preferably made in the form of two aluminum corrugated hoses, the pipes 14 and the collectors 15 are made of PVC plastic, and the posts 2 are made of stainless steel.

Solar energy storage means can be made in the form of a hanging sheet 7 (absorber \ reflector) of blackened aluminum foil or in the form of a mirror hanging sheet (not shown), mounted for rotation to regulate solarization.

The structure is preferably provided with an insulating side wall 10 located along the perimeter of the structure and made along the upper edge with guide grooves (not shown) to move additional polycarbonate sheets located between the sheets 3 fixed by means of reinforcing cables 4.

The gable roof of sheets 3 is made in cross section in the form of an isosceles triangle with an angle at the apex of at least 60 °.

The honeycomb sheets 3 are preferably made with a thickness of 4 or 6 mm.

The construction can be implemented as a building from the group: greenhouse, garage, hangar, warehouse, prefabricated residential building, sports facility.

Prefabricated collapsible structure is used as follows.

To commission a structure, for example, a greenhouse, it is assembled at the place of operation.

At the installation site mark the site, as shown in figure 4. Pipes 14 are laid in the ground for heating the greenhouse floor with warm air. At the ends of the platform, the pipes 14 are combined using collectors 15. Next, screw piles-anchors 5 are installed, racks 2 are installed and fixed with cables 4, as shown in FIG. 5. When installing the racks 2, the holes of the racks 2 are combined with the entrances of the collector 15. After this, the farm 1 is placed in the middle of the platform and the polycarbonate sheets 3 are mounted on it using reinforcing cables 4, as shown in Fig. 7 The upper ends of the reinforcing cables 4 are threaded into the holes at the top of the farm 1 and fix (it is enough to tie 4 knots on the cable). At the lower ends of the cables 4, it is necessary to make similar clamps so that the polycarbonate sheets 3 do not jump out of the holes of the cables 4.

Next, raise the ends of the truss 1 from two sides and install it between the struts, supports 2. Depending on the size of the greenhouse, this procedure is performed manually or using a crane. When lifting the truss 1 it is necessary to take measures to ensure that the lateral joint of the sheets 3, which is provided by standard polycarbonate strips (H-strips), is not disturbed. Fasten and pull all reinforcing cables 4 with the help of lanyards (not shown).

Lastly, air ducts 9 are mounted - aluminum corrugated hoses (Figure 2) at the top of the greenhouse, fixing them to the farm 1. To circulate air in the heating system, you can use fans or create a slope when installing corrugated hoses 1:20 and then natural circulation can work. In order to ensure tightness at the bottom of the greenhouse, an insulating side wall 10 of improvised material is mounted around the perimeter of the structure. In this case, it should be possible to slide freely overlapped additional sheets of polycarbonate along the upper edge of this wall 16 to ventilate the room. It is advisable to close the space between the hull of the greenhouse and the end braces with polycarbonate with cables 4. In this case, vestibules are formed where it is convenient to store tools, fertilizers, finished products, etc.

During the operation of the greenhouse, solar energy is accumulated by the sheet 7, warm air is collected at the top, under the ridge 6 and through the aluminum ducts 9 is pumped by the fan into the pipe system 14, 15 located in the floor of the greenhouse to heat the working area 13.

The air heated by the sheet 7 (heat absorber) rises and heats the air heat exchanger in the form of 2 aluminum corrugated hoses 9, placed under the ridge 6 of the roof. Then, through the hollow racks 2, with the help of the fan (s), air is pumped into the floor heating system of the greenhouse - pipe 14, where excess heat is accumulated.

In winter, heat deficiency is covered by the use of “curtaining” technology, i.e. a slight overlap at a height of 2-3 meters can be created in a greenhouse made of a transparent material, with low thermal conductivity, for example of bubble polyethylene (not shown). In this case, heat loss is reduced by 30%.

As can be seen from Figure 1, the greenhouse has a gable roof. The rolling angle is determined based on the conditions of use of the greenhouse. For example, in the midland of Russia to eliminate problems with snow, this angle should be at least 60 degrees. Cables 4 significantly enhance the strength of the polycarbonate coating. Cables 4 are not inserted into each cell of sheet 3; therefore, the metal consumption of the structure is small, and polycarbonate does not experience large static loads. Given the good heat-insulating properties of cellular polycarbonate, even with a thickness of 4-6 mm, cable reinforcement 4 reduces the cost of shelter several times in comparison with the classic type constructions with powerful power arches and rigid polycarbonate fastening.

The structure can be easily disassembled in the reverse order and packed with minimal dimensions for transportation, since it does not have curved polycarbonate sheets.

This design has several more positive properties. In the proposed design, polycarbonate does not have a single fixing bolt and does not experience thermal stress at all, since it slides along the cables in the vertical direction, in which the temperature coefficient is maximum. In the transverse direction, polycarbonate freely expands in the intercellular space due to the possibility of using cables 4 of small cross section. For example, with a honeycomb size of 4 mm, the cable diameter may be only 1 mm. For joining sheets of 3 polycarbonate to increase the size of the greenhouse, it is advisable to use standard polycarbonate connectors with special slats with grooves (not shown). These connection strips are supplied by polycarbonate manufacturers.

The next important factor is the ability to provide ventilation in the greenhouse. To do this, it is enough to lift the polycarbonate sheet 3 along the 4 cables up and open fresh air from the bottom of the greenhouse from the surrounding area, or vice versa, lower the polycarbonate sheet 3 down. A “window” is formed at the top of the greenhouse. The shift of the polycarbonate sheets 3 is illustrated in FIG. 1, where one sheet is depicted in the “sheet down” position i.e. "window". To reduce air leakage through the junction between the sheet 3 and the wall (fencing 10) of the greenhouse, soft sealing gaskets (not shown) are installed at the junction, preventing the sheet 3 from sliding.

The free sliding of the polycarbonate sheet 3 on the cables 4 provides a minimum of effort for this task due to the low weight of the sheet. The shear process of polycarbonate sheets 3 is easy to mechanize (not shown).

The proposed design provides for the use of solar energy for heating or changing the illumination of the space of the greenhouse. For this purpose, a light metal absorber sheet 7 of solar energy, for example, blackened aluminum foil, is suspended along the axis of the upper truss. To receive heat from the sun, this sheet is covered with black paint on both sides. The length of the sheet 7 is equal to the length of the supporting truss 1, and the width depends on the height of the greenhouse and can be 5-7 meters.

When the greenhouse is located in the north-south direction due to the construction height of several meters (7-9), the absorption of solar energy begins immediately at sunrise, then the solar energy works like in an ordinary greenhouse, and in the afternoon until the sunset, solar energy is also used. In ordinary greenhouses, the sun is used only at elevation angles of the sun above the horizon of 25-35 degrees.

The proposed system provides the use of solar energy much more efficiently. If necessary, this heating system can be used as a mirror to increase solarization. For this, aluminum sheets are used uncoated, polished. By shifting the lower part of the mirror to the sides, you can change the angle of reflection and, accordingly, direct the light flux of the rising or setting sun to the plants.

The greenhouse in cross section is an isosceles triangle of Figs. 1, 2, 3. When using polycarbonate sheets, for example, 12 meters long, the greenhouse has a height of 9 meters. This allows you to place the absorber 7 of solar energy of a large area and thus significantly (up to 80%) to save traditional energy. The length of the greenhouse is not limited and is expanded in sections of 2.1 meters (standard sheet width). In some cases, a complete autonomy of the system is possible without the use of external traditional sources of heat - electricity, hot heat supply, gas boilers, etc.

For example, a greenhouse of 12 meter sheets of 3 polycarbonate with a total area of 100 sq.m. has an absorber of 50 -70 sq.m. This gives about 40 kW of thermal energy, i.e. 0.4 kW per 1 sq. meter of the greenhouse.

It is known that during year-round operation of greenhouses in central Russia, the heat consumption rate is 3 Gcal per 1000 sq.m. the area of the greenhouse per month, or, in terms of capacity for 1 sq. m 12 MJ / 24 hours * 3600 sec = 140 J, or 0.140 kW are required. Thus, the proposed system covers the necessary costs of thermal energy by almost 3 times. Given the seasonal fluctuations in ambient temperature, there may be some excess heat in summer and deficiency in winter, but the temperature of the working fluid (air) does not take extreme values.

The presence of a heat accumulator in the form of a greenhouse floor heated by pipes 14 can reduce the effect of energy fluctuations. Calculations show that for a greenhouse of 100 square meters. m. requires a battery in the form of soil weighing 16 tons, or 160 kg per 1 square. meter. This is a 20 cm thick layer of soil.

In this invention, modern materials are used that provide high strength and durability of the structure. At the same time, the shelter allows you to create the necessary temperature and climatic conditions inside the protected volume.

Structural design in the form of a gable roof from sheets of cellular polycarbonate installed with the possibility of movement provides good thermal insulation, light transmission, strength, and durability. The greenhouse allows you to provide heating with heated air, increase the solarization of plants, accumulate heat, and provide ventilation.

The proposed structure has a simple structure, is convenient in operation and has the following positive qualities:

1. Applied the most modern durable covering translucent material - cellular polycarbonate.

2. The metal consumption of the structure is sharply reduced, which allows the use of corrosion-resistant metals (stainless steel) and ensures the service life of the greenhouse up to 10 years or more.

3. The standard available items are used - stainless pipes, cables, corrugated hoses, PVC pipes.

4. The use of screw piles (anchors 5) ensures the reliability of the design when installed on various soils.

5. The design does not use threaded elements (bolts, screws), which reduces the complexity of installation.

6. The greenhouse has a triangular cross-section with a large slope, which eliminates problems with snow load, does not require bending of polycarbonate sheets.

7. The large height of the greenhouse allows you to place a large area solar absorber in the upper part of the greenhouse, which effectively uses the sun with sunrise and sunset, fully meeting the heat demand.

8. The use of a heat accumulator provides equalization of soil temperature during daytime solar solarization fluctuations.

9. The use of reinforcing cables increases the strength of the structure, does not load polycarbonate, allows you to shift up the polycarbonate sheets and, thus, ventilate the room.

Claims (12)

1. A collapsible structure containing a horizontally located supporting metal truss, covered with a ridge and supported at the ends on hollow metal racks, as well as a gable roof made of sheet honeycomb polycarbonate, at least two sheets of which are fixed on both sides of the truss by means of inclined metal reinforcing ropes passed into the openings of the sheets of cellular polycarbonate and each fixed with its upper end to the holes of the supporting truss under the ridge, and the lower end to the ground using a tension anchor and, while the reinforcing cables are passed into the openings of the sheets of cellular polycarbonate with the possibility of moving the latter along the cables. 2. The structure according to claim 1, characterized in that it is equipped with means for controlling the temperature inside its volume. 3. The construction according to claim 2, characterized in that the temperature control means is made in the form of a longitudinal duct installed along the truss, a group of pipes laid in the floor and connected by collectors connected through hollow racks to the longitudinal duct. 4. The construction according to claim 3, characterized in that the longitudinal duct is made in the form of two aluminum corrugated hoses, pipes and manifolds are made of PVC plastic, and the racks are made of stainless steel. 5. The construction according to any one of paragraphs.3 and 4, characterized in that the longitudinal duct is made in the form of two aluminum corrugated hoses installed with a slope of 1:20. 6. The construction according to any one of paragraphs.3 and 4, characterized in that the temperature control means are equipped with at least one fan installed with the possibility of forced air circulation between the specified duct, racks and pipes. 7. The structure according to claim 2, characterized in that it is equipped with solar energy storage means in the form of a hanging sheet of blackened aluminum foil. 8. The structure according to claim 2, characterized in that it is equipped with means for regulating solarization in the form of a mirror hanging sheet. 9. The structure according to any one of claims 1 to 4, 7 and 8, characterized in that it is equipped with an insulating side wall located along the perimeter of the structure and made with guides for moving polycarbonate sheets located between sheets fixed by means of reinforcing cables. 10. The construction according to any one of claims 1 to 4, 7 and 8, characterized in that the gable roof is made in cross section in the form of an isosceles triangle with an angle at the apex of at least 60 °. 11. The construction according to any one of claims 1 to 4, 7 and 8, characterized in that the sheets of cellular polycarbonate are made with a thickness of 4 or 6 mm. 12. The building according to any one of claims 1 to 4, 7 and 8, characterized in that it is made in the form of a building from the group: greenhouse, garage, hangar, warehouse, residential building, sports facility.